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An FP’s guide to caring for patients with seizure and epilepsy
Managing first-time seizures and epilepsy often requires consultation with a neurologist or epileptologist for diagnosis and subsequent management, including when medical treatment fails or in determining whether patients may benefit from surgery. However, given the high prevalence of epilepsy and even higher incidence of a single seizure, family physicians contribute significantly to the management of these patients. The main issues are managing a first-time seizure, making the diagnosis, establishing a treatment plan, and exploring triggers and mitigating factors.
Seizure vs epilepsy
All patients with epilepsy experience seizures, but not every person who experiences a seizure has (or will develop) epilepsy. Nearly 10% of the population has one seizure during their lifetime,whereas the risk for epilepsy is just 3%.1 Therefore, a first-time seizure may not herald epilepsy, defined as repetitive (≥ 2) unprovoked seizures more than 24 hours apart.2 Seizures can be provoked (acute symptomatic) or unprovoked; a clear distinction between these 2 occurrences—as well as between single and recurrent seizures—is critical for proper management. A close look at the circumstances of a first-time seizure is imperative to define the nature of the event and the possibility of further seizures before devising a treatment plan.
Provoked seizures are due to an acute brain insult such as toxic-metabolic disorders, concussion, alcohol withdrawal, an adverse effect of a medication or its withdrawal, or photic stimulation presumably by disrupting the brain’s metabolic homeostasis or integrity. The key factor is that provoked seizures always happen in close temporal association with an acute insult. A single provoked seizure happens each year in 29 to 39 individuals per 100,000.3 While these seizures typically occur singly, there is a small risk they may recur if the triggering insult persists or repeats.1 Therefore, more than 1 seizure per se may not indicate epilepsy.3
Unprovoked seizures reflect an underlying brain dysfunction. A single unprovoked seizure happens in 23 to 61 individuals per 100,000 per year, often in men in either younger or older age groups.3 Unprovoked seizures may occur only once or may recur (ie, evolve into epilepsy). The latter scenario happens in only about half of cases; the overall risk for a recurrent seizure within 2 years of a first seizure is estimated at 42% (24% to 65%, depending on the etiology and electroencephalogram [EEG] findings).4 More specifically, without treatment the relapse rate will be 36% at 1 year and 47% at 2 years.4 Further, a second unprovoked seizure, if untreated, would increase the risk for third and fourth seizures to 73% and 76%, respectively, within 4 years.3
Evaluating the first-time seizure
Ask the patient or observers about the circumstances of the event to differentiate provoked from unprovoked onset. For one thing, not all “spells” are seizures. The differential diagnoses may include syncope, psychogenic nonepileptic events, drug intoxication or withdrawal, migraine, panic attacks, sleep disorders (parasomnia), transient global amnesia, concussion, and transient ischemic attack. EEG, neuroimaging, and other relevant diagnostic tests often are needed (eg, electrocardiogram/echocardiogram/Holter monitoring to evaluate for syncope/cardiac arrhythmia). Clinically, syncopal episodes tend to be brief with rapid recovery and no confusion, speech problems, aura, or lateralizing signs such as hand posturing or lip smacking that are typical with focal seizures. However, cases of convulsive syncope can be challenging to assess without diagnostic tests.
True convulsive seizures do not have the variability in clinical signs seen with psychogenic nonepileptic events (eg, alternating body parts involved or direction of movements). Transient global amnesia is a rare condition with no established diagnostic test and is considered a diagnosis of exclusion, although bitemporal hyperintensities on magnetic resonance imaging (MRI) may appear 12 to 48 hours after the clinical episode.5 Blood work is needed in patients with medical issues treated with multiple medications to evaluate for metabolic derangements; otherwise, routine blood work provides minimal information in stable patients.
Region-specific causes. Neurocysticercosis is common in some regions, such as Latin America; therefore, attention should be paid to this aspect of patient history.
Continue to: Is it really a first-time seizure?
Is it really a first-time seizure? A “first,” usually dramatic, generalized tonic-clonic seizure that triggers the diagnostic work-up may not be the very first seizure. Evidence suggests that many patients have experienced prior undiagnosed seizures. Subtle prior events often missed include episodes of deja vu, transient feelings of fear or unusual smells, speech difficulties, staring spells, or myoclonic jerks.1 A routine EEG to record epileptiform discharges and a high-resolution brain MRI to rule out any intracranial pathology are indicated. However, if the EEG indicates a primary generalized (as opposed to focal-onset) epilepsy, a brain MRI may not be needed. If a routine EEG is unrevealing, long-term video-EEG monitoring may be needed to detect an abnormality.
Accuracy of EEG and MRI. Following a first unprovoked seizure, routine EEG to detect epileptiform discharges in adults has yielded a sensitivity of 17.3% and specificity of 94.7%. In evaluating children, these values are 57.8% and 69.6%, respectively.6 If results are equivocal, a 24-hour EEG can increase the likelihood of detecting epileptiform discharges to 89% of patients.7 Brain MRI may detect an abnormality in 12% to 14% of patients with newly diagnosed epilepsy, and in up to 80% of those with recurrent seizures.8 In confirming hippocampus sclerosis, MRI has demonstrated a sensitivity of 93% and specificity of 86%.9
When to treat a first-time seizure. Available data and prediction models identify risk factors that would help determine whether to start an antiseizure medication after a first unprovoked seizure:
Epilepsy diagnosis
The International League Against Epilepsy (ILAE) previously defined epilepsy as 2 unprovoked seizures more than 24 hours apart. However, a more recent ILAE task force modified this definition: even a single unprovoked seizure would be enough to diagnose epilepsy if there is high probability of further seizures—eg, in the presence of definitive epileptiform discharges on EEG or presence of a brain tumor or a remote brain insult on imaging, since such conditions induce an enduring predisposition to generate epileptic seizures. 2 Also, a single unprovoked seizure is enough to diagnose epilepsy if it is part of an epileptic syndrome such as juvenile myoclonic epilepsy. Further, a time limit was added to the definition—ie, epilepsy is considered resolved if a patient remains seizure free for 10 years without use of antiseizure medications during the past 5 years. However, given the multitude of variables and evidence, the task force acknowledged the need for individualized considerations. 2
Seizure classification
Classification of seizure type is based on the site of seizure onset and its spread pattern—ie, focal, generalized, or unknown onset.
Continue to: Focal-onset seizures
Focal-onset seizures originate “within networks limited to one hemisphere,” although possibly in more than 1 region (ie, multifocal, and presence or absence of loss of awareness). 12 Focal seizures may then be further classified into “motor onset” or “nonmotor onset” (eg, autonomic, emotional, sensory). 2
Generalized seizures are those “originating at some point within, and rapidly engaging, bilaterally distributed networks.” 13 Unlike focal-onset seizures, generalized seizures are not classified based on awareness, as most generalized seizures involve loss of awareness (absence) or total loss of consciousness (generalized tonic-clonic). They are instead categorized based on the presence of motor vs nonmotor features (eg, tonic-clonic, myoclonic, atonic). Epilepsy classification is quite dynamic and constantly updated based on new genetic, electroencephalographic, and neuroimaging discoveries.
Treatment of epilepsy
Antiseizure medications
Treatment with antiseizure medications (ASMs; formerly known as antiepileptic drugs ) is the mainstay of epilepsy management. Achieving efficacy (seizure freedom) and tolerability (minimal adverse effects) are the primary goals of treatment. Factors that should govern the selection of an ASM include the seizure type/epilepsy syndrome, adverse effect profile of the ASM, pharmacodynamic/pharmacokinetic considerations, and patient comorbidities.
The Standard and New Antiepileptic Drugs (SANAD I and II) trials provide data from direct, unblinded, and longitudinal comparisons of existing and new ASMs and their utility in different seizure types. In the SANAD I cohort of patients with generalized and unclassified epilepsies, valproate was superior to lamotrigine and topiramate for 12-month remission and treatment failure rates, respectively.14 However, valproate generally is avoided in women of childbearing age due its potential adverse effects during pregnancy. In focal epilepsies, lamotrigine was superior to carbamazepine, gabapentin, and topiramate with respect to treatment failure, and noninferior to carbamazepine for 12-month remission.15 In the SANAD II trial, levetiracetam was noninferior to valproate for incidence of adverse events in patients with generalized and unclassified epilepsies although was found to be neither more clinically effective nor more cost effective.16 For patients of childbearing potential with generalized and unclassified epilepsies, there is evidence to support the safe and effective use of levetiracetam.17In focal epilepsies, lamotrigine was superior to levetiracetam and zonisamide with respect to treatment failures and adverse events and was noninferior to zonisamide for 12-month remission.18 In summary, levetiracetam and valproate (not to be used in women of childbearing potential) are considered appropriate first-line agents for generalized and unclassified epilepsies while lamotrigine is deemed an appropriate first-line agent for focal epilepsies (TABLE 119-28).
Drug level monitoring. It is standard practice to periodically monitor serum levels in patients taking first-generation ASMs such as phenytoin, carbamazepine, phenobarbital, and valproic acid because of their narrow therapeutic range and the potential for overdose or interaction with other medications or foods (eg, grapefruit juice may increase carbamazepine serum level by inhibiting CYP3A4, the enzyme that metabolizes the drug). Patients taking newer ASMs may not require regular serum level monitoring except during titration, with hepatic or renal dosing, when concomitantly used with estrogen-based oral contraceptives (eg, lamotrigine), before or during pregnancy, or when nonadherence is suspected.
Continue to: Can antiseizure treatment be stopped?
Can antiseizure treatment be stopped?
Current evidence favors continuing ASM therapy in patients whose seizures are under control, although the decision should be tailored to an individual’s circumstances. According to the 2021 American Academy of Neurology (AAN) guidelines, adults who have been seizure free for at least 2 years and discontinue ASMs are possibly still at higher risk for seizure recurrence in the long term (24-60 months), compared with those who continue treatment.29 On the other hand, for adults who have been seizure free for at least 12 months, ASM withdrawal may not increase their risk for status epilepticus, and there are insufficient data to support or refute an effect on mortality or quality of life with ASM withdrawal in this population. The decision to taper or maintain ASM therapy in seizure-free patients also should take into consideration other clinically relevant outcome measures such as the patient’s lifestyle and medication adverse effects. Therefore, this decision should be made after sufficient discussion with patients and their caregivers. (Information for patients can be found at: www.epilepsy.com/treatment/medicines/stopping-medication.)
For children, the AAN guideline panel recommends discussing with family the small risk (2%) for becoming medication resistant if seizures recur during or after ASM withdrawal. 29 For children who have been seizure free for 18 to 24 months, there is probably not a significant long-term (24-48 months) difference in seizure recurrence in those who taper ASMs vs those who do not. However, presence of epileptiform discharges on EEG before discontinuation of an ASM indicates increased risk for seizure recurrence. 29
Intractable (refractory) epilepsy
While most patients with epilepsy attain complete seizure control with appropriate drug therapy, approximately 30% continue to experience seizures (“drug-resistant” epilepsy, also termed intractable or refractory ). 30 In 2010, the ILAE defined drug-resistant epilepsy as “failure of adequate trials of two tolerated, appropriately chosen and used anti-epileptic drug schedules (whether as monotherapy or in combination) to achieve sustained seizure freedom” (defined as cessation of seizures for at least 3 times the longest pre-intervention inter-seizure interval or 12 months, whichever is longer). 21,31 It should be noted that drug withdrawal due to adverse effects is not counted as failure of that ASM. Recognition of drug-resistant epilepsy may prompt referral to an epileptologist who can consider rational combination drug therapy or surgical resection of the seizure focus, vagus nerve stimulation, electrical stimulation of the seizure focus, or deep brain (thalamic) stimulation.
Seizure triggers and mitigating factors
Epilepsy mostly affects patients during seizure episodes; however, the unpredictability of these events adds significantly to the burden of disease. There are no reliable methods for predicting seizure other than knowing of the several potential risks and recognizing and avoiding these triggers.
Noncompliance with antiseizure medications is a common seizure trigger affecting up to one-half of patients with epilepsy.32
Continue to: Medications
Medications may provoke seizures in susceptible individuals
Sleep deprivation is a potential seizure trigger in people with epilepsy based on observational studies, case reports, patient surveys, and EEG-based studies, although data from randomized controlled studies are limited.36 The standard best practice is to encourage appropriate sleep hygiene, which involves getting at least 7 hours of sleep per night.37
Alcohol is a GABAergic substance like benzodiazepines with antiseizure effects. However, it acts as a potential precipitant of seizures in cases of withdrawal or acute intoxication, or when it leads to sleep disruption or nonadherence to antiseizure medications. Therefore, advise patients with alcohol use disorder to slowly taper consumption (best done through a support program) and avoid sudden withdrawal. However, complete abstinence from alcohol use is not often recommended except in special circumstances (eg, a history of alcohol-related seizures). Several studies have demonstrated that modest alcohol use (1-2 drinks per occasion) does not increase seizure frequency or significantly alter serum concentrations of commonly used ASMs.38
Cannabis and other substances. The 2 main biologically active components of marijuana are delta-9-tetrahydrocannibinol (THC), the main psychoactive constituent, and cannabidiol (CBD). Animal and human studies have demonstrated anticonvulsant properties of THC and CBD. But THC, in high amounts, can result in adverse cognitive effects and worsening seizures.39 A purified 98% oil-based CBD extract (Epidiolex) has been approved as an adjunctive treatment for certain medically refractory epilepsy syndromes in children and young adults—ie, Dravet syndrome, Lennox-Gastaut syndrome, and tuberous sclerosis complex syndrome.40 There are no reliable data on the effect of recreational use of marijuana on seizure control. Other illicit substances such as cocaine may lower seizure threshold by their stimulatory and disruptive effects on sleep, diet, and healthy routines.
Special clinical cases
Pregnancy and epilepsy
Despite the potential adverse effects of ASMs on fetal health, the current global consensus is to continue treatment during pregnancy, given that the potential harm of convulsive seizures outweighs the potential risks associated with in-utero exposure to ASMs. There is not enough evidence to indicate significant harm to the fetus caused by focal, absence, or myoclonic seizures. Low-dose folic acid is used to minimize the risks of ASMs during pregnancy.
Continue to: As the fetus develops...
As the fetus develops, there are changes in volume of ASM distribution, renal clearance, protein binding, and hepatic metabolism, which require checking serum levels at regular intervals and making dosage adjustments.
The ongoing study evaluating Maternal Outcomes and Neurodevelopmental Effects of Antiepileptic Drugs (MONEAD)41 has led to multiple landmark studies guiding the choice of preferred ASMs during pregnancy in patients with epilepsy.42,43 This has culminated in today’s use of lamotrigine and levetiracetam as the 2 preferred agents (while avoiding valproate) in pregnant patients with epilepsy.44
Psychogenic nonepileptic seizures
A form of conversion disorder, psychogenic nonepileptic seizures (PNES) manifests as abnormal motor or behavioral events mimicking seizures but without associated epileptiform discharges on EEG. This is observed in 10% of patients seen in epilepsy clinics and even more often in those admitted to epilepsy monitoring units (25%-40%).45 Diagnosis of PNES requires EEG monitoring both for confirmation and for discernment from true epileptic seizures, in particular frontal lobe epilepsy that may clinically mimic PNES. PNES often is associated with underlying psychological tensions or comorbid conditions such as depression, anxiety, or traumatic life experiences. There is no treatment for PNES per se, and its management is focused on controlling any underlying psychological comorbidities that may not always be obvious. There is some evidence suggesting that these patients experience an innate inability to verbally express their emotions and instead subconsciously resort to psychosomatics to express them in a somatic dimension.46,47
Status epilepticus
Defined as prolonged seizures (> 5 min) or 2 consecutive seizures without regaining aware ness in between, status epilepticus (SE) is a potentially fatal condition. Subclinical nonconvulsive SE, especially in comatose patients, can be diagnosed only via EEG monitoring. Untreated SE may manifest as a diagnostic dilemma in unresponsive or critically ill patients and can increase the risk for mortality. 48
Febrile seizures
Febrile seizures affect 2% to 5% of children most often in the second year of life.49 The use of preventive antiseizure medication is not recommended; instead, the key is to investigate the underlying febrile illness. Lumbar puncture is indicated if there are signs and symptoms of meningitis (25% of children with bacterial meningitis present with seizures).49 Febrile seizures often are self-limited, but there is risk for SE in up to 15% of cases.50 If convulsive febrile seizures last longer than 5 minutes, initiate benzodiazepines followed by the standard protocol used for the management of SE.51
Continue to: Epilepsy as a spectrum disorder
Epilepsy as a spectrum disorder
The higher prevalence of comorbid cognitive and psychiatric conditions in patients with epilepsy, affecting about half of patients, 52 suggests that seizures may constitute only one aspect of a multifaceted disease that otherwise should be considered a spectrum disorder. Among such conditions are memory deficits, depression, and anxiety. Conversely, epilepsy is more common in patients with depression than in those without. 52
Social impact of epilepsy
Vehicle driving regulations. Patients with epilepsy are required to follow state law regarding driving restrictions. Different states have different rules and regulations about driving restrictions and reporting requirements (by patients or their physicians). Refer patients to the Department of Motor Vehicles (DMV) in their state of residence for up-to-date instructions.53 The Epilepsy Foundation (epilepsy.com) can serve as a resource for each state’s DMV website.
Employment assistance. Having epilepsy should not preclude patients from seeking employment and pursuing meaningful careers. The Americans with Disabilities Act (ADA) and the US Equal Employment Opportunity Commission (EEOC) forbid discrimination against qualified people with disabilities, including those with epilepsy, and require reasonable accommodations in the workplace (www.eeoc.gov/laws/guidance/epilepsy-workplace-and-ada).54
CORRESPONDENCE
Gholam K. Motamedi, MD, Department of Neurology, PHC 7, Georgetown University Hospital, 3800 Reservoir Road, NW, Washington, DC 20007; [email protected]
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7. Narayanan JT, Labar DR, Schaul N. Latency to first spike in the EEG of epilepsy patients. Seizure. 2008;17:34-41. doi: 10.1016/j.seizure.2007.06.003
8. Salmenpera TM, Duncan JS. Imaging in epilepsy. J Neurol Neurosurg Psychiatry. 2005;76:iii2-iii10. doi: 10.1136/jnnp.2005.075135
9. Jackson GD, Berkovic SF, Tress , et al Hippocampal sclerosis can be reliably detected by magnetic resonance imaging. Neurology. 1990;40:1869-1875. doi: 10.1212/wnl.40.12.1869
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11. Krumholz A, Wiebe S, Gronseth GS, et al. Evidence-based guideline: management of an unprovoked first seizure in adults: Report of the Guideline Development Subcommittee of the American Academy of Neurology and the American Epilepsy Society. Neurology. 2015;84:1705-1713. doi: 10.1212/WNL.0000000000001487
12. Fisher RS, Cross JH, French JA, et al. Operational classification of seizure types by the International League Against Epilepsy: position paper of the ILAE Commission for Classification and terminology. Epilepsia. 2017;58:522-530. doi: 10.1111/epi.13670
13. Berg AT, Berkovic SF, Brodie MJ, et al. Revised terminology and concepts for organization of seizures and epilepsy: report of the ILAE Commission on Classification and Terminology, 2005-2009. Epilepsia. 2010;51:676-685. doi: 10.1111/j.1528-1167.2010.02522.x
14. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of valproate, lamotrigine, or topiramate for generalized and unclassifiable epilepsy: an unblinded randomized controlled trial. Lancet. 2007;369:1016-1026. doi: 10.1016/S0140-6736(07)60461-9
15. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of carbamazepine, gabapentin, lamotrigine, oxcarbazepine, or topiramate for treatment of partial epilepsy: an unblinded randomized controlled trial. Lancet 2007;369:1000-1015. doi: 10.1016/S0140-6736(07)60460-7
16. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of valproate versus levetiracetam for newly diagnosed generalized and unclassified epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1375-1386. doi: 10.1016/S0140-6736(21)00246-4
17. Mawhinney E, Craig J, Morrow J. Levetiracetam in pregnancy: results from the UK and Ireland epilepsy and pregnancy registers. Neurology. 2013;80:400-405.
18. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of levetiracetam, zonisamide, or lamotrigine for newly diagnosed focal epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1363-1374. doi: 10.1016/S0140-6736(21)00247-6
19. Smith PE. Initial management of seizure in adults. N Engl J Med. 2021;385:251-263. doi: 10.1056/NEJMcp2024526
20. Depakene (valproic acid). Package insert. Abbott Laboratories; 2011. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2011/018081s046_18082s031lbl.pdf
21. Greenberg RG, Melloni C, Wu H, et al. Therapeutic index estimation of antiepileptic drugs: a systematic literature review approach. Clin Neuropharmacol. 2016;39:232-240. doi: 10.1097/WNF.0000000000000172
22. Lamictal (lamotrigine). Package insert. GlaxoSmithKline; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/020241s037s038,020764s030s031lbl.pdf
23. LaRoche SM, Helmers SL. The new antiepileptic drugs: scientific review. JAMA. 2004;291:605-614. doi: 10.1001/jama.291.5.605
24. Topamax (topiramate). Package insert. Janssen Pharmaceuticals, Inc. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2012/020844s041lbl.pdf
25. Keppra (levetiracetam). Package insert. UCB, Inc.; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/021035s078s080%2C021505s021s024lbl.pdf
26. Carbatrol (carbamazepine). Package insert. Shire US Inc; 2013. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2013/020712s032s035lbl.pdf
27.Neurontin (gabapentin). Package insert. Pfizer; 2017. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2017/020235s064_020882s047_021129s046lbl.pdf
28.Zonegran (zonisamide). Package insert. Eisai Inc; 2006. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2006/020789s019lbl.pdf
29.Gloss D, Paragon K, Pack A, et al. Antiseizure medication withdrawal in seizure-free patients: practice advisory update. Report of the AAN Guideline Subcommittee. Neurology. 2021;97:1072-1081. doi: 10.1212/WNL.0000000000012944
30.Kwan P, Brodie MJ. Early identification of refractory epilepsy. N Engl J Med. 2000:342:314-319. doi: 10.1056/NEJM200002033420503
31.Kwan P, Arzimanoglou A, Berg AT, et al. Definition of drug resistant epilepsy: consensus proposal by the ad hoc Task Force of the ILAE Commission on Therapeutic Strategies. Epilepsia. 2010;51:1069-1077. doi: 10.1111/j.1528-1167.2009.02397.x
Compliance during treatment of epilepsy. Epilepsia 1988;29(suppl 2):S79-S84.
33.utter R, Rüegg S, Tschudin-Sutter S. Seizures as adverse events of antibiotic drugs: a systematic review. Neurology. 2015;13;85:1332-1341. doi: 10.1212/WNL.0000000000002023
34.Singh G, Rees JH, Sander JW. Seizures and epilepsy in oncological practice: causes, course, mechanisms and treatment. JNNP. 2007;78:342-349. doi: 10.1136/jnnp.2006.106211
35.Pisani F, Oteri G, Costa C., et al. Effects of psychotropic drugs on seizure threshold. Drug Safety. 2002;25:91-110.
36.Rossi KC, Joe J, Makhjia M, et al. Insufficient sleep, electroencephalogram activation, and seizure risk: re-evaluating the evidence. Ann Neurol. 2020;86:798-806. doi: 10.1002/ana.25710
37.Watson NF, Badr MS, Belenky G, et al. Recommended amount of sleep for a healthy adult: a Joint Consensus Statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep. 2015;38:843-844. doi: 10.5665/sleep.4716
38.Höppener RJ, Kuyer A, van der Lugt PJ. Epilepsy and alcohol: the influence of social alcohol intake on seizures and treatment in epilepsy. Epilepsia. 1983;24:459-471. doi: 10.1111/j.1528-1157.1983.tb04917.x
39.Keeler MH, Reifler CB. Grand mal convulsions subsequent to marijuana use. Case report. Dis Nerv Syst. 1967:28:474-475.
40.Epidiolex (cannabidiol). Package insert. Greenwich Biosciences Inc; 2018. Accessed September 27, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2018/210365lbl.pdf
41.ClinicalTrials.gov. Maternal Outcomes and Neurodevelopmental Effects of Antiseizure Drugs (MONEAD). Accessed September 24, 2023. https://classic.clinicaltrials.gov/ct2/show/NCT01730170
42.Meador KJ, Baker GA, Finnell RH, et al. In utero antiepileptic drug exposure: fetal death and malformations. Neurology. 2006;67:407-412. doi: 10.1212/01.wnl.0000227919.81208.b2
43.Meador K, Reynolds MW, Crean S. Pregnancy outcomes in women with epilepsy: a systematic review and meta-analysis of published pregnancy registries and cohorts. Epilepsy Res. 2008;81:1-13. doi:10.1016/j.eplepsyres.2008.04.022
44.Marxer CA, Rüegg S, Rauch A review of the evidence on the risk of congenital malformations and neurodevelopmental disorders in association with antiseizure medications during pregnancy. Expert Opin Drug Saf. 2021;20:1487-1499. doi: 10.1080/14740338.2021.1943355
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Evaluation and treatment of psychogenic nonepileptic seizures. Neurol Clin. 2022;40:799-820. doi: 10.1016/j.ncl.2022.03.017
47.Motamedi GK. Psychogenic nonepileptic seizures: a disconnect between body and mind. Epilepsy Behav. 2018;78:293-294. doi: 10.1016/j.yebeh.2017.10.016
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Managing first-time seizures and epilepsy often requires consultation with a neurologist or epileptologist for diagnosis and subsequent management, including when medical treatment fails or in determining whether patients may benefit from surgery. However, given the high prevalence of epilepsy and even higher incidence of a single seizure, family physicians contribute significantly to the management of these patients. The main issues are managing a first-time seizure, making the diagnosis, establishing a treatment plan, and exploring triggers and mitigating factors.
Seizure vs epilepsy
All patients with epilepsy experience seizures, but not every person who experiences a seizure has (or will develop) epilepsy. Nearly 10% of the population has one seizure during their lifetime,whereas the risk for epilepsy is just 3%.1 Therefore, a first-time seizure may not herald epilepsy, defined as repetitive (≥ 2) unprovoked seizures more than 24 hours apart.2 Seizures can be provoked (acute symptomatic) or unprovoked; a clear distinction between these 2 occurrences—as well as between single and recurrent seizures—is critical for proper management. A close look at the circumstances of a first-time seizure is imperative to define the nature of the event and the possibility of further seizures before devising a treatment plan.
