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HRT may prevent Alzheimer’s in high-risk women
new research suggests.
Results from a cohort study of almost 1,200 women showed that use of HRT was associated with higher delayed memory scores and larger entorhinal and hippocampal brain volumes – areas that are affected early by Alzheimer’s disease (AD) pathology.
HRT was also found to be most effective, as seen by larger hippocampal volume, when introduced during early perimenopause.
“Clinicians are very much aware of the susceptibility of women to cognitive disturbances during menopause,” lead author Rasha Saleh, MD, senior research associate, University of East Anglia (England), said in an interview.
“Identifying the at-risk APOE4 women and early HRT introduction can be of benefit. Confirming our findings in a clinical trial would be the next step forward,” Dr. Saleh said.
The findings were published online in Alzheimer’s Research and Therapy.
Personalized approaches
Dr. Saleh noted that estrogen receptors are localized in various areas of the brain, including cognition-related areas. Estrogen regulates such things as neuroinflammatory status, glucose utilization, and lipid metabolism.
“The decline of estrogen during menopause can lead to disturbance in these functions, which can accelerate AD-related pathology,” she said.
HRT during the menopausal transition and afterward is “being considered as a strategy to mitigate cognitive decline,” the investigators wrote. Early observational studies have suggested that oral estrogen “may be protective against dementia,” but results of clinical trials have been inconsistent, and some have even shown “harmful effects.”
The current researchers were “interested in the personalized approaches in the prevention of AD,” Dr. Saleh said. Preclinical and pilot data from her group have shown that women with APOE4 have “better cognitive test scores with nutritional and hormonal interventions.”
This led Dr. Saleh to hypothesize that HRT would be of more cognitive benefit for those with versus without APOE4, particularly when introduced early during the menopausal transition.
To investigate this hypothesis, the researchers analyzed baseline data from participants in the European Prevention of Alzheimer’s Dementia (EPAD) cohort. This project was initiated in 2015 with the aim of developing longitudinal models over the entire course of AD prior to dementia clinical diagnosis.
Participants were recruited from 10 European countries. All were required to be at least 50 years old, to have not been diagnosed with dementia at baseline, and to have no medical or psychiatric illness that could potentially exclude them from further research.
The current study included 1,178 women (mean age, 65.1 years), who were divided by genotype into non-APOE4 and APOE4 groups. HRT treatment for current or previous users included estrogen alone or estrogen plus progestogens via oral or transdermal administration routes, and at different doses.
The four tests used to assess cognition were the Mini-Mental State Examination dot counting to evaluate verbal working memory, the Repeatable Battery for the Assessment of Neuropsychological Status (RBANS) total score, the Four Mountain Test, and the supermarket trolley virtual reality test.
Brain MRI data were collected. The researchers focused on the medial temporal lobe as the “main brain region regulating cognition and memory processing.” This lobe includes the hippocampus, the parahippocampus, the entorhinal cortex, and the amygdala.
‘Critical window’
The researchers found a “trend” toward an APOE-HRT interaction (P-interaction = .097) for the total RBANS score. In particular, it was significant for the RBANS delayed memory index, where scores were consistently higher for women with APOE4 who had received HRT, compared with all other groups (P-interaction = .009).
Within-genotype group comparisons showed that HRT users had a higher RBANS total scale score and delayed memory index (P = .045 and P = .002, respectively), but only among APOE4 carriers. Effect size analyses showed a large effect of HRT use on the Four Mountain Test score and the supermarket trolley virtual reality test score (Cohen’s d = 0.988 and 1.2, respectively).
“This large effect was found only in APOE4 carriers,” the investigators noted.
Similarly, a moderate to large effect of HRT on the left entorhinal volume was observed in APOE4 carriers (Cohen’s d = 0.63).
In members of the APOE4 group who received HRT, the left entorhinal and left and right amygdala volumes were larger, compared with both no-APOE4 and non-HRT users (P-interaction = .002, .003, and .005, respectively). Similar trends were observed for the right entorhinal volume (P = .074).
In addition, among HRT users, the left entorhinal volume was larger (P = .03); the right and left anterior cingulate gyrus volumes were smaller (P = .003 and .062, respectively); and the left superior frontal gyrus volume was larger (P = .009) in comparison with women who did not receive HRT, independently of their APOE genotype.
Early use of HRT among APOE4 carriers was associated with larger right and left hippocampal volume (P = .035 and P = .028, respectively) – an association not found in non-APOE4 carriers. The association was also not significant when participants were not stratified by APOE genotype.
“The key important point here is the timing, or the ‘critical window,’ when HRT can be of most benefit,” Dr. Saleh said. “This is most beneficial when introduced early, before the neuropathology becomes irreversible.”
Study limitations include its cross-sectional design, which precludes the establishment of a causal relationship, and the fact that information regarding the type and dose of estrogen was not available for all participants.
HRT is not without risk, Dr. Saleh noted. She recommended that clinicians “carry out various screening tests to make sure that a woman is eligible for HRT and not at risk of hypercoagulability, for instance.”
Risk-benefit ratio
In a comment, Howard Fillit, MD, cofounder and chief science officer at the Alzheimer’s Drug Discovery Foundation, called the study “exactly the kind of work that needs to be done.”
Dr. Fillit, who was not involved with the current research, is a clinical professor of geriatric medicine, palliative care medicine, and neuroscience at Mount Sinai Hospital, New York.
He compared the process with that of osteoporosis. “We know that if women are treated [with HRT] at the time of the menopause, you can prevent the rapid bone loss that occurs with rapid estrogen loss. But if you wait 5, 10 years out, once the bone loss has occurred, the HRT doesn’t really have any impact on osteoporosis risk because the horse is already out of the barn,” he said.
Although HRT carries risks, “they can clearly be managed; and if it’s proven that estrogen or hormone replacement around the time of the menopause can be protective [against AD], the risk-benefit ratio of HRT could be in favor of treatment,” Dr. Fillit added.
The study was conducted as part of the Medical Research Council NuBrain Consortium. The investigators and Dr. Fillit reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
new research suggests.
Results from a cohort study of almost 1,200 women showed that use of HRT was associated with higher delayed memory scores and larger entorhinal and hippocampal brain volumes – areas that are affected early by Alzheimer’s disease (AD) pathology.
HRT was also found to be most effective, as seen by larger hippocampal volume, when introduced during early perimenopause.
“Clinicians are very much aware of the susceptibility of women to cognitive disturbances during menopause,” lead author Rasha Saleh, MD, senior research associate, University of East Anglia (England), said in an interview.
“Identifying the at-risk APOE4 women and early HRT introduction can be of benefit. Confirming our findings in a clinical trial would be the next step forward,” Dr. Saleh said.
The findings were published online in Alzheimer’s Research and Therapy.
Personalized approaches
Dr. Saleh noted that estrogen receptors are localized in various areas of the brain, including cognition-related areas. Estrogen regulates such things as neuroinflammatory status, glucose utilization, and lipid metabolism.
“The decline of estrogen during menopause can lead to disturbance in these functions, which can accelerate AD-related pathology,” she said.
HRT during the menopausal transition and afterward is “being considered as a strategy to mitigate cognitive decline,” the investigators wrote. Early observational studies have suggested that oral estrogen “may be protective against dementia,” but results of clinical trials have been inconsistent, and some have even shown “harmful effects.”
The current researchers were “interested in the personalized approaches in the prevention of AD,” Dr. Saleh said. Preclinical and pilot data from her group have shown that women with APOE4 have “better cognitive test scores with nutritional and hormonal interventions.”
This led Dr. Saleh to hypothesize that HRT would be of more cognitive benefit for those with versus without APOE4, particularly when introduced early during the menopausal transition.
To investigate this hypothesis, the researchers analyzed baseline data from participants in the European Prevention of Alzheimer’s Dementia (EPAD) cohort. This project was initiated in 2015 with the aim of developing longitudinal models over the entire course of AD prior to dementia clinical diagnosis.
Participants were recruited from 10 European countries. All were required to be at least 50 years old, to have not been diagnosed with dementia at baseline, and to have no medical or psychiatric illness that could potentially exclude them from further research.
The current study included 1,178 women (mean age, 65.1 years), who were divided by genotype into non-APOE4 and APOE4 groups. HRT treatment for current or previous users included estrogen alone or estrogen plus progestogens via oral or transdermal administration routes, and at different doses.
The four tests used to assess cognition were the Mini-Mental State Examination dot counting to evaluate verbal working memory, the Repeatable Battery for the Assessment of Neuropsychological Status (RBANS) total score, the Four Mountain Test, and the supermarket trolley virtual reality test.
Brain MRI data were collected. The researchers focused on the medial temporal lobe as the “main brain region regulating cognition and memory processing.” This lobe includes the hippocampus, the parahippocampus, the entorhinal cortex, and the amygdala.
‘Critical window’
The researchers found a “trend” toward an APOE-HRT interaction (P-interaction = .097) for the total RBANS score. In particular, it was significant for the RBANS delayed memory index, where scores were consistently higher for women with APOE4 who had received HRT, compared with all other groups (P-interaction = .009).
Within-genotype group comparisons showed that HRT users had a higher RBANS total scale score and delayed memory index (P = .045 and P = .002, respectively), but only among APOE4 carriers. Effect size analyses showed a large effect of HRT use on the Four Mountain Test score and the supermarket trolley virtual reality test score (Cohen’s d = 0.988 and 1.2, respectively).
“This large effect was found only in APOE4 carriers,” the investigators noted.
Similarly, a moderate to large effect of HRT on the left entorhinal volume was observed in APOE4 carriers (Cohen’s d = 0.63).
In members of the APOE4 group who received HRT, the left entorhinal and left and right amygdala volumes were larger, compared with both no-APOE4 and non-HRT users (P-interaction = .002, .003, and .005, respectively). Similar trends were observed for the right entorhinal volume (P = .074).
In addition, among HRT users, the left entorhinal volume was larger (P = .03); the right and left anterior cingulate gyrus volumes were smaller (P = .003 and .062, respectively); and the left superior frontal gyrus volume was larger (P = .009) in comparison with women who did not receive HRT, independently of their APOE genotype.
Early use of HRT among APOE4 carriers was associated with larger right and left hippocampal volume (P = .035 and P = .028, respectively) – an association not found in non-APOE4 carriers. The association was also not significant when participants were not stratified by APOE genotype.
“The key important point here is the timing, or the ‘critical window,’ when HRT can be of most benefit,” Dr. Saleh said. “This is most beneficial when introduced early, before the neuropathology becomes irreversible.”
Study limitations include its cross-sectional design, which precludes the establishment of a causal relationship, and the fact that information regarding the type and dose of estrogen was not available for all participants.
HRT is not without risk, Dr. Saleh noted. She recommended that clinicians “carry out various screening tests to make sure that a woman is eligible for HRT and not at risk of hypercoagulability, for instance.”
Risk-benefit ratio
In a comment, Howard Fillit, MD, cofounder and chief science officer at the Alzheimer’s Drug Discovery Foundation, called the study “exactly the kind of work that needs to be done.”
Dr. Fillit, who was not involved with the current research, is a clinical professor of geriatric medicine, palliative care medicine, and neuroscience at Mount Sinai Hospital, New York.
He compared the process with that of osteoporosis. “We know that if women are treated [with HRT] at the time of the menopause, you can prevent the rapid bone loss that occurs with rapid estrogen loss. But if you wait 5, 10 years out, once the bone loss has occurred, the HRT doesn’t really have any impact on osteoporosis risk because the horse is already out of the barn,” he said.
Although HRT carries risks, “they can clearly be managed; and if it’s proven that estrogen or hormone replacement around the time of the menopause can be protective [against AD], the risk-benefit ratio of HRT could be in favor of treatment,” Dr. Fillit added.
The study was conducted as part of the Medical Research Council NuBrain Consortium. The investigators and Dr. Fillit reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
new research suggests.
Results from a cohort study of almost 1,200 women showed that use of HRT was associated with higher delayed memory scores and larger entorhinal and hippocampal brain volumes – areas that are affected early by Alzheimer’s disease (AD) pathology.
HRT was also found to be most effective, as seen by larger hippocampal volume, when introduced during early perimenopause.
“Clinicians are very much aware of the susceptibility of women to cognitive disturbances during menopause,” lead author Rasha Saleh, MD, senior research associate, University of East Anglia (England), said in an interview.
“Identifying the at-risk APOE4 women and early HRT introduction can be of benefit. Confirming our findings in a clinical trial would be the next step forward,” Dr. Saleh said.
The findings were published online in Alzheimer’s Research and Therapy.
Personalized approaches
Dr. Saleh noted that estrogen receptors are localized in various areas of the brain, including cognition-related areas. Estrogen regulates such things as neuroinflammatory status, glucose utilization, and lipid metabolism.
“The decline of estrogen during menopause can lead to disturbance in these functions, which can accelerate AD-related pathology,” she said.
HRT during the menopausal transition and afterward is “being considered as a strategy to mitigate cognitive decline,” the investigators wrote. Early observational studies have suggested that oral estrogen “may be protective against dementia,” but results of clinical trials have been inconsistent, and some have even shown “harmful effects.”
The current researchers were “interested in the personalized approaches in the prevention of AD,” Dr. Saleh said. Preclinical and pilot data from her group have shown that women with APOE4 have “better cognitive test scores with nutritional and hormonal interventions.”
This led Dr. Saleh to hypothesize that HRT would be of more cognitive benefit for those with versus without APOE4, particularly when introduced early during the menopausal transition.
To investigate this hypothesis, the researchers analyzed baseline data from participants in the European Prevention of Alzheimer’s Dementia (EPAD) cohort. This project was initiated in 2015 with the aim of developing longitudinal models over the entire course of AD prior to dementia clinical diagnosis.
Participants were recruited from 10 European countries. All were required to be at least 50 years old, to have not been diagnosed with dementia at baseline, and to have no medical or psychiatric illness that could potentially exclude them from further research.
The current study included 1,178 women (mean age, 65.1 years), who were divided by genotype into non-APOE4 and APOE4 groups. HRT treatment for current or previous users included estrogen alone or estrogen plus progestogens via oral or transdermal administration routes, and at different doses.
The four tests used to assess cognition were the Mini-Mental State Examination dot counting to evaluate verbal working memory, the Repeatable Battery for the Assessment of Neuropsychological Status (RBANS) total score, the Four Mountain Test, and the supermarket trolley virtual reality test.
Brain MRI data were collected. The researchers focused on the medial temporal lobe as the “main brain region regulating cognition and memory processing.” This lobe includes the hippocampus, the parahippocampus, the entorhinal cortex, and the amygdala.
‘Critical window’
The researchers found a “trend” toward an APOE-HRT interaction (P-interaction = .097) for the total RBANS score. In particular, it was significant for the RBANS delayed memory index, where scores were consistently higher for women with APOE4 who had received HRT, compared with all other groups (P-interaction = .009).
Within-genotype group comparisons showed that HRT users had a higher RBANS total scale score and delayed memory index (P = .045 and P = .002, respectively), but only among APOE4 carriers. Effect size analyses showed a large effect of HRT use on the Four Mountain Test score and the supermarket trolley virtual reality test score (Cohen’s d = 0.988 and 1.2, respectively).
“This large effect was found only in APOE4 carriers,” the investigators noted.
Similarly, a moderate to large effect of HRT on the left entorhinal volume was observed in APOE4 carriers (Cohen’s d = 0.63).
In members of the APOE4 group who received HRT, the left entorhinal and left and right amygdala volumes were larger, compared with both no-APOE4 and non-HRT users (P-interaction = .002, .003, and .005, respectively). Similar trends were observed for the right entorhinal volume (P = .074).
In addition, among HRT users, the left entorhinal volume was larger (P = .03); the right and left anterior cingulate gyrus volumes were smaller (P = .003 and .062, respectively); and the left superior frontal gyrus volume was larger (P = .009) in comparison with women who did not receive HRT, independently of their APOE genotype.
Early use of HRT among APOE4 carriers was associated with larger right and left hippocampal volume (P = .035 and P = .028, respectively) – an association not found in non-APOE4 carriers. The association was also not significant when participants were not stratified by APOE genotype.
“The key important point here is the timing, or the ‘critical window,’ when HRT can be of most benefit,” Dr. Saleh said. “This is most beneficial when introduced early, before the neuropathology becomes irreversible.”
Study limitations include its cross-sectional design, which precludes the establishment of a causal relationship, and the fact that information regarding the type and dose of estrogen was not available for all participants.
HRT is not without risk, Dr. Saleh noted. She recommended that clinicians “carry out various screening tests to make sure that a woman is eligible for HRT and not at risk of hypercoagulability, for instance.”
Risk-benefit ratio
In a comment, Howard Fillit, MD, cofounder and chief science officer at the Alzheimer’s Drug Discovery Foundation, called the study “exactly the kind of work that needs to be done.”
Dr. Fillit, who was not involved with the current research, is a clinical professor of geriatric medicine, palliative care medicine, and neuroscience at Mount Sinai Hospital, New York.
He compared the process with that of osteoporosis. “We know that if women are treated [with HRT] at the time of the menopause, you can prevent the rapid bone loss that occurs with rapid estrogen loss. But if you wait 5, 10 years out, once the bone loss has occurred, the HRT doesn’t really have any impact on osteoporosis risk because the horse is already out of the barn,” he said.
Although HRT carries risks, “they can clearly be managed; and if it’s proven that estrogen or hormone replacement around the time of the menopause can be protective [against AD], the risk-benefit ratio of HRT could be in favor of treatment,” Dr. Fillit added.
The study was conducted as part of the Medical Research Council NuBrain Consortium. The investigators and Dr. Fillit reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM ALZHEIMER’S RESEARCH AND THERAPY
The Respect for Marriage Act: How this law supports the health and well-being of LGBTQ+ youth
Childhood and adolescence are periods of life with rapid growth and development in which the psychosocial factors of one’s environment can have a profound effect on health. There is increasing evidence that adverse childhood experiences (ACEs) can have significant negative effects on long-term health with effects persisting into subsequent generations.1 Youth themselves, however, often do not have the voice, ability, or political power to advocate for safe and more supportive environments that are essential to their well-being. Thus, advocacy has been central to the profession of pediatrics since its inception, where providers can partner with their patients, families, and communities to push for changes in the environments in which youth live and grow.2
LGBTQ+ youth are known to be at increased risk for ACEs because of the stress that comes from being part of a minority group and the discrimination they experience by their families, communities, and society at large. These factors within their environments have been shown to be associated with increased rates of anxiety, depression, substance use, sexually transmitted infections, and homelessness.3 As with other health outcomes that have been linked to the social determinants of health, these disparities are not inevitable and could be greatly improved upon through advocacy and changes in the environments of LGBTQ+ youth.