Provoked seizures are due to an acute brain insult such as toxic-metabolic disorders, concussion, alcohol withdrawal, an adverse effect of a medication or its withdrawal, or photic stimulation presumably by disrupting the brain’s metabolic homeostasis or integrity. The key factor is that provoked seizures always happen in close temporal association with an acute insult. A single provoked seizure happens each year in 29 to 39 individuals per 100,000.3 While these seizures typically occur singly, there is a small risk they may recur if the triggering insult persists or repeats.1 Therefore, more than 1 seizure per se may not indicate epilepsy.3
Unprovoked seizures reflect an underlying brain dysfunction. A single unprovoked seizure happens in 23 to 61 individuals per 100,000 per year, often in men in either younger or older age groups.3 Unprovoked seizures may occur only once or may recur (ie, evolve into epilepsy). The latter scenario happens in only about half of cases; the overall risk for a recurrent seizure within 2 years of a first seizure is estimated at 42% (24% to 65%, depending on the etiology and electroencephalogram [EEG] findings).4 More specifically, without treatment the relapse rate will be 36% at 1 year and 47% at 2 years.4 Further, a second unprovoked seizure, if untreated, would increase the risk for third and fourth seizures to 73% and 76%, respectively, within 4 years.3
Evaluating the first-time seizure
Ask the patient or observers about the circumstances of the event to differentiate provoked from unprovoked onset. For one thing, not all “spells” are seizures. The differential diagnoses may include syncope, psychogenic nonepileptic events, drug intoxication or withdrawal, migraine, panic attacks, sleep disorders (parasomnia), transient global amnesia, concussion, and transient ischemic attack. EEG, neuroimaging, and other relevant diagnostic tests often are needed (eg, electrocardiogram/echocardiogram/Holter monitoring to evaluate for syncope/cardiac arrhythmia). Clinically, syncopal episodes tend to be brief with rapid recovery and no confusion, speech problems, aura, or lateralizing signs such as hand posturing or lip smacking that are typical with focal seizures. However, cases of convulsive syncope can be challenging to assess without diagnostic tests.
True convulsive seizures do not have the variability in clinical signs seen with psychogenic nonepileptic events (eg, alternating body parts involved or direction of movements). Transient global amnesia is a rare condition with no established diagnostic test and is considered a diagnosis of exclusion, although bitemporal hyperintensities on magnetic resonance imaging (MRI) may appear 12 to 48 hours after the clinical episode.5 Blood work is needed in patients with medical issues treated with multiple medications to evaluate for metabolic derangements; otherwise, routine blood work provides minimal information in stable patients.
Region-specific causes. Neurocysticercosis is common in some regions, such as Latin America; therefore, attention should be paid to this aspect of patient history.
Continue to: Is it really a first-time seizure?
Is it really a first-time seizure? A “first,” usually dramatic, generalized tonic-clonic seizure that triggers the diagnostic work-up may not be the very first seizure. Evidence suggests that many patients have experienced prior undiagnosed seizures. Subtle prior events often missed include episodes of deja vu, transient feelings of fear or unusual smells, speech difficulties, staring spells, or myoclonic jerks.1 A routine EEG to record epileptiform discharges and a high-resolution brain MRI to rule out any intracranial pathology are indicated. However, if the EEG indicates a primary generalized (as opposed to focal-onset) epilepsy, a brain MRI may not be needed. If a routine EEG is unrevealing, long-term video-EEG monitoring may be needed to detect an abnormality.
Accuracy of EEG and MRI. Following a first unprovoked seizure, routine EEG to detect epileptiform discharges in adults has yielded a sensitivity of 17.3% and specificity of 94.7%. In evaluating children, these values are 57.8% and 69.6%, respectively.6 If results are equivocal, a 24-hour EEG can increase the likelihood of detecting epileptiform discharges to 89% of patients.7 Brain MRI may detect an abnormality in 12% to 14% of patients with newly diagnosed epilepsy, and in up to 80% of those with recurrent seizures.8 In confirming hippocampus sclerosis, MRI has demonstrated a sensitivity of 93% and specificity of 86%.9
When to treat a first-time seizure. Available data and prediction models identify risk factors that would help determine whether to start an antiseizure medication after a first unprovoked seizure:
Epilepsy diagnosis
The International League Against Epilepsy (ILAE) previously defined epilepsy as 2 unprovoked seizures more than 24 hours apart. However, a more recent ILAE task force modified this definition: even a single unprovoked seizure would be enough to diagnose epilepsy if there is high probability of further seizures—eg, in the presence of definitive epileptiform discharges on EEG or presence of a brain tumor or a remote brain insult on imaging, since such conditions induce an enduring predisposition to generate epileptic seizures. 2 Also, a single unprovoked seizure is enough to diagnose epilepsy if it is part of an epileptic syndrome such as juvenile myoclonic epilepsy. Further, a time limit was added to the definition—ie, epilepsy is considered resolved if a patient remains seizure free for 10 years without use of antiseizure medications during the past 5 years. However, given the multitude of variables and evidence, the task force acknowledged the need for individualized considerations. 2
Seizure classification
Classification of seizure type is based on the site of seizure onset and its spread pattern—ie, focal, generalized, or unknown onset.
Continue to: Focal-onset seizures
Focal-onset seizures originate “within networks limited to one hemisphere,” although possibly in more than 1 region (ie, multifocal, and presence or absence of loss of awareness). 12 Focal seizures may then be further classified into “motor onset” or “nonmotor onset” (eg, autonomic, emotional, sensory). 2
Generalized seizures are those “originating at some point within, and rapidly engaging, bilaterally distributed networks.” 13 Unlike focal-onset seizures, generalized seizures are not classified based on awareness, as most generalized seizures involve loss of awareness (absence) or total loss of consciousness (generalized tonic-clonic). They are instead categorized based on the presence of motor vs nonmotor features (eg, tonic-clonic, myoclonic, atonic). Epilepsy classification is quite dynamic and constantly updated based on new genetic, electroencephalographic, and neuroimaging discoveries.
Treatment of epilepsy
Antiseizure medications
Treatment with antiseizure medications (ASMs; formerly known as antiepileptic drugs ) is the mainstay of epilepsy management. Achieving efficacy (seizure freedom) and tolerability (minimal adverse effects) are the primary goals of treatment. Factors that should govern the selection of an ASM include the seizure type/epilepsy syndrome, adverse effect profile of the ASM, pharmacodynamic/pharmacokinetic considerations, and patient comorbidities.
The Standard and New Antiepileptic Drugs (SANAD I and II) trials provide data from direct, unblinded, and longitudinal comparisons of existing and new ASMs and their utility in different seizure types. In the SANAD I cohort of patients with generalized and unclassified epilepsies, valproate was superior to lamotrigine and topiramate for 12-month remission and treatment failure rates, respectively.14 However, valproate generally is avoided in women of childbearing age due its potential adverse effects during pregnancy. In focal epilepsies, lamotrigine was superior to carbamazepine, gabapentin, and topiramate with respect to treatment failure, and noninferior to carbamazepine for 12-month remission.15 In the SANAD II trial, levetiracetam was noninferior to valproate for incidence of adverse events in patients with generalized and unclassified epilepsies although was found to be neither more clinically effective nor more cost effective.16 For patients of childbearing potential with generalized and unclassified epilepsies, there is evidence to support the safe and effective use of levetiracetam.17In focal epilepsies, lamotrigine was superior to levetiracetam and zonisamide with respect to treatment failures and adverse events and was noninferior to zonisamide for 12-month remission.18 In summary, levetiracetam and valproate (not to be used in women of childbearing potential) are considered appropriate first-line agents for generalized and unclassified epilepsies while lamotrigine is deemed an appropriate first-line agent for focal epilepsies (TABLE 119-28).
Drug level monitoring. It is standard practice to periodically monitor serum levels in patients taking first-generation ASMs such as phenytoin, carbamazepine, phenobarbital, and valproic acid because of their narrow therapeutic range and the potential for overdose or interaction with other medications or foods (eg, grapefruit juice may increase carbamazepine serum level by inhibiting CYP3A4, the enzyme that metabolizes the drug). Patients taking newer ASMs may not require regular serum level monitoring except during titration, with hepatic or renal dosing, when concomitantly used with estrogen-based oral contraceptives (eg, lamotrigine), before or during pregnancy, or when nonadherence is suspected.
Continue to: Can antiseizure treatment be stopped?
Can antiseizure treatment be stopped?
Current evidence favors continuing ASM therapy in patients whose seizures are under control, although the decision should be tailored to an individual’s circumstances. According to the 2021 American Academy of Neurology (AAN) guidelines, adults who have been seizure free for at least 2 years and discontinue ASMs are possibly still at higher risk for seizure recurrence in the long term (24-60 months), compared with those who continue treatment.29 On the other hand, for adults who have been seizure free for at least 12 months, ASM withdrawal may not increase their risk for status epilepticus, and there are insufficient data to support or refute an effect on mortality or quality of life with ASM withdrawal in this population. The decision to taper or maintain ASM therapy in seizure-free patients also should take into consideration other clinically relevant outcome measures such as the patient’s lifestyle and medication adverse effects. Therefore, this decision should be made after sufficient discussion with patients and their caregivers. (Information for patients can be found at: www.epilepsy.com/treatment/medicines/stopping-medication.)
For children, the AAN guideline panel recommends discussing with family the small risk (2%) for becoming medication resistant if seizures recur during or after ASM withdrawal. 29 For children who have been seizure free for 18 to 24 months, there is probably not a significant long-term (24-48 months) difference in seizure recurrence in those who taper ASMs vs those who do not. However, presence of epileptiform discharges on EEG before discontinuation of an ASM indicates increased risk for seizure recurrence. 29
Intractable (refractory) epilepsy
While most patients with epilepsy attain complete seizure control with appropriate drug therapy, approximately 30% continue to experience seizures (“drug-resistant” epilepsy, also termed intractable or refractory ). 30 In 2010, the ILAE defined drug-resistant epilepsy as “failure of adequate trials of two tolerated, appropriately chosen and used anti-epileptic drug schedules (whether as monotherapy or in combination) to achieve sustained seizure freedom” (defined as cessation of seizures for at least 3 times the longest pre-intervention inter-seizure interval or 12 months, whichever is longer). 21,31 It should be noted that drug withdrawal due to adverse effects is not counted as failure of that ASM. Recognition of drug-resistant epilepsy may prompt referral to an epileptologist who can consider rational combination drug therapy or surgical resection of the seizure focus, vagus nerve stimulation, electrical stimulation of the seizure focus, or deep brain (thalamic) stimulation.
Seizure triggers and mitigating factors
Epilepsy mostly affects patients during seizure episodes; however, the unpredictability of these events adds significantly to the burden of disease. There are no reliable methods for predicting seizure other than knowing of the several potential risks and recognizing and avoiding these triggers.
Noncompliance with antiseizure medications is a common seizure trigger affecting up to one-half of patients with epilepsy.32
Continue to: Medications
Medications may provoke seizures in susceptible individuals
Sleep deprivation is a potential seizure trigger in people with epilepsy based on observational studies, case reports, patient surveys, and EEG-based studies, although data from randomized controlled studies are limited.36 The standard best practice is to encourage appropriate sleep hygiene, which involves getting at least 7 hours of sleep per night.37
Alcohol is a GABAergic substance like benzodiazepines with antiseizure effects. However, it acts as a potential precipitant of seizures in cases of withdrawal or acute intoxication, or when it leads to sleep disruption or nonadherence to antiseizure medications. Therefore, advise patients with alcohol use disorder to slowly taper consumption (best done through a support program) and avoid sudden withdrawal. However, complete abstinence from alcohol use is not often recommended except in special circumstances (eg, a history of alcohol-related seizures). Several studies have demonstrated that modest alcohol use (1-2 drinks per occasion) does not increase seizure frequency or significantly alter serum concentrations of commonly used ASMs.38
Cannabis and other substances. The 2 main biologically active components of marijuana are delta-9-tetrahydrocannibinol (THC), the main psychoactive constituent, and cannabidiol (CBD). Animal and human studies have demonstrated anticonvulsant properties of THC and CBD. But THC, in high amounts, can result in adverse cognitive effects and worsening seizures.39 A purified 98% oil-based CBD extract (Epidiolex) has been approved as an adjunctive treatment for certain medically refractory epilepsy syndromes in children and young adults—ie, Dravet syndrome, Lennox-Gastaut syndrome, and tuberous sclerosis complex syndrome.40 There are no reliable data on the effect of recreational use of marijuana on seizure control. Other illicit substances such as cocaine may lower seizure threshold by their stimulatory and disruptive effects on sleep, diet, and healthy routines.
Special clinical cases
Pregnancy and epilepsy
Despite the potential adverse effects of ASMs on fetal health, the current global consensus is to continue treatment during pregnancy, given that the potential harm of convulsive seizures outweighs the potential risks associated with in-utero exposure to ASMs. There is not enough evidence to indicate significant harm to the fetus caused by focal, absence, or myoclonic seizures. Low-dose folic acid is used to minimize the risks of ASMs during pregnancy.
Continue to: As the fetus develops...
As the fetus develops, there are changes in volume of ASM distribution, renal clearance, protein binding, and hepatic metabolism, which require checking serum levels at regular intervals and making dosage adjustments.
The ongoing study evaluating Maternal Outcomes and Neurodevelopmental Effects of Antiepileptic Drugs (MONEAD)41 has led to multiple landmark studies guiding the choice of preferred ASMs during pregnancy in patients with epilepsy.42,43 This has culminated in today’s use of lamotrigine and levetiracetam as the 2 preferred agents (while avoiding valproate) in pregnant patients with epilepsy.44
Psychogenic nonepileptic seizures
A form of conversion disorder, psychogenic nonepileptic seizures (PNES) manifests as abnormal motor or behavioral events mimicking seizures but without associated epileptiform discharges on EEG. This is observed in 10% of patients seen in epilepsy clinics and even more often in those admitted to epilepsy monitoring units (25%-40%).45 Diagnosis of PNES requires EEG monitoring both for confirmation and for discernment from true epileptic seizures, in particular frontal lobe epilepsy that may clinically mimic PNES. PNES often is associated with underlying psychological tensions or comorbid conditions such as depression, anxiety, or traumatic life experiences. There is no treatment for PNES per se, and its management is focused on controlling any underlying psychological comorbidities that may not always be obvious. There is some evidence suggesting that these patients experience an innate inability to verbally express their emotions and instead subconsciously resort to psychosomatics to express them in a somatic dimension.46,47
Status epilepticus
Defined as prolonged seizures (> 5 min) or 2 consecutive seizures without regaining aware ness in between, status epilepticus (SE) is a potentially fatal condition. Subclinical nonconvulsive SE, especially in comatose patients, can be diagnosed only via EEG monitoring. Untreated SE may manifest as a diagnostic dilemma in unresponsive or critically ill patients and can increase the risk for mortality. 48
Febrile seizures
Febrile seizures affect 2% to 5% of children most often in the second year of life.49 The use of preventive antiseizure medication is not recommended; instead, the key is to investigate the underlying febrile illness. Lumbar puncture is indicated if there are signs and symptoms of meningitis (25% of children with bacterial meningitis present with seizures).49 Febrile seizures often are self-limited, but there is risk for SE in up to 15% of cases.50 If convulsive febrile seizures last longer than 5 minutes, initiate benzodiazepines followed by the standard protocol used for the management of SE.51
Continue to: Epilepsy as a spectrum disorder
Epilepsy as a spectrum disorder
The higher prevalence of comorbid cognitive and psychiatric conditions in patients with epilepsy, affecting about half of patients, 52 suggests that seizures may constitute only one aspect of a multifaceted disease that otherwise should be considered a spectrum disorder. Among such conditions are memory deficits, depression, and anxiety. Conversely, epilepsy is more common in patients with depression than in those without. 52
Social impact of epilepsy
Vehicle driving regulations. Patients with epilepsy are required to follow state law regarding driving restrictions. Different states have different rules and regulations about driving restrictions and reporting requirements (by patients or their physicians). Refer patients to the Department of Motor Vehicles (DMV) in their state of residence for up-to-date instructions.53 The Epilepsy Foundation (epilepsy.com) can serve as a resource for each state’s DMV website.
Employment assistance. Having epilepsy should not preclude patients from seeking employment and pursuing meaningful careers. The Americans with Disabilities Act (ADA) and the US Equal Employment Opportunity Commission (EEOC) forbid discrimination against qualified people with disabilities, including those with epilepsy, and require reasonable accommodations in the workplace (www.eeoc.gov/laws/guidance/epilepsy-workplace-and-ada).54
CORRESPONDENCE
Gholam K. Motamedi, MD, Department of Neurology, PHC 7, Georgetown University Hospital, 3800 Reservoir Road, NW, Washington, DC 20007; [email protected]
Managing first-time seizures and epilepsy often requires consultation with a neurologist or epileptologist for diagnosis and subsequent management, including when medical treatment fails or in determining whether patients may benefit from surgery. However, given the high prevalence of epilepsy and even higher incidence of a single seizure, family physicians contribute significantly to the management of these patients. The main issues are managing a first-time seizure, making the diagnosis, establishing a treatment plan, and exploring triggers and mitigating factors.
Seizure vs epilepsy
All patients with epilepsy experience seizures, but not every person who experiences a seizure has (or will develop) epilepsy. Nearly 10% of the population has one seizure during their lifetime,whereas the risk for epilepsy is just 3%.1 Therefore, a first-time seizure may not herald epilepsy, defined as repetitive (≥ 2) unprovoked seizures more than 24 hours apart.2 Seizures can be provoked (acute symptomatic) or unprovoked; a clear distinction between these 2 occurrences—as well as between single and recurrent seizures—is critical for proper management. A close look at the circumstances of a first-time seizure is imperative to define the nature of the event and the possibility of further seizures before devising a treatment plan.
Provoked seizures are due to an acute brain insult such as toxic-metabolic disorders, concussion, alcohol withdrawal, an adverse effect of a medication or its withdrawal, or photic stimulation presumably by disrupting the brain’s metabolic homeostasis or integrity. The key factor is that provoked seizures always happen in close temporal association with an acute insult. A single provoked seizure happens each year in 29 to 39 individuals per 100,000.3 While these seizures typically occur singly, there is a small risk they may recur if the triggering insult persists or repeats.1 Therefore, more than 1 seizure per se may not indicate epilepsy.3
Unprovoked seizures reflect an underlying brain dysfunction. A single unprovoked seizure happens in 23 to 61 individuals per 100,000 per year, often in men in either younger or older age groups.3 Unprovoked seizures may occur only once or may recur (ie, evolve into epilepsy). The latter scenario happens in only about half of cases; the overall risk for a recurrent seizure within 2 years of a first seizure is estimated at 42% (24% to 65%, depending on the etiology and electroencephalogram [EEG] findings).4 More specifically, without treatment the relapse rate will be 36% at 1 year and 47% at 2 years.4 Further, a second unprovoked seizure, if untreated, would increase the risk for third and fourth seizures to 73% and 76%, respectively, within 4 years.3
Evaluating the first-time seizure
Ask the patient or observers about the circumstances of the event to differentiate provoked from unprovoked onset. For one thing, not all “spells” are seizures. The differential diagnoses may include syncope, psychogenic nonepileptic events, drug intoxication or withdrawal, migraine, panic attacks, sleep disorders (parasomnia), transient global amnesia, concussion, and transient ischemic attack. EEG, neuroimaging, and other relevant diagnostic tests often are needed (eg, electrocardiogram/echocardiogram/Holter monitoring to evaluate for syncope/cardiac arrhythmia). Clinically, syncopal episodes tend to be brief with rapid recovery and no confusion, speech problems, aura, or lateralizing signs such as hand posturing or lip smacking that are typical with focal seizures. However, cases of convulsive syncope can be challenging to assess without diagnostic tests.
True convulsive seizures do not have the variability in clinical signs seen with psychogenic nonepileptic events (eg, alternating body parts involved or direction of movements). Transient global amnesia is a rare condition with no established diagnostic test and is considered a diagnosis of exclusion, although bitemporal hyperintensities on magnetic resonance imaging (MRI) may appear 12 to 48 hours after the clinical episode.5 Blood work is needed in patients with medical issues treated with multiple medications to evaluate for metabolic derangements; otherwise, routine blood work provides minimal information in stable patients.
Region-specific causes. Neurocysticercosis is common in some regions, such as Latin America; therefore, attention should be paid to this aspect of patient history.
Continue to: Is it really a first-time seizure?
Is it really a first-time seizure? A “first,” usually dramatic, generalized tonic-clonic seizure that triggers the diagnostic work-up may not be the very first seizure. Evidence suggests that many patients have experienced prior undiagnosed seizures. Subtle prior events often missed include episodes of deja vu, transient feelings of fear or unusual smells, speech difficulties, staring spells, or myoclonic jerks.1 A routine EEG to record epileptiform discharges and a high-resolution brain MRI to rule out any intracranial pathology are indicated. However, if the EEG indicates a primary generalized (as opposed to focal-onset) epilepsy, a brain MRI may not be needed. If a routine EEG is unrevealing, long-term video-EEG monitoring may be needed to detect an abnormality.
Accuracy of EEG and MRI. Following a first unprovoked seizure, routine EEG to detect epileptiform discharges in adults has yielded a sensitivity of 17.3% and specificity of 94.7%. In evaluating children, these values are 57.8% and 69.6%, respectively.6 If results are equivocal, a 24-hour EEG can increase the likelihood of detecting epileptiform discharges to 89% of patients.7 Brain MRI may detect an abnormality in 12% to 14% of patients with newly diagnosed epilepsy, and in up to 80% of those with recurrent seizures.8 In confirming hippocampus sclerosis, MRI has demonstrated a sensitivity of 93% and specificity of 86%.9
When to treat a first-time seizure. Available data and prediction models identify risk factors that would help determine whether to start an antiseizure medication after a first unprovoked seizure:
Epilepsy diagnosis
The International League Against Epilepsy (ILAE) previously defined epilepsy as 2 unprovoked seizures more than 24 hours apart. However, a more recent ILAE task force modified this definition: even a single unprovoked seizure would be enough to diagnose epilepsy if there is high probability of further seizures—eg, in the presence of definitive epileptiform discharges on EEG or presence of a brain tumor or a remote brain insult on imaging, since such conditions induce an enduring predisposition to generate epileptic seizures. 2 Also, a single unprovoked seizure is enough to diagnose epilepsy if it is part of an epileptic syndrome such as juvenile myoclonic epilepsy. Further, a time limit was added to the definition—ie, epilepsy is considered resolved if a patient remains seizure free for 10 years without use of antiseizure medications during the past 5 years. However, given the multitude of variables and evidence, the task force acknowledged the need for individualized considerations. 2
Seizure classification
Classification of seizure type is based on the site of seizure onset and its spread pattern—ie, focal, generalized, or unknown onset.
Continue to: Focal-onset seizures
Focal-onset seizures originate “within networks limited to one hemisphere,” although possibly in more than 1 region (ie, multifocal, and presence or absence of loss of awareness). 12 Focal seizures may then be further classified into “motor onset” or “nonmotor onset” (eg, autonomic, emotional, sensory). 2
Generalized seizures are those “originating at some point within, and rapidly engaging, bilaterally distributed networks.” 13 Unlike focal-onset seizures, generalized seizures are not classified based on awareness, as most generalized seizures involve loss of awareness (absence) or total loss of consciousness (generalized tonic-clonic). They are instead categorized based on the presence of motor vs nonmotor features (eg, tonic-clonic, myoclonic, atonic). Epilepsy classification is quite dynamic and constantly updated based on new genetic, electroencephalographic, and neuroimaging discoveries.
Treatment of epilepsy
Antiseizure medications
Treatment with antiseizure medications (ASMs; formerly known as antiepileptic drugs ) is the mainstay of epilepsy management. Achieving efficacy (seizure freedom) and tolerability (minimal adverse effects) are the primary goals of treatment. Factors that should govern the selection of an ASM include the seizure type/epilepsy syndrome, adverse effect profile of the ASM, pharmacodynamic/pharmacokinetic considerations, and patient comorbidities.
The Standard and New Antiepileptic Drugs (SANAD I and II) trials provide data from direct, unblinded, and longitudinal comparisons of existing and new ASMs and their utility in different seizure types. In the SANAD I cohort of patients with generalized and unclassified epilepsies, valproate was superior to lamotrigine and topiramate for 12-month remission and treatment failure rates, respectively.14 However, valproate generally is avoided in women of childbearing age due its potential adverse effects during pregnancy. In focal epilepsies, lamotrigine was superior to carbamazepine, gabapentin, and topiramate with respect to treatment failure, and noninferior to carbamazepine for 12-month remission.15 In the SANAD II trial, levetiracetam was noninferior to valproate for incidence of adverse events in patients with generalized and unclassified epilepsies although was found to be neither more clinically effective nor more cost effective.16 For patients of childbearing potential with generalized and unclassified epilepsies, there is evidence to support the safe and effective use of levetiracetam.17In focal epilepsies, lamotrigine was superior to levetiracetam and zonisamide with respect to treatment failures and adverse events and was noninferior to zonisamide for 12-month remission.18 In summary, levetiracetam and valproate (not to be used in women of childbearing potential) are considered appropriate first-line agents for generalized and unclassified epilepsies while lamotrigine is deemed an appropriate first-line agent for focal epilepsies (TABLE 119-28).
Drug level monitoring. It is standard practice to periodically monitor serum levels in patients taking first-generation ASMs such as phenytoin, carbamazepine, phenobarbital, and valproic acid because of their narrow therapeutic range and the potential for overdose or interaction with other medications or foods (eg, grapefruit juice may increase carbamazepine serum level by inhibiting CYP3A4, the enzyme that metabolizes the drug). Patients taking newer ASMs may not require regular serum level monitoring except during titration, with hepatic or renal dosing, when concomitantly used with estrogen-based oral contraceptives (eg, lamotrigine), before or during pregnancy, or when nonadherence is suspected.
Continue to: Can antiseizure treatment be stopped?
Can antiseizure treatment be stopped?
Current evidence favors continuing ASM therapy in patients whose seizures are under control, although the decision should be tailored to an individual’s circumstances. According to the 2021 American Academy of Neurology (AAN) guidelines, adults who have been seizure free for at least 2 years and discontinue ASMs are possibly still at higher risk for seizure recurrence in the long term (24-60 months), compared with those who continue treatment.29 On the other hand, for adults who have been seizure free for at least 12 months, ASM withdrawal may not increase their risk for status epilepticus, and there are insufficient data to support or refute an effect on mortality or quality of life with ASM withdrawal in this population. The decision to taper or maintain ASM therapy in seizure-free patients also should take into consideration other clinically relevant outcome measures such as the patient’s lifestyle and medication adverse effects. Therefore, this decision should be made after sufficient discussion with patients and their caregivers. (Information for patients can be found at: www.epilepsy.com/treatment/medicines/stopping-medication.)
For children, the AAN guideline panel recommends discussing with family the small risk (2%) for becoming medication resistant if seizures recur during or after ASM withdrawal. 29 For children who have been seizure free for 18 to 24 months, there is probably not a significant long-term (24-48 months) difference in seizure recurrence in those who taper ASMs vs those who do not. However, presence of epileptiform discharges on EEG before discontinuation of an ASM indicates increased risk for seizure recurrence. 29
Intractable (refractory) epilepsy
While most patients with epilepsy attain complete seizure control with appropriate drug therapy, approximately 30% continue to experience seizures (“drug-resistant” epilepsy, also termed intractable or refractory ). 30 In 2010, the ILAE defined drug-resistant epilepsy as “failure of adequate trials of two tolerated, appropriately chosen and used anti-epileptic drug schedules (whether as monotherapy or in combination) to achieve sustained seizure freedom” (defined as cessation of seizures for at least 3 times the longest pre-intervention inter-seizure interval or 12 months, whichever is longer). 21,31 It should be noted that drug withdrawal due to adverse effects is not counted as failure of that ASM. Recognition of drug-resistant epilepsy may prompt referral to an epileptologist who can consider rational combination drug therapy or surgical resection of the seizure focus, vagus nerve stimulation, electrical stimulation of the seizure focus, or deep brain (thalamic) stimulation.
Seizure triggers and mitigating factors
Epilepsy mostly affects patients during seizure episodes; however, the unpredictability of these events adds significantly to the burden of disease. There are no reliable methods for predicting seizure other than knowing of the several potential risks and recognizing and avoiding these triggers.
Noncompliance with antiseizure medications is a common seizure trigger affecting up to one-half of patients with epilepsy.32
Continue to: Medications
Medications may provoke seizures in susceptible individuals
Sleep deprivation is a potential seizure trigger in people with epilepsy based on observational studies, case reports, patient surveys, and EEG-based studies, although data from randomized controlled studies are limited.36 The standard best practice is to encourage appropriate sleep hygiene, which involves getting at least 7 hours of sleep per night.37
Alcohol is a GABAergic substance like benzodiazepines with antiseizure effects. However, it acts as a potential precipitant of seizures in cases of withdrawal or acute intoxication, or when it leads to sleep disruption or nonadherence to antiseizure medications. Therefore, advise patients with alcohol use disorder to slowly taper consumption (best done through a support program) and avoid sudden withdrawal. However, complete abstinence from alcohol use is not often recommended except in special circumstances (eg, a history of alcohol-related seizures). Several studies have demonstrated that modest alcohol use (1-2 drinks per occasion) does not increase seizure frequency or significantly alter serum concentrations of commonly used ASMs.38
Cannabis and other substances. The 2 main biologically active components of marijuana are delta-9-tetrahydrocannibinol (THC), the main psychoactive constituent, and cannabidiol (CBD). Animal and human studies have demonstrated anticonvulsant properties of THC and CBD. But THC, in high amounts, can result in adverse cognitive effects and worsening seizures.39 A purified 98% oil-based CBD extract (Epidiolex) has been approved as an adjunctive treatment for certain medically refractory epilepsy syndromes in children and young adults—ie, Dravet syndrome, Lennox-Gastaut syndrome, and tuberous sclerosis complex syndrome.40 There are no reliable data on the effect of recreational use of marijuana on seizure control. Other illicit substances such as cocaine may lower seizure threshold by their stimulatory and disruptive effects on sleep, diet, and healthy routines.
Special clinical cases
Pregnancy and epilepsy
Despite the potential adverse effects of ASMs on fetal health, the current global consensus is to continue treatment during pregnancy, given that the potential harm of convulsive seizures outweighs the potential risks associated with in-utero exposure to ASMs. There is not enough evidence to indicate significant harm to the fetus caused by focal, absence, or myoclonic seizures. Low-dose folic acid is used to minimize the risks of ASMs during pregnancy.
Continue to: As the fetus develops...
As the fetus develops, there are changes in volume of ASM distribution, renal clearance, protein binding, and hepatic metabolism, which require checking serum levels at regular intervals and making dosage adjustments.
The ongoing study evaluating Maternal Outcomes and Neurodevelopmental Effects of Antiepileptic Drugs (MONEAD)41 has led to multiple landmark studies guiding the choice of preferred ASMs during pregnancy in patients with epilepsy.42,43 This has culminated in today’s use of lamotrigine and levetiracetam as the 2 preferred agents (while avoiding valproate) in pregnant patients with epilepsy.44
Psychogenic nonepileptic seizures
A form of conversion disorder, psychogenic nonepileptic seizures (PNES) manifests as abnormal motor or behavioral events mimicking seizures but without associated epileptiform discharges on EEG. This is observed in 10% of patients seen in epilepsy clinics and even more often in those admitted to epilepsy monitoring units (25%-40%).45 Diagnosis of PNES requires EEG monitoring both for confirmation and for discernment from true epileptic seizures, in particular frontal lobe epilepsy that may clinically mimic PNES. PNES often is associated with underlying psychological tensions or comorbid conditions such as depression, anxiety, or traumatic life experiences. There is no treatment for PNES per se, and its management is focused on controlling any underlying psychological comorbidities that may not always be obvious. There is some evidence suggesting that these patients experience an innate inability to verbally express their emotions and instead subconsciously resort to psychosomatics to express them in a somatic dimension.46,47
Status epilepticus
Defined as prolonged seizures (> 5 min) or 2 consecutive seizures without regaining aware ness in between, status epilepticus (SE) is a potentially fatal condition. Subclinical nonconvulsive SE, especially in comatose patients, can be diagnosed only via EEG monitoring. Untreated SE may manifest as a diagnostic dilemma in unresponsive or critically ill patients and can increase the risk for mortality. 48
Febrile seizures
Febrile seizures affect 2% to 5% of children most often in the second year of life.49 The use of preventive antiseizure medication is not recommended; instead, the key is to investigate the underlying febrile illness. Lumbar puncture is indicated if there are signs and symptoms of meningitis (25% of children with bacterial meningitis present with seizures).49 Febrile seizures often are self-limited, but there is risk for SE in up to 15% of cases.50 If convulsive febrile seizures last longer than 5 minutes, initiate benzodiazepines followed by the standard protocol used for the management of SE.51
Continue to: Epilepsy as a spectrum disorder
Epilepsy as a spectrum disorder
The higher prevalence of comorbid cognitive and psychiatric conditions in patients with epilepsy, affecting about half of patients, 52 suggests that seizures may constitute only one aspect of a multifaceted disease that otherwise should be considered a spectrum disorder. Among such conditions are memory deficits, depression, and anxiety. Conversely, epilepsy is more common in patients with depression than in those without. 52
Social impact of epilepsy
Vehicle driving regulations. Patients with epilepsy are required to follow state law regarding driving restrictions. Different states have different rules and regulations about driving restrictions and reporting requirements (by patients or their physicians). Refer patients to the Department of Motor Vehicles (DMV) in their state of residence for up-to-date instructions.53 The Epilepsy Foundation (epilepsy.com) can serve as a resource for each state’s DMV website.
Employment assistance. Having epilepsy should not preclude patients from seeking employment and pursuing meaningful careers. The Americans with Disabilities Act (ADA) and the US Equal Employment Opportunity Commission (EEOC) forbid discrimination against qualified people with disabilities, including those with epilepsy, and require reasonable accommodations in the workplace (www.eeoc.gov/laws/guidance/epilepsy-workplace-and-ada).54
CORRESPONDENCE
Gholam K. Motamedi, MD, Department of Neurology, PHC 7, Georgetown University Hospital, 3800 Reservoir Road, NW, Washington, DC 20007; [email protected]
1. Hauser WA, Annegers JF, Rocca WA. Descriptive epidemiology of epilepsy: contributions of population-based studies from Rochester, Minnesota. Mayo Clin Proc. 1996;71:576-586. doi: 10.4065/71.6.576
2. Fisher RS, Acevedo C, Arzimanoglou A, et al. ILAE official report: a practical clinical definition of epilepsy. Epilepsia. 2014;55:475-482. doi: 10.1111/epi.12550.
3. Hauser WA, Beghi E. First seizure definitions and worldwide incidence and mortality. Epilepsia. 2008;49:8-12. doi: 10.1111/j.1528-1167.2008.01443.x
4. Berg AT, Shinnar S. The risk of seizure recurrence following a first unprovoked seizure: a quantitative review. Neurology. 1991;41:965-972. doi: 10.1212/wnl.41.7.965
5. Ropper AH. Transient global amnesia. N Engl J Med. 2023;388:635-540. doi: 10.1056/NEJMra2213867
6. Bouma HK, Labos C, Gore GC, et al. The diagnostic accuracy of routine electroencephalography after a first unprovoked seizure. Eur J Neurol. 2016;23:455-463. doi: 10.1111/ene.12739
7. Narayanan JT, Labar DR, Schaul N. Latency to first spike in the EEG of epilepsy patients. Seizure. 2008;17:34-41. doi: 10.1016/j.seizure.2007.06.003
8. Salmenpera TM, Duncan JS. Imaging in epilepsy. J Neurol Neurosurg Psychiatry. 2005;76:iii2-iii10. doi: 10.1136/jnnp.2005.075135
9. Jackson GD, Berkovic SF, Tress , et al Hippocampal sclerosis can be reliably detected by magnetic resonance imaging. Neurology. 1990;40:1869-1875. doi: 10.1212/wnl.40.12.1869
10. Bonnett LJ, Kim, L, Johnson A, et al. Risk of seizure recurrence in people with single seizures and early epilepsy - model development and external validation. Seizure. 2022;94:26-32. doi: 10.1016/j.seizure.2021.11.007
11. Krumholz A, Wiebe S, Gronseth GS, et al. Evidence-based guideline: management of an unprovoked first seizure in adults: Report of the Guideline Development Subcommittee of the American Academy of Neurology and the American Epilepsy Society. Neurology. 2015;84:1705-1713. doi: 10.1212/WNL.0000000000001487
12. Fisher RS, Cross JH, French JA, et al. Operational classification of seizure types by the International League Against Epilepsy: position paper of the ILAE Commission for Classification and terminology. Epilepsia. 2017;58:522-530. doi: 10.1111/epi.13670
13. Berg AT, Berkovic SF, Brodie MJ, et al. Revised terminology and concepts for organization of seizures and epilepsy: report of the ILAE Commission on Classification and Terminology, 2005-2009. Epilepsia. 2010;51:676-685. doi: 10.1111/j.1528-1167.2010.02522.x
14. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of valproate, lamotrigine, or topiramate for generalized and unclassifiable epilepsy: an unblinded randomized controlled trial. Lancet. 2007;369:1016-1026. doi: 10.1016/S0140-6736(07)60461-9
15. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of carbamazepine, gabapentin, lamotrigine, oxcarbazepine, or topiramate for treatment of partial epilepsy: an unblinded randomized controlled trial. Lancet 2007;369:1000-1015. doi: 10.1016/S0140-6736(07)60460-7
16. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of valproate versus levetiracetam for newly diagnosed generalized and unclassified epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1375-1386. doi: 10.1016/S0140-6736(21)00246-4
17. Mawhinney E, Craig J, Morrow J. Levetiracetam in pregnancy: results from the UK and Ireland epilepsy and pregnancy registers. Neurology. 2013;80:400-405.
18. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of levetiracetam, zonisamide, or lamotrigine for newly diagnosed focal epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1363-1374. doi: 10.1016/S0140-6736(21)00247-6
19. Smith PE. Initial management of seizure in adults. N Engl J Med. 2021;385:251-263. doi: 10.1056/NEJMcp2024526
20. Depakene (valproic acid). Package insert. Abbott Laboratories; 2011. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2011/018081s046_18082s031lbl.pdf
21. Greenberg RG, Melloni C, Wu H, et al. Therapeutic index estimation of antiepileptic drugs: a systematic literature review approach. Clin Neuropharmacol. 2016;39:232-240. doi: 10.1097/WNF.0000000000000172
22. Lamictal (lamotrigine). Package insert. GlaxoSmithKline; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/020241s037s038,020764s030s031lbl.pdf
23. LaRoche SM, Helmers SL. The new antiepileptic drugs: scientific review. JAMA. 2004;291:605-614. doi: 10.1001/jama.291.5.605
24. Topamax (topiramate). Package insert. Janssen Pharmaceuticals, Inc. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2012/020844s041lbl.pdf
25. Keppra (levetiracetam). Package insert. UCB, Inc.; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/021035s078s080%2C021505s021s024lbl.pdf
26. Carbatrol (carbamazepine). Package insert. Shire US Inc; 2013. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2013/020712s032s035lbl.pdf
27.Neurontin (gabapentin). Package insert. Pfizer; 2017. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2017/020235s064_020882s047_021129s046lbl.pdf
28.Zonegran (zonisamide). Package insert. Eisai Inc; 2006. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2006/020789s019lbl.pdf
29.Gloss D, Paragon K, Pack A, et al. Antiseizure medication withdrawal in seizure-free patients: practice advisory update. Report of the AAN Guideline Subcommittee. Neurology. 2021;97:1072-1081. doi: 10.1212/WNL.0000000000012944
30.Kwan P, Brodie MJ. Early identification of refractory epilepsy. N Engl J Med. 2000:342:314-319. doi: 10.1056/NEJM200002033420503
31.Kwan P, Arzimanoglou A, Berg AT, et al. Definition of drug resistant epilepsy: consensus proposal by the ad hoc Task Force of the ILAE Commission on Therapeutic Strategies. Epilepsia. 2010;51:1069-1077. doi: 10.1111/j.1528-1167.2009.02397.x
Compliance during treatment of epilepsy. Epilepsia 1988;29(suppl 2):S79-S84.
33.utter R, Rüegg S, Tschudin-Sutter S. Seizures as adverse events of antibiotic drugs: a systematic review. Neurology. 2015;13;85:1332-1341. doi: 10.1212/WNL.0000000000002023
34.Singh G, Rees JH, Sander JW. Seizures and epilepsy in oncological practice: causes, course, mechanisms and treatment. JNNP. 2007;78:342-349. doi: 10.1136/jnnp.2006.106211
35.Pisani F, Oteri G, Costa C., et al. Effects of psychotropic drugs on seizure threshold. Drug Safety. 2002;25:91-110.
36.Rossi KC, Joe J, Makhjia M, et al. Insufficient sleep, electroencephalogram activation, and seizure risk: re-evaluating the evidence. Ann Neurol. 2020;86:798-806. doi: 10.1002/ana.25710
37.Watson NF, Badr MS, Belenky G, et al. Recommended amount of sleep for a healthy adult: a Joint Consensus Statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep. 2015;38:843-844. doi: 10.5665/sleep.4716
38.Höppener RJ, Kuyer A, van der Lugt PJ. Epilepsy and alcohol: the influence of social alcohol intake on seizures and treatment in epilepsy. Epilepsia. 1983;24:459-471. doi: 10.1111/j.1528-1157.1983.tb04917.x
39.Keeler MH, Reifler CB. Grand mal convulsions subsequent to marijuana use. Case report. Dis Nerv Syst. 1967:28:474-475.
40.Epidiolex (cannabidiol). Package insert. Greenwich Biosciences Inc; 2018. Accessed September 27, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2018/210365lbl.pdf
41.ClinicalTrials.gov. Maternal Outcomes and Neurodevelopmental Effects of Antiseizure Drugs (MONEAD). Accessed September 24, 2023. https://classic.clinicaltrials.gov/ct2/show/NCT01730170
42.Meador KJ, Baker GA, Finnell RH, et al. In utero antiepileptic drug exposure: fetal death and malformations. Neurology. 2006;67:407-412. doi: 10.1212/01.wnl.0000227919.81208.b2
43.Meador K, Reynolds MW, Crean S. Pregnancy outcomes in women with epilepsy: a systematic review and meta-analysis of published pregnancy registries and cohorts. Epilepsy Res. 2008;81:1-13. doi:10.1016/j.eplepsyres.2008.04.022
44.Marxer CA, Rüegg S, Rauch A review of the evidence on the risk of congenital malformations and neurodevelopmental disorders in association with antiseizure medications during pregnancy. Expert Opin Drug Saf. 2021;20:1487-1499. doi: 10.1080/14740338.2021.1943355
Asadi-Pooya AA, Sperling MR. Epidemiology of psychogenic nonepileptic seizures. Epilepsy Behav. 2015;46:60-65. doi: 10.1016/j.yebeh.2015.03.015
Evaluation and treatment of psychogenic nonepileptic seizures. Neurol Clin. 2022;40:799-820. doi: 10.1016/j.ncl.2022.03.017
47.Motamedi GK. Psychogenic nonepileptic seizures: a disconnect between body and mind. Epilepsy Behav. 2018;78:293-294. doi: 10.1016/j.yebeh.2017.10.016
, Nonconvulsive status epilepticus. Emerg Med Clin North Am. 2011;29:65-72. doi: 10.1016/j.emc.2010.08.006
doi: 10.1542/peds.2010-3318
Drug management for acute tonic-clonic convulsions including convulsive status epilepticus in children. Cochrane Database Sys Rev. 2018;1(1):CD001905. doi: 10.1002/14651858.CD001905.pub3
52.Jensen FE. Epilepsy as a spectrum disorder: implications from novel clinical and basic neuroscience. Epilepsia. 2011;52(suppl 1):1-6. doi: 10.1111/j.1528-1167.2010.02904.x
53.Kass JS, Rose RV. Driving and epilepsy: ethical, legal, and health care policy challenges. Continuum (Minneap Minn). 2019;25:537-542. doi: 10.1212/CON.0000000000000714
54.Troxell J. Epilepsy and employment: the Americans with Disabilities Act and its protections against employment discrimination. Med Law. 1997;16:375-384.
1. Hauser WA, Annegers JF, Rocca WA. Descriptive epidemiology of epilepsy: contributions of population-based studies from Rochester, Minnesota. Mayo Clin Proc. 1996;71:576-586. doi: 10.4065/71.6.576
2. Fisher RS, Acevedo C, Arzimanoglou A, et al. ILAE official report: a practical clinical definition of epilepsy. Epilepsia. 2014;55:475-482. doi: 10.1111/epi.12550.
3. Hauser WA, Beghi E. First seizure definitions and worldwide incidence and mortality. Epilepsia. 2008;49:8-12. doi: 10.1111/j.1528-1167.2008.01443.x
4. Berg AT, Shinnar S. The risk of seizure recurrence following a first unprovoked seizure: a quantitative review. Neurology. 1991;41:965-972. doi: 10.1212/wnl.41.7.965
5. Ropper AH. Transient global amnesia. N Engl J Med. 2023;388:635-540. doi: 10.1056/NEJMra2213867
6. Bouma HK, Labos C, Gore GC, et al. The diagnostic accuracy of routine electroencephalography after a first unprovoked seizure. Eur J Neurol. 2016;23:455-463. doi: 10.1111/ene.12739
7. Narayanan JT, Labar DR, Schaul N. Latency to first spike in the EEG of epilepsy patients. Seizure. 2008;17:34-41. doi: 10.1016/j.seizure.2007.06.003
8. Salmenpera TM, Duncan JS. Imaging in epilepsy. J Neurol Neurosurg Psychiatry. 2005;76:iii2-iii10. doi: 10.1136/jnnp.2005.075135
9. Jackson GD, Berkovic SF, Tress , et al Hippocampal sclerosis can be reliably detected by magnetic resonance imaging. Neurology. 1990;40:1869-1875. doi: 10.1212/wnl.40.12.1869
10. Bonnett LJ, Kim, L, Johnson A, et al. Risk of seizure recurrence in people with single seizures and early epilepsy - model development and external validation. Seizure. 2022;94:26-32. doi: 10.1016/j.seizure.2021.11.007
11. Krumholz A, Wiebe S, Gronseth GS, et al. Evidence-based guideline: management of an unprovoked first seizure in adults: Report of the Guideline Development Subcommittee of the American Academy of Neurology and the American Epilepsy Society. Neurology. 2015;84:1705-1713. doi: 10.1212/WNL.0000000000001487
12. Fisher RS, Cross JH, French JA, et al. Operational classification of seizure types by the International League Against Epilepsy: position paper of the ILAE Commission for Classification and terminology. Epilepsia. 2017;58:522-530. doi: 10.1111/epi.13670
13. Berg AT, Berkovic SF, Brodie MJ, et al. Revised terminology and concepts for organization of seizures and epilepsy: report of the ILAE Commission on Classification and Terminology, 2005-2009. Epilepsia. 2010;51:676-685. doi: 10.1111/j.1528-1167.2010.02522.x
14. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of valproate, lamotrigine, or topiramate for generalized and unclassifiable epilepsy: an unblinded randomized controlled trial. Lancet. 2007;369:1016-1026. doi: 10.1016/S0140-6736(07)60461-9
15. Marson AG, Al-Kharusi AM, Alwaidh M, et al. The SANAD study of effectiveness of carbamazepine, gabapentin, lamotrigine, oxcarbazepine, or topiramate for treatment of partial epilepsy: an unblinded randomized controlled trial. Lancet 2007;369:1000-1015. doi: 10.1016/S0140-6736(07)60460-7
16. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of valproate versus levetiracetam for newly diagnosed generalized and unclassified epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1375-1386. doi: 10.1016/S0140-6736(21)00246-4
17. Mawhinney E, Craig J, Morrow J. Levetiracetam in pregnancy: results from the UK and Ireland epilepsy and pregnancy registers. Neurology. 2013;80:400-405.
18. Marson A, Burnside G, Appleton R, et al. The SANAD II study of the effectiveness and cost-effectiveness of levetiracetam, zonisamide, or lamotrigine for newly diagnosed focal epilepsy: an open-label, non-inferiority, multicentre, phase 4, randomized controlled trial. Lancet. 2021;397:1363-1374. doi: 10.1016/S0140-6736(21)00247-6
19. Smith PE. Initial management of seizure in adults. N Engl J Med. 2021;385:251-263. doi: 10.1056/NEJMcp2024526
20. Depakene (valproic acid). Package insert. Abbott Laboratories; 2011. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2011/018081s046_18082s031lbl.pdf
21. Greenberg RG, Melloni C, Wu H, et al. Therapeutic index estimation of antiepileptic drugs: a systematic literature review approach. Clin Neuropharmacol. 2016;39:232-240. doi: 10.1097/WNF.0000000000000172
22. Lamictal (lamotrigine). Package insert. GlaxoSmithKline; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/020241s037s038,020764s030s031lbl.pdf
23. LaRoche SM, Helmers SL. The new antiepileptic drugs: scientific review. JAMA. 2004;291:605-614. doi: 10.1001/jama.291.5.605
24. Topamax (topiramate). Package insert. Janssen Pharmaceuticals, Inc. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2012/020844s041lbl.pdf
25. Keppra (levetiracetam). Package insert. UCB, Inc.; 2009. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2009/021035s078s080%2C021505s021s024lbl.pdf
26. Carbatrol (carbamazepine). Package insert. Shire US Inc; 2013. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2013/020712s032s035lbl.pdf
27.Neurontin (gabapentin). Package insert. Pfizer; 2017. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2017/020235s064_020882s047_021129s046lbl.pdf
28.Zonegran (zonisamide). Package insert. Eisai Inc; 2006. Accessed October 6, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2006/020789s019lbl.pdf
29.Gloss D, Paragon K, Pack A, et al. Antiseizure medication withdrawal in seizure-free patients: practice advisory update. Report of the AAN Guideline Subcommittee. Neurology. 2021;97:1072-1081. doi: 10.1212/WNL.0000000000012944
30.Kwan P, Brodie MJ. Early identification of refractory epilepsy. N Engl J Med. 2000:342:314-319. doi: 10.1056/NEJM200002033420503
31.Kwan P, Arzimanoglou A, Berg AT, et al. Definition of drug resistant epilepsy: consensus proposal by the ad hoc Task Force of the ILAE Commission on Therapeutic Strategies. Epilepsia. 2010;51:1069-1077. doi: 10.1111/j.1528-1167.2009.02397.x
Compliance during treatment of epilepsy. Epilepsia 1988;29(suppl 2):S79-S84.
33.utter R, Rüegg S, Tschudin-Sutter S. Seizures as adverse events of antibiotic drugs: a systematic review. Neurology. 2015;13;85:1332-1341. doi: 10.1212/WNL.0000000000002023
34.Singh G, Rees JH, Sander JW. Seizures and epilepsy in oncological practice: causes, course, mechanisms and treatment. JNNP. 2007;78:342-349. doi: 10.1136/jnnp.2006.106211
35.Pisani F, Oteri G, Costa C., et al. Effects of psychotropic drugs on seizure threshold. Drug Safety. 2002;25:91-110.
36.Rossi KC, Joe J, Makhjia M, et al. Insufficient sleep, electroencephalogram activation, and seizure risk: re-evaluating the evidence. Ann Neurol. 2020;86:798-806. doi: 10.1002/ana.25710
37.Watson NF, Badr MS, Belenky G, et al. Recommended amount of sleep for a healthy adult: a Joint Consensus Statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep. 2015;38:843-844. doi: 10.5665/sleep.4716
38.Höppener RJ, Kuyer A, van der Lugt PJ. Epilepsy and alcohol: the influence of social alcohol intake on seizures and treatment in epilepsy. Epilepsia. 1983;24:459-471. doi: 10.1111/j.1528-1157.1983.tb04917.x
39.Keeler MH, Reifler CB. Grand mal convulsions subsequent to marijuana use. Case report. Dis Nerv Syst. 1967:28:474-475.
40.Epidiolex (cannabidiol). Package insert. Greenwich Biosciences Inc; 2018. Accessed September 27, 2023. www.accessdata.fda.gov/drugsatfda_docs/label/2018/210365lbl.pdf
41.ClinicalTrials.gov. Maternal Outcomes and Neurodevelopmental Effects of Antiseizure Drugs (MONEAD). Accessed September 24, 2023. https://classic.clinicaltrials.gov/ct2/show/NCT01730170
42.Meador KJ, Baker GA, Finnell RH, et al. In utero antiepileptic drug exposure: fetal death and malformations. Neurology. 2006;67:407-412. doi: 10.1212/01.wnl.0000227919.81208.b2
43.Meador K, Reynolds MW, Crean S. Pregnancy outcomes in women with epilepsy: a systematic review and meta-analysis of published pregnancy registries and cohorts. Epilepsy Res. 2008;81:1-13. doi:10.1016/j.eplepsyres.2008.04.022
44.Marxer CA, Rüegg S, Rauch A review of the evidence on the risk of congenital malformations and neurodevelopmental disorders in association with antiseizure medications during pregnancy. Expert Opin Drug Saf. 2021;20:1487-1499. doi: 10.1080/14740338.2021.1943355
Asadi-Pooya AA, Sperling MR. Epidemiology of psychogenic nonepileptic seizures. Epilepsy Behav. 2015;46:60-65. doi: 10.1016/j.yebeh.2015.03.015
Evaluation and treatment of psychogenic nonepileptic seizures. Neurol Clin. 2022;40:799-820. doi: 10.1016/j.ncl.2022.03.017
47.Motamedi GK. Psychogenic nonepileptic seizures: a disconnect between body and mind. Epilepsy Behav. 2018;78:293-294. doi: 10.1016/j.yebeh.2017.10.016
, Nonconvulsive status epilepticus. Emerg Med Clin North Am. 2011;29:65-72. doi: 10.1016/j.emc.2010.08.006
doi: 10.1542/peds.2010-3318
Drug management for acute tonic-clonic convulsions including convulsive status epilepticus in children. Cochrane Database Sys Rev. 2018;1(1):CD001905. doi: 10.1002/14651858.CD001905.pub3
52.Jensen FE. Epilepsy as a spectrum disorder: implications from novel clinical and basic neuroscience. Epilepsia. 2011;52(suppl 1):1-6. doi: 10.1111/j.1528-1167.2010.02904.x
53.Kass JS, Rose RV. Driving and epilepsy: ethical, legal, and health care policy challenges. Continuum (Minneap Minn). 2019;25:537-542. doi: 10.1212/CON.0000000000000714
54.Troxell J. Epilepsy and employment: the Americans with Disabilities Act and its protections against employment discrimination. Med Law. 1997;16:375-384.