Marriage equality (the recognition that same-sex couples have the same legal right to marry as opposite-sex couples) has been shown to be not only a political issue, but one that affects health. The debates surrounding marriage equality have contributed to minority stress by questioning the validity of same-sex relationships and assigning them less value relative to opposite-sex relationships.4 In 1996, the U.S. Congress passed the Defense of Marriage Act (DOMA), which federally defined marriage as being legally recognized only between opposite-sex couples.
Individual states then continued the marriage equality debate by passing individual state laws either allowing or prohibiting same-sex marriage. During this time, it was shown that, in states where same-sex marriage was legally prohibited, LGBTQ+ adults reported significantly higher rates of generalized anxiety disorder, alcohol use disorder, any mood disorder, and psychiatric comorbidity when compared with states without a legal ban on same-sex marriage.5
Using data from the Youth Risk Behavior Surveillance System, it was shown that state policies recognizing same-sex marriage were associated with a 7% relative reduction in suicide attempts reported by adolescent sexual minority students compared with before these policies.6 It was also shown that children with same-sex parents were overall less likely to have private health insurance, but this disparity was improved in states that legally recognized same-sex marriage and allowed second-parent adoptions.7
In 2013, the U.S. Supreme Court ruled that DOMA was unconstitutional, requiring the federal government to legally recognize same-sex marriages for the purposes of federal benefits. In 2015, the U.S. Supreme Court further ruled that same-sex couples are guaranteed the fundamental right to marry, requiring that all states issue marriage licenses to same-sex couples. These rulings were associated with a decrease in reported levels of stigma over time and increased reported levels of family support, particularly for those in same-sex relationships.8
The Respect for Marriage Act (RFMA) was passed by the U.S. Congress and signed into law by President Biden on Dec. 13, 2022. This law officially repeals DOMA and requires all states and the federal government to recognize same-sex marriages performed in any U.S. state or territory.9
If the U.S. Supreme Court were to overturn the 2015 marriage equality decision, individual state laws ensuring or banning same-sex marriage would again be in effect. However, the RFMA ensures that all states continue to recognize same-sex marriages performed in any U.S. state or territory (even if that state itself bans same-sex marriage). While we do not yet have any studies or data regarding the effect of the RFMA on public health, we can expect positive effects by drawing on the previous evidence on the effect of marriage equality and its effect on the health and well-being of LGBTQ+ individuals. By establishing marriage equality in the United States, our government institutions are affirming the relationships and identities of those in same-sex relationships, with the potential effect of helping to destigmatize the LGBTQ+ community.
Since 2002, the American Academy of Pediatrics has recommended that pediatricians “support the right of every child and family to the financial, psychological, and legal security that results from having legally recognized parents who are committed to each other and to the welfare of their children,” acknowledging that “legislative initiatives assuring legal status equivalent to marriage for gay and lesbian partners … can also attend to providing security and permanence for the children of those partnerships.”10 While changes in legal marriage equality are likely to have a positive effect on those within the LGBTQ+ community, it should also be understood that this will not solve all of the psychosocial effects and resultant health disparities that these children face.
A recent scoping review highlights that, as the result of marriage equality progress, sexual minority adults have reported increased social acceptance and reduced stigma across individual, community, and societal levels, but that sexual minority stigma continues to persist across all levels.11
As pediatricians, we can continue to support LGBTQ+ patients and parents by providing care in a safe and affirming environment in which families understand and embrace the healthy development of gender identity and sexuality in an open and destigmatized manner. Delivering care using this approach in and of itself can be seen as advocacy to promote health and well-being within minoritized populations. Pediatricians are also encouraged to become engaged in local and national advocacy initiatives to have a broader effect in the fight for health equity in minority populations, including LGBTQ+ families and youth.
Pediatricians should work with their patients, families, and communities to advocate for structural change needed to address the social determinants of health for optimal growth and development.
Dr. Warus is an adolescent medicine physician who specializes in care for transgender and gender-nonconforming youth, and LGBTQ health for youth at Children’s Hospital of Los Angeles. He is an assistant professor of pediatrics at University of Southern California, Los Angeles.
Resources
Bright Futures – Promoting Healthy Development of Sexuality and Gender Identity (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/BF_HealthySexualityGenderIdentity_Tipsheet.pdf
Bright Futures – Implementing Social Determinants of Health Into Health Supervision Visits (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/Bright%20Futures/BF_IntegrateSDoH_Tipsheet.pdf?_ga=2.214227031.1330574154.1673910248-58875083.1673910248
American Academy of Pediatrics – Advocacy Website: https://www.aap.org/en/advocacy/
References
1. Hughes K et al. Lancet Public Health. 2017;2(8):e356-66.
2. Camero K and Javier JR. Pediatr Clin N Am. 2023;70:43-51.
3. Lund EM and Burgess CM. Prim Care Clin Office Pract. 2021;48:179-89.
4. Buffie WC. Am J Public Health. 2011;101(6):986-90.
5. Hatzenbuehler ML et al. Am J Public Health. 2010;100:452-9.
6. Raifman J et al. JAMA Pediatr. 2017;171(4):350-6.
7. Gonzales G and Blewett LA. Pediatrics. 2013;132(4):703-11.
8. Ogolsky BG et al. J Fam Psychol. 2019;33(4):422-32.
9. Library of Congress. H.R.8404 – 117th Congress (2021-2022): Respect for Marriage Act. 2022 Dec 13. www.congress.gov/bill/117th-congress/house-bill/8404/text.
10. Perrin EC and Committee on Psychosocial Aspects of Child and Family Health. Pediatrics. 2002;109(2):341-4.
11. Drabble LA et al. PLoS ONE. 2021;16(5):e0249125.
Childhood and adolescence are periods of life with rapid growth and development in which the psychosocial factors of one’s environment can have a profound effect on health. There is increasing evidence that adverse childhood experiences (ACEs) can have significant negative effects on long-term health with effects persisting into subsequent generations.1 Youth themselves, however, often do not have the voice, ability, or political power to advocate for safe and more supportive environments that are essential to their well-being. Thus, advocacy has been central to the profession of pediatrics since its inception, where providers can partner with their patients, families, and communities to push for changes in the environments in which youth live and grow.2
LGBTQ+ youth are known to be at increased risk for ACEs because of the stress that comes from being part of a minority group and the discrimination they experience by their families, communities, and society at large. These factors within their environments have been shown to be associated with increased rates of anxiety, depression, substance use, sexually transmitted infections, and homelessness.3 As with other health outcomes that have been linked to the social determinants of health, these disparities are not inevitable and could be greatly improved upon through advocacy and changes in the environments of LGBTQ+ youth.
Marriage equality (the recognition that same-sex couples have the same legal right to marry as opposite-sex couples) has been shown to be not only a political issue, but one that affects health. The debates surrounding marriage equality have contributed to minority stress by questioning the validity of same-sex relationships and assigning them less value relative to opposite-sex relationships.4 In 1996, the U.S. Congress passed the Defense of Marriage Act (DOMA), which federally defined marriage as being legally recognized only between opposite-sex couples.
Individual states then continued the marriage equality debate by passing individual state laws either allowing or prohibiting same-sex marriage. During this time, it was shown that, in states where same-sex marriage was legally prohibited, LGBTQ+ adults reported significantly higher rates of generalized anxiety disorder, alcohol use disorder, any mood disorder, and psychiatric comorbidity when compared with states without a legal ban on same-sex marriage.5
Using data from the Youth Risk Behavior Surveillance System, it was shown that state policies recognizing same-sex marriage were associated with a 7% relative reduction in suicide attempts reported by adolescent sexual minority students compared with before these policies.6 It was also shown that children with same-sex parents were overall less likely to have private health insurance, but this disparity was improved in states that legally recognized same-sex marriage and allowed second-parent adoptions.7
In 2013, the U.S. Supreme Court ruled that DOMA was unconstitutional, requiring the federal government to legally recognize same-sex marriages for the purposes of federal benefits. In 2015, the U.S. Supreme Court further ruled that same-sex couples are guaranteed the fundamental right to marry, requiring that all states issue marriage licenses to same-sex couples. These rulings were associated with a decrease in reported levels of stigma over time and increased reported levels of family support, particularly for those in same-sex relationships.8
The Respect for Marriage Act (RFMA) was passed by the U.S. Congress and signed into law by President Biden on Dec. 13, 2022. This law officially repeals DOMA and requires all states and the federal government to recognize same-sex marriages performed in any U.S. state or territory.9
If the U.S. Supreme Court were to overturn the 2015 marriage equality decision, individual state laws ensuring or banning same-sex marriage would again be in effect. However, the RFMA ensures that all states continue to recognize same-sex marriages performed in any U.S. state or territory (even if that state itself bans same-sex marriage). While we do not yet have any studies or data regarding the effect of the RFMA on public health, we can expect positive effects by drawing on the previous evidence on the effect of marriage equality and its effect on the health and well-being of LGBTQ+ individuals. By establishing marriage equality in the United States, our government institutions are affirming the relationships and identities of those in same-sex relationships, with the potential effect of helping to destigmatize the LGBTQ+ community.
Since 2002, the American Academy of Pediatrics has recommended that pediatricians “support the right of every child and family to the financial, psychological, and legal security that results from having legally recognized parents who are committed to each other and to the welfare of their children,” acknowledging that “legislative initiatives assuring legal status equivalent to marriage for gay and lesbian partners … can also attend to providing security and permanence for the children of those partnerships.”10 While changes in legal marriage equality are likely to have a positive effect on those within the LGBTQ+ community, it should also be understood that this will not solve all of the psychosocial effects and resultant health disparities that these children face.
A recent scoping review highlights that, as the result of marriage equality progress, sexual minority adults have reported increased social acceptance and reduced stigma across individual, community, and societal levels, but that sexual minority stigma continues to persist across all levels.11
As pediatricians, we can continue to support LGBTQ+ patients and parents by providing care in a safe and affirming environment in which families understand and embrace the healthy development of gender identity and sexuality in an open and destigmatized manner. Delivering care using this approach in and of itself can be seen as advocacy to promote health and well-being within minoritized populations. Pediatricians are also encouraged to become engaged in local and national advocacy initiatives to have a broader effect in the fight for health equity in minority populations, including LGBTQ+ families and youth.
Pediatricians should work with their patients, families, and communities to advocate for structural change needed to address the social determinants of health for optimal growth and development.
Dr. Warus is an adolescent medicine physician who specializes in care for transgender and gender-nonconforming youth, and LGBTQ health for youth at Children’s Hospital of Los Angeles. He is an assistant professor of pediatrics at University of Southern California, Los Angeles.
Resources
Bright Futures – Promoting Healthy Development of Sexuality and Gender Identity (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/BF_HealthySexualityGenderIdentity_Tipsheet.pdf
Bright Futures – Implementing Social Determinants of Health Into Health Supervision Visits (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/Bright%20Futures/BF_IntegrateSDoH_Tipsheet.pdf?_ga=2.214227031.1330574154.1673910248-58875083.1673910248
American Academy of Pediatrics – Advocacy Website: https://www.aap.org/en/advocacy/
References
1. Hughes K et al. Lancet Public Health. 2017;2(8):e356-66.
2. Camero K and Javier JR. Pediatr Clin N Am. 2023;70:43-51.
3. Lund EM and Burgess CM. Prim Care Clin Office Pract. 2021;48:179-89.
4. Buffie WC. Am J Public Health. 2011;101(6):986-90.
5. Hatzenbuehler ML et al. Am J Public Health. 2010;100:452-9.
6. Raifman J et al. JAMA Pediatr. 2017;171(4):350-6.
7. Gonzales G and Blewett LA. Pediatrics. 2013;132(4):703-11.
8. Ogolsky BG et al. J Fam Psychol. 2019;33(4):422-32.
9. Library of Congress. H.R.8404 – 117th Congress (2021-2022): Respect for Marriage Act. 2022 Dec 13. www.congress.gov/bill/117th-congress/house-bill/8404/text.
10. Perrin EC and Committee on Psychosocial Aspects of Child and Family Health. Pediatrics. 2002;109(2):341-4.
11. Drabble LA et al. PLoS ONE. 2021;16(5):e0249125.
Childhood and adolescence are periods of life with rapid growth and development in which the psychosocial factors of one’s environment can have a profound effect on health. There is increasing evidence that adverse childhood experiences (ACEs) can have significant negative effects on long-term health with effects persisting into subsequent generations.1 Youth themselves, however, often do not have the voice, ability, or political power to advocate for safe and more supportive environments that are essential to their well-being. Thus, advocacy has been central to the profession of pediatrics since its inception, where providers can partner with their patients, families, and communities to push for changes in the environments in which youth live and grow.2
LGBTQ+ youth are known to be at increased risk for ACEs because of the stress that comes from being part of a minority group and the discrimination they experience by their families, communities, and society at large. These factors within their environments have been shown to be associated with increased rates of anxiety, depression, substance use, sexually transmitted infections, and homelessness.3 As with other health outcomes that have been linked to the social determinants of health, these disparities are not inevitable and could be greatly improved upon through advocacy and changes in the environments of LGBTQ+ youth.
Marriage equality (the recognition that same-sex couples have the same legal right to marry as opposite-sex couples) has been shown to be not only a political issue, but one that affects health. The debates surrounding marriage equality have contributed to minority stress by questioning the validity of same-sex relationships and assigning them less value relative to opposite-sex relationships.4 In 1996, the U.S. Congress passed the Defense of Marriage Act (DOMA), which federally defined marriage as being legally recognized only between opposite-sex couples.
Individual states then continued the marriage equality debate by passing individual state laws either allowing or prohibiting same-sex marriage. During this time, it was shown that, in states where same-sex marriage was legally prohibited, LGBTQ+ adults reported significantly higher rates of generalized anxiety disorder, alcohol use disorder, any mood disorder, and psychiatric comorbidity when compared with states without a legal ban on same-sex marriage.5
Using data from the Youth Risk Behavior Surveillance System, it was shown that state policies recognizing same-sex marriage were associated with a 7% relative reduction in suicide attempts reported by adolescent sexual minority students compared with before these policies.6 It was also shown that children with same-sex parents were overall less likely to have private health insurance, but this disparity was improved in states that legally recognized same-sex marriage and allowed second-parent adoptions.7
In 2013, the U.S. Supreme Court ruled that DOMA was unconstitutional, requiring the federal government to legally recognize same-sex marriages for the purposes of federal benefits. In 2015, the U.S. Supreme Court further ruled that same-sex couples are guaranteed the fundamental right to marry, requiring that all states issue marriage licenses to same-sex couples. These rulings were associated with a decrease in reported levels of stigma over time and increased reported levels of family support, particularly for those in same-sex relationships.8
The Respect for Marriage Act (RFMA) was passed by the U.S. Congress and signed into law by President Biden on Dec. 13, 2022. This law officially repeals DOMA and requires all states and the federal government to recognize same-sex marriages performed in any U.S. state or territory.9
If the U.S. Supreme Court were to overturn the 2015 marriage equality decision, individual state laws ensuring or banning same-sex marriage would again be in effect. However, the RFMA ensures that all states continue to recognize same-sex marriages performed in any U.S. state or territory (even if that state itself bans same-sex marriage). While we do not yet have any studies or data regarding the effect of the RFMA on public health, we can expect positive effects by drawing on the previous evidence on the effect of marriage equality and its effect on the health and well-being of LGBTQ+ individuals. By establishing marriage equality in the United States, our government institutions are affirming the relationships and identities of those in same-sex relationships, with the potential effect of helping to destigmatize the LGBTQ+ community.
Since 2002, the American Academy of Pediatrics has recommended that pediatricians “support the right of every child and family to the financial, psychological, and legal security that results from having legally recognized parents who are committed to each other and to the welfare of their children,” acknowledging that “legislative initiatives assuring legal status equivalent to marriage for gay and lesbian partners … can also attend to providing security and permanence for the children of those partnerships.”10 While changes in legal marriage equality are likely to have a positive effect on those within the LGBTQ+ community, it should also be understood that this will not solve all of the psychosocial effects and resultant health disparities that these children face.
A recent scoping review highlights that, as the result of marriage equality progress, sexual minority adults have reported increased social acceptance and reduced stigma across individual, community, and societal levels, but that sexual minority stigma continues to persist across all levels.11
As pediatricians, we can continue to support LGBTQ+ patients and parents by providing care in a safe and affirming environment in which families understand and embrace the healthy development of gender identity and sexuality in an open and destigmatized manner. Delivering care using this approach in and of itself can be seen as advocacy to promote health and well-being within minoritized populations. Pediatricians are also encouraged to become engaged in local and national advocacy initiatives to have a broader effect in the fight for health equity in minority populations, including LGBTQ+ families and youth.
Pediatricians should work with their patients, families, and communities to advocate for structural change needed to address the social determinants of health for optimal growth and development.
Dr. Warus is an adolescent medicine physician who specializes in care for transgender and gender-nonconforming youth, and LGBTQ health for youth at Children’s Hospital of Los Angeles. He is an assistant professor of pediatrics at University of Southern California, Los Angeles.