PRACTICE RECOMMENDATIONS
› Consider treating a first-time seizure if electroencephalography shows particular epileptiform activity, if the neurologic exam or computerized tomography or magnetic resonance imaging results are abnormal, if the seizure is focal or nocturnal, or if there is a family history of seizures. A
› Consider valproate (except for women of childbearing age) and levetiracetam as first-line agents for generalized or unclassified epilepsy, and lamotrigine for focal epilepsies. A
Strength of recommendation (SOR)
A Good-quality patient-oriented evidence
B Inconsistent or limited-quality patient-oriented evidence
C Consensus, usual practice, opinion, disease-oriented evidence, case series
Stroke patients benefit from neurologic music therapy
Neurologic music therapy (NMT), a specially designed intervention targeting movement, balance, and cognitive functioning, improves depressive symptoms and increases brain-derived neurotrophic factor (BDNF), early results of a small study suggest.
“We’re really happy with the results,” said lead study author psychotherapist Honey Bryant, a PhD candidate and research assistant at the Centre for Neuroscience Studies, Queen’s University, Kingston, Ont.
“We showed ”
The findings were presented at the virtual XXVI World Congress of Neurology.
Moving with music
With improved stroke survival rates and longer life expectancy, there’s an increasing need for effective post-stroke interventions for neurocognitive impairments and mood disorders, the authors noted.
NMT is an evidence-based treatment system that uses elements of music such as rhythm, melody, and tempo to treat various brain conditions. A trained NMT therapist uses standardized techniques to address goals in the areas of speech, movement, and cognition.
The intervention is not new – it’s been around for a few decades – but there are “minimal papers on NMT and nothing on stroke rehabilitation used in the way we did it,” said Ms. Bryant.
The study included 57 patients, mean age 75 years, receiving rehabilitation following a stroke who were randomly assigned to NMT or passive music listening.
In the NMT group, a music therapist asked participants to choose music beforehand and integrated this into each session.
“Each day was different,” said Ms. Bryant. “For example, if it involved motor movement, the music therapist would say, ‘When I sing this word, raise your arm up.’ For Johnny Cash’s ‘Ring of Fire,’ we made our arms into a circle.”
She explained that the rhythm and timing of the music can affect the motor system and other areas of the brain.
Those in the passive music group listened to a curated list of calming classical and relaxing spa music.
Both groups were offered five 45-minute sessions per week for 2 weeks.
Among other things, researchers used the Hospital Anxiety and Depression Scale (HADS), administered a semistructured interview, and collected blood samples to determine levels of cortisol and BDNF.
After the 2-week intervention, the researchers found participants in the NMT group had a significant mean decrease in depression.
They also had increased cortisol levels, which is not unexpected after a stroke, especially with increased anxiety linked to financial and other stressors, said Ms. Bryant, adding these levels should decrease with treatment.
Recipients of the NMT had significant increases in BDNF, a neurotrophin that plays an important role in neuronal survival and growth, but only in those who attended several consecutive sessions.
Increased plasticity
“We see greater increases in plasticity when the therapy is used intensively, meaning at least four treatments consecutively,” said Ms. Bryant. Participants in the NMT group also reported they “overall felt well,” she added.
She noted NMT can be tailored to individual deficit, “so you can make it solely for motor movement or you can make it solely for language.”
Next steps could include more closely targeting the music to individual preferences and investigating whether the benefits of the intervention extend to other types of brain injury, for example traumatic brain injury, which typically affects younger people, said Ms. Bryant.
“In this study, participants were older and there was an unknown; a lot of them were going back into the community but didn’t know if it was into a retirement home or long-term care.”
It’s unclear if the benefits are sustained after the intervention stops, she said.
There are also the issues of cost and accessibility; in Kingston, there are few music therapists certified in the area of NMT.
Ms. Bryant hopes NMT is eventually included in stroke rehabilitation. “Stroke therapy is typically very intensive on its own; you’re doing it every single day for about a month or 6 weeks,” she said. “It would be interesting to see whether we would see a shorter hospital stay if this is included in stroke rehab.”
Asked to comment, Michael H. Thaut, PhD, professor, faculty of music and faculty of medicine, and Canada research chair in music, neuroscience and health at the University of Toronto, said while these data are preliminary, “they do extend the benefits of NMT in stroke rehabilitation, especially measuring BDNF in addition to having behavioral data.”
However, it’s “unfortunate” the poster didn’t specify which cognitive intervention techniques were used in the study, said Dr. Thaut. “There are nine coded techniques in NMT, including for attention, memory, psychosocial function, and executive function.”
His own study, published in NeuroRehabilitation, focused on training for motor goals in stroke patients. It showed that NMT benefited cognitive functioning and affective responses.
The study was funded by a Queen’s University Research Initiation Grant. Ms. Bryant and Dr. Thaut have not disclosed any relevant financial relationships.
A version of this article first appeared on Medscape.com.
Neurologic music therapy (NMT), a specially designed intervention targeting movement, balance, and cognitive functioning, improves depressive symptoms and increases brain-derived neurotrophic factor (BDNF), early results of a small study suggest.
“We’re really happy with the results,” said lead study author psychotherapist Honey Bryant, a PhD candidate and research assistant at the Centre for Neuroscience Studies, Queen’s University, Kingston, Ont.
“We showed ”
The findings were presented at the virtual XXVI World Congress of Neurology.
Moving with music
With improved stroke survival rates and longer life expectancy, there’s an increasing need for effective post-stroke interventions for neurocognitive impairments and mood disorders, the authors noted.
NMT is an evidence-based treatment system that uses elements of music such as rhythm, melody, and tempo to treat various brain conditions. A trained NMT therapist uses standardized techniques to address goals in the areas of speech, movement, and cognition.
The intervention is not new – it’s been around for a few decades – but there are “minimal papers on NMT and nothing on stroke rehabilitation used in the way we did it,” said Ms. Bryant.
The study included 57 patients, mean age 75 years, receiving rehabilitation following a stroke who were randomly assigned to NMT or passive music listening.
In the NMT group, a music therapist asked participants to choose music beforehand and integrated this into each session.
“Each day was different,” said Ms. Bryant. “For example, if it involved motor movement, the music therapist would say, ‘When I sing this word, raise your arm up.’ For Johnny Cash’s ‘Ring of Fire,’ we made our arms into a circle.”
She explained that the rhythm and timing of the music can affect the motor system and other areas of the brain.
Those in the passive music group listened to a curated list of calming classical and relaxing spa music.
Both groups were offered five 45-minute sessions per week for 2 weeks.
Among other things, researchers used the Hospital Anxiety and Depression Scale (HADS), administered a semistructured interview, and collected blood samples to determine levels of cortisol and BDNF.
After the 2-week intervention, the researchers found participants in the NMT group had a significant mean decrease in depression.
They also had increased cortisol levels, which is not unexpected after a stroke, especially with increased anxiety linked to financial and other stressors, said Ms. Bryant, adding these levels should decrease with treatment.
Recipients of the NMT had significant increases in BDNF, a neurotrophin that plays an important role in neuronal survival and growth, but only in those who attended several consecutive sessions.
Increased plasticity
“We see greater increases in plasticity when the therapy is used intensively, meaning at least four treatments consecutively,” said Ms. Bryant. Participants in the NMT group also reported they “overall felt well,” she added.
She noted NMT can be tailored to individual deficit, “so you can make it solely for motor movement or you can make it solely for language.”
Next steps could include more closely targeting the music to individual preferences and investigating whether the benefits of the intervention extend to other types of brain injury, for example traumatic brain injury, which typically affects younger people, said Ms. Bryant.
“In this study, participants were older and there was an unknown; a lot of them were going back into the community but didn’t know if it was into a retirement home or long-term care.”
It’s unclear if the benefits are sustained after the intervention stops, she said.
There are also the issues of cost and accessibility; in Kingston, there are few music therapists certified in the area of NMT.
Ms. Bryant hopes NMT is eventually included in stroke rehabilitation. “Stroke therapy is typically very intensive on its own; you’re doing it every single day for about a month or 6 weeks,” she said. “It would be interesting to see whether we would see a shorter hospital stay if this is included in stroke rehab.”
Asked to comment, Michael H. Thaut, PhD, professor, faculty of music and faculty of medicine, and Canada research chair in music, neuroscience and health at the University of Toronto, said while these data are preliminary, “they do extend the benefits of NMT in stroke rehabilitation, especially measuring BDNF in addition to having behavioral data.”
However, it’s “unfortunate” the poster didn’t specify which cognitive intervention techniques were used in the study, said Dr. Thaut. “There are nine coded techniques in NMT, including for attention, memory, psychosocial function, and executive function.”
His own study, published in NeuroRehabilitation, focused on training for motor goals in stroke patients. It showed that NMT benefited cognitive functioning and affective responses.
The study was funded by a Queen’s University Research Initiation Grant. Ms. Bryant and Dr. Thaut have not disclosed any relevant financial relationships.
A version of this article first appeared on Medscape.com.
Neurologic music therapy (NMT), a specially designed intervention targeting movement, balance, and cognitive functioning, improves depressive symptoms and increases brain-derived neurotrophic factor (BDNF), early results of a small study suggest.
“We’re really happy with the results,” said lead study author psychotherapist Honey Bryant, a PhD candidate and research assistant at the Centre for Neuroscience Studies, Queen’s University, Kingston, Ont.
“We showed ”
The findings were presented at the virtual XXVI World Congress of Neurology.
Moving with music
With improved stroke survival rates and longer life expectancy, there’s an increasing need for effective post-stroke interventions for neurocognitive impairments and mood disorders, the authors noted.
NMT is an evidence-based treatment system that uses elements of music such as rhythm, melody, and tempo to treat various brain conditions. A trained NMT therapist uses standardized techniques to address goals in the areas of speech, movement, and cognition.
The intervention is not new – it’s been around for a few decades – but there are “minimal papers on NMT and nothing on stroke rehabilitation used in the way we did it,” said Ms. Bryant.
The study included 57 patients, mean age 75 years, receiving rehabilitation following a stroke who were randomly assigned to NMT or passive music listening.
In the NMT group, a music therapist asked participants to choose music beforehand and integrated this into each session.
“Each day was different,” said Ms. Bryant. “For example, if it involved motor movement, the music therapist would say, ‘When I sing this word, raise your arm up.’ For Johnny Cash’s ‘Ring of Fire,’ we made our arms into a circle.”
She explained that the rhythm and timing of the music can affect the motor system and other areas of the brain.
Those in the passive music group listened to a curated list of calming classical and relaxing spa music.
Both groups were offered five 45-minute sessions per week for 2 weeks.
Among other things, researchers used the Hospital Anxiety and Depression Scale (HADS), administered a semistructured interview, and collected blood samples to determine levels of cortisol and BDNF.
After the 2-week intervention, the researchers found participants in the NMT group had a significant mean decrease in depression.
They also had increased cortisol levels, which is not unexpected after a stroke, especially with increased anxiety linked to financial and other stressors, said Ms. Bryant, adding these levels should decrease with treatment.
Recipients of the NMT had significant increases in BDNF, a neurotrophin that plays an important role in neuronal survival and growth, but only in those who attended several consecutive sessions.
Increased plasticity
“We see greater increases in plasticity when the therapy is used intensively, meaning at least four treatments consecutively,” said Ms. Bryant. Participants in the NMT group also reported they “overall felt well,” she added.
She noted NMT can be tailored to individual deficit, “so you can make it solely for motor movement or you can make it solely for language.”
Next steps could include more closely targeting the music to individual preferences and investigating whether the benefits of the intervention extend to other types of brain injury, for example traumatic brain injury, which typically affects younger people, said Ms. Bryant.
“In this study, participants were older and there was an unknown; a lot of them were going back into the community but didn’t know if it was into a retirement home or long-term care.”
It’s unclear if the benefits are sustained after the intervention stops, she said.
There are also the issues of cost and accessibility; in Kingston, there are few music therapists certified in the area of NMT.
Ms. Bryant hopes NMT is eventually included in stroke rehabilitation. “Stroke therapy is typically very intensive on its own; you’re doing it every single day for about a month or 6 weeks,” she said. “It would be interesting to see whether we would see a shorter hospital stay if this is included in stroke rehab.”
Asked to comment, Michael H. Thaut, PhD, professor, faculty of music and faculty of medicine, and Canada research chair in music, neuroscience and health at the University of Toronto, said while these data are preliminary, “they do extend the benefits of NMT in stroke rehabilitation, especially measuring BDNF in addition to having behavioral data.”
However, it’s “unfortunate” the poster didn’t specify which cognitive intervention techniques were used in the study, said Dr. Thaut. “There are nine coded techniques in NMT, including for attention, memory, psychosocial function, and executive function.”
His own study, published in NeuroRehabilitation, focused on training for motor goals in stroke patients. It showed that NMT benefited cognitive functioning and affective responses.
The study was funded by a Queen’s University Research Initiation Grant. Ms. Bryant and Dr. Thaut have not disclosed any relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM WCN 2023
‘Hidden’ cognitive impairments in DMD may worsen outcomes
A new tool from the National Institutes of Health, called NIH Toolbox, could improve that outcome, according to Mathula Thangarajh, MD, PhD, who has conducted research in the field.
“When we talk to families and parents, they are able to identify that even during infancy that [children with DMD] have delayed cognitive function. This includes speech delay, but also language and adaptive skills. We also know that those children with speech delay, which is really a very commonly reported phenotype in up to 50%, go on to have school-based needs. They may repeat [grades] in elementary years, but they also use more resources at school,” said Dr. Thangarajh, who is an assistant professor of neurology at the Children’s Hospital of Richmond at Virginia Commonwealth University, Richmond, during a talk at the 2023 annual meeting of the American Association for Neuromuscular and Electrodiagnostic Medicine (AANEM).
A previous natural history study that utilized the Pediatric Quality of Life assessment also showed that DMD patients reported the lowest scores in brain health, including emotional health and school performance.
Other research has shown a correlation between cognitive function and survival in DMD. “This suggests that health maintenance may play an important role [in outcomes],” said Dr. Thangarajh. Another study found a correlation between psychomotor delay that required school-based interventions and earlier loss of ambulation, lower cardiac ejection fraction, and worse pulmonary function. The researchers also found that boys with cognitive delay were diagnosed at an earlier age, and yet had delays in diagnosis and worse motor function, pulmonary health, and cardiac health outcomes. On average, they lost ambulatory ability 2 years earlier.
A study by Dr. Thangarajh’s group showed that patients with speech delay and lower IQ had lower performance in timed tests, including 6-minute walk test distance and scored an average of 2 points lower on the North Star Ambulatory Assessment.
A tool for continuous cognitive assessment
The Centers for Disease Control and Prevention–supported DMD CARE guidelines only say that neuropsychological evaluations should be considered at diagnosis, but is essential if concerns arise about developmental progress. However, the Muscular Dystrophy Association has found barriers both in access to specialists, with an average wait time of 1-2 years, and burdensome out-of-pocket costs.
Those issues prompted Dr. Thangarajh to look for an alternative solution. At the time that she embarked on this work, the NIH was interested in technologies to assess neurobehavioral issues across different diseases. The resulting NIH Toolbox iPad app was driven largely by failed clinical trials in dementia, and the aim was to be able to provide continuous assessment over time. “It will allow for assessments across the lifespan, so you can use the same construct from age 3 to 80-plus,” said Dr. Thangarajh. It can also normalize population factors, such as annual household income and mother’s IQ.
She set out to validate the NIH Toolbox in children with DMD. The toolbox includes measures of crystalized cognition and fluid cognition. The former encompasses vocabulary and reading ability, which are strongly predicted by socioeconomic status and maternal IQ. On the other hand, fluid cognition includes cognitive features that develop across the lifespan and is directly related to academic underperformance in DMD patients.
Dr. Thangarajh’s group assessed 30 boys with DMD and found that crystallized cognition was normal, but they had a deficit in fluid cognition. They found deficits within several subdomains of fluid cognition. “This tells us that the NIH Toolbox was able to replicate what we had known in the literature, that these boys really have lower intellectual capacity, but they also have significant weakness in fluid cognition,” she said.
She also wanted to examine changes over time by testing the boys at a 1-year interview. “What we found was that they are not making as much gain in fluid cognition as we would like. They are just making marginal improvements over time. This has implications on how often we should screen them, but also not be over reliant on using school-based resources for them to get tested,” said Dr. Thangarajh.
Her group’s analysis of a dataset of 55 boys provided by PTC Therapeutics revealed a difference by age in a test of working memory. “What we found was that boys who are actually greater than 9 years, compared with those who are less than 9 years, they actually had a reversal of development-based improvement. The older they get, they were not making as much gains as you would expect,” said Dr. Thangarajh.
She went on to discuss psychosocial determinants of cognitive health in DMD. It is known that women who are carriers of the dystrophin mutation can underperform in cognitively stressful tasks, leading her to wonder if this could lead to transgenerational risk to offspring with DMD. Her group tested women who were carriers of the mutation with the NIH Toolbox and found that they had lower fluid cognition than noncarriers. They then tested 65 dyads of mothers and children, and found a correlation, but only when it came to inhibitory control, which required the individual to note the direction of an arrow while ignoring surrounding arrows pointing in various directions.
Next, the researchers examined neighborhoods and their impact on cognitive health, which can be affected by the presence of green spaces, access to public transportation and good nutrition, and other factors. There were significant deficits associated with residence zip codes. “We were pretty shocked. Someone who is not in a socially vulnerable region is scoring slightly below average, but someone who is in a very socially vulnerable neighborhood is only scoring 75 [age-adjusted score] on the NIH toolbox. So with this, we can conclude that carrier women are vulnerable in certain cognitive domains, but also children who come from socially vulnerable [situations] have poor cognitive control. This, again, has implications on how often we should screen and how much we should overly rely on school-based resources for these individuals,” said Dr. Thangarajh.
Overcoming a significant barrier
The NIH Toolbox has a lot of potential to improve DMD care, according to Dianna Quan, MD, who is the incoming president of AANEM, and professor of neurology at the University of Colorado at Denver, Aurora. “There’s this huge problem in terms of getting people in to see neuropsychologists and having formal evaluations. I think that’s a huge barrier. If we have people able to access this toolkit, which is simple and easily and universally accessible, how wonderful is that? I think that will be a really great improvement on what’s going on right now. It allows people to easily screen for these cognitive disabilities and make sure that we address them,” Dr. Quan said in an interview.
Asked how the tool could specifically improve care, Dr. Quan suggested that the first step is to understand the contributing factors to cognitive issues, whether they are biological, social, or a combination. “Some of them we can modify, potentially, through addressing the social environment. Some of those biologic factors may also be modifiable with many of the new drug studies that are coming.”
Dr. Thangarajh has received speaker honoraria from NS Pharma and PTC Therapeutics. Dr. Quan has received funding from Alnylam, Pfizer, Cytokinetics, Momenta, and Argenx.
A new tool from the National Institutes of Health, called NIH Toolbox, could improve that outcome, according to Mathula Thangarajh, MD, PhD, who has conducted research in the field.
“When we talk to families and parents, they are able to identify that even during infancy that [children with DMD] have delayed cognitive function. This includes speech delay, but also language and adaptive skills. We also know that those children with speech delay, which is really a very commonly reported phenotype in up to 50%, go on to have school-based needs. They may repeat [grades] in elementary years, but they also use more resources at school,” said Dr. Thangarajh, who is an assistant professor of neurology at the Children’s Hospital of Richmond at Virginia Commonwealth University, Richmond, during a talk at the 2023 annual meeting of the American Association for Neuromuscular and Electrodiagnostic Medicine (AANEM).
A previous natural history study that utilized the Pediatric Quality of Life assessment also showed that DMD patients reported the lowest scores in brain health, including emotional health and school performance.
Other research has shown a correlation between cognitive function and survival in DMD. “This suggests that health maintenance may play an important role [in outcomes],” said Dr. Thangarajh. Another study found a correlation between psychomotor delay that required school-based interventions and earlier loss of ambulation, lower cardiac ejection fraction, and worse pulmonary function. The researchers also found that boys with cognitive delay were diagnosed at an earlier age, and yet had delays in diagnosis and worse motor function, pulmonary health, and cardiac health outcomes. On average, they lost ambulatory ability 2 years earlier.
A study by Dr. Thangarajh’s group showed that patients with speech delay and lower IQ had lower performance in timed tests, including 6-minute walk test distance and scored an average of 2 points lower on the North Star Ambulatory Assessment.
A tool for continuous cognitive assessment
The Centers for Disease Control and Prevention–supported DMD CARE guidelines only say that neuropsychological evaluations should be considered at diagnosis, but is essential if concerns arise about developmental progress. However, the Muscular Dystrophy Association has found barriers both in access to specialists, with an average wait time of 1-2 years, and burdensome out-of-pocket costs.
Those issues prompted Dr. Thangarajh to look for an alternative solution. At the time that she embarked on this work, the NIH was interested in technologies to assess neurobehavioral issues across different diseases. The resulting NIH Toolbox iPad app was driven largely by failed clinical trials in dementia, and the aim was to be able to provide continuous assessment over time. “It will allow for assessments across the lifespan, so you can use the same construct from age 3 to 80-plus,” said Dr. Thangarajh. It can also normalize population factors, such as annual household income and mother’s IQ.
She set out to validate the NIH Toolbox in children with DMD. The toolbox includes measures of crystalized cognition and fluid cognition. The former encompasses vocabulary and reading ability, which are strongly predicted by socioeconomic status and maternal IQ. On the other hand, fluid cognition includes cognitive features that develop across the lifespan and is directly related to academic underperformance in DMD patients.
Dr. Thangarajh’s group assessed 30 boys with DMD and found that crystallized cognition was normal, but they had a deficit in fluid cognition. They found deficits within several subdomains of fluid cognition. “This tells us that the NIH Toolbox was able to replicate what we had known in the literature, that these boys really have lower intellectual capacity, but they also have significant weakness in fluid cognition,” she said.
She also wanted to examine changes over time by testing the boys at a 1-year interview. “What we found was that they are not making as much gain in fluid cognition as we would like. They are just making marginal improvements over time. This has implications on how often we should screen them, but also not be over reliant on using school-based resources for them to get tested,” said Dr. Thangarajh.
Her group’s analysis of a dataset of 55 boys provided by PTC Therapeutics revealed a difference by age in a test of working memory. “What we found was that boys who are actually greater than 9 years, compared with those who are less than 9 years, they actually had a reversal of development-based improvement. The older they get, they were not making as much gains as you would expect,” said Dr. Thangarajh.
She went on to discuss psychosocial determinants of cognitive health in DMD. It is known that women who are carriers of the dystrophin mutation can underperform in cognitively stressful tasks, leading her to wonder if this could lead to transgenerational risk to offspring with DMD. Her group tested women who were carriers of the mutation with the NIH Toolbox and found that they had lower fluid cognition than noncarriers. They then tested 65 dyads of mothers and children, and found a correlation, but only when it came to inhibitory control, which required the individual to note the direction of an arrow while ignoring surrounding arrows pointing in various directions.
Next, the researchers examined neighborhoods and their impact on cognitive health, which can be affected by the presence of green spaces, access to public transportation and good nutrition, and other factors. There were significant deficits associated with residence zip codes. “We were pretty shocked. Someone who is not in a socially vulnerable region is scoring slightly below average, but someone who is in a very socially vulnerable neighborhood is only scoring 75 [age-adjusted score] on the NIH toolbox. So with this, we can conclude that carrier women are vulnerable in certain cognitive domains, but also children who come from socially vulnerable [situations] have poor cognitive control. This, again, has implications on how often we should screen and how much we should overly rely on school-based resources for these individuals,” said Dr. Thangarajh.
Overcoming a significant barrier
The NIH Toolbox has a lot of potential to improve DMD care, according to Dianna Quan, MD, who is the incoming president of AANEM, and professor of neurology at the University of Colorado at Denver, Aurora. “There’s this huge problem in terms of getting people in to see neuropsychologists and having formal evaluations. I think that’s a huge barrier. If we have people able to access this toolkit, which is simple and easily and universally accessible, how wonderful is that? I think that will be a really great improvement on what’s going on right now. It allows people to easily screen for these cognitive disabilities and make sure that we address them,” Dr. Quan said in an interview.
Asked how the tool could specifically improve care, Dr. Quan suggested that the first step is to understand the contributing factors to cognitive issues, whether they are biological, social, or a combination. “Some of them we can modify, potentially, through addressing the social environment. Some of those biologic factors may also be modifiable with many of the new drug studies that are coming.”
Dr. Thangarajh has received speaker honoraria from NS Pharma and PTC Therapeutics. Dr. Quan has received funding from Alnylam, Pfizer, Cytokinetics, Momenta, and Argenx.
A new tool from the National Institutes of Health, called NIH Toolbox, could improve that outcome, according to Mathula Thangarajh, MD, PhD, who has conducted research in the field.
“When we talk to families and parents, they are able to identify that even during infancy that [children with DMD] have delayed cognitive function. This includes speech delay, but also language and adaptive skills. We also know that those children with speech delay, which is really a very commonly reported phenotype in up to 50%, go on to have school-based needs. They may repeat [grades] in elementary years, but they also use more resources at school,” said Dr. Thangarajh, who is an assistant professor of neurology at the Children’s Hospital of Richmond at Virginia Commonwealth University, Richmond, during a talk at the 2023 annual meeting of the American Association for Neuromuscular and Electrodiagnostic Medicine (AANEM).
A previous natural history study that utilized the Pediatric Quality of Life assessment also showed that DMD patients reported the lowest scores in brain health, including emotional health and school performance.
Other research has shown a correlation between cognitive function and survival in DMD. “This suggests that health maintenance may play an important role [in outcomes],” said Dr. Thangarajh. Another study found a correlation between psychomotor delay that required school-based interventions and earlier loss of ambulation, lower cardiac ejection fraction, and worse pulmonary function. The researchers also found that boys with cognitive delay were diagnosed at an earlier age, and yet had delays in diagnosis and worse motor function, pulmonary health, and cardiac health outcomes. On average, they lost ambulatory ability 2 years earlier.
A study by Dr. Thangarajh’s group showed that patients with speech delay and lower IQ had lower performance in timed tests, including 6-minute walk test distance and scored an average of 2 points lower on the North Star Ambulatory Assessment.
A tool for continuous cognitive assessment
The Centers for Disease Control and Prevention–supported DMD CARE guidelines only say that neuropsychological evaluations should be considered at diagnosis, but is essential if concerns arise about developmental progress. However, the Muscular Dystrophy Association has found barriers both in access to specialists, with an average wait time of 1-2 years, and burdensome out-of-pocket costs.
Those issues prompted Dr. Thangarajh to look for an alternative solution. At the time that she embarked on this work, the NIH was interested in technologies to assess neurobehavioral issues across different diseases. The resulting NIH Toolbox iPad app was driven largely by failed clinical trials in dementia, and the aim was to be able to provide continuous assessment over time. “It will allow for assessments across the lifespan, so you can use the same construct from age 3 to 80-plus,” said Dr. Thangarajh. It can also normalize population factors, such as annual household income and mother’s IQ.
She set out to validate the NIH Toolbox in children with DMD. The toolbox includes measures of crystalized cognition and fluid cognition. The former encompasses vocabulary and reading ability, which are strongly predicted by socioeconomic status and maternal IQ. On the other hand, fluid cognition includes cognitive features that develop across the lifespan and is directly related to academic underperformance in DMD patients.
Dr. Thangarajh’s group assessed 30 boys with DMD and found that crystallized cognition was normal, but they had a deficit in fluid cognition. They found deficits within several subdomains of fluid cognition. “This tells us that the NIH Toolbox was able to replicate what we had known in the literature, that these boys really have lower intellectual capacity, but they also have significant weakness in fluid cognition,” she said.
She also wanted to examine changes over time by testing the boys at a 1-year interview. “What we found was that they are not making as much gain in fluid cognition as we would like. They are just making marginal improvements over time. This has implications on how often we should screen them, but also not be over reliant on using school-based resources for them to get tested,” said Dr. Thangarajh.
Her group’s analysis of a dataset of 55 boys provided by PTC Therapeutics revealed a difference by age in a test of working memory. “What we found was that boys who are actually greater than 9 years, compared with those who are less than 9 years, they actually had a reversal of development-based improvement. The older they get, they were not making as much gains as you would expect,” said Dr. Thangarajh.
She went on to discuss psychosocial determinants of cognitive health in DMD. It is known that women who are carriers of the dystrophin mutation can underperform in cognitively stressful tasks, leading her to wonder if this could lead to transgenerational risk to offspring with DMD. Her group tested women who were carriers of the mutation with the NIH Toolbox and found that they had lower fluid cognition than noncarriers. They then tested 65 dyads of mothers and children, and found a correlation, but only when it came to inhibitory control, which required the individual to note the direction of an arrow while ignoring surrounding arrows pointing in various directions.
Next, the researchers examined neighborhoods and their impact on cognitive health, which can be affected by the presence of green spaces, access to public transportation and good nutrition, and other factors. There were significant deficits associated with residence zip codes. “We were pretty shocked. Someone who is not in a socially vulnerable region is scoring slightly below average, but someone who is in a very socially vulnerable neighborhood is only scoring 75 [age-adjusted score] on the NIH toolbox. So with this, we can conclude that carrier women are vulnerable in certain cognitive domains, but also children who come from socially vulnerable [situations] have poor cognitive control. This, again, has implications on how often we should screen and how much we should overly rely on school-based resources for these individuals,” said Dr. Thangarajh.
Overcoming a significant barrier
The NIH Toolbox has a lot of potential to improve DMD care, according to Dianna Quan, MD, who is the incoming president of AANEM, and professor of neurology at the University of Colorado at Denver, Aurora. “There’s this huge problem in terms of getting people in to see neuropsychologists and having formal evaluations. I think that’s a huge barrier. If we have people able to access this toolkit, which is simple and easily and universally accessible, how wonderful is that? I think that will be a really great improvement on what’s going on right now. It allows people to easily screen for these cognitive disabilities and make sure that we address them,” Dr. Quan said in an interview.
Asked how the tool could specifically improve care, Dr. Quan suggested that the first step is to understand the contributing factors to cognitive issues, whether they are biological, social, or a combination. “Some of them we can modify, potentially, through addressing the social environment. Some of those biologic factors may also be modifiable with many of the new drug studies that are coming.”
Dr. Thangarajh has received speaker honoraria from NS Pharma and PTC Therapeutics. Dr. Quan has received funding from Alnylam, Pfizer, Cytokinetics, Momenta, and Argenx.
FROM AANEM 2023
Duchenne muscular dystrophy gene therapy safe, effective at 4 years
PHOENIX – compared with untreated patients who showed significant decline over the same time period, new research shows.
“Functional assessments demonstrated long-term sustained stabilization of motor function that was clinically meaningful, at ages where functional decline would be expected based on natural history,” the investigators noted in their abstract. Furthermore, the treatment, known as delandistrogene moxeparvovec-rokl (SRP-9001), was well tolerated 4 years post treatment.
The study was presented at the annual meeting of the American Association of Neuromuscular Electrodiagnostic Medicine.
Severe type of DMD
Considered one of the most severe forms of muscular dystrophy, DMD causes progressive muscle wasting stemming from the root genetic cause of missing dystrophin in muscle cells. Often referred to as a molecular “shock absorber,” dystrophin stabilizes the sarcolemma during muscle contractions to prevent degeneration.
SRP-9001, a single-dose recombinant gene therapy administered as an intravenous infusion, was designed to deliver a trimmed down form of dystrophin to compensate for the deficit.
In July, the adeno-associated virus vector (AAV)–based SRP-9001 gene therapy was granted accelerated approval by the Food and Drug Administration for the treatment of ambulatory pediatric patients aged 4-5 years with DMD with a confirmed mutation in the DMD gene.
The therapy is administered over 1-2 hours at a dose of 133 trillion vector genomes per kilogram of body weight.
For Study 101, one of several evaluating the novel therapy, a research team led by senior investigator Jerry Mendell, MD, an attending neurologist at Nationwide Children’s Hospital and professor of pediatrics and neurology at Ohio State University, both in Columbus,evaluated data on four ambulatory male patients aged 4-8 years who received a single IV infusion of the therapy.
All patients also received prednisone 1 mg/kg, 1 day preinfusion and 30 days post infusion.
At 4 years post treatment, there were no new safety events. All treatment-related adverse events occurred mainly within the first 70 days, and all resolved.
The most commonly reported adverse reactions of the gene therapy include vomiting, nausea, increases in liver enzymes, pyrexia (fever), and thrombocytopenia, all of which occurred within 90 days of infusion and been manageable.
Risk mitigation strategies for hepatotoxicity or acute liver injury include pre- and postinfusion monitoring of liver enzymes, the authors noted.
No serious abnormalities were observed in hematologic or chemistry panels, and while three patients had elevated gamma-glutamyl transpeptidase in the first 3 months post treatment, those cases resolved with oral steroid treatment.
Significant improvements in function were observed, with a mean improvement in North Star Ambulatory Assessment (NSAA) scores from baseline of 7.0 points (range, 4-11).
Exploratory analyses further showed that, compared with a propensity score–weighted external control cohort of 21 patients with DMD who did not receive the therapy, those receiving SRP-9001 had a statistically significant difference of 9.4 points in least-squares mean change from baseline to 4 years on the NSAA score (P = .0125).
Similar trends were observed in improvement from baseline in key measures of time to rise, 4-stair climb, and 10- and 100-meter walk/run function tests.
Other reported adverse events include acute serious liver injury, immune-mediated myositis, and myocarditis. Because of the latter risk, the therapy is contraindicated in patients with any deletion in exon 8 and/or exon 9 in the DMD gene.
The current 4-year update on SRP-9001 adds to clinical trial results that have been reported on more than 80 patients treated to date, with favorable results and consistent safety profiles reported at other time points.
Continued FDA approval for the therapy will be contingent upon verification of a clinical benefit in the confirmatory trials, including the EMBARK trial.
Increased function, long-term stability
Discussing the research at the meeting, Craig McDonald, MD, professor and chair of physical medicine & rehabilitation, a professor of pediatrics and study chair of the CINRG Duchenne Natural History Study at University of California Davis Health, noted that top-line results from the ongoing, confirmatory phase 3 EMBARK trial show functional benefits of SRP-9001 not only in 4- to 5-year-olds but also in other older age groups.
“What’s really striking, and in my mind the most impressive, is that when you follow these patients out 3 or 4 years ... you see there is this bump in function followed by long-term stability, whereas the external control cohort predictably shows really quite significant declines in their [NSAA] functional values,” he said in his presentation.
“When you look at each individually treated patient versus their own predicted trajectory using their baseline values on the time function test, each of the patients actually has a really quite impressive stabilization of function over their predicted disease trajectory,” he added.
A caveat that SRP-9001 shares with other gene therapies is the issue of cost – reported in the range of $2 million–$3 million.
In the context of racial and socioeconomic disparities in access to diagnosis and care reported in DMD, Emma Ciafaloni, MD, a professor of neurology and pediatrics at the University of Rochester (N.Y.) Medical Center, underscored the need to consider approval versus access to gene therapies and how to optimize access to the novel treatments.
“We need to consider what the cost is, how it’s going to be accessed, and whether there is a sustainable model,” said Ciafaloni, who was not associated with the study. “There will need to be institutional readiness and support for specialized multidisciplinary clinics for gene therapy.”
She also noted “we need to consider how we can do better on a broader level, because this is not a provider problem or a manufacturer problem — it’s a society problem.”
The study was funded by Sarepta Therapeutics. McDonald reported consulting work for Sarepta Therapeutics and has been an investigator in SRP-9001 research. Ciafaloni reported serving on advisory boards or other relationships with Alexion, Argenx, Biogen, Amicus, Momenta, Medscape, Pfizer, Sanofi/Genzyme, Sarepta, Jansen, NS Pharma, CureSMA, Orphazyme, the Patient-Centered Outcomes Research Institute, PPMD, PTC Therapeutics, and Santhera.
A version of this article first appeared on Medscape.com.
PHOENIX – compared with untreated patients who showed significant decline over the same time period, new research shows.
“Functional assessments demonstrated long-term sustained stabilization of motor function that was clinically meaningful, at ages where functional decline would be expected based on natural history,” the investigators noted in their abstract. Furthermore, the treatment, known as delandistrogene moxeparvovec-rokl (SRP-9001), was well tolerated 4 years post treatment.
The study was presented at the annual meeting of the American Association of Neuromuscular Electrodiagnostic Medicine.
Severe type of DMD
Considered one of the most severe forms of muscular dystrophy, DMD causes progressive muscle wasting stemming from the root genetic cause of missing dystrophin in muscle cells. Often referred to as a molecular “shock absorber,” dystrophin stabilizes the sarcolemma during muscle contractions to prevent degeneration.
SRP-9001, a single-dose recombinant gene therapy administered as an intravenous infusion, was designed to deliver a trimmed down form of dystrophin to compensate for the deficit.
In July, the adeno-associated virus vector (AAV)–based SRP-9001 gene therapy was granted accelerated approval by the Food and Drug Administration for the treatment of ambulatory pediatric patients aged 4-5 years with DMD with a confirmed mutation in the DMD gene.
The therapy is administered over 1-2 hours at a dose of 133 trillion vector genomes per kilogram of body weight.
For Study 101, one of several evaluating the novel therapy, a research team led by senior investigator Jerry Mendell, MD, an attending neurologist at Nationwide Children’s Hospital and professor of pediatrics and neurology at Ohio State University, both in Columbus,evaluated data on four ambulatory male patients aged 4-8 years who received a single IV infusion of the therapy.
All patients also received prednisone 1 mg/kg, 1 day preinfusion and 30 days post infusion.
At 4 years post treatment, there were no new safety events. All treatment-related adverse events occurred mainly within the first 70 days, and all resolved.
The most commonly reported adverse reactions of the gene therapy include vomiting, nausea, increases in liver enzymes, pyrexia (fever), and thrombocytopenia, all of which occurred within 90 days of infusion and been manageable.
Risk mitigation strategies for hepatotoxicity or acute liver injury include pre- and postinfusion monitoring of liver enzymes, the authors noted.
No serious abnormalities were observed in hematologic or chemistry panels, and while three patients had elevated gamma-glutamyl transpeptidase in the first 3 months post treatment, those cases resolved with oral steroid treatment.
Significant improvements in function were observed, with a mean improvement in North Star Ambulatory Assessment (NSAA) scores from baseline of 7.0 points (range, 4-11).
Exploratory analyses further showed that, compared with a propensity score–weighted external control cohort of 21 patients with DMD who did not receive the therapy, those receiving SRP-9001 had a statistically significant difference of 9.4 points in least-squares mean change from baseline to 4 years on the NSAA score (P = .0125).
Similar trends were observed in improvement from baseline in key measures of time to rise, 4-stair climb, and 10- and 100-meter walk/run function tests.
Other reported adverse events include acute serious liver injury, immune-mediated myositis, and myocarditis. Because of the latter risk, the therapy is contraindicated in patients with any deletion in exon 8 and/or exon 9 in the DMD gene.
The current 4-year update on SRP-9001 adds to clinical trial results that have been reported on more than 80 patients treated to date, with favorable results and consistent safety profiles reported at other time points.
Continued FDA approval for the therapy will be contingent upon verification of a clinical benefit in the confirmatory trials, including the EMBARK trial.
Increased function, long-term stability
Discussing the research at the meeting, Craig McDonald, MD, professor and chair of physical medicine & rehabilitation, a professor of pediatrics and study chair of the CINRG Duchenne Natural History Study at University of California Davis Health, noted that top-line results from the ongoing, confirmatory phase 3 EMBARK trial show functional benefits of SRP-9001 not only in 4- to 5-year-olds but also in other older age groups.
“What’s really striking, and in my mind the most impressive, is that when you follow these patients out 3 or 4 years ... you see there is this bump in function followed by long-term stability, whereas the external control cohort predictably shows really quite significant declines in their [NSAA] functional values,” he said in his presentation.
“When you look at each individually treated patient versus their own predicted trajectory using their baseline values on the time function test, each of the patients actually has a really quite impressive stabilization of function over their predicted disease trajectory,” he added.
A caveat that SRP-9001 shares with other gene therapies is the issue of cost – reported in the range of $2 million–$3 million.
In the context of racial and socioeconomic disparities in access to diagnosis and care reported in DMD, Emma Ciafaloni, MD, a professor of neurology and pediatrics at the University of Rochester (N.Y.) Medical Center, underscored the need to consider approval versus access to gene therapies and how to optimize access to the novel treatments.
“We need to consider what the cost is, how it’s going to be accessed, and whether there is a sustainable model,” said Ciafaloni, who was not associated with the study. “There will need to be institutional readiness and support for specialized multidisciplinary clinics for gene therapy.”
She also noted “we need to consider how we can do better on a broader level, because this is not a provider problem or a manufacturer problem — it’s a society problem.”
The study was funded by Sarepta Therapeutics. McDonald reported consulting work for Sarepta Therapeutics and has been an investigator in SRP-9001 research. Ciafaloni reported serving on advisory boards or other relationships with Alexion, Argenx, Biogen, Amicus, Momenta, Medscape, Pfizer, Sanofi/Genzyme, Sarepta, Jansen, NS Pharma, CureSMA, Orphazyme, the Patient-Centered Outcomes Research Institute, PPMD, PTC Therapeutics, and Santhera.
A version of this article first appeared on Medscape.com.
PHOENIX – compared with untreated patients who showed significant decline over the same time period, new research shows.
“Functional assessments demonstrated long-term sustained stabilization of motor function that was clinically meaningful, at ages where functional decline would be expected based on natural history,” the investigators noted in their abstract. Furthermore, the treatment, known as delandistrogene moxeparvovec-rokl (SRP-9001), was well tolerated 4 years post treatment.
The study was presented at the annual meeting of the American Association of Neuromuscular Electrodiagnostic Medicine.
Severe type of DMD
Considered one of the most severe forms of muscular dystrophy, DMD causes progressive muscle wasting stemming from the root genetic cause of missing dystrophin in muscle cells. Often referred to as a molecular “shock absorber,” dystrophin stabilizes the sarcolemma during muscle contractions to prevent degeneration.
SRP-9001, a single-dose recombinant gene therapy administered as an intravenous infusion, was designed to deliver a trimmed down form of dystrophin to compensate for the deficit.
In July, the adeno-associated virus vector (AAV)–based SRP-9001 gene therapy was granted accelerated approval by the Food and Drug Administration for the treatment of ambulatory pediatric patients aged 4-5 years with DMD with a confirmed mutation in the DMD gene.
The therapy is administered over 1-2 hours at a dose of 133 trillion vector genomes per kilogram of body weight.
For Study 101, one of several evaluating the novel therapy, a research team led by senior investigator Jerry Mendell, MD, an attending neurologist at Nationwide Children’s Hospital and professor of pediatrics and neurology at Ohio State University, both in Columbus,evaluated data on four ambulatory male patients aged 4-8 years who received a single IV infusion of the therapy.
All patients also received prednisone 1 mg/kg, 1 day preinfusion and 30 days post infusion.
At 4 years post treatment, there were no new safety events. All treatment-related adverse events occurred mainly within the first 70 days, and all resolved.
The most commonly reported adverse reactions of the gene therapy include vomiting, nausea, increases in liver enzymes, pyrexia (fever), and thrombocytopenia, all of which occurred within 90 days of infusion and been manageable.
Risk mitigation strategies for hepatotoxicity or acute liver injury include pre- and postinfusion monitoring of liver enzymes, the authors noted.
No serious abnormalities were observed in hematologic or chemistry panels, and while three patients had elevated gamma-glutamyl transpeptidase in the first 3 months post treatment, those cases resolved with oral steroid treatment.
Significant improvements in function were observed, with a mean improvement in North Star Ambulatory Assessment (NSAA) scores from baseline of 7.0 points (range, 4-11).
Exploratory analyses further showed that, compared with a propensity score–weighted external control cohort of 21 patients with DMD who did not receive the therapy, those receiving SRP-9001 had a statistically significant difference of 9.4 points in least-squares mean change from baseline to 4 years on the NSAA score (P = .0125).
Similar trends were observed in improvement from baseline in key measures of time to rise, 4-stair climb, and 10- and 100-meter walk/run function tests.
Other reported adverse events include acute serious liver injury, immune-mediated myositis, and myocarditis. Because of the latter risk, the therapy is contraindicated in patients with any deletion in exon 8 and/or exon 9 in the DMD gene.
The current 4-year update on SRP-9001 adds to clinical trial results that have been reported on more than 80 patients treated to date, with favorable results and consistent safety profiles reported at other time points.
Continued FDA approval for the therapy will be contingent upon verification of a clinical benefit in the confirmatory trials, including the EMBARK trial.
Increased function, long-term stability
Discussing the research at the meeting, Craig McDonald, MD, professor and chair of physical medicine & rehabilitation, a professor of pediatrics and study chair of the CINRG Duchenne Natural History Study at University of California Davis Health, noted that top-line results from the ongoing, confirmatory phase 3 EMBARK trial show functional benefits of SRP-9001 not only in 4- to 5-year-olds but also in other older age groups.
“What’s really striking, and in my mind the most impressive, is that when you follow these patients out 3 or 4 years ... you see there is this bump in function followed by long-term stability, whereas the external control cohort predictably shows really quite significant declines in their [NSAA] functional values,” he said in his presentation.
“When you look at each individually treated patient versus their own predicted trajectory using their baseline values on the time function test, each of the patients actually has a really quite impressive stabilization of function over their predicted disease trajectory,” he added.
A caveat that SRP-9001 shares with other gene therapies is the issue of cost – reported in the range of $2 million–$3 million.
In the context of racial and socioeconomic disparities in access to diagnosis and care reported in DMD, Emma Ciafaloni, MD, a professor of neurology and pediatrics at the University of Rochester (N.Y.) Medical Center, underscored the need to consider approval versus access to gene therapies and how to optimize access to the novel treatments.
“We need to consider what the cost is, how it’s going to be accessed, and whether there is a sustainable model,” said Ciafaloni, who was not associated with the study. “There will need to be institutional readiness and support for specialized multidisciplinary clinics for gene therapy.”
She also noted “we need to consider how we can do better on a broader level, because this is not a provider problem or a manufacturer problem — it’s a society problem.”
The study was funded by Sarepta Therapeutics. McDonald reported consulting work for Sarepta Therapeutics and has been an investigator in SRP-9001 research. Ciafaloni reported serving on advisory boards or other relationships with Alexion, Argenx, Biogen, Amicus, Momenta, Medscape, Pfizer, Sanofi/Genzyme, Sarepta, Jansen, NS Pharma, CureSMA, Orphazyme, the Patient-Centered Outcomes Research Institute, PPMD, PTC Therapeutics, and Santhera.
A version of this article first appeared on Medscape.com.
AT AANEM 2023
AF tied to 45% increase in mild cognitive impairment
TOPLINE:
results of a new study suggest.
METHODOLOGY:
- From over 4.3 million people in the UK primary electronic health record (EHR) database, researchers identified 233,833 (5.4%) with AF (mean age, 74.2 years) and randomly selected one age- and sex-matched control person without AF for each AF case patient.
- The primary outcome was incidence of mild cognitive impairment (MCI).
- The authors adjusted for age, sex, year at study entry, socioeconomic status, smoking, and a number of comorbid conditions.
- During a median of 5.3 years of follow-up, there were 4,269 incident MCI cases among both AF and non-AF patients.
TAKEAWAY:
- Individuals with AF had a higher risk of MCI than that of those without AF (adjusted hazard ratio [aHR], 1.45; 95% confidence interval [CI], 1.35-1.56).
- Besides AF, older age (risk ratio [RR], 1.08) and history of depression (RR, 1.44) were associated with greater risk of MCI, as were female sex, greater socioeconomic deprivation, stroke, and multimorbidity, including, for example, diabetes, hypercholesterolemia, and peripheral artery disease (all P < .001).
- Individuals with AF who received oral anticoagulants or amiodarone were not at increased risk of MCI, as was the case for those treated with digoxin.
- Individuals with AF and MCI were at greater risk of dementia (aHR, 1.25; 95% CI, 1.09-1.42). Sex, smoking, chronic kidney disease, and multi-comorbidity were among factors linked to elevated dementia risk.
IN PRACTICE:
The findings emphasize the association of multi-comorbidity and cardiovascular risk factors with development of MCI and progression to dementia in AF patients, the authors wrote. They noted that the data suggest combining anticoagulation and symptom and comorbidity management may prevent cognitive deterioration.
SOURCE:
The study was conducted by Sheng-Chia Chung, PhD, Institute of Health informatics Research, University College London, and colleagues. It was published online Oct. 25, 2023, as a research letter in the Journal of the American College of Cardiology (JACC): Advances.
LIMITATIONS:
The EHR dataset may have lacked granularity and detail, and some risk factors or comorbidities may not have been measured. While those with AF receiving digoxin or amiodarone treatment had no higher risk of MCI than their non-AF peers, the study’s observational design and very wide confidence intervals for these subgroups prevent making solid inferences about causality or a potential protective role of these drugs.
DISCLOSURES:
Dr. Chung is supported by the National Institute of Health and Care Research (NIHR) Author Rui Providencia, MD, PhD, of the Institute of Health informatics Research, University College London, is supported by the University College London British Heart Foundation and NIHR. All other authors report no relevant conflicts of interest.
A version of this article appeared on Medscape.com.
TOPLINE:
results of a new study suggest.
METHODOLOGY:
- From over 4.3 million people in the UK primary electronic health record (EHR) database, researchers identified 233,833 (5.4%) with AF (mean age, 74.2 years) and randomly selected one age- and sex-matched control person without AF for each AF case patient.
- The primary outcome was incidence of mild cognitive impairment (MCI).
- The authors adjusted for age, sex, year at study entry, socioeconomic status, smoking, and a number of comorbid conditions.
- During a median of 5.3 years of follow-up, there were 4,269 incident MCI cases among both AF and non-AF patients.
TAKEAWAY:
- Individuals with AF had a higher risk of MCI than that of those without AF (adjusted hazard ratio [aHR], 1.45; 95% confidence interval [CI], 1.35-1.56).
- Besides AF, older age (risk ratio [RR], 1.08) and history of depression (RR, 1.44) were associated with greater risk of MCI, as were female sex, greater socioeconomic deprivation, stroke, and multimorbidity, including, for example, diabetes, hypercholesterolemia, and peripheral artery disease (all P < .001).
- Individuals with AF who received oral anticoagulants or amiodarone were not at increased risk of MCI, as was the case for those treated with digoxin.
- Individuals with AF and MCI were at greater risk of dementia (aHR, 1.25; 95% CI, 1.09-1.42). Sex, smoking, chronic kidney disease, and multi-comorbidity were among factors linked to elevated dementia risk.
IN PRACTICE:
The findings emphasize the association of multi-comorbidity and cardiovascular risk factors with development of MCI and progression to dementia in AF patients, the authors wrote. They noted that the data suggest combining anticoagulation and symptom and comorbidity management may prevent cognitive deterioration.
SOURCE:
The study was conducted by Sheng-Chia Chung, PhD, Institute of Health informatics Research, University College London, and colleagues. It was published online Oct. 25, 2023, as a research letter in the Journal of the American College of Cardiology (JACC): Advances.
LIMITATIONS:
The EHR dataset may have lacked granularity and detail, and some risk factors or comorbidities may not have been measured. While those with AF receiving digoxin or amiodarone treatment had no higher risk of MCI than their non-AF peers, the study’s observational design and very wide confidence intervals for these subgroups prevent making solid inferences about causality or a potential protective role of these drugs.
DISCLOSURES:
Dr. Chung is supported by the National Institute of Health and Care Research (NIHR) Author Rui Providencia, MD, PhD, of the Institute of Health informatics Research, University College London, is supported by the University College London British Heart Foundation and NIHR. All other authors report no relevant conflicts of interest.
A version of this article appeared on Medscape.com.
TOPLINE:
results of a new study suggest.
METHODOLOGY:
- From over 4.3 million people in the UK primary electronic health record (EHR) database, researchers identified 233,833 (5.4%) with AF (mean age, 74.2 years) and randomly selected one age- and sex-matched control person without AF for each AF case patient.
- The primary outcome was incidence of mild cognitive impairment (MCI).
- The authors adjusted for age, sex, year at study entry, socioeconomic status, smoking, and a number of comorbid conditions.
- During a median of 5.3 years of follow-up, there were 4,269 incident MCI cases among both AF and non-AF patients.
TAKEAWAY:
- Individuals with AF had a higher risk of MCI than that of those without AF (adjusted hazard ratio [aHR], 1.45; 95% confidence interval [CI], 1.35-1.56).