Resources
Bright Futures – Promoting Healthy Development of Sexuality and Gender Identity (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/BF_HealthySexualityGenderIdentity_Tipsheet.pdf
Bright Futures – Implementing Social Determinants of Health Into Health Supervision Visits (Implementation Tip Sheet): https://downloads.aap.org/AAP/PDF/Bright%20Futures/BF_IntegrateSDoH_Tipsheet.pdf?_ga=2.214227031.1330574154.1673910248-58875083.1673910248
American Academy of Pediatrics – Advocacy Website: https://www.aap.org/en/advocacy/
References
1. Hughes K et al. Lancet Public Health. 2017;2(8):e356-66.
2. Camero K and Javier JR. Pediatr Clin N Am. 2023;70:43-51.
3. Lund EM and Burgess CM. Prim Care Clin Office Pract. 2021;48:179-89.
4. Buffie WC. Am J Public Health. 2011;101(6):986-90.
5. Hatzenbuehler ML et al. Am J Public Health. 2010;100:452-9.
6. Raifman J et al. JAMA Pediatr. 2017;171(4):350-6.
7. Gonzales G and Blewett LA. Pediatrics. 2013;132(4):703-11.
8. Ogolsky BG et al. J Fam Psychol. 2019;33(4):422-32.
9. Library of Congress. H.R.8404 – 117th Congress (2021-2022): Respect for Marriage Act. 2022 Dec 13. www.congress.gov/bill/117th-congress/house-bill/8404/text.
10. Perrin EC and Committee on Psychosocial Aspects of Child and Family Health. Pediatrics. 2002;109(2):341-4.
11. Drabble LA et al. PLoS ONE. 2021;16(5):e0249125.
Can 6 minutes of intense cycling put the brakes on Alzheimer’s?
new research suggests.
In a small study of healthy adults, 6 minutes of high-intensity cycling increased circulating levels of brain-derived neurotrophic factor (BDNF) to a significantly greater extent than prolonged light cycling or fasting.
However, the data do not suggest that 6 minutes of high-intensity exercise “wards off dementia,” cautioned lead investigator Travis Gibbons, MSc, PhD candidate in environmental physiology at the University of Otago (New Zealand), Dunedin, and now postdoctoral fellow at the University of British Columbia – Okanagan, Kelowna.
“Like all science, this is just a small piece that supports a potential mechanistic role for how exercise might improve brain health,” Dr. Gibbons told this news organization.
The findings were published online in the Journal of Physiology.
Targeting BDNF
Both intermittent fasting and exercise have previously been shown to have potent neuroprotective effects; and an acute upregulation of BDNF appears to be a common mechanistic link.
To tease apart the influence of fasting and exercise on BDNF production, Dr. Gibbons and colleagues studied 12 aerobically fit, healthy men (n = 6) and women (n = 6) aged 20-40 years.
In a study that employed a repeated-measures crossover design, they assessed circulating BDNF levels after a 20-hour fast, prolonged (90-min) light cycling, short (6-min) high-intensity cycling, and combined fasting and exercise.
Six minutes of high-intensity exercise appeared to be the most efficient way to increase BDNF.
Fasting for 20 hours led to a ninefold increase in ketone body delivery to the brain but had no effect on any metric of BDNF in peripheral circulation at rest or during exercise.
Six minutes of high-intensity exercise increased every metric of circulating BDNF four to five times more than prolonged low-intensity exercise.
In addition, the increase in plasma-derived BDNF correlated with a sixfold increase in circulating lactate irrespective of feeding or fasting state.
Lactate delivery?
“My leading theory is that, during and following intense exercise, lactate produced by muscles is delivered and consumed by the brain,” Dr. Gibbons noted.
“It takes high-intensity exercise to provoke this ‘cerebral substrate switch’ from glucose to lactate. Critically, this cerebral substrate switch has been shown to contribute to the early processes that upregulate BDNF production in the brain,” he said.
However, “Whether this translates to ‘warding off dementia’ is not clear,” Dr. Gibbons added.
The study also suggests that increases in plasma volume and platelet concentration appear to play a role in concentrating BDNF in the circulation during exercise.
The investigators note that BDNF and other neurotrophic-based pharmaceutical therapies have shown “great promise” in slowing and even arresting neurodegenerative processes in animals, but attempts to harness the protective power of BDNF in human neurodegeneration have thus far failed.
“Whether episodically upregulating BDNF production with intense exercise is an effective strategy to curb age-related cognitive decline in humans is unknown, but animal models indicate that it is and that BDNF plays a primary role,” the researchers write.
Funding for the study was provided by the Healthcare Otago Charitable Trust. The investigators have reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
new research suggests.
In a small study of healthy adults, 6 minutes of high-intensity cycling increased circulating levels of brain-derived neurotrophic factor (BDNF) to a significantly greater extent than prolonged light cycling or fasting.
However, the data do not suggest that 6 minutes of high-intensity exercise “wards off dementia,” cautioned lead investigator Travis Gibbons, MSc, PhD candidate in environmental physiology at the University of Otago (New Zealand), Dunedin, and now postdoctoral fellow at the University of British Columbia – Okanagan, Kelowna.
“Like all science, this is just a small piece that supports a potential mechanistic role for how exercise might improve brain health,” Dr. Gibbons told this news organization.
The findings were published online in the Journal of Physiology.
Targeting BDNF
Both intermittent fasting and exercise have previously been shown to have potent neuroprotective effects; and an acute upregulation of BDNF appears to be a common mechanistic link.
To tease apart the influence of fasting and exercise on BDNF production, Dr. Gibbons and colleagues studied 12 aerobically fit, healthy men (n = 6) and women (n = 6) aged 20-40 years.
In a study that employed a repeated-measures crossover design, they assessed circulating BDNF levels after a 20-hour fast, prolonged (90-min) light cycling, short (6-min) high-intensity cycling, and combined fasting and exercise.
Six minutes of high-intensity exercise appeared to be the most efficient way to increase BDNF.
Fasting for 20 hours led to a ninefold increase in ketone body delivery to the brain but had no effect on any metric of BDNF in peripheral circulation at rest or during exercise.
Six minutes of high-intensity exercise increased every metric of circulating BDNF four to five times more than prolonged low-intensity exercise.
In addition, the increase in plasma-derived BDNF correlated with a sixfold increase in circulating lactate irrespective of feeding or fasting state.
Lactate delivery?
“My leading theory is that, during and following intense exercise, lactate produced by muscles is delivered and consumed by the brain,” Dr. Gibbons noted.
“It takes high-intensity exercise to provoke this ‘cerebral substrate switch’ from glucose to lactate. Critically, this cerebral substrate switch has been shown to contribute to the early processes that upregulate BDNF production in the brain,” he said.
However, “Whether this translates to ‘warding off dementia’ is not clear,” Dr. Gibbons added.
The study also suggests that increases in plasma volume and platelet concentration appear to play a role in concentrating BDNF in the circulation during exercise.
The investigators note that BDNF and other neurotrophic-based pharmaceutical therapies have shown “great promise” in slowing and even arresting neurodegenerative processes in animals, but attempts to harness the protective power of BDNF in human neurodegeneration have thus far failed.
“Whether episodically upregulating BDNF production with intense exercise is an effective strategy to curb age-related cognitive decline in humans is unknown, but animal models indicate that it is and that BDNF plays a primary role,” the researchers write.
Funding for the study was provided by the Healthcare Otago Charitable Trust. The investigators have reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
new research suggests.
In a small study of healthy adults, 6 minutes of high-intensity cycling increased circulating levels of brain-derived neurotrophic factor (BDNF) to a significantly greater extent than prolonged light cycling or fasting.
However, the data do not suggest that 6 minutes of high-intensity exercise “wards off dementia,” cautioned lead investigator Travis Gibbons, MSc, PhD candidate in environmental physiology at the University of Otago (New Zealand), Dunedin, and now postdoctoral fellow at the University of British Columbia – Okanagan, Kelowna.
“Like all science, this is just a small piece that supports a potential mechanistic role for how exercise might improve brain health,” Dr. Gibbons told this news organization.
The findings were published online in the Journal of Physiology.
Targeting BDNF
Both intermittent fasting and exercise have previously been shown to have potent neuroprotective effects; and an acute upregulation of BDNF appears to be a common mechanistic link.
To tease apart the influence of fasting and exercise on BDNF production, Dr. Gibbons and colleagues studied 12 aerobically fit, healthy men (n = 6) and women (n = 6) aged 20-40 years.
In a study that employed a repeated-measures crossover design, they assessed circulating BDNF levels after a 20-hour fast, prolonged (90-min) light cycling, short (6-min) high-intensity cycling, and combined fasting and exercise.
Six minutes of high-intensity exercise appeared to be the most efficient way to increase BDNF.
Fasting for 20 hours led to a ninefold increase in ketone body delivery to the brain but had no effect on any metric of BDNF in peripheral circulation at rest or during exercise.
Six minutes of high-intensity exercise increased every metric of circulating BDNF four to five times more than prolonged low-intensity exercise.
In addition, the increase in plasma-derived BDNF correlated with a sixfold increase in circulating lactate irrespective of feeding or fasting state.
Lactate delivery?
“My leading theory is that, during and following intense exercise, lactate produced by muscles is delivered and consumed by the brain,” Dr. Gibbons noted.
“It takes high-intensity exercise to provoke this ‘cerebral substrate switch’ from glucose to lactate. Critically, this cerebral substrate switch has been shown to contribute to the early processes that upregulate BDNF production in the brain,” he said.
However, “Whether this translates to ‘warding off dementia’ is not clear,” Dr. Gibbons added.
The study also suggests that increases in plasma volume and platelet concentration appear to play a role in concentrating BDNF in the circulation during exercise.
The investigators note that BDNF and other neurotrophic-based pharmaceutical therapies have shown “great promise” in slowing and even arresting neurodegenerative processes in animals, but attempts to harness the protective power of BDNF in human neurodegeneration have thus far failed.
“Whether episodically upregulating BDNF production with intense exercise is an effective strategy to curb age-related cognitive decline in humans is unknown, but animal models indicate that it is and that BDNF plays a primary role,” the researchers write.
Funding for the study was provided by the Healthcare Otago Charitable Trust. The investigators have reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM THE JOURNAL OF PHYSIOLOGY
Low serum LDH shows potential as depression biomarker
The pathogenesis of depression is complex, and recent research has focused on the potential relationship between energy metabolism and depression, wrote Qian Yao, MD, of Wuhan University, Hubei, China, and colleagues.
Previous studies have suggested that serum lactate dehydrogenase (LDH) may be a biomarker for Parkinson’s disease, Huntington’s disease, and post-stroke depression, but the link between lactate metabolism and depression remains unclear, they said.
“We hypothesize that LDH may act as a potential biomarker for MDD, considering it represents a reduced energy metabolic status in depressive patients,” they explained.
In a study published in General Hospital Psychiatry, the researchers examined differences in serum LDH in 232 patients with major depressive disorder (MDD) and 110 healthy controls. They also examined whether LDH was predictive of suicide attempts in the MDD patients. Depression was assessed via the 24-item Hamilton Depression Scale (HAMD-24).
The mean age across both groups was 33 years; other clinical characteristics were similar between the groups.
The serum LDH level of the MDD group was significantly lower than the control group was (177.94 U/L vs. 196.50 U/L; P < .001). Analysis of blood lipid levels showed significantly lower levels of total cholesterol in the MDD group compared with controls, but no significant differences were noted in LDL cholesterol, HDL cholesterol, or triglycerides.
In a further analysis of subgroups of depression, the serum LDH in MDD patients who had attempted suicide was significantly lower compared to those without suicide attempts (169.96 vs. 181.25; P = .002), although the LDH level for the non-suicide MDD patients also was significantly lower than controls (181.25 vs. 196.50; P < .001). No significant correlation was noted between HAMD-24 score and suicide attempts.
Some gender differences also appeared. Both male and female MDD patients had significantly lower LDH levels compared with controls. However, in a regression analysis, a correlation between total cholesterol and LDL cholesterol as potential suicide markers was noted in female MDD patients, but not male MDD patients, which suggests an impact of gender on suicide risk in MDD, the researchers wrote in their discussion.
The findings were limited by several factors including the retrospective design, lack of investigation of changes in LDH isozymes in MDD patients, and lack of assessment of changes in LDH in cerebrospinal fluid, the researchers noted. However, the results “provide clear evidence that the concentration of LDH in serum is associated with early onset and clinical prognosis of depressive symptoms,” in MDD, which may inform diagnosis and guide clinical intervention, including early identification of suicide risk, they concluded.
The study was supported by the National Natural Science Foundation of China. The researchers had no financial conflicts to disclose.
The pathogenesis of depression is complex, and recent research has focused on the potential relationship between energy metabolism and depression, wrote Qian Yao, MD, of Wuhan University, Hubei, China, and colleagues.
Previous studies have suggested that serum lactate dehydrogenase (LDH) may be a biomarker for Parkinson’s disease, Huntington’s disease, and post-stroke depression, but the link between lactate metabolism and depression remains unclear, they said.
“We hypothesize that LDH may act as a potential biomarker for MDD, considering it represents a reduced energy metabolic status in depressive patients,” they explained.
In a study published in General Hospital Psychiatry, the researchers examined differences in serum LDH in 232 patients with major depressive disorder (MDD) and 110 healthy controls. They also examined whether LDH was predictive of suicide attempts in the MDD patients. Depression was assessed via the 24-item Hamilton Depression Scale (HAMD-24).
The mean age across both groups was 33 years; other clinical characteristics were similar between the groups.
The serum LDH level of the MDD group was significantly lower than the control group was (177.94 U/L vs. 196.50 U/L; P < .001). Analysis of blood lipid levels showed significantly lower levels of total cholesterol in the MDD group compared with controls, but no significant differences were noted in LDL cholesterol, HDL cholesterol, or triglycerides.
In a further analysis of subgroups of depression, the serum LDH in MDD patients who had attempted suicide was significantly lower compared to those without suicide attempts (169.96 vs. 181.25; P = .002), although the LDH level for the non-suicide MDD patients also was significantly lower than controls (181.25 vs. 196.50; P < .001). No significant correlation was noted between HAMD-24 score and suicide attempts.
Some gender differences also appeared. Both male and female MDD patients had significantly lower LDH levels compared with controls. However, in a regression analysis, a correlation between total cholesterol and LDL cholesterol as potential suicide markers was noted in female MDD patients, but not male MDD patients, which suggests an impact of gender on suicide risk in MDD, the researchers wrote in their discussion.
The findings were limited by several factors including the retrospective design, lack of investigation of changes in LDH isozymes in MDD patients, and lack of assessment of changes in LDH in cerebrospinal fluid, the researchers noted. However, the results “provide clear evidence that the concentration of LDH in serum is associated with early onset and clinical prognosis of depressive symptoms,” in MDD, which may inform diagnosis and guide clinical intervention, including early identification of suicide risk, they concluded.
The study was supported by the National Natural Science Foundation of China. The researchers had no financial conflicts to disclose.
The pathogenesis of depression is complex, and recent research has focused on the potential relationship between energy metabolism and depression, wrote Qian Yao, MD, of Wuhan University, Hubei, China, and colleagues.
Previous studies have suggested that serum lactate dehydrogenase (LDH) may be a biomarker for Parkinson’s disease, Huntington’s disease, and post-stroke depression, but the link between lactate metabolism and depression remains unclear, they said.
“We hypothesize that LDH may act as a potential biomarker for MDD, considering it represents a reduced energy metabolic status in depressive patients,” they explained.
In a study published in General Hospital Psychiatry, the researchers examined differences in serum LDH in 232 patients with major depressive disorder (MDD) and 110 healthy controls. They also examined whether LDH was predictive of suicide attempts in the MDD patients. Depression was assessed via the 24-item Hamilton Depression Scale (HAMD-24).
The mean age across both groups was 33 years; other clinical characteristics were similar between the groups.
The serum LDH level of the MDD group was significantly lower than the control group was (177.94 U/L vs. 196.50 U/L; P < .001). Analysis of blood lipid levels showed significantly lower levels of total cholesterol in the MDD group compared with controls, but no significant differences were noted in LDL cholesterol, HDL cholesterol, or triglycerides.
In a further analysis of subgroups of depression, the serum LDH in MDD patients who had attempted suicide was significantly lower compared to those without suicide attempts (169.96 vs. 181.25; P = .002), although the LDH level for the non-suicide MDD patients also was significantly lower than controls (181.25 vs. 196.50; P < .001). No significant correlation was noted between HAMD-24 score and suicide attempts.
Some gender differences also appeared. Both male and female MDD patients had significantly lower LDH levels compared with controls. However, in a regression analysis, a correlation between total cholesterol and LDL cholesterol as potential suicide markers was noted in female MDD patients, but not male MDD patients, which suggests an impact of gender on suicide risk in MDD, the researchers wrote in their discussion.
The findings were limited by several factors including the retrospective design, lack of investigation of changes in LDH isozymes in MDD patients, and lack of assessment of changes in LDH in cerebrospinal fluid, the researchers noted. However, the results “provide clear evidence that the concentration of LDH in serum is associated with early onset and clinical prognosis of depressive symptoms,” in MDD, which may inform diagnosis and guide clinical intervention, including early identification of suicide risk, they concluded.
The study was supported by the National Natural Science Foundation of China. The researchers had no financial conflicts to disclose.
FROM GENERAL HOSPITAL PSYCHIATRY
Mood disorder? Assessment in primary care
The assessment and diagnosis of bipolar disorder in youth has a complicated and controversial history. I recall from my child and adolescent fellowship training that there was a thinly veiled faculty argument about the diagnosis itself with strong opinions on each side. To revisit this quandary, I reviewed the most up-to-date literature and outlined a case-based approach to the initial screening assessment. Certainly, the assessment by a child and adolescent psychiatrist would be the standard for diagnosis, but we do know that the pediatrician’s office may be the first setting for a child and parent to present with mood symptoms and concerns about bipolar disorder. What can you do to address this adolescent, Carrie, and her mother’s concerns?
Case
Carrie is a 17-year-old girl who has struggled through her childhood and adolescence with anxious and depressive symptoms which have ebbed and flowed with major life stressors, including her parent’s divorce. She has tried cognitive-behavioral therapy and selective serotonin reuptake inhibitors, but the SSRI seemed to cause feelings of anxiousness and agitation, so she stopped it within weeks.
Her mother presents to you concerned that Carrie has had a more persistently irritable mood toward her, often just wanting to be with her friends or otherwise isolate in her room when home to study.
Most concerning to her mother is that Carrie, as a straight A student, has also developed a pattern of staying up all night to study for tests and then “crashes” and sleeps through the weekend, avoiding her mother and only brightening with her friends.
To complicate matters, Carrie’s biological father had type 1 bipolar disorder and an addiction. Her mother comes to you with an initially nonparticipatory Carrie in tow and says: “My former husband began his manic episodes with a lack of sleep and Carrie is so irritable towards me. I feel like I am walking on eggshells all the time. Could this be bipolar disorder?”
Case discussion
First, it’s always useful to frame a visit stating that you will spend some time with the patient and some time with both the patient and parent. Emphasizing confidentiality about issues such as drug use, which can be comorbid with mood symptoms and go undetected in high-achieving students such as Carrie, is also important. Further emphasizing that information will not be reflexively shared with the parent unless the child presents a danger to herself or others is also paramount to receive an honest report of symptoms.
Second, there are many signs and symptoms of bipolar disorder that naturally overlap with other conditions such as distractibility with attention-deficit/hyperactivity disorder, or irritability in either a unipolar depression or disruptive mood dysregulation disorder.1 You are looking for an episodic (not chronic) course of symptoms with episodes that last over 5 days for hypomania and over the course of weeks for mania all while meeting all the classic criteria for bipolar disorder.
Note that the broadening of diagnostic criteria has been thought to contribute to an inflated sense of prevalence. The actual expert estimate of prevalence is around 0.8%-1.8% in pediatric populations, although there is a large published range depending on whether the criteria are modified or not.2 Use of the unmodified criteria from the DSM-5 is the recommended approach. Bipolar disorder is exceedingly rare in prepubertal children, and it would be more common for prodromal symptoms such as Carrie’s to emerge and escalate over the teenage years, culminating in a clearer diagnosis in the later teens or 20s.3
In my screening questions, I find the idea of an “infatiguable state” is the most pathognomonic one in considering mania in bipolar disorder.4 Carrie’s “crashing” after nights of studying shows that she clearly fatigues. Patients with bipolar disorder within episodes of hypomania or mania have a seismic shift in perceived energy and a matching lack of ability to sleep that can affect their thought processes, speech, and decision-making. At first blush, Carrie’s history does not indicate current symptoms of bipolar disorder.3
Case, continued
When you meet with Carrie alone she shares that she has been experimenting with prescribed stimulants from her older college-aged brother in order to study and ace her tests. She is also experimenting with alcohol and marijuana with her friends. You provide her the CRAFFT tool to deepen your screening of this issue.5
With her mother, you administer the Parent General Behavior Inventory6 and the and the Child Mania Rating Scale7. From these scales, you note that the irritability is more specific to Carrie’s family than pan-present in school and with friends. Her lack of sleep occurs at high-pressure and discreet times.
At this point, you reassure Carrie and her mother that Carrie does not present with symptoms of bipolar disorder but that certainly you will continue screening assessments over time, as they are a good means to track symptoms. You also recommend that Carrie consider mood tracking so she can develop insights into her mood and its relationship to sleep and other events as she prepares for college.8
Case discussion, continued
The strongest risk factor for bipolar disorder in youth is family history (specifically a parent) with bipolar disorder).9 If there is the chance to explore the parent’s illness with open-ended questions, you will want to hear about the parent’s age of symptom onset, course of treatment, any hospitalizations, and stabilizing medications because this has prognostic power for your patient. It is important to ensure that the parent indeed has a diagnosis of bipolar disorder and that it is not just being used colloquially to characterize an adult who has labile moods from hour to hour or day to day. This would give undue anticipatory anxiety to a youth about their risk, which is up to 8- to 10-fold greater with a parent with bipolar disorder.9
Even with a strong family history, we do not often see bipolar disorder emerge in prepubertal children.10,11 There may be still concerning prodromal symptoms in which a diagnosis of unipolar depression with more irritable features and mood lability seems more commonly complicated by substance use, as with Carrie.
Activation with an SSRI, as in Carrie’s case, even if not resulting in full mania or hypomania, can also be a soft sign of the serotonergic sensitivity present in bipolar disorder. However, if there are not additional symptoms of bipolar disorder and you are concerned based on family history alone, you do not want to withhold antidepressant treatment because fear of risk. You would want to consider a “dose low and go slow” titration process with more frequent monitoring.
A diagnostic interview with a child and adolescent psychiatrist and administration of scales such as the Young Mania Rating Scale and the Modified Child Depression Rating Scale are the standard means to assess for bipolar symptoms.12 Considering the dearth of child psychiatrists nationally, it would be useful to improve one’s screening in primary care so as to not inadvertently “refer out” all patients for whom mood dysregulation is a concern.
There is also a more expanded tool that includes several scales integrated with clinical information (parent’s age of mood disorder onset, child’s age) which can culminate in a risk score.13
Lastly, I provide my patients with a handout of the Young Mania Rating Scale to take home as a reference and to complete before our next visit.14
You can repeat scales to monitor for more striking bipolar disorder signs and symptoms that emerge over the course of one’s longitudinal treatment of a pediatric patient. This can be an ongoing, episodic assessment since the emergence of bipolar disorder has been shown to range from the teenage years and beyond into the 20s and sometimes 30s.
Case, continued
Carrie presents to you again while in her first semester of college at the age of 19. She is taking a leave of absence after she began experimenting with cocaine at college and had a manic episode characterized by a lack of sleep without fatigue, persistent unabating energy, rapid and pressured speech, and ultimately, concern from her college friends. She was admitted to a psychiatric unit and stabilized on a second-generation antipsychotic, risperidone, which has solid evidence for mania, but she and you are now concerned about longer-term metabolic effects.15,16
You discuss monitoring her lipid profile and hemoglobin A1c, in addition to weight gain and waist circumference. She has connected with a therapist and psychiatrist through the college counseling center and hopes to return next semester with a fresh start and commitment to sobriety and social rhythms therapy known to be helpful for patients with bipolar disorder.17
While it is challenging to manage a chronic illness at her age, she feels hopeful that she can make better choices for her overall health with your support and the support of her family and mental health team.
Dr. Pawlowski is a child and adolescent consulting psychiatrist. She is a division chief at the University of Vermont Medical Center, Burlington, where she focuses on primary care mental health integration within primary care pediatrics, internal medicine, and family medicine.
References
1. Bipolar Disord. 2016 Jan 9 doi: 10.1111/bdi.12358.
2. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
3. Am J Psychiatry. 2018 Dec 11. doi: 10.1176/appi.ajp.2018.18040461.
4. DSM-5 Changes: Implications for Child Serious Emotional Disturbance. Rockville, Md.: Substance Abuse and Mental Health Services Administration, 2016.
5. The CRAFFT tool.
6. General Behavior Inventory. Parent Version (P-GBI) Short Form – H/B (Revised Version, 2008).
7. Child Mania Rating Scale, Parent Version (CMRS-P).
8. https://www.moodtracker.com.
9. J Clin Psychiatry. 2000 Sep. doi: 10.4088/jcp.v61n0906.
10. Int J Bipolar Disord. 2020 Apr 20. doi: 10.1186/s40345-020-00185-2.
11. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
12. Bipolar Disord. 2017 Sep 25. doi: 10.1111/bdi.12556.
13. www.cabsresearch.pitt.edu/bpriskcalculator/.
14. Parent Version of the Young Mania Rating Scale (PYMRS).
15. Arch Gen Psychiatry. 2012 Jan 2. doi: 10.1001/archgenpsychiatry.2011.1508.
16. The Carlat Child Psychiatry Report. “Bipolar Disorder” Newburyport, Mass.: Carlat Publishing, 2012.
17. https://www.ipsrt.org/.
The assessment and diagnosis of bipolar disorder in youth has a complicated and controversial history. I recall from my child and adolescent fellowship training that there was a thinly veiled faculty argument about the diagnosis itself with strong opinions on each side. To revisit this quandary, I reviewed the most up-to-date literature and outlined a case-based approach to the initial screening assessment. Certainly, the assessment by a child and adolescent psychiatrist would be the standard for diagnosis, but we do know that the pediatrician’s office may be the first setting for a child and parent to present with mood symptoms and concerns about bipolar disorder. What can you do to address this adolescent, Carrie, and her mother’s concerns?
Case
Carrie is a 17-year-old girl who has struggled through her childhood and adolescence with anxious and depressive symptoms which have ebbed and flowed with major life stressors, including her parent’s divorce. She has tried cognitive-behavioral therapy and selective serotonin reuptake inhibitors, but the SSRI seemed to cause feelings of anxiousness and agitation, so she stopped it within weeks.
Her mother presents to you concerned that Carrie has had a more persistently irritable mood toward her, often just wanting to be with her friends or otherwise isolate in her room when home to study.
Most concerning to her mother is that Carrie, as a straight A student, has also developed a pattern of staying up all night to study for tests and then “crashes” and sleeps through the weekend, avoiding her mother and only brightening with her friends.
To complicate matters, Carrie’s biological father had type 1 bipolar disorder and an addiction. Her mother comes to you with an initially nonparticipatory Carrie in tow and says: “My former husband began his manic episodes with a lack of sleep and Carrie is so irritable towards me. I feel like I am walking on eggshells all the time. Could this be bipolar disorder?”
Case discussion
First, it’s always useful to frame a visit stating that you will spend some time with the patient and some time with both the patient and parent. Emphasizing confidentiality about issues such as drug use, which can be comorbid with mood symptoms and go undetected in high-achieving students such as Carrie, is also important. Further emphasizing that information will not be reflexively shared with the parent unless the child presents a danger to herself or others is also paramount to receive an honest report of symptoms.
Second, there are many signs and symptoms of bipolar disorder that naturally overlap with other conditions such as distractibility with attention-deficit/hyperactivity disorder, or irritability in either a unipolar depression or disruptive mood dysregulation disorder.1 You are looking for an episodic (not chronic) course of symptoms with episodes that last over 5 days for hypomania and over the course of weeks for mania all while meeting all the classic criteria for bipolar disorder.
Note that the broadening of diagnostic criteria has been thought to contribute to an inflated sense of prevalence. The actual expert estimate of prevalence is around 0.8%-1.8% in pediatric populations, although there is a large published range depending on whether the criteria are modified or not.2 Use of the unmodified criteria from the DSM-5 is the recommended approach. Bipolar disorder is exceedingly rare in prepubertal children, and it would be more common for prodromal symptoms such as Carrie’s to emerge and escalate over the teenage years, culminating in a clearer diagnosis in the later teens or 20s.3
In my screening questions, I find the idea of an “infatiguable state” is the most pathognomonic one in considering mania in bipolar disorder.4 Carrie’s “crashing” after nights of studying shows that she clearly fatigues. Patients with bipolar disorder within episodes of hypomania or mania have a seismic shift in perceived energy and a matching lack of ability to sleep that can affect their thought processes, speech, and decision-making. At first blush, Carrie’s history does not indicate current symptoms of bipolar disorder.3
Case, continued
When you meet with Carrie alone she shares that she has been experimenting with prescribed stimulants from her older college-aged brother in order to study and ace her tests. She is also experimenting with alcohol and marijuana with her friends. You provide her the CRAFFT tool to deepen your screening of this issue.5
With her mother, you administer the Parent General Behavior Inventory6 and the and the Child Mania Rating Scale7. From these scales, you note that the irritability is more specific to Carrie’s family than pan-present in school and with friends. Her lack of sleep occurs at high-pressure and discreet times.
At this point, you reassure Carrie and her mother that Carrie does not present with symptoms of bipolar disorder but that certainly you will continue screening assessments over time, as they are a good means to track symptoms. You also recommend that Carrie consider mood tracking so she can develop insights into her mood and its relationship to sleep and other events as she prepares for college.8
Case discussion, continued
The strongest risk factor for bipolar disorder in youth is family history (specifically a parent) with bipolar disorder).9 If there is the chance to explore the parent’s illness with open-ended questions, you will want to hear about the parent’s age of symptom onset, course of treatment, any hospitalizations, and stabilizing medications because this has prognostic power for your patient. It is important to ensure that the parent indeed has a diagnosis of bipolar disorder and that it is not just being used colloquially to characterize an adult who has labile moods from hour to hour or day to day. This would give undue anticipatory anxiety to a youth about their risk, which is up to 8- to 10-fold greater with a parent with bipolar disorder.9
Even with a strong family history, we do not often see bipolar disorder emerge in prepubertal children.10,11 There may be still concerning prodromal symptoms in which a diagnosis of unipolar depression with more irritable features and mood lability seems more commonly complicated by substance use, as with Carrie.
Activation with an SSRI, as in Carrie’s case, even if not resulting in full mania or hypomania, can also be a soft sign of the serotonergic sensitivity present in bipolar disorder. However, if there are not additional symptoms of bipolar disorder and you are concerned based on family history alone, you do not want to withhold antidepressant treatment because fear of risk. You would want to consider a “dose low and go slow” titration process with more frequent monitoring.
A diagnostic interview with a child and adolescent psychiatrist and administration of scales such as the Young Mania Rating Scale and the Modified Child Depression Rating Scale are the standard means to assess for bipolar symptoms.12 Considering the dearth of child psychiatrists nationally, it would be useful to improve one’s screening in primary care so as to not inadvertently “refer out” all patients for whom mood dysregulation is a concern.
There is also a more expanded tool that includes several scales integrated with clinical information (parent’s age of mood disorder onset, child’s age) which can culminate in a risk score.13
Lastly, I provide my patients with a handout of the Young Mania Rating Scale to take home as a reference and to complete before our next visit.14
You can repeat scales to monitor for more striking bipolar disorder signs and symptoms that emerge over the course of one’s longitudinal treatment of a pediatric patient. This can be an ongoing, episodic assessment since the emergence of bipolar disorder has been shown to range from the teenage years and beyond into the 20s and sometimes 30s.
Case, continued
Carrie presents to you again while in her first semester of college at the age of 19. She is taking a leave of absence after she began experimenting with cocaine at college and had a manic episode characterized by a lack of sleep without fatigue, persistent unabating energy, rapid and pressured speech, and ultimately, concern from her college friends. She was admitted to a psychiatric unit and stabilized on a second-generation antipsychotic, risperidone, which has solid evidence for mania, but she and you are now concerned about longer-term metabolic effects.15,16
You discuss monitoring her lipid profile and hemoglobin A1c, in addition to weight gain and waist circumference. She has connected with a therapist and psychiatrist through the college counseling center and hopes to return next semester with a fresh start and commitment to sobriety and social rhythms therapy known to be helpful for patients with bipolar disorder.17
While it is challenging to manage a chronic illness at her age, she feels hopeful that she can make better choices for her overall health with your support and the support of her family and mental health team.
Dr. Pawlowski is a child and adolescent consulting psychiatrist. She is a division chief at the University of Vermont Medical Center, Burlington, where she focuses on primary care mental health integration within primary care pediatrics, internal medicine, and family medicine.
References
1. Bipolar Disord. 2016 Jan 9 doi: 10.1111/bdi.12358.
2. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
3. Am J Psychiatry. 2018 Dec 11. doi: 10.1176/appi.ajp.2018.18040461.
4. DSM-5 Changes: Implications for Child Serious Emotional Disturbance. Rockville, Md.: Substance Abuse and Mental Health Services Administration, 2016.
5. The CRAFFT tool.
6. General Behavior Inventory. Parent Version (P-GBI) Short Form – H/B (Revised Version, 2008).
7. Child Mania Rating Scale, Parent Version (CMRS-P).
8. https://www.moodtracker.com.
9. J Clin Psychiatry. 2000 Sep. doi: 10.4088/jcp.v61n0906.
10. Int J Bipolar Disord. 2020 Apr 20. doi: 10.1186/s40345-020-00185-2.
11. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
12. Bipolar Disord. 2017 Sep 25. doi: 10.1111/bdi.12556.
13. www.cabsresearch.pitt.edu/bpriskcalculator/.
14. Parent Version of the Young Mania Rating Scale (PYMRS).
15. Arch Gen Psychiatry. 2012 Jan 2. doi: 10.1001/archgenpsychiatry.2011.1508.
16. The Carlat Child Psychiatry Report. “Bipolar Disorder” Newburyport, Mass.: Carlat Publishing, 2012.
17. https://www.ipsrt.org/.
The assessment and diagnosis of bipolar disorder in youth has a complicated and controversial history. I recall from my child and adolescent fellowship training that there was a thinly veiled faculty argument about the diagnosis itself with strong opinions on each side. To revisit this quandary, I reviewed the most up-to-date literature and outlined a case-based approach to the initial screening assessment. Certainly, the assessment by a child and adolescent psychiatrist would be the standard for diagnosis, but we do know that the pediatrician’s office may be the first setting for a child and parent to present with mood symptoms and concerns about bipolar disorder. What can you do to address this adolescent, Carrie, and her mother’s concerns?
Case
Carrie is a 17-year-old girl who has struggled through her childhood and adolescence with anxious and depressive symptoms which have ebbed and flowed with major life stressors, including her parent’s divorce. She has tried cognitive-behavioral therapy and selective serotonin reuptake inhibitors, but the SSRI seemed to cause feelings of anxiousness and agitation, so she stopped it within weeks.
Her mother presents to you concerned that Carrie has had a more persistently irritable mood toward her, often just wanting to be with her friends or otherwise isolate in her room when home to study.
Most concerning to her mother is that Carrie, as a straight A student, has also developed a pattern of staying up all night to study for tests and then “crashes” and sleeps through the weekend, avoiding her mother and only brightening with her friends.
To complicate matters, Carrie’s biological father had type 1 bipolar disorder and an addiction. Her mother comes to you with an initially nonparticipatory Carrie in tow and says: “My former husband began his manic episodes with a lack of sleep and Carrie is so irritable towards me. I feel like I am walking on eggshells all the time. Could this be bipolar disorder?”
Case discussion
First, it’s always useful to frame a visit stating that you will spend some time with the patient and some time with both the patient and parent. Emphasizing confidentiality about issues such as drug use, which can be comorbid with mood symptoms and go undetected in high-achieving students such as Carrie, is also important. Further emphasizing that information will not be reflexively shared with the parent unless the child presents a danger to herself or others is also paramount to receive an honest report of symptoms.