- Besides AF, older age (risk ratio [RR], 1.08) and history of depression (RR, 1.44) were associated with greater risk of MCI, as were female sex, greater socioeconomic deprivation, stroke, and multimorbidity, including, for example, diabetes, hypercholesterolemia, and peripheral artery disease (all P < .001).
- Individuals with AF who received oral anticoagulants or amiodarone were not at increased risk of MCI, as was the case for those treated with digoxin.
- Individuals with AF and MCI were at greater risk of dementia (aHR, 1.25; 95% CI, 1.09-1.42). Sex, smoking, chronic kidney disease, and multi-comorbidity were among factors linked to elevated dementia risk.
IN PRACTICE:
The findings emphasize the association of multi-comorbidity and cardiovascular risk factors with development of MCI and progression to dementia in AF patients, the authors wrote. They noted that the data suggest combining anticoagulation and symptom and comorbidity management may prevent cognitive deterioration.
SOURCE:
The study was conducted by Sheng-Chia Chung, PhD, Institute of Health informatics Research, University College London, and colleagues. It was published online Oct. 25, 2023, as a research letter in the Journal of the American College of Cardiology (JACC): Advances.
LIMITATIONS:
The EHR dataset may have lacked granularity and detail, and some risk factors or comorbidities may not have been measured. While those with AF receiving digoxin or amiodarone treatment had no higher risk of MCI than their non-AF peers, the study’s observational design and very wide confidence intervals for these subgroups prevent making solid inferences about causality or a potential protective role of these drugs.
DISCLOSURES:
Dr. Chung is supported by the National Institute of Health and Care Research (NIHR) Author Rui Providencia, MD, PhD, of the Institute of Health informatics Research, University College London, is supported by the University College London British Heart Foundation and NIHR. All other authors report no relevant conflicts of interest.
A version of this article appeared on Medscape.com.
Nightmare on CIL Street: A Simulation Series to Increase Confidence and Skill in Responding to Clinical Emergencies
The Central Texas Veteran’s Health Care System (CTVHCS) in Temple, Texas, is a 189-bed teaching hospital. CTVHCS opened the Center for Innovation and Learning (CIL) in 2022. The CIL has about 279 m2 of simulation space that includes high- and low-fidelity simulation equipment and multiple laboratories, which can be used to simulate inpatient and outpatient settings. The CIL high-fidelity manikins and environment allow learners to be immersed in the simulation for maximum realism. Computer and video systems provide clear viewing of training, which allows for more in-depth debriefing and learning. CIL simulation training is used by CTVHCS staff, medical residents, and medical and physician assistant students.
The utility of technology in medical education is rapidly evolving. As noted in many studies, simulation creates an environment that can imitate real patients in the format of a lifelike manikin, anatomic regions stations, clinical tasks, and many real-life circumstances.1 Task trainers for procedure simulation have been widely used and studied. A 2020 study noted that simulation training is effective for developing procedural skills in surgery and prevents the decay of surgical skills.2
In reviewing health care education curriculums, we noted that most of the rapid response situations are learned through active patient experiences. Rapid responses are managed by the intensive care unit and primary care teams during the day but at night are run primarily by the postgraduate year 2 (PGY2) night resident and intern. Knowing these logistics and current studies, we decided to build a rapid response simulation curriculum to improve preparedness for PGY1 residents, medical students, and physician assistant students.
Curriculum Planning
Planning the simulation curriculum began with the CTVHCS internal medicine chief resident and registered nurse (RN) educator. CTVHCS data were reviewed to identify the 3 most common rapid response calls from the past 3 years; research on the most common systems affected by rapid responses also was evaluated.
A 2019 study by Lyons and colleagues evaluated 402,023 rapid response activations across 360 hospitals and found that respiratory scenarios made up 38% and cardiac scenarios made up 37%.3 In addition, the CTVHCS has limited support in stroke neurology. Therefore, the internal medicine chief resident and RN educator decided to run 3 evolving rapid response scenarios per session that included cardiac, respiratory, and neurological scenarios. Capabilities and limitations of different high-fidelity manikins were discussed to identify and use the most appropriate simulator for each situation. Objectives that met both general medicine and site-specific education were discussed, and the program was formulated.
Program Description
Nightmare on CIL Street is a simulation-based program designed for new internal medicine residents and students to encounter difficult situations (late at night, on call, or when resources are limited; ie, weekends/holidays) in a controlled simulation environment. During the simulation, learners will be unable to transfer the patient and no additional help is available. Each learner must determine a differential diagnosis and make appropriate medical interventions with only the assistance of a nurse. Scenarios are derived from common rapid response team calls and low-volume/high-impact situations where clinical decisions must be made quickly to ensure the best patient outcomes. High-fidelity manikins that have abilities to respond to questions, simulate breathing, reproduce pathological heart and breath sounds and more are used to create a realistic patient environment.
This program aligns with 2 national Veterans Health Administration priorities: (1) connect veterans to the soonest and best care; and (2) accelerate the Veterans Health Administration journey to be a high-reliability organization (sensitivity to operations, preoccupation with failure, commitment to resilience, and deference to expertise). Nightmare on CIL Street has 3 clinical episodes: 2 cardiac (A Tell-Tale Heart), respiratory (Don’t Breathe), and neurologic (Brain Scan). Additional clinical episodes will be added based on learner feedback and assessed need.
Each simulation event encompassed all 3 episodes that an individual or a team of 2 learners rotate through in a round-robin fashion. The overarching theme for each episode was a rapid response team call with minimal resources that the learner would have to provide care and stabilization. A literature search for rapid response team training programs found few results, but the literature assisted with providing a foundation for Nightmare on CIL Street.4,5 The goal was to completely envelop the learners in a nightmare scenario that required a solution.
After the safety brief and predata collection, learners received a phone call with minimal information about a patient in need of care. The learners responded to the requested area and provided treatment to the emergency over 25 minutes with the bedside nurse (who is an embedded participant). At the conclusion of the scenario, a physician subject matter expert who has been observing, provided a personalized 10-minute debriefing to the learner, which presented specific learning points and opportunities for the learner’s educational development. After the debriefing, learners returned to a conference room and awaited the next call. After all learners completed the 3 episodes, a group debriefing was conducted using the gather, analyze, summarize debriefing framework. The debriefing begins with an open-ended forum for learners to express their thoughts. Then, each scenario is discussed and broken down by key learning objectives. Starting with cardiac and ending with neurology, the logistics of the cases are discussed based on the trajectory of the learners during the scenarios. Each objective is discussed, and learners are allowed to ask questions before moving to the next scenario. After the debriefing, postevent data were gathered.
Objectives
The program objective was to educate residents and students on common rapid response scenarios. We devised each scenario as an evolving simulation where various interventions would improve or worsen vital signs and symptoms. Each scenario had an end goal: cardioversion (cardiac), intubation (respiratory), and transfer (neurologic). Objectives were tailored to the trainees present during the specific simulation (Table).
IMPLEMENTATION
The initial run of the simulation curriculum was implemented on February 22, 2023, and ended on May 17, 2023, with 5 events. Participants included internal medicine PGY1 residents, third-year medical students, and fourth-year physician assistant students. Internal medicine residents ran each scenario with a subject matter expert monitoring; the undergraduate medical trainees partnered with another student. Students were pulled from their ward rotations to attend the simulation, and residents were pulled from electives and wards. Each trainee was able to experience each planned scenario. They were then briefed, participated in each scenario, and ended with a debriefing, discussing each case in detail. Two subject matter experts were always available, and occasionally 4 were present to provide additional knowledge transfer to learners. These included board-certified physicians in internal medicine and pulmonary critical care. Most scenarios were conducted on Wednesday afternoon or Thursday.
The CIL provided 6 staff minimum for every event. The staff controlled the manikins and acted as embedded players for the learners to interact and work with at the bedside. Every embedded RN was provided the same script: They were a new nurse just off orientation and did not know what to do. In addition, they were instructed that no matter who the learner wanted to call/page, that person or service was not answering or unavailable. This forced learners to respond and treat the simulated patient on their own.
Survey Responses
To evaluate the effect of this program on medical education, we administered surveys to the trainees before and after the simulation (Appendix). All questions were evaluated on a 10-point Likert scale (1, minimal comfort; 10, maximum comfort). The postsurvey added an additional Likert scale question and an open-ended question.
Sixteen trainees underwent the simulation curriculum during the 2022 to 2023 academic year, 9 internal medicine PGY1 residents, 4 medical students, and 3 physician assistant students. Postsimulation surveys indicated a mean 2.2 point increase in comfort compared with the presimulation surveys across all questions and participants.
DISCUSSION
The simulation curriculum proved to be successful for all parties, including trainees, medical educators, and simulation staff. Trainees expressed gratitude for the teaching ability of the simulation and the challenge of confronting an evolving scenario. Students also stated that the simulation allowed them to identify knowledge weaknesses.
Medical technology is rapidly advancing. A study evaluating high-fidelity medical simulations between 1969 and 2003 found that they are educationally effective and complement other medical education modalities.6 It is also noted that care provided by junior physicians with a lack of prior exposure to emergencies and unusual clinical syndromes can lead to more adverse effects.7 Simulation curriculums can be used to educate junior physicians as well as trainees on a multitude of medical emergencies, teach systematic approaches to medical scenarios, and increase exposure to unfamiliar experiences.
The goals of this article are to share program details and encourage other training programs with similar capabilities to incorporate simulation into medical education. Using pre- and postsimulation surveys, there was a concrete improvement in the value obtained by participating in this simulation. The Nightmare on CIL Street learners experienced a mean 2.2 point improvement from presimulation survey to postsimulation survey. Some notable improvements were the feelings of preparedness for rapid response situations and developing a systematic approach. As the students who participated in our Nightmare on CIL Street simulation were early in training, we believe the improvement in preparation and developing a systematic approach can be key to their success in their practical environments.
From a site-specific standpoint, improvement in confidence working through cardiac, respiratory, and neurological emergencies will be very useful. The anesthesiology service intubates during respiratory failures and there is no stroke neurologist available at the CTVHCS hospital. Giving trainees experience in these conditions may allow them to better understand their role in coordination during these times and potentially improve patient outcomes. A follow-up questionnaire administered a year after this simulation may be useful in ascertaining the usefulness of the simulation and what items may have been approached differently. We encourage other institutions to build in aspects of their site-specific challenges to improve trainee awareness in approaches to critical scenarios.
Challenges
The greatest challenge for Nightmare on CIL Street was the ability to pull internal medicine residents from their clinical duties to participate in the simulation. As there are many moving parts to their clinical scheduling, residents do not always have sufficient coverage to participate in training. There were also instances where residents needed to cover for another resident preventing them from attending the simulation. In the future, this program will schedule residents months in advance and will have the simulation training built into their rotations.
Medical and physician assistant students were pulled from their ward rotations as well. They rotate on a 2-to-4-week basis and often had already experienced the simulation the week prior, leaving out students for the following week. With more longitudinal planning, students can be pulled on a rotating monthly basis to maximize their participation. Another challenge was deciding whether residents should partner or experience the simulation on their own. After some feedback, it was noted that residents preferred to experience the simulation on their own as this improves their learning value. With the limited resources available, only rotating 3 residents on a scenario limits the number of trainees who can be reached with the program. Running this program throughout an academic year can help to reach more trainees.
CONCLUSIONS
Educating trainees on rapid response scenarios by using a simulation curriculum provides many benefits. Our trainees reported improvement in addressing cardiac, respiratory, and neurological rapid response scenarios after experiencing the simulation. They felt better prepared and had developed a better systematic approach for the future.
Acknowledgments
The authors thank Pawan Sikka, MD, George Martinez, MD and Braden Anderson, MD for participating as physician experts and educating our students. We thank Naomi Devers; Dinetra Jones; Stephanie Garrett; Sara Holton; Evelina Bartnick; Tanelle Smith; Michael Lomax; Shaun Kelemen for their participation as nurses, assistants, and simulation technology experts.
1. Guze PA. Using technology to meet the challenges of medical education. Trans Am Clin Climatol Assoc. 2015;126:260-270.
2. Higgins M, Madan C, Patel R. Development and decay of procedural skills in surgery: a systematic review of the effectiveness of simulation-based medical education interventions. Surgeon. 2021;19(4):e67-e77. doi:10.1016/j.surge.2020.07.013
3. Lyons PG, Edelson DP, Carey KA, et al. Characteristics of rapid response calls in the United States: an analysis of the first 402,023 adult cases from the Get With the Guidelines Resuscitation-Medical Emergency Team registry. Crit Care Med. 2019;47(10):1283-1289. doi:10.1097/CCM.0000000000003912
4. McMurray L, Hall AK, Rich J, Merchant S, Chaplin T. The nightmares course: a longitudinal, multidisciplinary, simulation-based curriculum to train and assess resident competence in resuscitation. J Grad Med Educ. 2017;9(4):503-508. doi:10.4300/JGME-D-16-00462.1
5. Gilic F, Schultz K, Sempowski I, Blagojevic A. “Nightmares-Family Medicine” course is an effective acute care teaching tool for family medicine residents. Simul Healthc. 2019;14(3):157-162. doi:10.1097/SIH.0000000000000355
6. Issenberg SB, McGaghie WC, Petrusa ER, Lee Gordon D, Scalese RJ. Features and uses of high-fidelity medical simulations that lead to effective learning: a BEME systematic review. Med Teach. 2005;27(1):10-28. doi:10.1080/01421590500046924
7. Datta R, Upadhyay K, Jaideep C. Simulation and its role in medical education. Med J Armed Forces India. 2012;68(2):167-172. doi:10.1016/S0377-1237(12)60040-9
The Central Texas Veteran’s Health Care System (CTVHCS) in Temple, Texas, is a 189-bed teaching hospital. CTVHCS opened the Center for Innovation and Learning (CIL) in 2022. The CIL has about 279 m2 of simulation space that includes high- and low-fidelity simulation equipment and multiple laboratories, which can be used to simulate inpatient and outpatient settings. The CIL high-fidelity manikins and environment allow learners to be immersed in the simulation for maximum realism. Computer and video systems provide clear viewing of training, which allows for more in-depth debriefing and learning. CIL simulation training is used by CTVHCS staff, medical residents, and medical and physician assistant students.
The utility of technology in medical education is rapidly evolving. As noted in many studies, simulation creates an environment that can imitate real patients in the format of a lifelike manikin, anatomic regions stations, clinical tasks, and many real-life circumstances.1 Task trainers for procedure simulation have been widely used and studied. A 2020 study noted that simulation training is effective for developing procedural skills in surgery and prevents the decay of surgical skills.2
In reviewing health care education curriculums, we noted that most of the rapid response situations are learned through active patient experiences. Rapid responses are managed by the intensive care unit and primary care teams during the day but at night are run primarily by the postgraduate year 2 (PGY2) night resident and intern. Knowing these logistics and current studies, we decided to build a rapid response simulation curriculum to improve preparedness for PGY1 residents, medical students, and physician assistant students.
Curriculum Planning
Planning the simulation curriculum began with the CTVHCS internal medicine chief resident and registered nurse (RN) educator. CTVHCS data were reviewed to identify the 3 most common rapid response calls from the past 3 years; research on the most common systems affected by rapid responses also was evaluated.
A 2019 study by Lyons and colleagues evaluated 402,023 rapid response activations across 360 hospitals and found that respiratory scenarios made up 38% and cardiac scenarios made up 37%.3 In addition, the CTVHCS has limited support in stroke neurology. Therefore, the internal medicine chief resident and RN educator decided to run 3 evolving rapid response scenarios per session that included cardiac, respiratory, and neurological scenarios. Capabilities and limitations of different high-fidelity manikins were discussed to identify and use the most appropriate simulator for each situation. Objectives that met both general medicine and site-specific education were discussed, and the program was formulated.
Program Description
Nightmare on CIL Street is a simulation-based program designed for new internal medicine residents and students to encounter difficult situations (late at night, on call, or when resources are limited; ie, weekends/holidays) in a controlled simulation environment. During the simulation, learners will be unable to transfer the patient and no additional help is available. Each learner must determine a differential diagnosis and make appropriate medical interventions with only the assistance of a nurse. Scenarios are derived from common rapid response team calls and low-volume/high-impact situations where clinical decisions must be made quickly to ensure the best patient outcomes. High-fidelity manikins that have abilities to respond to questions, simulate breathing, reproduce pathological heart and breath sounds and more are used to create a realistic patient environment.
This program aligns with 2 national Veterans Health Administration priorities: (1) connect veterans to the soonest and best care; and (2) accelerate the Veterans Health Administration journey to be a high-reliability organization (sensitivity to operations, preoccupation with failure, commitment to resilience, and deference to expertise). Nightmare on CIL Street has 3 clinical episodes: 2 cardiac (A Tell-Tale Heart), respiratory (Don’t Breathe), and neurologic (Brain Scan). Additional clinical episodes will be added based on learner feedback and assessed need.
Each simulation event encompassed all 3 episodes that an individual or a team of 2 learners rotate through in a round-robin fashion. The overarching theme for each episode was a rapid response team call with minimal resources that the learner would have to provide care and stabilization. A literature search for rapid response team training programs found few results, but the literature assisted with providing a foundation for Nightmare on CIL Street.4,5 The goal was to completely envelop the learners in a nightmare scenario that required a solution.
After the safety brief and predata collection, learners received a phone call with minimal information about a patient in need of care. The learners responded to the requested area and provided treatment to the emergency over 25 minutes with the bedside nurse (who is an embedded participant). At the conclusion of the scenario, a physician subject matter expert who has been observing, provided a personalized 10-minute debriefing to the learner, which presented specific learning points and opportunities for the learner’s educational development. After the debriefing, learners returned to a conference room and awaited the next call. After all learners completed the 3 episodes, a group debriefing was conducted using the gather, analyze, summarize debriefing framework. The debriefing begins with an open-ended forum for learners to express their thoughts. Then, each scenario is discussed and broken down by key learning objectives. Starting with cardiac and ending with neurology, the logistics of the cases are discussed based on the trajectory of the learners during the scenarios. Each objective is discussed, and learners are allowed to ask questions before moving to the next scenario. After the debriefing, postevent data were gathered.
Objectives
The program objective was to educate residents and students on common rapid response scenarios. We devised each scenario as an evolving simulation where various interventions would improve or worsen vital signs and symptoms. Each scenario had an end goal: cardioversion (cardiac), intubation (respiratory), and transfer (neurologic). Objectives were tailored to the trainees present during the specific simulation (Table).
IMPLEMENTATION
The initial run of the simulation curriculum was implemented on February 22, 2023, and ended on May 17, 2023, with 5 events. Participants included internal medicine PGY1 residents, third-year medical students, and fourth-year physician assistant students. Internal medicine residents ran each scenario with a subject matter expert monitoring; the undergraduate medical trainees partnered with another student. Students were pulled from their ward rotations to attend the simulation, and residents were pulled from electives and wards. Each trainee was able to experience each planned scenario. They were then briefed, participated in each scenario, and ended with a debriefing, discussing each case in detail. Two subject matter experts were always available, and occasionally 4 were present to provide additional knowledge transfer to learners. These included board-certified physicians in internal medicine and pulmonary critical care. Most scenarios were conducted on Wednesday afternoon or Thursday.
The CIL provided 6 staff minimum for every event. The staff controlled the manikins and acted as embedded players for the learners to interact and work with at the bedside. Every embedded RN was provided the same script: They were a new nurse just off orientation and did not know what to do. In addition, they were instructed that no matter who the learner wanted to call/page, that person or service was not answering or unavailable. This forced learners to respond and treat the simulated patient on their own.
Survey Responses
To evaluate the effect of this program on medical education, we administered surveys to the trainees before and after the simulation (Appendix). All questions were evaluated on a 10-point Likert scale (1, minimal comfort; 10, maximum comfort). The postsurvey added an additional Likert scale question and an open-ended question.
Sixteen trainees underwent the simulation curriculum during the 2022 to 2023 academic year, 9 internal medicine PGY1 residents, 4 medical students, and 3 physician assistant students. Postsimulation surveys indicated a mean 2.2 point increase in comfort compared with the presimulation surveys across all questions and participants.
DISCUSSION
The simulation curriculum proved to be successful for all parties, including trainees, medical educators, and simulation staff. Trainees expressed gratitude for the teaching ability of the simulation and the challenge of confronting an evolving scenario. Students also stated that the simulation allowed them to identify knowledge weaknesses.
Medical technology is rapidly advancing. A study evaluating high-fidelity medical simulations between 1969 and 2003 found that they are educationally effective and complement other medical education modalities.6 It is also noted that care provided by junior physicians with a lack of prior exposure to emergencies and unusual clinical syndromes can lead to more adverse effects.7 Simulation curriculums can be used to educate junior physicians as well as trainees on a multitude of medical emergencies, teach systematic approaches to medical scenarios, and increase exposure to unfamiliar experiences.
The goals of this article are to share program details and encourage other training programs with similar capabilities to incorporate simulation into medical education. Using pre- and postsimulation surveys, there was a concrete improvement in the value obtained by participating in this simulation. The Nightmare on CIL Street learners experienced a mean 2.2 point improvement from presimulation survey to postsimulation survey. Some notable improvements were the feelings of preparedness for rapid response situations and developing a systematic approach. As the students who participated in our Nightmare on CIL Street simulation were early in training, we believe the improvement in preparation and developing a systematic approach can be key to their success in their practical environments.
From a site-specific standpoint, improvement in confidence working through cardiac, respiratory, and neurological emergencies will be very useful. The anesthesiology service intubates during respiratory failures and there is no stroke neurologist available at the CTVHCS hospital. Giving trainees experience in these conditions may allow them to better understand their role in coordination during these times and potentially improve patient outcomes. A follow-up questionnaire administered a year after this simulation may be useful in ascertaining the usefulness of the simulation and what items may have been approached differently. We encourage other institutions to build in aspects of their site-specific challenges to improve trainee awareness in approaches to critical scenarios.
Challenges
The greatest challenge for Nightmare on CIL Street was the ability to pull internal medicine residents from their clinical duties to participate in the simulation. As there are many moving parts to their clinical scheduling, residents do not always have sufficient coverage to participate in training. There were also instances where residents needed to cover for another resident preventing them from attending the simulation. In the future, this program will schedule residents months in advance and will have the simulation training built into their rotations.
Medical and physician assistant students were pulled from their ward rotations as well. They rotate on a 2-to-4-week basis and often had already experienced the simulation the week prior, leaving out students for the following week. With more longitudinal planning, students can be pulled on a rotating monthly basis to maximize their participation. Another challenge was deciding whether residents should partner or experience the simulation on their own. After some feedback, it was noted that residents preferred to experience the simulation on their own as this improves their learning value. With the limited resources available, only rotating 3 residents on a scenario limits the number of trainees who can be reached with the program. Running this program throughout an academic year can help to reach more trainees.
CONCLUSIONS
Educating trainees on rapid response scenarios by using a simulation curriculum provides many benefits. Our trainees reported improvement in addressing cardiac, respiratory, and neurological rapid response scenarios after experiencing the simulation. They felt better prepared and had developed a better systematic approach for the future.
Acknowledgments
The authors thank Pawan Sikka, MD, George Martinez, MD and Braden Anderson, MD for participating as physician experts and educating our students. We thank Naomi Devers; Dinetra Jones; Stephanie Garrett; Sara Holton; Evelina Bartnick; Tanelle Smith; Michael Lomax; Shaun Kelemen for their participation as nurses, assistants, and simulation technology experts.
The Central Texas Veteran’s Health Care System (CTVHCS) in Temple, Texas, is a 189-bed teaching hospital. CTVHCS opened the Center for Innovation and Learning (CIL) in 2022. The CIL has about 279 m2 of simulation space that includes high- and low-fidelity simulation equipment and multiple laboratories, which can be used to simulate inpatient and outpatient settings. The CIL high-fidelity manikins and environment allow learners to be immersed in the simulation for maximum realism. Computer and video systems provide clear viewing of training, which allows for more in-depth debriefing and learning. CIL simulation training is used by CTVHCS staff, medical residents, and medical and physician assistant students.
The utility of technology in medical education is rapidly evolving. As noted in many studies, simulation creates an environment that can imitate real patients in the format of a lifelike manikin, anatomic regions stations, clinical tasks, and many real-life circumstances.1 Task trainers for procedure simulation have been widely used and studied. A 2020 study noted that simulation training is effective for developing procedural skills in surgery and prevents the decay of surgical skills.2
In reviewing health care education curriculums, we noted that most of the rapid response situations are learned through active patient experiences. Rapid responses are managed by the intensive care unit and primary care teams during the day but at night are run primarily by the postgraduate year 2 (PGY2) night resident and intern. Knowing these logistics and current studies, we decided to build a rapid response simulation curriculum to improve preparedness for PGY1 residents, medical students, and physician assistant students.
Curriculum Planning
Planning the simulation curriculum began with the CTVHCS internal medicine chief resident and registered nurse (RN) educator. CTVHCS data were reviewed to identify the 3 most common rapid response calls from the past 3 years; research on the most common systems affected by rapid responses also was evaluated.
A 2019 study by Lyons and colleagues evaluated 402,023 rapid response activations across 360 hospitals and found that respiratory scenarios made up 38% and cardiac scenarios made up 37%.3 In addition, the CTVHCS has limited support in stroke neurology. Therefore, the internal medicine chief resident and RN educator decided to run 3 evolving rapid response scenarios per session that included cardiac, respiratory, and neurological scenarios. Capabilities and limitations of different high-fidelity manikins were discussed to identify and use the most appropriate simulator for each situation. Objectives that met both general medicine and site-specific education were discussed, and the program was formulated.
Program Description
Nightmare on CIL Street is a simulation-based program designed for new internal medicine residents and students to encounter difficult situations (late at night, on call, or when resources are limited; ie, weekends/holidays) in a controlled simulation environment. During the simulation, learners will be unable to transfer the patient and no additional help is available. Each learner must determine a differential diagnosis and make appropriate medical interventions with only the assistance of a nurse. Scenarios are derived from common rapid response team calls and low-volume/high-impact situations where clinical decisions must be made quickly to ensure the best patient outcomes. High-fidelity manikins that have abilities to respond to questions, simulate breathing, reproduce pathological heart and breath sounds and more are used to create a realistic patient environment.
This program aligns with 2 national Veterans Health Administration priorities: (1) connect veterans to the soonest and best care; and (2) accelerate the Veterans Health Administration journey to be a high-reliability organization (sensitivity to operations, preoccupation with failure, commitment to resilience, and deference to expertise). Nightmare on CIL Street has 3 clinical episodes: 2 cardiac (A Tell-Tale Heart), respiratory (Don’t Breathe), and neurologic (Brain Scan). Additional clinical episodes will be added based on learner feedback and assessed need.