Second, there are many signs and symptoms of bipolar disorder that naturally overlap with other conditions such as distractibility with attention-deficit/hyperactivity disorder, or irritability in either a unipolar depression or disruptive mood dysregulation disorder.1 You are looking for an episodic (not chronic) course of symptoms with episodes that last over 5 days for hypomania and over the course of weeks for mania all while meeting all the classic criteria for bipolar disorder.
Note that the broadening of diagnostic criteria has been thought to contribute to an inflated sense of prevalence. The actual expert estimate of prevalence is around 0.8%-1.8% in pediatric populations, although there is a large published range depending on whether the criteria are modified or not.2 Use of the unmodified criteria from the DSM-5 is the recommended approach. Bipolar disorder is exceedingly rare in prepubertal children, and it would be more common for prodromal symptoms such as Carrie’s to emerge and escalate over the teenage years, culminating in a clearer diagnosis in the later teens or 20s.3
In my screening questions, I find the idea of an “infatiguable state” is the most pathognomonic one in considering mania in bipolar disorder.4 Carrie’s “crashing” after nights of studying shows that she clearly fatigues. Patients with bipolar disorder within episodes of hypomania or mania have a seismic shift in perceived energy and a matching lack of ability to sleep that can affect their thought processes, speech, and decision-making. At first blush, Carrie’s history does not indicate current symptoms of bipolar disorder.3
Case, continued
When you meet with Carrie alone she shares that she has been experimenting with prescribed stimulants from her older college-aged brother in order to study and ace her tests. She is also experimenting with alcohol and marijuana with her friends. You provide her the CRAFFT tool to deepen your screening of this issue.5
With her mother, you administer the Parent General Behavior Inventory6 and the and the Child Mania Rating Scale7. From these scales, you note that the irritability is more specific to Carrie’s family than pan-present in school and with friends. Her lack of sleep occurs at high-pressure and discreet times.
At this point, you reassure Carrie and her mother that Carrie does not present with symptoms of bipolar disorder but that certainly you will continue screening assessments over time, as they are a good means to track symptoms. You also recommend that Carrie consider mood tracking so she can develop insights into her mood and its relationship to sleep and other events as she prepares for college.8
Case discussion, continued
The strongest risk factor for bipolar disorder in youth is family history (specifically a parent) with bipolar disorder).9 If there is the chance to explore the parent’s illness with open-ended questions, you will want to hear about the parent’s age of symptom onset, course of treatment, any hospitalizations, and stabilizing medications because this has prognostic power for your patient. It is important to ensure that the parent indeed has a diagnosis of bipolar disorder and that it is not just being used colloquially to characterize an adult who has labile moods from hour to hour or day to day. This would give undue anticipatory anxiety to a youth about their risk, which is up to 8- to 10-fold greater with a parent with bipolar disorder.9
Even with a strong family history, we do not often see bipolar disorder emerge in prepubertal children.10,11 There may be still concerning prodromal symptoms in which a diagnosis of unipolar depression with more irritable features and mood lability seems more commonly complicated by substance use, as with Carrie.
Activation with an SSRI, as in Carrie’s case, even if not resulting in full mania or hypomania, can also be a soft sign of the serotonergic sensitivity present in bipolar disorder. However, if there are not additional symptoms of bipolar disorder and you are concerned based on family history alone, you do not want to withhold antidepressant treatment because fear of risk. You would want to consider a “dose low and go slow” titration process with more frequent monitoring.
A diagnostic interview with a child and adolescent psychiatrist and administration of scales such as the Young Mania Rating Scale and the Modified Child Depression Rating Scale are the standard means to assess for bipolar symptoms.12 Considering the dearth of child psychiatrists nationally, it would be useful to improve one’s screening in primary care so as to not inadvertently “refer out” all patients for whom mood dysregulation is a concern.
There is also a more expanded tool that includes several scales integrated with clinical information (parent’s age of mood disorder onset, child’s age) which can culminate in a risk score.13
Lastly, I provide my patients with a handout of the Young Mania Rating Scale to take home as a reference and to complete before our next visit.14
You can repeat scales to monitor for more striking bipolar disorder signs and symptoms that emerge over the course of one’s longitudinal treatment of a pediatric patient. This can be an ongoing, episodic assessment since the emergence of bipolar disorder has been shown to range from the teenage years and beyond into the 20s and sometimes 30s.
Case, continued
Carrie presents to you again while in her first semester of college at the age of 19. She is taking a leave of absence after she began experimenting with cocaine at college and had a manic episode characterized by a lack of sleep without fatigue, persistent unabating energy, rapid and pressured speech, and ultimately, concern from her college friends. She was admitted to a psychiatric unit and stabilized on a second-generation antipsychotic, risperidone, which has solid evidence for mania, but she and you are now concerned about longer-term metabolic effects.15,16
You discuss monitoring her lipid profile and hemoglobin A1c, in addition to weight gain and waist circumference. She has connected with a therapist and psychiatrist through the college counseling center and hopes to return next semester with a fresh start and commitment to sobriety and social rhythms therapy known to be helpful for patients with bipolar disorder.17
While it is challenging to manage a chronic illness at her age, she feels hopeful that she can make better choices for her overall health with your support and the support of her family and mental health team.
Dr. Pawlowski is a child and adolescent consulting psychiatrist. She is a division chief at the University of Vermont Medical Center, Burlington, where she focuses on primary care mental health integration within primary care pediatrics, internal medicine, and family medicine.
References
1. Bipolar Disord. 2016 Jan 9 doi: 10.1111/bdi.12358.
2. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
3. Am J Psychiatry. 2018 Dec 11. doi: 10.1176/appi.ajp.2018.18040461.
4. DSM-5 Changes: Implications for Child Serious Emotional Disturbance. Rockville, Md.: Substance Abuse and Mental Health Services Administration, 2016.
5. The CRAFFT tool.
6. General Behavior Inventory. Parent Version (P-GBI) Short Form – H/B (Revised Version, 2008).
7. Child Mania Rating Scale, Parent Version (CMRS-P).
8. https://www.moodtracker.com.
9. J Clin Psychiatry. 2000 Sep. doi: 10.4088/jcp.v61n0906.
10. Int J Bipolar Disord. 2020 Apr 20. doi: 10.1186/s40345-020-00185-2.
11. Int J Bipolar Disord. 2021 Jun 25. doi: 10.1186/s40345-021-00225-5.
12. Bipolar Disord. 2017 Sep 25. doi: 10.1111/bdi.12556.
13. www.cabsresearch.pitt.edu/bpriskcalculator/.
14. Parent Version of the Young Mania Rating Scale (PYMRS).
15. Arch Gen Psychiatry. 2012 Jan 2. doi: 10.1001/archgenpsychiatry.2011.1508.
16. The Carlat Child Psychiatry Report. “Bipolar Disorder” Newburyport, Mass.: Carlat Publishing, 2012.
17. https://www.ipsrt.org/.
The pediatrician’s office may be the first setting for a child to present with mood symptoms.
Self-management app may boost quality of life
In a randomized clinical trial of usual care plus the experimental smartphone-based intervention known as LiveWell vs. usual care alone, participants in the smartphone group who were categorized as low-risk or in asymptomatic recovery at baseline also showed reduced manic symptom severity.
The results suggest that “apps for individuals with bipolar disorder will likely be useful for some people in managing medication use, sleep duration, routine, and monitoring for and managing signs and symptoms” of the disorder, coinvestigator Evan H. Goulding, MD, PhD, assistant professor of psychiatry and behavioral sciences, Northwestern University, Chicago, told this news organization.
Use of the app may also “lead to decreased recurrence of mood episodes, impact overall depressive and manic symptom levels, and improve some aspects of quality of life,” Dr. Goulding added.
The findings were published online in JAMA Psychiatry.
Daily check-ins
The researchers randomly assigned 205 patients with BD to receive either usual care (n = 81; 56% women; mean age, 39 years) or usual care plus the smartphone-based self-management intervention LiveWell (n = 124; 65% women; mean age, 43 years) between March 2017 and April 2020. To be included, participants could not be experiencing a current mood episode or suicidal ideation.
The smartphone intervention included a daily check-in to monitor medication adherence, sleep, and wellness levels; coach visits to support adherence to the app; six phone calls over 16 weeks; and support from mental health professionals whenever needed. Participants in this group were asked to engage their mental health providers in the intervention as well.
Each participant in the control group had a visit with a coach who facilitated self-management support.
Investigators assessed all participants every 8 weeks until week 48 to gather information on mood symptoms and severity over the past 2 weeks and on quality of life.
The patients were also stratified into high- and low-risk relapse groups. The low-risk group was in asymptomatic recovery, meaning that they experienced two or fewer moderate symptoms of mania or depression in the previous 8 weeks. In addition, they had no moderate symptoms of mania or depression at study enrollment.
Patients in the high-risk group were recovering from an episode of mania or depression. They also had two or fewer moderate symptoms, but for 8 weeks or less.
Low-risk group fares better
Results showed that the smartphone intervention was significantly associated with a reduction in depressive symptoms vs. usual care (P = .02), as well as improvement in one aspect of the World Health Organization Quality of Life Assessment that measures social relationships (P = .02).
When the investigators stratified participants into risk groups, they found that for those in the low-risk group the smartphone-based intervention was associated with lower episode-relapse rates, lower mean percentage time symptomatic, and decreased manic symptom severity.
Mean estimated relapse rates by 48 weeks for the low-risk group were 12% for those in the intervention group and 37.2% for those in the control group. No differences were noted for the high-risk group.
Low-risk patients in the intervention group also had lower mean percentage-time symptomatic (17.9%) than those in the control group (26.1%) (Cohen d = .31).
“Our results are consistent with literature emphasizing the identification and facilitation of management plans for early warning signs of mood episodes and using these plans as an important self-management technique for avoiding relapse,” Dr. Goulding said.
Study limitations included low engagement by mental health professionals and low data generalizability to other populations, as the sample was mostly White (84% of the app group and 81% of the control group).
“There is a fairly large literature on risk factors, longitudinal trajectories, and stages of diseases that suggest we should already be able to predict relapse risk for individuals,” Dr. Goulding said.
“However, moving from overall risk to individual risk is trickier and will require larger datasets with longer follow-up to better understand what types of help should be delivered when and to whom,” he added.
‘Requires commitment’
John Torous, MD, director of the division of digital psychiatry at Beth Israel Deaconess Medical Center, Boston, noted that mental health apps such as LiveWell require “time and energy devoted by both the patient and their clinician for maximal efficacy, which requires commitment from and training for both parties as well.
“But with such an investment in people, there is good evidence apps can help people with bipolar disorder even during the more severe periods of the illness,” added Dr. Torous, who was not involved with the research.
The study was funded by the National Institute of Mental Health.
Dr. Goulding reports having received honoraria from Otsuka. Dr. Torous has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
In a randomized clinical trial of usual care plus the experimental smartphone-based intervention known as LiveWell vs. usual care alone, participants in the smartphone group who were categorized as low-risk or in asymptomatic recovery at baseline also showed reduced manic symptom severity.
The results suggest that “apps for individuals with bipolar disorder will likely be useful for some people in managing medication use, sleep duration, routine, and monitoring for and managing signs and symptoms” of the disorder, coinvestigator Evan H. Goulding, MD, PhD, assistant professor of psychiatry and behavioral sciences, Northwestern University, Chicago, told this news organization.
Use of the app may also “lead to decreased recurrence of mood episodes, impact overall depressive and manic symptom levels, and improve some aspects of quality of life,” Dr. Goulding added.
The findings were published online in JAMA Psychiatry.
Daily check-ins
The researchers randomly assigned 205 patients with BD to receive either usual care (n = 81; 56% women; mean age, 39 years) or usual care plus the smartphone-based self-management intervention LiveWell (n = 124; 65% women; mean age, 43 years) between March 2017 and April 2020. To be included, participants could not be experiencing a current mood episode or suicidal ideation.
The smartphone intervention included a daily check-in to monitor medication adherence, sleep, and wellness levels; coach visits to support adherence to the app; six phone calls over 16 weeks; and support from mental health professionals whenever needed. Participants in this group were asked to engage their mental health providers in the intervention as well.
Each participant in the control group had a visit with a coach who facilitated self-management support.
Investigators assessed all participants every 8 weeks until week 48 to gather information on mood symptoms and severity over the past 2 weeks and on quality of life.
The patients were also stratified into high- and low-risk relapse groups. The low-risk group was in asymptomatic recovery, meaning that they experienced two or fewer moderate symptoms of mania or depression in the previous 8 weeks. In addition, they had no moderate symptoms of mania or depression at study enrollment.
Patients in the high-risk group were recovering from an episode of mania or depression. They also had two or fewer moderate symptoms, but for 8 weeks or less.
Low-risk group fares better
Results showed that the smartphone intervention was significantly associated with a reduction in depressive symptoms vs. usual care (P = .02), as well as improvement in one aspect of the World Health Organization Quality of Life Assessment that measures social relationships (P = .02).
When the investigators stratified participants into risk groups, they found that for those in the low-risk group the smartphone-based intervention was associated with lower episode-relapse rates, lower mean percentage time symptomatic, and decreased manic symptom severity.
Mean estimated relapse rates by 48 weeks for the low-risk group were 12% for those in the intervention group and 37.2% for those in the control group. No differences were noted for the high-risk group.
Low-risk patients in the intervention group also had lower mean percentage-time symptomatic (17.9%) than those in the control group (26.1%) (Cohen d = .31).
“Our results are consistent with literature emphasizing the identification and facilitation of management plans for early warning signs of mood episodes and using these plans as an important self-management technique for avoiding relapse,” Dr. Goulding said.
Study limitations included low engagement by mental health professionals and low data generalizability to other populations, as the sample was mostly White (84% of the app group and 81% of the control group).
“There is a fairly large literature on risk factors, longitudinal trajectories, and stages of diseases that suggest we should already be able to predict relapse risk for individuals,” Dr. Goulding said.
“However, moving from overall risk to individual risk is trickier and will require larger datasets with longer follow-up to better understand what types of help should be delivered when and to whom,” he added.
‘Requires commitment’
John Torous, MD, director of the division of digital psychiatry at Beth Israel Deaconess Medical Center, Boston, noted that mental health apps such as LiveWell require “time and energy devoted by both the patient and their clinician for maximal efficacy, which requires commitment from and training for both parties as well.
“But with such an investment in people, there is good evidence apps can help people with bipolar disorder even during the more severe periods of the illness,” added Dr. Torous, who was not involved with the research.
The study was funded by the National Institute of Mental Health.
Dr. Goulding reports having received honoraria from Otsuka. Dr. Torous has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
In a randomized clinical trial of usual care plus the experimental smartphone-based intervention known as LiveWell vs. usual care alone, participants in the smartphone group who were categorized as low-risk or in asymptomatic recovery at baseline also showed reduced manic symptom severity.
The results suggest that “apps for individuals with bipolar disorder will likely be useful for some people in managing medication use, sleep duration, routine, and monitoring for and managing signs and symptoms” of the disorder, coinvestigator Evan H. Goulding, MD, PhD, assistant professor of psychiatry and behavioral sciences, Northwestern University, Chicago, told this news organization.
Use of the app may also “lead to decreased recurrence of mood episodes, impact overall depressive and manic symptom levels, and improve some aspects of quality of life,” Dr. Goulding added.
The findings were published online in JAMA Psychiatry.
Daily check-ins
The researchers randomly assigned 205 patients with BD to receive either usual care (n = 81; 56% women; mean age, 39 years) or usual care plus the smartphone-based self-management intervention LiveWell (n = 124; 65% women; mean age, 43 years) between March 2017 and April 2020. To be included, participants could not be experiencing a current mood episode or suicidal ideation.
The smartphone intervention included a daily check-in to monitor medication adherence, sleep, and wellness levels; coach visits to support adherence to the app; six phone calls over 16 weeks; and support from mental health professionals whenever needed. Participants in this group were asked to engage their mental health providers in the intervention as well.
Each participant in the control group had a visit with a coach who facilitated self-management support.
Investigators assessed all participants every 8 weeks until week 48 to gather information on mood symptoms and severity over the past 2 weeks and on quality of life.
The patients were also stratified into high- and low-risk relapse groups. The low-risk group was in asymptomatic recovery, meaning that they experienced two or fewer moderate symptoms of mania or depression in the previous 8 weeks. In addition, they had no moderate symptoms of mania or depression at study enrollment.
Patients in the high-risk group were recovering from an episode of mania or depression. They also had two or fewer moderate symptoms, but for 8 weeks or less.
Low-risk group fares better
Results showed that the smartphone intervention was significantly associated with a reduction in depressive symptoms vs. usual care (P = .02), as well as improvement in one aspect of the World Health Organization Quality of Life Assessment that measures social relationships (P = .02).
When the investigators stratified participants into risk groups, they found that for those in the low-risk group the smartphone-based intervention was associated with lower episode-relapse rates, lower mean percentage time symptomatic, and decreased manic symptom severity.
Mean estimated relapse rates by 48 weeks for the low-risk group were 12% for those in the intervention group and 37.2% for those in the control group. No differences were noted for the high-risk group.
Low-risk patients in the intervention group also had lower mean percentage-time symptomatic (17.9%) than those in the control group (26.1%) (Cohen d = .31).
“Our results are consistent with literature emphasizing the identification and facilitation of management plans for early warning signs of mood episodes and using these plans as an important self-management technique for avoiding relapse,” Dr. Goulding said.
Study limitations included low engagement by mental health professionals and low data generalizability to other populations, as the sample was mostly White (84% of the app group and 81% of the control group).
“There is a fairly large literature on risk factors, longitudinal trajectories, and stages of diseases that suggest we should already be able to predict relapse risk for individuals,” Dr. Goulding said.
“However, moving from overall risk to individual risk is trickier and will require larger datasets with longer follow-up to better understand what types of help should be delivered when and to whom,” he added.
‘Requires commitment’
John Torous, MD, director of the division of digital psychiatry at Beth Israel Deaconess Medical Center, Boston, noted that mental health apps such as LiveWell require “time and energy devoted by both the patient and their clinician for maximal efficacy, which requires commitment from and training for both parties as well.
“But with such an investment in people, there is good evidence apps can help people with bipolar disorder even during the more severe periods of the illness,” added Dr. Torous, who was not involved with the research.
The study was funded by the National Institute of Mental Health.
Dr. Goulding reports having received honoraria from Otsuka. Dr. Torous has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM JAMA PSYCHIATRY
Postconcussion symptoms tied to high risk of depression
Results of a large meta-analysis that included 18 studies and more than 9,000 patients showed a fourfold higher risk of developing depressive symptoms in those with PPCS versus those without PPCS.
“In this meta-analysis, experiencing PPCS was associated with a higher risk of experiencing depressive symptoms,” write the investigators, led by Maude Lambert, PhD, of the School of Psychology, University of Ottawa, and Bloorview Research Institute, Toronto.
“There are several important clinical and health policy implications of the findings. Most notably, the development of strategies for effective prevention and earlier intervention to optimize mental health recovery following a concussion should be supported,” they add.
The study was published online in JAMA Network Open.
‘Important minority’
An “important minority” of 15%-30% of those with concussions continue to experience symptoms for months, or even years, following the injury, the investigators note.
Symptoms vary but can include headaches, fatigue, dizziness, cognitive difficulties, and emotional changes, which can “significantly impact an individual’s everyday functioning.”
The association between PPCS and mental health outcomes “has emerged as an area of interest” over the past decade, with multiple studies pointing to bidirectional associations between depressive symptoms and PPCS, the researchers note. Individuals with PPCS are at significantly higher risk of experiencing depressive symptoms, and depressive symptoms, in turn, predict more prolonged postconcussion recovery, they add.
The authors conducted a previous scoping review that showed individuals with PPCS had “greater mental health difficulties than individuals who recovered from concussion or healthy controls.”
But “quantitative summaries evaluating the magnitude and nature of the association between PPCS and mental health outcomes were not conducted,” so they decided to conduct a follow-up meta-analysis to corroborate the hypothesis that PPCS may be associated with depressive symptoms.
The researchers also wanted to “investigate potential moderators of that association and determine whether the association between depressive symptoms and PPCS differed based on age, sex, mental illness, history of concussion, and time since the injury.”
This could have “significant public health implications” as it represents an “important step” toward understanding the association between PPCS and mental health, paving the way for the “development of optimal postconcussion intervention strategies, targeting effective prevention and earlier intervention to enhance recovery trajectories, improve mental health, and promote well-being following concussion.”
To be included in the meta-analysis, a study had to focus on participants who had experienced a concussion, diagnosed by a health care professional, or as classified by diagnostic measures, and who experienced greater than or equal to 1 concussion symptom lasting greater than 4 weeks.
There was no explicit upper limit on duration, and individuals of all ages were eligible.
Depressive symptoms were defined as “an outcome that must be measured by a validated and standardized measure of depression.”
Biopsychosocial model
Of 580 reports assessed for eligibility, 18 were included in the meta-analysis, incorporating a total of 9,101 participants, with a median (range) sample size of 154 (48-4,462) participants and a mean (SD) participant age of 33.7 (14.4) years.
The mean length of time since the concussion was 21.3 (18.7) weeks. Of the participants, a mean of 36.1% (11.1%) had a history of greater than or equal to 2 concussions.
Close to three-quarters of the studies (72%) used a cross-sectional design, with most studies conducted in North America, and the remaining conducted in Europe, China, and New Zealand.
The researchers found a “significant positive association” between PPCS and postinjury depressive symptoms (odds ratio, 4.87; 95% confidence interval, 3.01-7.90; P < .001), “representing a large effect size.”
Funnel plot and Egger test analyses “suggested the presence of a publication bias.” However, even after accounting for publication bias, the effect size “of large magnitude” remained, the authors report (OR, 4.56; 95% CI, 2.82-7.37; P < .001).
No significant moderators were identified, “likely due to the small number of studies included,” they speculate.
They note that the current study “does not allow inference about the causal directionality of the association” between PPCS and postinjury depressive symptoms, so the question remains: Do PPCS induce depressive symptoms, or do depressive symptoms induce PPCS?”
Despite this unanswered question, the findings still have important clinical and public health implications, highlighting “the need for a greater understanding of the mechanisms of development and etiology of depressive symptoms postconcussion” and emphasizing “the necessary emergence for timely and effective treatment interventions for depressive symptoms to optimize the long-term prognosis of concussion,” the authors note.
They add that several research teams “have aimed to gain more insight into the etiology and underlying mechanisms of development and course of mental health difficulties in individuals who experience a concussion” and have arrived at a biopsychosocial framework, in light of “the myriad of contributing physiological, biological, and psychosocial factors.”
They recommend the establishment of “specialized multidisciplinary or interdisciplinary concussion care programs should include health care professionals with strong clinical foundations and training in mental health conditions.”
Speedy multidisciplinary care
Commenting on the research, Charles Tator, MD, PhD, professor of neurosurgery, University of Toronto, Division of Neurosurgery, Toronto Western Hospital, said the researchers “performed a thorough systematic review” showing “emphatically that depression occurs in this population.”
Dr. Tator, the director of the Canadian Concussion Centre, who was not involved with the current study, continued: “Nowadays clinical discoveries are validated through a progression of case reports, single-center retrospective cohort studies like ours, referenced by [Dr.] Lambert et al., and then confirmatory systematic reviews, each adding important layers of evidence.”
“This evaluative process has now endorsed the importance of early treatment of mental health symptoms in patients with persisting symptoms, which can include depression, anxiety, and PTSD,” he said.
He recommended that treatment should start with family physicians and nurse practitioners “but may require escalation to psychologists and social workers and then to psychiatrists who are often more skilled in medication selection.”
He encouraged “speedy multidisciplinary care,” noting that the possibility of suicide is worrisome.
No source of study funding was listed. A study coauthor, Shannon Scratch, PhD, has reported receiving funds from the Holland Bloorview Kids Rehabilitation Hospital Foundation (via the Holland Family Professorship in Acquired Brain Injury) during the conduct of this study. No other disclosures were reported. Dr. Tator has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Results of a large meta-analysis that included 18 studies and more than 9,000 patients showed a fourfold higher risk of developing depressive symptoms in those with PPCS versus those without PPCS.
“In this meta-analysis, experiencing PPCS was associated with a higher risk of experiencing depressive symptoms,” write the investigators, led by Maude Lambert, PhD, of the School of Psychology, University of Ottawa, and Bloorview Research Institute, Toronto.
“There are several important clinical and health policy implications of the findings. Most notably, the development of strategies for effective prevention and earlier intervention to optimize mental health recovery following a concussion should be supported,” they add.
The study was published online in JAMA Network Open.
‘Important minority’
An “important minority” of 15%-30% of those with concussions continue to experience symptoms for months, or even years, following the injury, the investigators note.
Symptoms vary but can include headaches, fatigue, dizziness, cognitive difficulties, and emotional changes, which can “significantly impact an individual’s everyday functioning.”
The association between PPCS and mental health outcomes “has emerged as an area of interest” over the past decade, with multiple studies pointing to bidirectional associations between depressive symptoms and PPCS, the researchers note. Individuals with PPCS are at significantly higher risk of experiencing depressive symptoms, and depressive symptoms, in turn, predict more prolonged postconcussion recovery, they add.
The authors conducted a previous scoping review that showed individuals with PPCS had “greater mental health difficulties than individuals who recovered from concussion or healthy controls.”
But “quantitative summaries evaluating the magnitude and nature of the association between PPCS and mental health outcomes were not conducted,” so they decided to conduct a follow-up meta-analysis to corroborate the hypothesis that PPCS may be associated with depressive symptoms.
The researchers also wanted to “investigate potential moderators of that association and determine whether the association between depressive symptoms and PPCS differed based on age, sex, mental illness, history of concussion, and time since the injury.”
This could have “significant public health implications” as it represents an “important step” toward understanding the association between PPCS and mental health, paving the way for the “development of optimal postconcussion intervention strategies, targeting effective prevention and earlier intervention to enhance recovery trajectories, improve mental health, and promote well-being following concussion.”
To be included in the meta-analysis, a study had to focus on participants who had experienced a concussion, diagnosed by a health care professional, or as classified by diagnostic measures, and who experienced greater than or equal to 1 concussion symptom lasting greater than 4 weeks.
There was no explicit upper limit on duration, and individuals of all ages were eligible.
Depressive symptoms were defined as “an outcome that must be measured by a validated and standardized measure of depression.”
Biopsychosocial model
Of 580 reports assessed for eligibility, 18 were included in the meta-analysis, incorporating a total of 9,101 participants, with a median (range) sample size of 154 (48-4,462) participants and a mean (SD) participant age of 33.7 (14.4) years.
The mean length of time since the concussion was 21.3 (18.7) weeks. Of the participants, a mean of 36.1% (11.1%) had a history of greater than or equal to 2 concussions.
Close to three-quarters of the studies (72%) used a cross-sectional design, with most studies conducted in North America, and the remaining conducted in Europe, China, and New Zealand.
The researchers found a “significant positive association” between PPCS and postinjury depressive symptoms (odds ratio, 4.87; 95% confidence interval, 3.01-7.90; P < .001), “representing a large effect size.”
Funnel plot and Egger test analyses “suggested the presence of a publication bias.” However, even after accounting for publication bias, the effect size “of large magnitude” remained, the authors report (OR, 4.56; 95% CI, 2.82-7.37; P < .001).
No significant moderators were identified, “likely due to the small number of studies included,” they speculate.
They note that the current study “does not allow inference about the causal directionality of the association” between PPCS and postinjury depressive symptoms, so the question remains: Do PPCS induce depressive symptoms, or do depressive symptoms induce PPCS?”
Despite this unanswered question, the findings still have important clinical and public health implications, highlighting “the need for a greater understanding of the mechanisms of development and etiology of depressive symptoms postconcussion” and emphasizing “the necessary emergence for timely and effective treatment interventions for depressive symptoms to optimize the long-term prognosis of concussion,” the authors note.
They add that several research teams “have aimed to gain more insight into the etiology and underlying mechanisms of development and course of mental health difficulties in individuals who experience a concussion” and have arrived at a biopsychosocial framework, in light of “the myriad of contributing physiological, biological, and psychosocial factors.”
They recommend the establishment of “specialized multidisciplinary or interdisciplinary concussion care programs should include health care professionals with strong clinical foundations and training in mental health conditions.”
Speedy multidisciplinary care
Commenting on the research, Charles Tator, MD, PhD, professor of neurosurgery, University of Toronto, Division of Neurosurgery, Toronto Western Hospital, said the researchers “performed a thorough systematic review” showing “emphatically that depression occurs in this population.”
Dr. Tator, the director of the Canadian Concussion Centre, who was not involved with the current study, continued: “Nowadays clinical discoveries are validated through a progression of case reports, single-center retrospective cohort studies like ours, referenced by [Dr.] Lambert et al., and then confirmatory systematic reviews, each adding important layers of evidence.”
“This evaluative process has now endorsed the importance of early treatment of mental health symptoms in patients with persisting symptoms, which can include depression, anxiety, and PTSD,” he said.
He recommended that treatment should start with family physicians and nurse practitioners “but may require escalation to psychologists and social workers and then to psychiatrists who are often more skilled in medication selection.”
He encouraged “speedy multidisciplinary care,” noting that the possibility of suicide is worrisome.
No source of study funding was listed. A study coauthor, Shannon Scratch, PhD, has reported receiving funds from the Holland Bloorview Kids Rehabilitation Hospital Foundation (via the Holland Family Professorship in Acquired Brain Injury) during the conduct of this study. No other disclosures were reported. Dr. Tator has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Results of a large meta-analysis that included 18 studies and more than 9,000 patients showed a fourfold higher risk of developing depressive symptoms in those with PPCS versus those without PPCS.
“In this meta-analysis, experiencing PPCS was associated with a higher risk of experiencing depressive symptoms,” write the investigators, led by Maude Lambert, PhD, of the School of Psychology, University of Ottawa, and Bloorview Research Institute, Toronto.
“There are several important clinical and health policy implications of the findings. Most notably, the development of strategies for effective prevention and earlier intervention to optimize mental health recovery following a concussion should be supported,” they add.
The study was published online in JAMA Network Open.
‘Important minority’
An “important minority” of 15%-30% of those with concussions continue to experience symptoms for months, or even years, following the injury, the investigators note.
Symptoms vary but can include headaches, fatigue, dizziness, cognitive difficulties, and emotional changes, which can “significantly impact an individual’s everyday functioning.”
The association between PPCS and mental health outcomes “has emerged as an area of interest” over the past decade, with multiple studies pointing to bidirectional associations between depressive symptoms and PPCS, the researchers note. Individuals with PPCS are at significantly higher risk of experiencing depressive symptoms, and depressive symptoms, in turn, predict more prolonged postconcussion recovery, they add.
The authors conducted a previous scoping review that showed individuals with PPCS had “greater mental health difficulties than individuals who recovered from concussion or healthy controls.”
But “quantitative summaries evaluating the magnitude and nature of the association between PPCS and mental health outcomes were not conducted,” so they decided to conduct a follow-up meta-analysis to corroborate the hypothesis that PPCS may be associated with depressive symptoms.
The researchers also wanted to “investigate potential moderators of that association and determine whether the association between depressive symptoms and PPCS differed based on age, sex, mental illness, history of concussion, and time since the injury.”
This could have “significant public health implications” as it represents an “important step” toward understanding the association between PPCS and mental health, paving the way for the “development of optimal postconcussion intervention strategies, targeting effective prevention and earlier intervention to enhance recovery trajectories, improve mental health, and promote well-being following concussion.”
To be included in the meta-analysis, a study had to focus on participants who had experienced a concussion, diagnosed by a health care professional, or as classified by diagnostic measures, and who experienced greater than or equal to 1 concussion symptom lasting greater than 4 weeks.
There was no explicit upper limit on duration, and individuals of all ages were eligible.
Depressive symptoms were defined as “an outcome that must be measured by a validated and standardized measure of depression.”
Biopsychosocial model
Of 580 reports assessed for eligibility, 18 were included in the meta-analysis, incorporating a total of 9,101 participants, with a median (range) sample size of 154 (48-4,462) participants and a mean (SD) participant age of 33.7 (14.4) years.
The mean length of time since the concussion was 21.3 (18.7) weeks. Of the participants, a mean of 36.1% (11.1%) had a history of greater than or equal to 2 concussions.
Close to three-quarters of the studies (72%) used a cross-sectional design, with most studies conducted in North America, and the remaining conducted in Europe, China, and New Zealand.
The researchers found a “significant positive association” between PPCS and postinjury depressive symptoms (odds ratio, 4.87; 95% confidence interval, 3.01-7.90; P < .001), “representing a large effect size.”
Funnel plot and Egger test analyses “suggested the presence of a publication bias.” However, even after accounting for publication bias, the effect size “of large magnitude” remained, the authors report (OR, 4.56; 95% CI, 2.82-7.37; P < .001).
No significant moderators were identified, “likely due to the small number of studies included,” they speculate.
They note that the current study “does not allow inference about the causal directionality of the association” between PPCS and postinjury depressive symptoms, so the question remains: Do PPCS induce depressive symptoms, or do depressive symptoms induce PPCS?”
Despite this unanswered question, the findings still have important clinical and public health implications, highlighting “the need for a greater understanding of the mechanisms of development and etiology of depressive symptoms postconcussion” and emphasizing “the necessary emergence for timely and effective treatment interventions for depressive symptoms to optimize the long-term prognosis of concussion,” the authors note.
They add that several research teams “have aimed to gain more insight into the etiology and underlying mechanisms of development and course of mental health difficulties in individuals who experience a concussion” and have arrived at a biopsychosocial framework, in light of “the myriad of contributing physiological, biological, and psychosocial factors.”
They recommend the establishment of “specialized multidisciplinary or interdisciplinary concussion care programs should include health care professionals with strong clinical foundations and training in mental health conditions.”
Speedy multidisciplinary care
Commenting on the research, Charles Tator, MD, PhD, professor of neurosurgery, University of Toronto, Division of Neurosurgery, Toronto Western Hospital, said the researchers “performed a thorough systematic review” showing “emphatically that depression occurs in this population.”
Dr. Tator, the director of the Canadian Concussion Centre, who was not involved with the current study, continued: “Nowadays clinical discoveries are validated through a progression of case reports, single-center retrospective cohort studies like ours, referenced by [Dr.] Lambert et al., and then confirmatory systematic reviews, each adding important layers of evidence.”
“This evaluative process has now endorsed the importance of early treatment of mental health symptoms in patients with persisting symptoms, which can include depression, anxiety, and PTSD,” he said.
He recommended that treatment should start with family physicians and nurse practitioners “but may require escalation to psychologists and social workers and then to psychiatrists who are often more skilled in medication selection.”
He encouraged “speedy multidisciplinary care,” noting that the possibility of suicide is worrisome.
No source of study funding was listed. A study coauthor, Shannon Scratch, PhD, has reported receiving funds from the Holland Bloorview Kids Rehabilitation Hospital Foundation (via the Holland Family Professorship in Acquired Brain Injury) during the conduct of this study. No other disclosures were reported. Dr. Tator has reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM JAMA NETWORK OPEN
Sleep complaints in major depression flag risk for other psychiatric disorders
Investigators studied 3-year incidence rates of psychiatric disorders in almost 3,000 patients experiencing an MDE. Results showed that having a history of difficulty falling asleep, early morning awakening, and hypersomnia increased risk for incident psychiatric disorders.
“The findings of this study suggest the potential value of including insomnia and hypersomnia in clinical assessments of all psychiatric disorders,” write the investigators, led by Bénédicte Barbotin, MD, Département de Psychiatrie et d’Addictologie, Assistance Publique-Hôpitaux de Paris, Hôpital Bichat-Claude Bernard, France.
“Insomnia and hypersomnia symptoms may be prodromal transdiagnostic biomarkers and easily modifiable therapeutic targets for the prevention of psychiatric disorders,” they add.
The findings were published online recently in the Journal of Clinical Psychiatry.
Bidirectional association
The researchers note that sleep disturbance is “one of the most common symptoms” associated with major depressive disorder (MDD) and may be “both a consequence and a cause.”
Moreover, improving sleep disturbances for patients with an MDE “tends to improve depressive symptom and outcomes,” they add.