Each simulation event encompassed all 3 episodes that an individual or a team of 2 learners rotate through in a round-robin fashion. The overarching theme for each episode was a rapid response team call with minimal resources that the learner would have to provide care and stabilization. A literature search for rapid response team training programs found few results, but the literature assisted with providing a foundation for Nightmare on CIL Street.4,5 The goal was to completely envelop the learners in a nightmare scenario that required a solution.
After the safety brief and predata collection, learners received a phone call with minimal information about a patient in need of care. The learners responded to the requested area and provided treatment to the emergency over 25 minutes with the bedside nurse (who is an embedded participant). At the conclusion of the scenario, a physician subject matter expert who has been observing, provided a personalized 10-minute debriefing to the learner, which presented specific learning points and opportunities for the learner’s educational development. After the debriefing, learners returned to a conference room and awaited the next call. After all learners completed the 3 episodes, a group debriefing was conducted using the gather, analyze, summarize debriefing framework. The debriefing begins with an open-ended forum for learners to express their thoughts. Then, each scenario is discussed and broken down by key learning objectives. Starting with cardiac and ending with neurology, the logistics of the cases are discussed based on the trajectory of the learners during the scenarios. Each objective is discussed, and learners are allowed to ask questions before moving to the next scenario. After the debriefing, postevent data were gathered.
Objectives
The program objective was to educate residents and students on common rapid response scenarios. We devised each scenario as an evolving simulation where various interventions would improve or worsen vital signs and symptoms. Each scenario had an end goal: cardioversion (cardiac), intubation (respiratory), and transfer (neurologic). Objectives were tailored to the trainees present during the specific simulation (Table).
IMPLEMENTATION
The initial run of the simulation curriculum was implemented on February 22, 2023, and ended on May 17, 2023, with 5 events. Participants included internal medicine PGY1 residents, third-year medical students, and fourth-year physician assistant students. Internal medicine residents ran each scenario with a subject matter expert monitoring; the undergraduate medical trainees partnered with another student. Students were pulled from their ward rotations to attend the simulation, and residents were pulled from electives and wards. Each trainee was able to experience each planned scenario. They were then briefed, participated in each scenario, and ended with a debriefing, discussing each case in detail. Two subject matter experts were always available, and occasionally 4 were present to provide additional knowledge transfer to learners. These included board-certified physicians in internal medicine and pulmonary critical care. Most scenarios were conducted on Wednesday afternoon or Thursday.
The CIL provided 6 staff minimum for every event. The staff controlled the manikins and acted as embedded players for the learners to interact and work with at the bedside. Every embedded RN was provided the same script: They were a new nurse just off orientation and did not know what to do. In addition, they were instructed that no matter who the learner wanted to call/page, that person or service was not answering or unavailable. This forced learners to respond and treat the simulated patient on their own.
Survey Responses
To evaluate the effect of this program on medical education, we administered surveys to the trainees before and after the simulation (Appendix). All questions were evaluated on a 10-point Likert scale (1, minimal comfort; 10, maximum comfort). The postsurvey added an additional Likert scale question and an open-ended question.
Sixteen trainees underwent the simulation curriculum during the 2022 to 2023 academic year, 9 internal medicine PGY1 residents, 4 medical students, and 3 physician assistant students. Postsimulation surveys indicated a mean 2.2 point increase in comfort compared with the presimulation surveys across all questions and participants.
DISCUSSION
The simulation curriculum proved to be successful for all parties, including trainees, medical educators, and simulation staff. Trainees expressed gratitude for the teaching ability of the simulation and the challenge of confronting an evolving scenario. Students also stated that the simulation allowed them to identify knowledge weaknesses.
Medical technology is rapidly advancing. A study evaluating high-fidelity medical simulations between 1969 and 2003 found that they are educationally effective and complement other medical education modalities.6 It is also noted that care provided by junior physicians with a lack of prior exposure to emergencies and unusual clinical syndromes can lead to more adverse effects.7 Simulation curriculums can be used to educate junior physicians as well as trainees on a multitude of medical emergencies, teach systematic approaches to medical scenarios, and increase exposure to unfamiliar experiences.
The goals of this article are to share program details and encourage other training programs with similar capabilities to incorporate simulation into medical education. Using pre- and postsimulation surveys, there was a concrete improvement in the value obtained by participating in this simulation. The Nightmare on CIL Street learners experienced a mean 2.2 point improvement from presimulation survey to postsimulation survey. Some notable improvements were the feelings of preparedness for rapid response situations and developing a systematic approach. As the students who participated in our Nightmare on CIL Street simulation were early in training, we believe the improvement in preparation and developing a systematic approach can be key to their success in their practical environments.
From a site-specific standpoint, improvement in confidence working through cardiac, respiratory, and neurological emergencies will be very useful. The anesthesiology service intubates during respiratory failures and there is no stroke neurologist available at the CTVHCS hospital. Giving trainees experience in these conditions may allow them to better understand their role in coordination during these times and potentially improve patient outcomes. A follow-up questionnaire administered a year after this simulation may be useful in ascertaining the usefulness of the simulation and what items may have been approached differently. We encourage other institutions to build in aspects of their site-specific challenges to improve trainee awareness in approaches to critical scenarios.
Challenges
The greatest challenge for Nightmare on CIL Street was the ability to pull internal medicine residents from their clinical duties to participate in the simulation. As there are many moving parts to their clinical scheduling, residents do not always have sufficient coverage to participate in training. There were also instances where residents needed to cover for another resident preventing them from attending the simulation. In the future, this program will schedule residents months in advance and will have the simulation training built into their rotations.
Medical and physician assistant students were pulled from their ward rotations as well. They rotate on a 2-to-4-week basis and often had already experienced the simulation the week prior, leaving out students for the following week. With more longitudinal planning, students can be pulled on a rotating monthly basis to maximize their participation. Another challenge was deciding whether residents should partner or experience the simulation on their own. After some feedback, it was noted that residents preferred to experience the simulation on their own as this improves their learning value. With the limited resources available, only rotating 3 residents on a scenario limits the number of trainees who can be reached with the program. Running this program throughout an academic year can help to reach more trainees.
CONCLUSIONS
Educating trainees on rapid response scenarios by using a simulation curriculum provides many benefits. Our trainees reported improvement in addressing cardiac, respiratory, and neurological rapid response scenarios after experiencing the simulation. They felt better prepared and had developed a better systematic approach for the future.
Acknowledgments
The authors thank Pawan Sikka, MD, George Martinez, MD and Braden Anderson, MD for participating as physician experts and educating our students. We thank Naomi Devers; Dinetra Jones; Stephanie Garrett; Sara Holton; Evelina Bartnick; Tanelle Smith; Michael Lomax; Shaun Kelemen for their participation as nurses, assistants, and simulation technology experts.
1. Guze PA. Using technology to meet the challenges of medical education. Trans Am Clin Climatol Assoc. 2015;126:260-270.
2. Higgins M, Madan C, Patel R. Development and decay of procedural skills in surgery: a systematic review of the effectiveness of simulation-based medical education interventions. Surgeon. 2021;19(4):e67-e77. doi:10.1016/j.surge.2020.07.013
3. Lyons PG, Edelson DP, Carey KA, et al. Characteristics of rapid response calls in the United States: an analysis of the first 402,023 adult cases from the Get With the Guidelines Resuscitation-Medical Emergency Team registry. Crit Care Med. 2019;47(10):1283-1289. doi:10.1097/CCM.0000000000003912
4. McMurray L, Hall AK, Rich J, Merchant S, Chaplin T. The nightmares course: a longitudinal, multidisciplinary, simulation-based curriculum to train and assess resident competence in resuscitation. J Grad Med Educ. 2017;9(4):503-508. doi:10.4300/JGME-D-16-00462.1
5. Gilic F, Schultz K, Sempowski I, Blagojevic A. “Nightmares-Family Medicine” course is an effective acute care teaching tool for family medicine residents. Simul Healthc. 2019;14(3):157-162. doi:10.1097/SIH.0000000000000355
6. Issenberg SB, McGaghie WC, Petrusa ER, Lee Gordon D, Scalese RJ. Features and uses of high-fidelity medical simulations that lead to effective learning: a BEME systematic review. Med Teach. 2005;27(1):10-28. doi:10.1080/01421590500046924
7. Datta R, Upadhyay K, Jaideep C. Simulation and its role in medical education. Med J Armed Forces India. 2012;68(2):167-172. doi:10.1016/S0377-1237(12)60040-9
1. Guze PA. Using technology to meet the challenges of medical education. Trans Am Clin Climatol Assoc. 2015;126:260-270.
2. Higgins M, Madan C, Patel R. Development and decay of procedural skills in surgery: a systematic review of the effectiveness of simulation-based medical education interventions. Surgeon. 2021;19(4):e67-e77. doi:10.1016/j.surge.2020.07.013
3. Lyons PG, Edelson DP, Carey KA, et al. Characteristics of rapid response calls in the United States: an analysis of the first 402,023 adult cases from the Get With the Guidelines Resuscitation-Medical Emergency Team registry. Crit Care Med. 2019;47(10):1283-1289. doi:10.1097/CCM.0000000000003912
4. McMurray L, Hall AK, Rich J, Merchant S, Chaplin T. The nightmares course: a longitudinal, multidisciplinary, simulation-based curriculum to train and assess resident competence in resuscitation. J Grad Med Educ. 2017;9(4):503-508. doi:10.4300/JGME-D-16-00462.1
5. Gilic F, Schultz K, Sempowski I, Blagojevic A. “Nightmares-Family Medicine” course is an effective acute care teaching tool for family medicine residents. Simul Healthc. 2019;14(3):157-162. doi:10.1097/SIH.0000000000000355
6. Issenberg SB, McGaghie WC, Petrusa ER, Lee Gordon D, Scalese RJ. Features and uses of high-fidelity medical simulations that lead to effective learning: a BEME systematic review. Med Teach. 2005;27(1):10-28. doi:10.1080/01421590500046924
7. Datta R, Upadhyay K, Jaideep C. Simulation and its role in medical education. Med J Armed Forces India. 2012;68(2):167-172. doi:10.1016/S0377-1237(12)60040-9
More evidence metformin may be neuroprotective
TOPLINE:
New research suggests terminating metformin may raise the risk for dementia in older adults with type 2 diabetes, providing more evidence of metformin’s potential neuroprotective effects.
METHODOLOGY:
- Researchers evaluated the association between discontinuing metformin for reasons unrelated to kidney dysfunction and dementia incidence.
- The cohort included 12,220 Kaiser Permanente Northern California members who stopped metformin early (with normal kidney function) and 29,126 routine metformin users.
- The cohort of early terminators was 46% women with an average age of 59 years at the start of metformin prescription. The cohort continuing metformin was 47% women, with a start age of 61 years.
TAKEAWAY:
- Adults who stopped metformin early were 21% more likely to be diagnosed with dementia during follow up (hazard ratio, 1.21; 95% confidence interval, 1.12-1.30), compared with routine metformin users.
- This association was largely independent of changes in A1c level and insulin usage.
IN PRACTICE:
The findings “corroborate the largely consistent evidence from other observational studies showing an association between metformin use and lower dementia incidence [and] may have important implications for clinical treatment of adults with diabetes,” the authors write.
SOURCE:
The study, with first author Scott Zimmerman, MPH, University of California, San Francisco, was published online in JAMA Network Open.
LIMITATIONS:
Dementia diagnosis was obtained based on medical records. Factors such as race, ethnicity, or time on metformin were not evaluated. Information on the exact reason for stopping metformin was not available.
DISCLOSURES:
The study was funded by grants from the National Institutes of Health, National Institute on Aging. Mr. Zimmerman owns stock in AbbVie, Gilead Sciences, CRISPR Therapeutics, and Abbott Laboratories. Disclosure for the other study authors can be found with the original article.
A version of this article first appeared on Medscape.com.
TOPLINE:
New research suggests terminating metformin may raise the risk for dementia in older adults with type 2 diabetes, providing more evidence of metformin’s potential neuroprotective effects.
METHODOLOGY:
- Researchers evaluated the association between discontinuing metformin for reasons unrelated to kidney dysfunction and dementia incidence.
- The cohort included 12,220 Kaiser Permanente Northern California members who stopped metformin early (with normal kidney function) and 29,126 routine metformin users.
- The cohort of early terminators was 46% women with an average age of 59 years at the start of metformin prescription. The cohort continuing metformin was 47% women, with a start age of 61 years.
TAKEAWAY:
- Adults who stopped metformin early were 21% more likely to be diagnosed with dementia during follow up (hazard ratio, 1.21; 95% confidence interval, 1.12-1.30), compared with routine metformin users.
- This association was largely independent of changes in A1c level and insulin usage.
IN PRACTICE:
The findings “corroborate the largely consistent evidence from other observational studies showing an association between metformin use and lower dementia incidence [and] may have important implications for clinical treatment of adults with diabetes,” the authors write.
SOURCE:
The study, with first author Scott Zimmerman, MPH, University of California, San Francisco, was published online in JAMA Network Open.
LIMITATIONS:
Dementia diagnosis was obtained based on medical records. Factors such as race, ethnicity, or time on metformin were not evaluated. Information on the exact reason for stopping metformin was not available.
DISCLOSURES:
The study was funded by grants from the National Institutes of Health, National Institute on Aging. Mr. Zimmerman owns stock in AbbVie, Gilead Sciences, CRISPR Therapeutics, and Abbott Laboratories. Disclosure for the other study authors can be found with the original article.
A version of this article first appeared on Medscape.com.
TOPLINE:
New research suggests terminating metformin may raise the risk for dementia in older adults with type 2 diabetes, providing more evidence of metformin’s potential neuroprotective effects.
METHODOLOGY:
- Researchers evaluated the association between discontinuing metformin for reasons unrelated to kidney dysfunction and dementia incidence.
- The cohort included 12,220 Kaiser Permanente Northern California members who stopped metformin early (with normal kidney function) and 29,126 routine metformin users.
- The cohort of early terminators was 46% women with an average age of 59 years at the start of metformin prescription. The cohort continuing metformin was 47% women, with a start age of 61 years.
TAKEAWAY:
- Adults who stopped metformin early were 21% more likely to be diagnosed with dementia during follow up (hazard ratio, 1.21; 95% confidence interval, 1.12-1.30), compared with routine metformin users.
- This association was largely independent of changes in A1c level and insulin usage.
IN PRACTICE:
The findings “corroborate the largely consistent evidence from other observational studies showing an association between metformin use and lower dementia incidence [and] may have important implications for clinical treatment of adults with diabetes,” the authors write.
SOURCE:
The study, with first author Scott Zimmerman, MPH, University of California, San Francisco, was published online in JAMA Network Open.
LIMITATIONS:
Dementia diagnosis was obtained based on medical records. Factors such as race, ethnicity, or time on metformin were not evaluated. Information on the exact reason for stopping metformin was not available.
DISCLOSURES:
The study was funded by grants from the National Institutes of Health, National Institute on Aging. Mr. Zimmerman owns stock in AbbVie, Gilead Sciences, CRISPR Therapeutics, and Abbott Laboratories. Disclosure for the other study authors can be found with the original article.
A version of this article first appeared on Medscape.com.
Brain structural and cognitive changes during pregnancy
Pregnancy is unquestionably a major milestone in a woman’s life. During gestation, her body shape noticeably changes, but the invisible structural and cognitive changes in her brain are more striking. Some of those neurobiological changes are short-term, while others are long-lasting, well beyond delivery, and even into old age.
Physiological changes during pregnancy are extraordinary. The dramatic increases in estrogen, progesterone, and glucocorticoids help maintain pregnancy, ensure safe delivery of the baby, and trigger maternal behavior. However, other important changes also occur in the mother’s cardiac output, blood volume, renal function, respiratory output, and immune adaptations to accommodate the growth of the fetus. Gene expression also occurs to accomplish those changes, and there are lifelong repercussions from those drastic physiological changes.
During pregnancy, the brain is exposed to escalating levels of hormones released from the placenta, which the woman had never experienced. Those hormones regulate neuroplasticity, neuroinflammation, behavior, and cognition.
Structural brain changes1-6
Brain volume declines during pregnancy, reaching a nadir at the time of parturition. However, recovery occurs within 5 months after delivery. During the postpartum period, gray matter volume increases in the first 3 to 4 weeks, especially in areas involved in maternal behavior, including the amygdala, prefrontal cortex, and hypothalamus. Hippocampal gray matter decreases at 2 months postpartum compared to preconception levels, and reductions can still be observed up to 2 years following delivery. Gray matter reductions occur in multiple brain regions involved in social cognition, including the superior temporal gyrus, medial and inferior frontal cortex, fusiform areas, and hippocampus. Those changes correlate with positive maternal attachment. It is noteworthy that neural activity is highest in areas with reduced gray volume, so a decline in brain volume is associated with enhanced maternal attachment. Interestingly, those changes occur in fathers, too.
Childbearing improves stroke outcomes in middle age, but body weight will increase. The risk of Alzheimer’s disease increases with a higher number of gestations, but longevity is higher if the pregnancy occurs at an older age. Reproduction is also associated with shorter telomeres, which can elevate the risk of cancer, inflammation, diabetes, and dementia.
Cognitive changes7-10
The term “pregnancy brain” refers to cognitive changes during pregnancy and postpartum; these include decreased memory and concentration, absent-mindedness, heightened reactivity to threatening stimuli, and a decrease in motivation and executive functions. After delivery a mother has increased empathy (sometimes referred to as Theory of Mind) and greater activation in brain structures involved in empathy, including the paracingulate cortex, the posterior cingulate, and the insula. Also, the mirror neuron system becomes more activated in response to a woman’s own children compared to unfamiliar children. This incudes the ventral premotor cortex, the inferior frontal gyrus, and the posterior parietal cortex.
Certain forms of memory are impaired during pregnancy and early postpartum, including verbal free recall and working memory, as well as executive functions. Those are believed to correlate with glucocorticoids and estrogen levels.
Continue to: The following cognitive functions...
The following cognitive functions increase between the first and second trimester: verbal memory, attention, executive functions processing speed, verbal, and visuospatial abilities. Interestingly, mothers of a male fetus outperformed mothers of a female fetus on working memory and spatial ability.
Other changes11-16
- Cells from the fetus can traffic to the mother’s body and create microchimeric cells, which have short-term benefits (healing some of the other’s organs as stem cells do) but long-term downsides include future brain disorders such as Parkinson’s disease or Alzheimer’s disease, as well as autoimmune diseases and various types of cancer. The reverse also occurs with cells transferring from the mother to the fetus, persisting into infancy and childhood.
- Postpartum psychosis is associated with reductions in the volumes of the anterior cingulate, left parahippocampal gyrus, and superior temporal gyrus.
- A woman’s white matter increases during pregnancy compared to preconception. This is attributed to the high levels of prolactin, which proliferates oligodendrocytes, the glial cells that continuously manufacture myelin.
- The pituitary gland increases by 200% to 300% during pregnancy and returns to pre-pregnancy levels approximately 8 months following delivery. Prolactin also mediates the production of brain cells in the hippocampus (ie, neurogenesis).
- Sexual activity, even without pregnancy, increases neurogenesis. Plasma levels of prolactin increase significantly following an orgasm in both men and women, which indicates that sexual activity has beneficial brain effects.
- With pregnancy, the immune system shifts from proinflammatory to anti-inflammatory signaling. This protects the fetus from being attacked and rejected as foreign tissue. However, at the end of pregnancy, there is a “burst” of proinflammatory signaling, which serves as a major trigger to induce uterine contractions and initiate labor (to expel the foreign tissue).
- Brain levels of the anti-inflammatory cytokine interleukin-6 increase in the postpartum period, which represents a significant modification in the neuroimmune environment, and the maternal brain assumes an inflammatory-resistant state, which has cognitive and neuroplasticity implications. However, this neuroimmune dysregulation is implicated in postpartum depression and anxiety.
- Older females who were never pregnant or only had 1 pregnancy had better overall cognitive functioning than females who became pregnant at an young age.
- In animal studies, reproduction alleviates the negative effects of aging on several hippocampal functions, especially neurogenesis. Dendritic spine density in the CA1 region of the hippocampus is higher in pregnancy and early postpartum period compared to nulliparous females (based on animal studies).
Pregnancy is indispensable for the perpetuation of the species. Its hormonal, physiologic, neurobiological, and cognitive correlates are extensive. The cognitive changes in the postpartum period are designed by evolution to prepare a woman to care for her newborn and to ensure its survival. But the biological sequelae of pregnancy extend to the rest of a woman’s life and may predispose her to immune and brain disorders as she ages.
1. Barba-Müller E, Craddock S, Carmona S, et al. Brain plasticity in pregnancy and the postpartum period: links to maternal caregiving and mental health. Arch Womens Ment Health. 2019;22(2):289-299.
2. Pawluski JL, Hoekzema E, Leuner B, et al. Less can be more: fine tuning the maternal brain. Neurosci Biobehav Rev. 2022;133:104475. doi:10.1016/j.neubiorev.2021.11.045
3. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
4. Cárdenas EF, Kujawa A, Humphreys KL. Neurobiological changes during the peripartum period: implications for health and behavior. Soc Cogn Affect Neurosci. 2020;15(10):1097-1110.
5. Eid RS, Chaiton JA, Lieblich SE, et al. Early and late effects of maternal experience on hippocampal neurogenesis, microglia, and the circulating cytokine milieu. Neurobiol Aging. 2019;78:1-17.
6. Galea LA, Leuner B, Slattery DA. Hippocampal plasticity during the peripartum period: influence of sex steroids, stress and ageing. J Neuroendocrinol. 2014;26(10):641-648.
7. Henry JF, Sherwin BB. Hormones and cognitive functioning during late pregnancy and postpartum: a longitudinal study. Behav Neurosci. 2012;126(1):73-85.
8. Barda G, Mizrachi Y, Borokchovich I, et al. The effect of pregnancy on maternal cognition. Sci Rep. 2011;11(1)12187. doi:10.1038/s41598-021-91504-9
9. Davies SJ, Lum JA, Skouteris H, et al. Cognitive impairment during pregnancy: a meta-analysis. Med J Aust. 2018;208(1):35-40.
10. Pownall M, Hutter RRC, Rockliffe L, et al. Memory and mood changes in pregnancy: a qualitative content analysis of women’s first-hand accounts. J Reprod Infant Psychol. 2023;41(5):516-527.
11. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
12. Duarte-Guterman P, Leuner B, Galea LAM. The long and short term effects of motherhood on the brain. Front Neuroendocrinol. 2019;53:100740. doi:10.1016/j.yfrne.2019.02.004
13. Haim A, Julian D, Albin-Brooks C, et al. A survey of neuroimmune changes in pregnant and postpartum female rats. Brain Behav Immun. 2017;59:67-78.
14. Benson JC, Malyuk DF, Madhavan A, et al. Pituitary volume changes in pregnancy and the post-partum period. Neuroradiol J. 2023. doi:10.1177/19714009231196470
15. Schepanski S, Chini M, Sternemann V, et al. Pregnancy-induced maternal microchimerism shapes neurodevelopment and behavior in mice. Nat Commun. 2022;13(1):4571. doi:10.1038/s41467-022-32230-2
16. Larsen CM, Grattan DR. Prolactin, neurogenesis, and maternal behaviors. Brain Behav Immun. 2012;26(2):201-209.
Pregnancy is unquestionably a major milestone in a woman’s life. During gestation, her body shape noticeably changes, but the invisible structural and cognitive changes in her brain are more striking. Some of those neurobiological changes are short-term, while others are long-lasting, well beyond delivery, and even into old age.
Physiological changes during pregnancy are extraordinary. The dramatic increases in estrogen, progesterone, and glucocorticoids help maintain pregnancy, ensure safe delivery of the baby, and trigger maternal behavior. However, other important changes also occur in the mother’s cardiac output, blood volume, renal function, respiratory output, and immune adaptations to accommodate the growth of the fetus. Gene expression also occurs to accomplish those changes, and there are lifelong repercussions from those drastic physiological changes.
During pregnancy, the brain is exposed to escalating levels of hormones released from the placenta, which the woman had never experienced. Those hormones regulate neuroplasticity, neuroinflammation, behavior, and cognition.
Structural brain changes1-6
Brain volume declines during pregnancy, reaching a nadir at the time of parturition. However, recovery occurs within 5 months after delivery. During the postpartum period, gray matter volume increases in the first 3 to 4 weeks, especially in areas involved in maternal behavior, including the amygdala, prefrontal cortex, and hypothalamus. Hippocampal gray matter decreases at 2 months postpartum compared to preconception levels, and reductions can still be observed up to 2 years following delivery. Gray matter reductions occur in multiple brain regions involved in social cognition, including the superior temporal gyrus, medial and inferior frontal cortex, fusiform areas, and hippocampus. Those changes correlate with positive maternal attachment. It is noteworthy that neural activity is highest in areas with reduced gray volume, so a decline in brain volume is associated with enhanced maternal attachment. Interestingly, those changes occur in fathers, too.
Childbearing improves stroke outcomes in middle age, but body weight will increase. The risk of Alzheimer’s disease increases with a higher number of gestations, but longevity is higher if the pregnancy occurs at an older age. Reproduction is also associated with shorter telomeres, which can elevate the risk of cancer, inflammation, diabetes, and dementia.
Cognitive changes7-10
The term “pregnancy brain” refers to cognitive changes during pregnancy and postpartum; these include decreased memory and concentration, absent-mindedness, heightened reactivity to threatening stimuli, and a decrease in motivation and executive functions. After delivery a mother has increased empathy (sometimes referred to as Theory of Mind) and greater activation in brain structures involved in empathy, including the paracingulate cortex, the posterior cingulate, and the insula. Also, the mirror neuron system becomes more activated in response to a woman’s own children compared to unfamiliar children. This incudes the ventral premotor cortex, the inferior frontal gyrus, and the posterior parietal cortex.
Certain forms of memory are impaired during pregnancy and early postpartum, including verbal free recall and working memory, as well as executive functions. Those are believed to correlate with glucocorticoids and estrogen levels.
Continue to: The following cognitive functions...
The following cognitive functions increase between the first and second trimester: verbal memory, attention, executive functions processing speed, verbal, and visuospatial abilities. Interestingly, mothers of a male fetus outperformed mothers of a female fetus on working memory and spatial ability.
Other changes11-16
- Cells from the fetus can traffic to the mother’s body and create microchimeric cells, which have short-term benefits (healing some of the other’s organs as stem cells do) but long-term downsides include future brain disorders such as Parkinson’s disease or Alzheimer’s disease, as well as autoimmune diseases and various types of cancer. The reverse also occurs with cells transferring from the mother to the fetus, persisting into infancy and childhood.
- Postpartum psychosis is associated with reductions in the volumes of the anterior cingulate, left parahippocampal gyrus, and superior temporal gyrus.
- A woman’s white matter increases during pregnancy compared to preconception. This is attributed to the high levels of prolactin, which proliferates oligodendrocytes, the glial cells that continuously manufacture myelin.