Although the possibility of a bidirectional association between MDEs and sleep disturbances “offers a new perspective that sleep complaints might be a predictive prodromal symptom,” the association of sleep complaints with the subsequent development of other psychiatric disorders in MDEs “remains poorly documented,” the investigators write.
The observation that sleep complaints are associated with psychiatric complications and adverse outcomes, such as suicidality and substance overdose, suggests that longitudinal studies “may help to better understand these relationships.”
To investigate these issues, the researchers examined three sleep complaints among patients with MDE: trouble falling asleep, early morning awakening, and hypersomnia. They adjusted for an array of variables, including antisocial personality disorders, use of sedatives or tranquilizers, sociodemographic characteristics, MDE severity, poverty, obesity, educational level, and stressful life events.
They also used a “bifactor latent variable approach” to “disentangle” a number of effects, including those shared by all psychiatric disorders; those specific to dimensions of psychopathology, such as internalizing dimension; and those specific to individual psychiatric disorders, such as dysthymia.
“To our knowledge, this is the most extensive prospective assessment [ever conducted] of associations between sleep complaints and incident psychiatric disorders,” the investigators write.
They drew on data from Waves 1 and 2 of the National Epidemiological Survey on Alcohol and Related Conditions, a large nationally representative survey conducted in 2001-2002 (Wave 1) and 2004-2005 (Wave 2) by the National Institute on Alcoholism and Alcohol Abuse.
The analysis included 2,864 participants who experienced MDE in the year prior to Wave 1 and who completed interviews at both waves.
Researchers assessed past-year DSM-IV Axis I disorders and baseline sleep complaints at Wave 1, as well as incident DSM-IV Axis I disorders between the two waves – including substance use, mood, and anxiety disorders.
Screening needed?
Results showed a wide range of incidence rates for psychiatric disorders between Wave 1 and Wave 2, ranging from 2.7% for cannabis use to 8.2% for generalized anxiety disorder.
The lifetime prevalence of sleep complaints was higher among participants who developed a psychiatric disorder between the two waves than among those who did not have sleep complaints. The range (from lowest to highest percentage) is shown in the accompanying table.
A higher number of sleep complaints was also associated with higher percentages of psychiatric disorders.
Hypersomnia, in particular, significantly increased the odds of having another psychiatric disorder. For patients with MDD who reported hypersomnia, the mean number of sleep disorders was significantly higher than for patients without hypersomnia (2.08 vs. 1.32; P < .001).
“This explains why hypersomnia appears more strongly associated with the incidence of psychiatric disorders,” the investigators write.
After adjusting for sociodemographic and clinical characteristics and antisocial personality disorder, the effects shared across all sleep complaints were “significantly associated with the incident general psychopathology factor, representing mechanisms that may lead to incidence of all psychiatric disorder in the model,” they add.
The researchers note that insomnia and hypersomnia can impair cognitive function, decision-making, problem-solving, and emotion processing networks, thereby increasing the onset of psychiatric disorders in vulnerable individuals.
Shared biological determinants, such as monoamine neurotransmitters that play a major role in depression, anxiety, substance use disorders, and the regulation of sleep stages, may also underlie both sleep disturbances and psychiatric disorders, they speculate.
“These results suggest the importance of systematically assessing insomnia and hypersomnia when evaluating psychiatric disorders and considering these symptoms as nonspecific prodromal or at-risk symptoms, also shared with suicidal behaviors,” the investigators write.
“In addition, since most individuals who developed a psychiatric disorder had at least one sleep complaint, all psychiatric disorders should be carefully screened among individuals with sleep complaints,” they add.
Transdiagnostic phenomenon
In a comment, Roger McIntyre, MD, professor of psychiatry and pharmacology at the University of Toronto, and head of the Mood Disorders Psychopharmacology Unit, noted that the study replicates previous observations that a bidirectional relationship exists between sleep disturbances and mental disorders and that there “seems to be a relationship between sleep disturbance and suicidality that is bidirectional.”
He added that he appreciated the fact that the investigators “took this knowledge one step further; and what they are saying is that within the syndrome of depression, it is the sleep disturbance that is predicting future problems.”
Dr. McIntyre, who is also chairman and executive director of the Brain and Cognitive Discover Foundation in Toronto, was not involved with the study.
The data suggest that, “conceptually, sleep disturbance is a transdiagnostic phenomenon that may also be the nexus when multiple comorbid mental disorders occur,” he said.
“If this is the case, clinically, there is an opportunity here to prevent incident mental disorders in persons with depression and sleep disturbance, prioritizing sleep management in any patient with a mood disorder,” Dr. McIntyre added.
He noted that “the testable hypothesis” is how this is occurring mechanistically.
“I would conjecture that it could be inflammation and/or insulin resistance that is part of sleep disturbance that could predispose and portend other mental illnesses – and likely other medical conditions too, such as obesity and diabetes,” he said.
The study received no specific funding from any funding agency, commercial, or not-for-profit sectors. The investigators’ relevant financial relationships are listed in the original article. Dr. McIntyre has received research grant support from CIHR/GACD/National Natural Science Foundation of China and the Milken Institute; has received speaker/consultation fees from Lundbeck, Janssen, Alkermes,Neumora Therapeutics, Boehringer Ingelheim, Sage, Biogen, Mitsubishi Tanabe, Purdue, Pfizer, Otsuka, Takeda, Neurocrine, Sunovion, Bausch Health, Axsome, Novo Nordisk, Kris, Sanofi, Eisai, Intra-Cellular, NewBridge Pharmaceuticals, Viatris, AbbVie, and Atai Life Sciences; and is a CEO of Braxia Scientific Corp.
A version of this article first appeared on Medscape.com.
Investigators studied 3-year incidence rates of psychiatric disorders in almost 3,000 patients experiencing an MDE. Results showed that having a history of difficulty falling asleep, early morning awakening, and hypersomnia increased risk for incident psychiatric disorders.
“The findings of this study suggest the potential value of including insomnia and hypersomnia in clinical assessments of all psychiatric disorders,” write the investigators, led by Bénédicte Barbotin, MD, Département de Psychiatrie et d’Addictologie, Assistance Publique-Hôpitaux de Paris, Hôpital Bichat-Claude Bernard, France.
“Insomnia and hypersomnia symptoms may be prodromal transdiagnostic biomarkers and easily modifiable therapeutic targets for the prevention of psychiatric disorders,” they add.
The findings were published online recently in the Journal of Clinical Psychiatry.
Bidirectional association
The researchers note that sleep disturbance is “one of the most common symptoms” associated with major depressive disorder (MDD) and may be “both a consequence and a cause.”
Moreover, improving sleep disturbances for patients with an MDE “tends to improve depressive symptom and outcomes,” they add.
Although the possibility of a bidirectional association between MDEs and sleep disturbances “offers a new perspective that sleep complaints might be a predictive prodromal symptom,” the association of sleep complaints with the subsequent development of other psychiatric disorders in MDEs “remains poorly documented,” the investigators write.
The observation that sleep complaints are associated with psychiatric complications and adverse outcomes, such as suicidality and substance overdose, suggests that longitudinal studies “may help to better understand these relationships.”
To investigate these issues, the researchers examined three sleep complaints among patients with MDE: trouble falling asleep, early morning awakening, and hypersomnia. They adjusted for an array of variables, including antisocial personality disorders, use of sedatives or tranquilizers, sociodemographic characteristics, MDE severity, poverty, obesity, educational level, and stressful life events.
They also used a “bifactor latent variable approach” to “disentangle” a number of effects, including those shared by all psychiatric disorders; those specific to dimensions of psychopathology, such as internalizing dimension; and those specific to individual psychiatric disorders, such as dysthymia.
“To our knowledge, this is the most extensive prospective assessment [ever conducted] of associations between sleep complaints and incident psychiatric disorders,” the investigators write.
They drew on data from Waves 1 and 2 of the National Epidemiological Survey on Alcohol and Related Conditions, a large nationally representative survey conducted in 2001-2002 (Wave 1) and 2004-2005 (Wave 2) by the National Institute on Alcoholism and Alcohol Abuse.
The analysis included 2,864 participants who experienced MDE in the year prior to Wave 1 and who completed interviews at both waves.
Researchers assessed past-year DSM-IV Axis I disorders and baseline sleep complaints at Wave 1, as well as incident DSM-IV Axis I disorders between the two waves – including substance use, mood, and anxiety disorders.
Screening needed?
Results showed a wide range of incidence rates for psychiatric disorders between Wave 1 and Wave 2, ranging from 2.7% for cannabis use to 8.2% for generalized anxiety disorder.
The lifetime prevalence of sleep complaints was higher among participants who developed a psychiatric disorder between the two waves than among those who did not have sleep complaints. The range (from lowest to highest percentage) is shown in the accompanying table.
A higher number of sleep complaints was also associated with higher percentages of psychiatric disorders.
Hypersomnia, in particular, significantly increased the odds of having another psychiatric disorder. For patients with MDD who reported hypersomnia, the mean number of sleep disorders was significantly higher than for patients without hypersomnia (2.08 vs. 1.32; P < .001).
“This explains why hypersomnia appears more strongly associated with the incidence of psychiatric disorders,” the investigators write.
After adjusting for sociodemographic and clinical characteristics and antisocial personality disorder, the effects shared across all sleep complaints were “significantly associated with the incident general psychopathology factor, representing mechanisms that may lead to incidence of all psychiatric disorder in the model,” they add.
The researchers note that insomnia and hypersomnia can impair cognitive function, decision-making, problem-solving, and emotion processing networks, thereby increasing the onset of psychiatric disorders in vulnerable individuals.
Shared biological determinants, such as monoamine neurotransmitters that play a major role in depression, anxiety, substance use disorders, and the regulation of sleep stages, may also underlie both sleep disturbances and psychiatric disorders, they speculate.
“These results suggest the importance of systematically assessing insomnia and hypersomnia when evaluating psychiatric disorders and considering these symptoms as nonspecific prodromal or at-risk symptoms, also shared with suicidal behaviors,” the investigators write.
“In addition, since most individuals who developed a psychiatric disorder had at least one sleep complaint, all psychiatric disorders should be carefully screened among individuals with sleep complaints,” they add.
Transdiagnostic phenomenon
In a comment, Roger McIntyre, MD, professor of psychiatry and pharmacology at the University of Toronto, and head of the Mood Disorders Psychopharmacology Unit, noted that the study replicates previous observations that a bidirectional relationship exists between sleep disturbances and mental disorders and that there “seems to be a relationship between sleep disturbance and suicidality that is bidirectional.”
He added that he appreciated the fact that the investigators “took this knowledge one step further; and what they are saying is that within the syndrome of depression, it is the sleep disturbance that is predicting future problems.”
Dr. McIntyre, who is also chairman and executive director of the Brain and Cognitive Discover Foundation in Toronto, was not involved with the study.
The data suggest that, “conceptually, sleep disturbance is a transdiagnostic phenomenon that may also be the nexus when multiple comorbid mental disorders occur,” he said.
“If this is the case, clinically, there is an opportunity here to prevent incident mental disorders in persons with depression and sleep disturbance, prioritizing sleep management in any patient with a mood disorder,” Dr. McIntyre added.
He noted that “the testable hypothesis” is how this is occurring mechanistically.
“I would conjecture that it could be inflammation and/or insulin resistance that is part of sleep disturbance that could predispose and portend other mental illnesses – and likely other medical conditions too, such as obesity and diabetes,” he said.
The study received no specific funding from any funding agency, commercial, or not-for-profit sectors. The investigators’ relevant financial relationships are listed in the original article. Dr. McIntyre has received research grant support from CIHR/GACD/National Natural Science Foundation of China and the Milken Institute; has received speaker/consultation fees from Lundbeck, Janssen, Alkermes,Neumora Therapeutics, Boehringer Ingelheim, Sage, Biogen, Mitsubishi Tanabe, Purdue, Pfizer, Otsuka, Takeda, Neurocrine, Sunovion, Bausch Health, Axsome, Novo Nordisk, Kris, Sanofi, Eisai, Intra-Cellular, NewBridge Pharmaceuticals, Viatris, AbbVie, and Atai Life Sciences; and is a CEO of Braxia Scientific Corp.
A version of this article first appeared on Medscape.com.
Investigators studied 3-year incidence rates of psychiatric disorders in almost 3,000 patients experiencing an MDE. Results showed that having a history of difficulty falling asleep, early morning awakening, and hypersomnia increased risk for incident psychiatric disorders.
“The findings of this study suggest the potential value of including insomnia and hypersomnia in clinical assessments of all psychiatric disorders,” write the investigators, led by Bénédicte Barbotin, MD, Département de Psychiatrie et d’Addictologie, Assistance Publique-Hôpitaux de Paris, Hôpital Bichat-Claude Bernard, France.
“Insomnia and hypersomnia symptoms may be prodromal transdiagnostic biomarkers and easily modifiable therapeutic targets for the prevention of psychiatric disorders,” they add.
The findings were published online recently in the Journal of Clinical Psychiatry.
Bidirectional association
The researchers note that sleep disturbance is “one of the most common symptoms” associated with major depressive disorder (MDD) and may be “both a consequence and a cause.”
Moreover, improving sleep disturbances for patients with an MDE “tends to improve depressive symptom and outcomes,” they add.
Although the possibility of a bidirectional association between MDEs and sleep disturbances “offers a new perspective that sleep complaints might be a predictive prodromal symptom,” the association of sleep complaints with the subsequent development of other psychiatric disorders in MDEs “remains poorly documented,” the investigators write.
The observation that sleep complaints are associated with psychiatric complications and adverse outcomes, such as suicidality and substance overdose, suggests that longitudinal studies “may help to better understand these relationships.”
To investigate these issues, the researchers examined three sleep complaints among patients with MDE: trouble falling asleep, early morning awakening, and hypersomnia. They adjusted for an array of variables, including antisocial personality disorders, use of sedatives or tranquilizers, sociodemographic characteristics, MDE severity, poverty, obesity, educational level, and stressful life events.
They also used a “bifactor latent variable approach” to “disentangle” a number of effects, including those shared by all psychiatric disorders; those specific to dimensions of psychopathology, such as internalizing dimension; and those specific to individual psychiatric disorders, such as dysthymia.
“To our knowledge, this is the most extensive prospective assessment [ever conducted] of associations between sleep complaints and incident psychiatric disorders,” the investigators write.
They drew on data from Waves 1 and 2 of the National Epidemiological Survey on Alcohol and Related Conditions, a large nationally representative survey conducted in 2001-2002 (Wave 1) and 2004-2005 (Wave 2) by the National Institute on Alcoholism and Alcohol Abuse.
The analysis included 2,864 participants who experienced MDE in the year prior to Wave 1 and who completed interviews at both waves.
Researchers assessed past-year DSM-IV Axis I disorders and baseline sleep complaints at Wave 1, as well as incident DSM-IV Axis I disorders between the two waves – including substance use, mood, and anxiety disorders.
Screening needed?
Results showed a wide range of incidence rates for psychiatric disorders between Wave 1 and Wave 2, ranging from 2.7% for cannabis use to 8.2% for generalized anxiety disorder.
The lifetime prevalence of sleep complaints was higher among participants who developed a psychiatric disorder between the two waves than among those who did not have sleep complaints. The range (from lowest to highest percentage) is shown in the accompanying table.
A higher number of sleep complaints was also associated with higher percentages of psychiatric disorders.
Hypersomnia, in particular, significantly increased the odds of having another psychiatric disorder. For patients with MDD who reported hypersomnia, the mean number of sleep disorders was significantly higher than for patients without hypersomnia (2.08 vs. 1.32; P < .001).
“This explains why hypersomnia appears more strongly associated with the incidence of psychiatric disorders,” the investigators write.
After adjusting for sociodemographic and clinical characteristics and antisocial personality disorder, the effects shared across all sleep complaints were “significantly associated with the incident general psychopathology factor, representing mechanisms that may lead to incidence of all psychiatric disorder in the model,” they add.
The researchers note that insomnia and hypersomnia can impair cognitive function, decision-making, problem-solving, and emotion processing networks, thereby increasing the onset of psychiatric disorders in vulnerable individuals.
Shared biological determinants, such as monoamine neurotransmitters that play a major role in depression, anxiety, substance use disorders, and the regulation of sleep stages, may also underlie both sleep disturbances and psychiatric disorders, they speculate.
“These results suggest the importance of systematically assessing insomnia and hypersomnia when evaluating psychiatric disorders and considering these symptoms as nonspecific prodromal or at-risk symptoms, also shared with suicidal behaviors,” the investigators write.
“In addition, since most individuals who developed a psychiatric disorder had at least one sleep complaint, all psychiatric disorders should be carefully screened among individuals with sleep complaints,” they add.
Transdiagnostic phenomenon
In a comment, Roger McIntyre, MD, professor of psychiatry and pharmacology at the University of Toronto, and head of the Mood Disorders Psychopharmacology Unit, noted that the study replicates previous observations that a bidirectional relationship exists between sleep disturbances and mental disorders and that there “seems to be a relationship between sleep disturbance and suicidality that is bidirectional.”
He added that he appreciated the fact that the investigators “took this knowledge one step further; and what they are saying is that within the syndrome of depression, it is the sleep disturbance that is predicting future problems.”
Dr. McIntyre, who is also chairman and executive director of the Brain and Cognitive Discover Foundation in Toronto, was not involved with the study.
The data suggest that, “conceptually, sleep disturbance is a transdiagnostic phenomenon that may also be the nexus when multiple comorbid mental disorders occur,” he said.
“If this is the case, clinically, there is an opportunity here to prevent incident mental disorders in persons with depression and sleep disturbance, prioritizing sleep management in any patient with a mood disorder,” Dr. McIntyre added.
He noted that “the testable hypothesis” is how this is occurring mechanistically.
“I would conjecture that it could be inflammation and/or insulin resistance that is part of sleep disturbance that could predispose and portend other mental illnesses – and likely other medical conditions too, such as obesity and diabetes,” he said.