- The pituitary gland increases by 200% to 300% during pregnancy and returns to pre-pregnancy levels approximately 8 months following delivery. Prolactin also mediates the production of brain cells in the hippocampus (ie, neurogenesis).
- Sexual activity, even without pregnancy, increases neurogenesis. Plasma levels of prolactin increase significantly following an orgasm in both men and women, which indicates that sexual activity has beneficial brain effects.
- With pregnancy, the immune system shifts from proinflammatory to anti-inflammatory signaling. This protects the fetus from being attacked and rejected as foreign tissue. However, at the end of pregnancy, there is a “burst” of proinflammatory signaling, which serves as a major trigger to induce uterine contractions and initiate labor (to expel the foreign tissue).
- Brain levels of the anti-inflammatory cytokine interleukin-6 increase in the postpartum period, which represents a significant modification in the neuroimmune environment, and the maternal brain assumes an inflammatory-resistant state, which has cognitive and neuroplasticity implications. However, this neuroimmune dysregulation is implicated in postpartum depression and anxiety.
- Older females who were never pregnant or only had 1 pregnancy had better overall cognitive functioning than females who became pregnant at an young age.
- In animal studies, reproduction alleviates the negative effects of aging on several hippocampal functions, especially neurogenesis. Dendritic spine density in the CA1 region of the hippocampus is higher in pregnancy and early postpartum period compared to nulliparous females (based on animal studies).
Pregnancy is indispensable for the perpetuation of the species. Its hormonal, physiologic, neurobiological, and cognitive correlates are extensive. The cognitive changes in the postpartum period are designed by evolution to prepare a woman to care for her newborn and to ensure its survival. But the biological sequelae of pregnancy extend to the rest of a woman’s life and may predispose her to immune and brain disorders as she ages.
Pregnancy is unquestionably a major milestone in a woman’s life. During gestation, her body shape noticeably changes, but the invisible structural and cognitive changes in her brain are more striking. Some of those neurobiological changes are short-term, while others are long-lasting, well beyond delivery, and even into old age.
Physiological changes during pregnancy are extraordinary. The dramatic increases in estrogen, progesterone, and glucocorticoids help maintain pregnancy, ensure safe delivery of the baby, and trigger maternal behavior. However, other important changes also occur in the mother’s cardiac output, blood volume, renal function, respiratory output, and immune adaptations to accommodate the growth of the fetus. Gene expression also occurs to accomplish those changes, and there are lifelong repercussions from those drastic physiological changes.
During pregnancy, the brain is exposed to escalating levels of hormones released from the placenta, which the woman had never experienced. Those hormones regulate neuroplasticity, neuroinflammation, behavior, and cognition.
Structural brain changes1-6
Brain volume declines during pregnancy, reaching a nadir at the time of parturition. However, recovery occurs within 5 months after delivery. During the postpartum period, gray matter volume increases in the first 3 to 4 weeks, especially in areas involved in maternal behavior, including the amygdala, prefrontal cortex, and hypothalamus. Hippocampal gray matter decreases at 2 months postpartum compared to preconception levels, and reductions can still be observed up to 2 years following delivery. Gray matter reductions occur in multiple brain regions involved in social cognition, including the superior temporal gyrus, medial and inferior frontal cortex, fusiform areas, and hippocampus. Those changes correlate with positive maternal attachment. It is noteworthy that neural activity is highest in areas with reduced gray volume, so a decline in brain volume is associated with enhanced maternal attachment. Interestingly, those changes occur in fathers, too.
Childbearing improves stroke outcomes in middle age, but body weight will increase. The risk of Alzheimer’s disease increases with a higher number of gestations, but longevity is higher if the pregnancy occurs at an older age. Reproduction is also associated with shorter telomeres, which can elevate the risk of cancer, inflammation, diabetes, and dementia.
Cognitive changes7-10
The term “pregnancy brain” refers to cognitive changes during pregnancy and postpartum; these include decreased memory and concentration, absent-mindedness, heightened reactivity to threatening stimuli, and a decrease in motivation and executive functions. After delivery a mother has increased empathy (sometimes referred to as Theory of Mind) and greater activation in brain structures involved in empathy, including the paracingulate cortex, the posterior cingulate, and the insula. Also, the mirror neuron system becomes more activated in response to a woman’s own children compared to unfamiliar children. This incudes the ventral premotor cortex, the inferior frontal gyrus, and the posterior parietal cortex.
Certain forms of memory are impaired during pregnancy and early postpartum, including verbal free recall and working memory, as well as executive functions. Those are believed to correlate with glucocorticoids and estrogen levels.
Continue to: The following cognitive functions...
The following cognitive functions increase between the first and second trimester: verbal memory, attention, executive functions processing speed, verbal, and visuospatial abilities. Interestingly, mothers of a male fetus outperformed mothers of a female fetus on working memory and spatial ability.
Other changes11-16
- Cells from the fetus can traffic to the mother’s body and create microchimeric cells, which have short-term benefits (healing some of the other’s organs as stem cells do) but long-term downsides include future brain disorders such as Parkinson’s disease or Alzheimer’s disease, as well as autoimmune diseases and various types of cancer. The reverse also occurs with cells transferring from the mother to the fetus, persisting into infancy and childhood.
- Postpartum psychosis is associated with reductions in the volumes of the anterior cingulate, left parahippocampal gyrus, and superior temporal gyrus.
- A woman’s white matter increases during pregnancy compared to preconception. This is attributed to the high levels of prolactin, which proliferates oligodendrocytes, the glial cells that continuously manufacture myelin.
- The pituitary gland increases by 200% to 300% during pregnancy and returns to pre-pregnancy levels approximately 8 months following delivery. Prolactin also mediates the production of brain cells in the hippocampus (ie, neurogenesis).
- Sexual activity, even without pregnancy, increases neurogenesis. Plasma levels of prolactin increase significantly following an orgasm in both men and women, which indicates that sexual activity has beneficial brain effects.
- With pregnancy, the immune system shifts from proinflammatory to anti-inflammatory signaling. This protects the fetus from being attacked and rejected as foreign tissue. However, at the end of pregnancy, there is a “burst” of proinflammatory signaling, which serves as a major trigger to induce uterine contractions and initiate labor (to expel the foreign tissue).
- Brain levels of the anti-inflammatory cytokine interleukin-6 increase in the postpartum period, which represents a significant modification in the neuroimmune environment, and the maternal brain assumes an inflammatory-resistant state, which has cognitive and neuroplasticity implications. However, this neuroimmune dysregulation is implicated in postpartum depression and anxiety.
- Older females who were never pregnant or only had 1 pregnancy had better overall cognitive functioning than females who became pregnant at an young age.
- In animal studies, reproduction alleviates the negative effects of aging on several hippocampal functions, especially neurogenesis. Dendritic spine density in the CA1 region of the hippocampus is higher in pregnancy and early postpartum period compared to nulliparous females (based on animal studies).
Pregnancy is indispensable for the perpetuation of the species. Its hormonal, physiologic, neurobiological, and cognitive correlates are extensive. The cognitive changes in the postpartum period are designed by evolution to prepare a woman to care for her newborn and to ensure its survival. But the biological sequelae of pregnancy extend to the rest of a woman’s life and may predispose her to immune and brain disorders as she ages.
1. Barba-Müller E, Craddock S, Carmona S, et al. Brain plasticity in pregnancy and the postpartum period: links to maternal caregiving and mental health. Arch Womens Ment Health. 2019;22(2):289-299.
2. Pawluski JL, Hoekzema E, Leuner B, et al. Less can be more: fine tuning the maternal brain. Neurosci Biobehav Rev. 2022;133:104475. doi:10.1016/j.neubiorev.2021.11.045
3. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
4. Cárdenas EF, Kujawa A, Humphreys KL. Neurobiological changes during the peripartum period: implications for health and behavior. Soc Cogn Affect Neurosci. 2020;15(10):1097-1110.
5. Eid RS, Chaiton JA, Lieblich SE, et al. Early and late effects of maternal experience on hippocampal neurogenesis, microglia, and the circulating cytokine milieu. Neurobiol Aging. 2019;78:1-17.
6. Galea LA, Leuner B, Slattery DA. Hippocampal plasticity during the peripartum period: influence of sex steroids, stress and ageing. J Neuroendocrinol. 2014;26(10):641-648.
7. Henry JF, Sherwin BB. Hormones and cognitive functioning during late pregnancy and postpartum: a longitudinal study. Behav Neurosci. 2012;126(1):73-85.
8. Barda G, Mizrachi Y, Borokchovich I, et al. The effect of pregnancy on maternal cognition. Sci Rep. 2011;11(1)12187. doi:10.1038/s41598-021-91504-9
9. Davies SJ, Lum JA, Skouteris H, et al. Cognitive impairment during pregnancy: a meta-analysis. Med J Aust. 2018;208(1):35-40.
10. Pownall M, Hutter RRC, Rockliffe L, et al. Memory and mood changes in pregnancy: a qualitative content analysis of women’s first-hand accounts. J Reprod Infant Psychol. 2023;41(5):516-527.
11. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
12. Duarte-Guterman P, Leuner B, Galea LAM. The long and short term effects of motherhood on the brain. Front Neuroendocrinol. 2019;53:100740. doi:10.1016/j.yfrne.2019.02.004
13. Haim A, Julian D, Albin-Brooks C, et al. A survey of neuroimmune changes in pregnant and postpartum female rats. Brain Behav Immun. 2017;59:67-78.
14. Benson JC, Malyuk DF, Madhavan A, et al. Pituitary volume changes in pregnancy and the post-partum period. Neuroradiol J. 2023. doi:10.1177/19714009231196470
15. Schepanski S, Chini M, Sternemann V, et al. Pregnancy-induced maternal microchimerism shapes neurodevelopment and behavior in mice. Nat Commun. 2022;13(1):4571. doi:10.1038/s41467-022-32230-2
16. Larsen CM, Grattan DR. Prolactin, neurogenesis, and maternal behaviors. Brain Behav Immun. 2012;26(2):201-209.
1. Barba-Müller E, Craddock S, Carmona S, et al. Brain plasticity in pregnancy and the postpartum period: links to maternal caregiving and mental health. Arch Womens Ment Health. 2019;22(2):289-299.
2. Pawluski JL, Hoekzema E, Leuner B, et al. Less can be more: fine tuning the maternal brain. Neurosci Biobehav Rev. 2022;133:104475. doi:10.1016/j.neubiorev.2021.11.045
3. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
4. Cárdenas EF, Kujawa A, Humphreys KL. Neurobiological changes during the peripartum period: implications for health and behavior. Soc Cogn Affect Neurosci. 2020;15(10):1097-1110.
5. Eid RS, Chaiton JA, Lieblich SE, et al. Early and late effects of maternal experience on hippocampal neurogenesis, microglia, and the circulating cytokine milieu. Neurobiol Aging. 2019;78:1-17.
6. Galea LA, Leuner B, Slattery DA. Hippocampal plasticity during the peripartum period: influence of sex steroids, stress and ageing. J Neuroendocrinol. 2014;26(10):641-648.
7. Henry JF, Sherwin BB. Hormones and cognitive functioning during late pregnancy and postpartum: a longitudinal study. Behav Neurosci. 2012;126(1):73-85.
8. Barda G, Mizrachi Y, Borokchovich I, et al. The effect of pregnancy on maternal cognition. Sci Rep. 2011;11(1)12187. doi:10.1038/s41598-021-91504-9
9. Davies SJ, Lum JA, Skouteris H, et al. Cognitive impairment during pregnancy: a meta-analysis. Med J Aust. 2018;208(1):35-40.
10. Pownall M, Hutter RRC, Rockliffe L, et al. Memory and mood changes in pregnancy: a qualitative content analysis of women’s first-hand accounts. J Reprod Infant Psychol. 2023;41(5):516-527.
11. Hoekzema E, Barba-Müller E, Pozzobon C, et al. Pregnancy leads to long-lasting changes in human brain structure. Nat Neurosci. 2017;20(2):287-296.
12. Duarte-Guterman P, Leuner B, Galea LAM. The long and short term effects of motherhood on the brain. Front Neuroendocrinol. 2019;53:100740. doi:10.1016/j.yfrne.2019.02.004
13. Haim A, Julian D, Albin-Brooks C, et al. A survey of neuroimmune changes in pregnant and postpartum female rats. Brain Behav Immun. 2017;59:67-78.
14. Benson JC, Malyuk DF, Madhavan A, et al. Pituitary volume changes in pregnancy and the post-partum period. Neuroradiol J. 2023. doi:10.1177/19714009231196470
15. Schepanski S, Chini M, Sternemann V, et al. Pregnancy-induced maternal microchimerism shapes neurodevelopment and behavior in mice. Nat Commun. 2022;13(1):4571. doi:10.1038/s41467-022-32230-2
16. Larsen CM, Grattan DR. Prolactin, neurogenesis, and maternal behaviors. Brain Behav Immun. 2012;26(2):201-209.
Higher triglycerides linked to lower dementia risk
TOPLINE:
a large study of community-dwelling older adults suggests.
METHODOLOGY:
- The analysis included 18,294 participants, median age 75 years and median triglyceride level 106 mg/dL, from the Aspirin in Reducing Events in the Elderly (ASPREE) study, a placebo-controlled, randomized trial of daily low-dose aspirin in older people without dementia or history of cardiovascular disease (CVD) at recruitment.
- Researchers repeated their main analyses in a sub-cohort of 13,976 subjects with APOE epsilon-4 genetic data, and an external cohort of 68,200 participants, mean age 66.9 years and a median nonfasting triglyceride of 139 mg/dL, from the UK biobank, followed for a median of 12.5 years.
- The main outcome was incident dementia over 6.4 years and secondary outcomes included changes in composite cognitive function and domain-specific cognition.
- Researchers controlled for a number of potential confounders, including age, sex, race, smoking, alcohol consumption, education, family history of dementia, diabetes, hypertension, and statin use.
TAKEAWAY:
- Every doubling of baseline triglycerides was associated with an 18% lower risk of incident dementia across the entire study cohort (adjusted hazard ratio, 0.82) and in participants with genotypic data (aHR, 0.82) and a 17% lower risk in the external UK Biobank cohort (aHR, 0.83) (P ≤ .01 for all).
- In the entire cohort, the risk for dementia was 15% lower in those with triglyceride levels at 63-106 mg/dL (aHR, 0.85); 24% lower in those at 107-186 mg/dL (aHR, 0.76); and 36% lower for those with levels higher than 187 mg/dL (aHR, 0.64), compared with individuals with levels below 62 mg/dL (P for trend <.001).
- The direction and magnitude of the inverse association between triglycerides and dementia risk were not modified by age, sex, or risk factors related to triglycerides or dementia.
- In the entire study cohort, higher triglyceride levels were significantly associated with slower decline in global cognition (P = .02), composite cognition (P = .03), and a borderline significantly slower decline in episodic memory (P = .05).
IN PRACTICE:
“Triglyceride levels may serve as a useful predictor for dementia risk and cognitive decline in older populations,” the investigators write. Higher triglyceride levels may reflect better overall health and/or lifestyle behaviors that protect against dementia.
SOURCE:
The study was led by Zhen Zhou, of Monash University, Melbourne. It was published online in Neurology.
LIMITATIONS:
The study can’t establish a causal relationship between triglyceride levels and dementia or fully exclude reverse causality. As most ASPREE participants had normal to high-normal triglyceride levels, the results can’t be generalized to those with severe hypertriglyceridemia. The findings are unique to older people without CVD and may not be generalizable to other populations.
DISCLOSURES:
The study received support from the Royal Australian College of General Practitioners (RACGP)/HCF Research Foundation. Dr. Zhou reported receiving salary from the RACGP/HCF Research Foundation.
A version of this article first appeared on Medscape.com.
TOPLINE:
a large study of community-dwelling older adults suggests.
METHODOLOGY:
- The analysis included 18,294 participants, median age 75 years and median triglyceride level 106 mg/dL, from the Aspirin in Reducing Events in the Elderly (ASPREE) study, a placebo-controlled, randomized trial of daily low-dose aspirin in older people without dementia or history of cardiovascular disease (CVD) at recruitment.
- Researchers repeated their main analyses in a sub-cohort of 13,976 subjects with APOE epsilon-4 genetic data, and an external cohort of 68,200 participants, mean age 66.9 years and a median nonfasting triglyceride of 139 mg/dL, from the UK biobank, followed for a median of 12.5 years.
- The main outcome was incident dementia over 6.4 years and secondary outcomes included changes in composite cognitive function and domain-specific cognition.
- Researchers controlled for a number of potential confounders, including age, sex, race, smoking, alcohol consumption, education, family history of dementia, diabetes, hypertension, and statin use.
TAKEAWAY:
- Every doubling of baseline triglycerides was associated with an 18% lower risk of incident dementia across the entire study cohort (adjusted hazard ratio, 0.82) and in participants with genotypic data (aHR, 0.82) and a 17% lower risk in the external UK Biobank cohort (aHR, 0.83) (P ≤ .01 for all).
- In the entire cohort, the risk for dementia was 15% lower in those with triglyceride levels at 63-106 mg/dL (aHR, 0.85); 24% lower in those at 107-186 mg/dL (aHR, 0.76); and 36% lower for those with levels higher than 187 mg/dL (aHR, 0.64), compared with individuals with levels below 62 mg/dL (P for trend <.001).
- The direction and magnitude of the inverse association between triglycerides and dementia risk were not modified by age, sex, or risk factors related to triglycerides or dementia.
- In the entire study cohort, higher triglyceride levels were significantly associated with slower decline in global cognition (P = .02), composite cognition (P = .03), and a borderline significantly slower decline in episodic memory (P = .05).
IN PRACTICE:
“Triglyceride levels may serve as a useful predictor for dementia risk and cognitive decline in older populations,” the investigators write. Higher triglyceride levels may reflect better overall health and/or lifestyle behaviors that protect against dementia.
SOURCE:
The study was led by Zhen Zhou, of Monash University, Melbourne. It was published online in Neurology.
LIMITATIONS:
The study can’t establish a causal relationship between triglyceride levels and dementia or fully exclude reverse causality. As most ASPREE participants had normal to high-normal triglyceride levels, the results can’t be generalized to those with severe hypertriglyceridemia. The findings are unique to older people without CVD and may not be generalizable to other populations.
DISCLOSURES:
The study received support from the Royal Australian College of General Practitioners (RACGP)/HCF Research Foundation. Dr. Zhou reported receiving salary from the RACGP/HCF Research Foundation.
A version of this article first appeared on Medscape.com.
TOPLINE:
a large study of community-dwelling older adults suggests.
METHODOLOGY:
- The analysis included 18,294 participants, median age 75 years and median triglyceride level 106 mg/dL, from the Aspirin in Reducing Events in the Elderly (ASPREE) study, a placebo-controlled, randomized trial of daily low-dose aspirin in older people without dementia or history of cardiovascular disease (CVD) at recruitment.
- Researchers repeated their main analyses in a sub-cohort of 13,976 subjects with APOE epsilon-4 genetic data, and an external cohort of 68,200 participants, mean age 66.9 years and a median nonfasting triglyceride of 139 mg/dL, from the UK biobank, followed for a median of 12.5 years.
- The main outcome was incident dementia over 6.4 years and secondary outcomes included changes in composite cognitive function and domain-specific cognition.
- Researchers controlled for a number of potential confounders, including age, sex, race, smoking, alcohol consumption, education, family history of dementia, diabetes, hypertension, and statin use.
TAKEAWAY:
- Every doubling of baseline triglycerides was associated with an 18% lower risk of incident dementia across the entire study cohort (adjusted hazard ratio, 0.82) and in participants with genotypic data (aHR, 0.82) and a 17% lower risk in the external UK Biobank cohort (aHR, 0.83) (P ≤ .01 for all).
- In the entire cohort, the risk for dementia was 15% lower in those with triglyceride levels at 63-106 mg/dL (aHR, 0.85); 24% lower in those at 107-186 mg/dL (aHR, 0.76); and 36% lower for those with levels higher than 187 mg/dL (aHR, 0.64), compared with individuals with levels below 62 mg/dL (P for trend <.001).
- The direction and magnitude of the inverse association between triglycerides and dementia risk were not modified by age, sex, or risk factors related to triglycerides or dementia.
- In the entire study cohort, higher triglyceride levels were significantly associated with slower decline in global cognition (P = .02), composite cognition (P = .03), and a borderline significantly slower decline in episodic memory (P = .05).
IN PRACTICE:
“Triglyceride levels may serve as a useful predictor for dementia risk and cognitive decline in older populations,” the investigators write. Higher triglyceride levels may reflect better overall health and/or lifestyle behaviors that protect against dementia.
SOURCE:
The study was led by Zhen Zhou, of Monash University, Melbourne. It was published online in Neurology.
LIMITATIONS:
The study can’t establish a causal relationship between triglyceride levels and dementia or fully exclude reverse causality. As most ASPREE participants had normal to high-normal triglyceride levels, the results can’t be generalized to those with severe hypertriglyceridemia. The findings are unique to older people without CVD and may not be generalizable to other populations.
DISCLOSURES:
The study received support from the Royal Australian College of General Practitioners (RACGP)/HCF Research Foundation. Dr. Zhou reported receiving salary from the RACGP/HCF Research Foundation.
A version of this article first appeared on Medscape.com.
Urgent need to improve early detection of mild cognitive impairment in primary care
TOPLINE:
Detection rates of mild cognitive impairment (MCI) in primary care are extremely low, with only about 8% of expected cases diagnosed on average, a finding that points to an urgent need to improve early detection in primary care.
METHODOLOGY:
- Researchers estimated MCI detection rates among 226,756 primary care clinicians and 54,597 practices that had at least 25 patients enrolled in Medicare between 2017 and 2019.
- They compared the expected number of MCI cases, based on a predictive model, to actual diagnosed cases as documented in claims and encounter data.
- They accounted for uncertainty in these estimates to determine whether detection rates are within the expected range or significantly higher or lower.
TAKEAWAY:
- More than 25% of clinicians and practices did not have a single patient with diagnosed MCI; the average detection rate was 0.01 for both clinicians and practices.
- The modeled expected MCI detection rate, however, was much higher (average 0.19 for clinicians and 0.20 for practices).
- Average detection rates for clinicians and practices was 0.08, with more than 99% of clinicians and practices underdiagnosing MCI; clinicians practicing geriatric medicine had higher detection rates than others.
IN PRACTICE:
The findings are “concerning not only because patients might not get identified for a disease-modifying AD treatment in time, but also because numerous causes of MCI – such as hypothyroidism and medication side effects – are reversible, and the condition itself can be stabilized by lifestyle modification interventions,” the authors write.
SOURCE:
The study was published online in the Journal of Prevention of Alzheimer’s Disease. The first author was Ying Liu, PhD, of the University of Southern California, Los Angeles.
LIMITATIONS:
The predictive model based on demographic information has only moderate accuracy. Expected prevalence of MCI was based on cognitive test scores, which is not the same as a true clinical diagnosis.
DISCLOSURES:
The study was partially funded by a contract from Genentech to the University of Southern California. Coauthors Soeren Mattke and Christopher Wallick have disclosed relationships with Genentech.
A version of this article appeared on Medscape.com.
TOPLINE:
Detection rates of mild cognitive impairment (MCI) in primary care are extremely low, with only about 8% of expected cases diagnosed on average, a finding that points to an urgent need to improve early detection in primary care.
METHODOLOGY:
- Researchers estimated MCI detection rates among 226,756 primary care clinicians and 54,597 practices that had at least 25 patients enrolled in Medicare between 2017 and 2019.
- They compared the expected number of MCI cases, based on a predictive model, to actual diagnosed cases as documented in claims and encounter data.
- They accounted for uncertainty in these estimates to determine whether detection rates are within the expected range or significantly higher or lower.
TAKEAWAY:
- More than 25% of clinicians and practices did not have a single patient with diagnosed MCI; the average detection rate was 0.01 for both clinicians and practices.
- The modeled expected MCI detection rate, however, was much higher (average 0.19 for clinicians and 0.20 for practices).
- Average detection rates for clinicians and practices was 0.08, with more than 99% of clinicians and practices underdiagnosing MCI; clinicians practicing geriatric medicine had higher detection rates than others.
IN PRACTICE:
The findings are “concerning not only because patients might not get identified for a disease-modifying AD treatment in time, but also because numerous causes of MCI – such as hypothyroidism and medication side effects – are reversible, and the condition itself can be stabilized by lifestyle modification interventions,” the authors write.
SOURCE:
The study was published online in the Journal of Prevention of Alzheimer’s Disease. The first author was Ying Liu, PhD, of the University of Southern California, Los Angeles.
LIMITATIONS:
The predictive model based on demographic information has only moderate accuracy. Expected prevalence of MCI was based on cognitive test scores, which is not the same as a true clinical diagnosis.
DISCLOSURES:
The study was partially funded by a contract from Genentech to the University of Southern California. Coauthors Soeren Mattke and Christopher Wallick have disclosed relationships with Genentech.
A version of this article appeared on Medscape.com.
TOPLINE:
Detection rates of mild cognitive impairment (MCI) in primary care are extremely low, with only about 8% of expected cases diagnosed on average, a finding that points to an urgent need to improve early detection in primary care.
METHODOLOGY:
- Researchers estimated MCI detection rates among 226,756 primary care clinicians and 54,597 practices that had at least 25 patients enrolled in Medicare between 2017 and 2019.
- They compared the expected number of MCI cases, based on a predictive model, to actual diagnosed cases as documented in claims and encounter data.
- They accounted for uncertainty in these estimates to determine whether detection rates are within the expected range or significantly higher or lower.
TAKEAWAY:
- More than 25% of clinicians and practices did not have a single patient with diagnosed MCI; the average detection rate was 0.01 for both clinicians and practices.
- The modeled expected MCI detection rate, however, was much higher (average 0.19 for clinicians and 0.20 for practices).
- Average detection rates for clinicians and practices was 0.08, with more than 99% of clinicians and practices underdiagnosing MCI; clinicians practicing geriatric medicine had higher detection rates than others.
IN PRACTICE:
The findings are “concerning not only because patients might not get identified for a disease-modifying AD treatment in time, but also because numerous causes of MCI – such as hypothyroidism and medication side effects – are reversible, and the condition itself can be stabilized by lifestyle modification interventions,” the authors write.
SOURCE:
The study was published online in the Journal of Prevention of Alzheimer’s Disease. The first author was Ying Liu, PhD, of the University of Southern California, Los Angeles.
LIMITATIONS:
The predictive model based on demographic information has only moderate accuracy. Expected prevalence of MCI was based on cognitive test scores, which is not the same as a true clinical diagnosis.
DISCLOSURES:
The study was partially funded by a contract from Genentech to the University of Southern California. Coauthors Soeren Mattke and Christopher Wallick have disclosed relationships with Genentech.
A version of this article appeared on Medscape.com.