The study received no specific funding from any funding agency, commercial, or not-for-profit sectors. The investigators’ relevant financial relationships are listed in the original article. Dr. McIntyre has received research grant support from CIHR/GACD/National Natural Science Foundation of China and the Milken Institute; has received speaker/consultation fees from Lundbeck, Janssen, Alkermes,Neumora Therapeutics, Boehringer Ingelheim, Sage, Biogen, Mitsubishi Tanabe, Purdue, Pfizer, Otsuka, Takeda, Neurocrine, Sunovion, Bausch Health, Axsome, Novo Nordisk, Kris, Sanofi, Eisai, Intra-Cellular, NewBridge Pharmaceuticals, Viatris, AbbVie, and Atai Life Sciences; and is a CEO of Braxia Scientific Corp.
A version of this article first appeared on Medscape.com.
FROM THE JOURNAL OF CLINICAL PSYCHIATRY
Hearing loss strongly tied to increased dementia risk
Investigators also found that even mild hearing loss was associated with increased dementia risk, although it was not statistically significant, and that hearing aid use was tied to a 32% decrease in dementia prevalence.
“Every 10-decibel increase in hearing loss was associated with 16% greater prevalence of dementia, such that prevalence of dementia in older adults with moderate or greater hearing loss was 61% higher than prevalence in those with normal hearing,” lead investigator Alison Huang, PhD, senior research associate in epidemiology at Johns Hopkins Bloomberg School of Public Health and core faculty in the Cochlear Center for Hearing and Public Health, Baltimore, Md., told this news organization.
The findings were published online in JAMA.
Dose-dependent effect
For the study, researchers analyzed data on 2,413 community-dwelling participants in the National Health and Aging Trends Study, a nationally representative, continuous panel study of U.S. Medicare beneficiaries aged 65 and older.
Data from the study were collected during in-home interviews, setting it apart from previous work that relied on data collected in a clinical setting, Dr. Huang said.
“This study was able to capture more vulnerable populations, such as the oldest old and older adults with disabilities, typically excluded from prior epidemiologic studies of the hearing loss–dementia association that use clinic-based data collection, which only captures people who have the ability and means to get to clinics,” Dr. Huang said.
Weighted hearing loss prevalence was 36.7% for mild and 29.8% for moderate to severe hearing loss, and weighted prevalence of dementia was 10.3%.
Those with moderate to severe hearing loss were 61% more likely to have dementia than those with normal hearing (prevalence ratio, 1.61; 95% confidence interval, 1.09-2.38).
Dementia prevalence increased with increasing severity of hearing loss: normal hearing: 6.19% (95% CI, 4.31-8.80); mild hearing loss: 8.93% (95% CI, 6.99-11.34); moderate/severe hearing loss: 16.52% (95% CI, 13.81-19.64). But only moderate to severe hearing loss showed a statistically significant association with dementia (P = .02).
Dementia prevalence increased 16% per 10-decibel increase in hearing loss (prevalence ratio 1.16; P < .001).
Among the 853 individuals in the study with moderate to severe hearing loss, those who used hearing aids (n = 414) had a 32% lower risk of dementia compared with those who didn’t use assistive devices (prevalence ratio, 0.68; 95% CI, 0.47-1.00). This news organization last month reported on similar data published in JAMA Neurology suggesting that hearing aids reduce dementia risk.
“With this study, we were able to refine our understanding of the strength of the hearing loss–dementia association in a study more representative of older adults in the United States,” said Dr. Huang.
Robust association
Commenting on the findings, Justin S. Golub, MD, associate professor in the department of otolaryngology–head and neck surgery at Columbia University, New York, said the study supports earlier research and suggests a “robust” association between hearing loss and dementia.
“The particular advantage of this study was that it was high quality and nationally representative,” Dr. Golub said. “It is also among a smaller set of studies that have shown hearing aid use to be associated with lower risk of dementia.”
Although not statistically significant, researchers did find increasing prevalence of dementia among people with only mild hearing loss, and clinicians should take note, said Dr. Golub, who was not involved with this study.
“We would expect the relationship between mild hearing loss and dementia to be weaker than severe hearing loss and dementia and, as a result, it might take more participants to show an association among the mild group,” Dr. Golub said.
“Even though this particular study did not specifically find a relationship between mild hearing loss and dementia, I would still recommend people to start treating their hearing loss when it is early,” Dr. Golub added.
The study was funded by the National Institute on Aging. Dr. Golub reports no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Investigators also found that even mild hearing loss was associated with increased dementia risk, although it was not statistically significant, and that hearing aid use was tied to a 32% decrease in dementia prevalence.
“Every 10-decibel increase in hearing loss was associated with 16% greater prevalence of dementia, such that prevalence of dementia in older adults with moderate or greater hearing loss was 61% higher than prevalence in those with normal hearing,” lead investigator Alison Huang, PhD, senior research associate in epidemiology at Johns Hopkins Bloomberg School of Public Health and core faculty in the Cochlear Center for Hearing and Public Health, Baltimore, Md., told this news organization.
The findings were published online in JAMA.
Dose-dependent effect
For the study, researchers analyzed data on 2,413 community-dwelling participants in the National Health and Aging Trends Study, a nationally representative, continuous panel study of U.S. Medicare beneficiaries aged 65 and older.
Data from the study were collected during in-home interviews, setting it apart from previous work that relied on data collected in a clinical setting, Dr. Huang said.
“This study was able to capture more vulnerable populations, such as the oldest old and older adults with disabilities, typically excluded from prior epidemiologic studies of the hearing loss–dementia association that use clinic-based data collection, which only captures people who have the ability and means to get to clinics,” Dr. Huang said.
Weighted hearing loss prevalence was 36.7% for mild and 29.8% for moderate to severe hearing loss, and weighted prevalence of dementia was 10.3%.
Those with moderate to severe hearing loss were 61% more likely to have dementia than those with normal hearing (prevalence ratio, 1.61; 95% confidence interval, 1.09-2.38).
Dementia prevalence increased with increasing severity of hearing loss: normal hearing: 6.19% (95% CI, 4.31-8.80); mild hearing loss: 8.93% (95% CI, 6.99-11.34); moderate/severe hearing loss: 16.52% (95% CI, 13.81-19.64). But only moderate to severe hearing loss showed a statistically significant association with dementia (P = .02).
Dementia prevalence increased 16% per 10-decibel increase in hearing loss (prevalence ratio 1.16; P < .001).
Among the 853 individuals in the study with moderate to severe hearing loss, those who used hearing aids (n = 414) had a 32% lower risk of dementia compared with those who didn’t use assistive devices (prevalence ratio, 0.68; 95% CI, 0.47-1.00). This news organization last month reported on similar data published in JAMA Neurology suggesting that hearing aids reduce dementia risk.
“With this study, we were able to refine our understanding of the strength of the hearing loss–dementia association in a study more representative of older adults in the United States,” said Dr. Huang.
Robust association
Commenting on the findings, Justin S. Golub, MD, associate professor in the department of otolaryngology–head and neck surgery at Columbia University, New York, said the study supports earlier research and suggests a “robust” association between hearing loss and dementia.
“The particular advantage of this study was that it was high quality and nationally representative,” Dr. Golub said. “It is also among a smaller set of studies that have shown hearing aid use to be associated with lower risk of dementia.”
Although not statistically significant, researchers did find increasing prevalence of dementia among people with only mild hearing loss, and clinicians should take note, said Dr. Golub, who was not involved with this study.
“We would expect the relationship between mild hearing loss and dementia to be weaker than severe hearing loss and dementia and, as a result, it might take more participants to show an association among the mild group,” Dr. Golub said.
“Even though this particular study did not specifically find a relationship between mild hearing loss and dementia, I would still recommend people to start treating their hearing loss when it is early,” Dr. Golub added.
The study was funded by the National Institute on Aging. Dr. Golub reports no relevant financial relationships.
A version of this article first appeared on Medscape.com.
Investigators also found that even mild hearing loss was associated with increased dementia risk, although it was not statistically significant, and that hearing aid use was tied to a 32% decrease in dementia prevalence.
“Every 10-decibel increase in hearing loss was associated with 16% greater prevalence of dementia, such that prevalence of dementia in older adults with moderate or greater hearing loss was 61% higher than prevalence in those with normal hearing,” lead investigator Alison Huang, PhD, senior research associate in epidemiology at Johns Hopkins Bloomberg School of Public Health and core faculty in the Cochlear Center for Hearing and Public Health, Baltimore, Md., told this news organization.
The findings were published online in JAMA.
Dose-dependent effect
For the study, researchers analyzed data on 2,413 community-dwelling participants in the National Health and Aging Trends Study, a nationally representative, continuous panel study of U.S. Medicare beneficiaries aged 65 and older.
Data from the study were collected during in-home interviews, setting it apart from previous work that relied on data collected in a clinical setting, Dr. Huang said.
“This study was able to capture more vulnerable populations, such as the oldest old and older adults with disabilities, typically excluded from prior epidemiologic studies of the hearing loss–dementia association that use clinic-based data collection, which only captures people who have the ability and means to get to clinics,” Dr. Huang said.
Weighted hearing loss prevalence was 36.7% for mild and 29.8% for moderate to severe hearing loss, and weighted prevalence of dementia was 10.3%.
Those with moderate to severe hearing loss were 61% more likely to have dementia than those with normal hearing (prevalence ratio, 1.61; 95% confidence interval, 1.09-2.38).
Dementia prevalence increased with increasing severity of hearing loss: normal hearing: 6.19% (95% CI, 4.31-8.80); mild hearing loss: 8.93% (95% CI, 6.99-11.34); moderate/severe hearing loss: 16.52% (95% CI, 13.81-19.64). But only moderate to severe hearing loss showed a statistically significant association with dementia (P = .02).
Dementia prevalence increased 16% per 10-decibel increase in hearing loss (prevalence ratio 1.16; P < .001).
Among the 853 individuals in the study with moderate to severe hearing loss, those who used hearing aids (n = 414) had a 32% lower risk of dementia compared with those who didn’t use assistive devices (prevalence ratio, 0.68; 95% CI, 0.47-1.00). This news organization last month reported on similar data published in JAMA Neurology suggesting that hearing aids reduce dementia risk.
“With this study, we were able to refine our understanding of the strength of the hearing loss–dementia association in a study more representative of older adults in the United States,” said Dr. Huang.
Robust association
Commenting on the findings, Justin S. Golub, MD, associate professor in the department of otolaryngology–head and neck surgery at Columbia University, New York, said the study supports earlier research and suggests a “robust” association between hearing loss and dementia.
“The particular advantage of this study was that it was high quality and nationally representative,” Dr. Golub said. “It is also among a smaller set of studies that have shown hearing aid use to be associated with lower risk of dementia.”
Although not statistically significant, researchers did find increasing prevalence of dementia among people with only mild hearing loss, and clinicians should take note, said Dr. Golub, who was not involved with this study.
“We would expect the relationship between mild hearing loss and dementia to be weaker than severe hearing loss and dementia and, as a result, it might take more participants to show an association among the mild group,” Dr. Golub said.
“Even though this particular study did not specifically find a relationship between mild hearing loss and dementia, I would still recommend people to start treating their hearing loss when it is early,” Dr. Golub added.
The study was funded by the National Institute on Aging. Dr. Golub reports no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM JAMA
Telehealth parent-child interaction therapy improved behavior in children with developmental delay
The children received the therapy with their parents or caregivers, who were more likely to demonstrate positive parenting behaviors than parents in the control group, authors of the new research published in JAMA Pediatrics found.
Approximately 13% of children have some form of developmental delay (DD) and more than half of these children also have at least one mental health disorder, which makes behavior problems a common and ongoing challenge, Daniel M. Bagner, PhD, a psychologist at Florida International University, Miami, and colleagues wrote.
Clinic-based interventions such as parent-child interaction therapy (PCIT) have been effective for improving behavior in children with DD, the researchers said. PCIT involves in-session caregiver coaching using a 1-way mirror and a wireless earpiece worn by the caregiver.
Barriers to the use of PCIT, especially in marginalized and low-income communities, include transportation, clinician shortages, and stigma-related concerns about a clinic visit, the researchers wrote. Technology now allows for Internet-delivered PCIT to reach more children and families, but its effectiveness for children with DD has not been well studied.
In the new study, the researchers randomized 150 children with DD and externalizing behavior problems to up to 20 weeks of Internet-delivered parent-child interaction therapy (iPCIT) or to referral as usual (RAU, the control group). The children were randomized after completion of early intervention services within 3 months of their third birthday, and participated in the sessions with a parent or caregiver. Most of the participants were from economically disadvantaged households and underrepresented ethnic backgrounds.
The iPCIT intervention was conducted weekly with a remote therapist and lasted for 1-1.5 hours; approximately half of the families received the intervention in Spanish.
The primary outcome was rating on the Child Behavior Checklist (CBCL) and assessment of children and caregivers using the Dyadic Parent-Child Interaction Coding System, fourth edition (DPICS). Assessments occurred at baseline and at week 20 (post treatment), with follow ups at 6 and 12 months.
Scores on the CBCL in the iPCIT group decreased from a mean of 61.18 at baseline to 53.83 post intervention. Scores for the control group started at 64.05 and decreased to 59.49 post intervention. At 6-12 months, the scores for both groups remained stable.
Children who received iPCIT with their parent or caregiver also showed significantly lower levels of externalizing behavior problems, compared with the RAU controls post treatment, and at 6-month and 12-month follow-ups based on the Cohen d measure of standardized effect size for differences between groups.
Significantly more children in the iPCIT group showed clinically significant improvements in externalizing problems at post treatment, compared with the RAU group (74% vs. 42%; P < .001) and at 6 months’ follow-up (73% vs. 45%; P = .002). However, the differences from baseline were not significantly different between the two groups after 12 months, which suggests that the effects may wane over time, the researchers noted.
In addition, the rate of child compliance with parent commands, as measured by a cleanup task, approximately doubled by the 12-month follow-up among children in the iPCIT group versus an increase of approximately one-third in the RAU group.
For secondary outcome measures related to caregiver behaviors, the proportion of observed positive parenting behaviors increased in the iPCIT group during the course of the intervention (postintervention odds ratio, 1.10), and the proportion of controlling and critical behaviors decreased (postintervention OR, 1.40). Harsh and inconsistent discipline decreased in both groups based on self-reports, but the decrease was steeper in iPCIT families.
iPCIT did not have a greater impact than RAU in reducing caregiver stress. The researchers wrote that they were not surprised by the lack of stress reduction “given mixed findings on the impact of parenting interventions on stress in caregivers of children with DD.”
Data support iPCIT potential
Overall, the results support findings from previous studies of clinic-based PCIT for children with DD and previous studies of telehealth interventions for typically developing children, the researchers said.
“Moreover, iPCIT-treated children not only showed reductions in behavior problems, such as aggression, but demonstrated higher rates of following directions, which is especially important for children entering kindergarten,” they wrote.
The findings were limited by several factors including the narrow focus on the primary and secondary outcomes, the use of data from a single site in a single metropolitan area – which may limit generalizability – and the lack of comparison between iPCIT and a clinic-based PCIT control group, the researchers noted. The equipment in the current study was provided to families; therefore, differences in treatment response could not be attributed to differences in technology.
The study represents the first known randomized controlled trial to evaluate a telehealth parenting intervention for children with, according to the researchers. The results suggest that technology can be leveraged to help these patients, including those from ethnic minority families who may be underserved by clinic-based care in overcoming barriers to treatment such as transportation and availability of clinicians. Use of iPCIT could be a critical resource as young children with DD complete Part C services and enter the school system.
Practical pediatric takeaways
“This was a great study, well-designed and very important and helpful for pediatric providers,” Cathy Haut, DNP, CPNP-AC, CPNP-PC, a pediatric nurse practitioner in Rehoboth Beach, Del., said in an interview.
“Young children with developmental delay and/or mental and behavioral health disorders require early identification and intervention,” said Dr. Haut. However, obstacles to intervention include stigma or parental denial of the disorder, as well as more practical challenges related to transportation, time to access a clinic or office, potential long length of treatment, and cost.
“Despite availability of state programs for young children, follow up and continued services can be challenging to complete. Once the child outgrows the state program finding alternative therapy can be difficult with the current shortage of pediatric mental health providers,” Dr. Haut noted.
“I was surprised to see that this study treatment phase was completed prior to the COVID-19 pandemic, when telehealth was not as popular a mode for health care and was not utilized to the extent that it is now, especially for pediatric care,” said Dr. Haut. “I was not surprised at the results, as the traditional mode of PCIT includes therapy and training in a space that may not be as familiar to the child as their home environment, and would include live presence of the therapist/s, which may add to anxiety for both the parent and child.”
That almost half of the parents participating in the study had graduated from college and/or completed graduate degrees “may have contributed to some of the success of this study,” Dr. Haut noted.
Benefits and barriers
“The COVID-19 pandemic brought significant change to the frequency of use and overall success of telehealth services,” Dr. Haut said. “Additional provider education in aspects such as provider technique and the use of medical devices with improved specific health care technology assisted in advancing the experience and opportunity for successful telehealth visits. Telehealth therapy offers a cost-effective option for any pediatric patients and for providers, as the time and space commitment for the patient visit can be considerably less than live office visits.
“Unfortunately, there are still overall barriers that I have personally experienced with telehealth, including interruptions in connectivity, background noise, and lack of an available computer or tablet; and with the use of cell phones not always allowing full inclusion of the caregiver and child,” said Dr. Haut. Children with DD, behavioral problems, or other mental health disorders may pose challenges for parents to manage at home while simultaneously trying to fully focus on the therapy in an online setting.
Although the current study is encouraging, “larger studies focused on specific or individual pediatric mental health and/or behavioral disorders may offer more information for providers, and better document the success of telehealth delivery of services,” Dr. Haut said.
The study was supported by the National Institute of Child Health and Human Development. Dr. Bagner disclosed funding from the National Institutes of Health. He also disclosed personal fees from PCIT International to train clinicians in PCIT supported by a grant from the Florida Department of Children and Families outside the current study. Dr. Haut had no financial conflicts to disclose, but serves on the editorial advisory board of Pediatric News.
The children received the therapy with their parents or caregivers, who were more likely to demonstrate positive parenting behaviors than parents in the control group, authors of the new research published in JAMA Pediatrics found.
Approximately 13% of children have some form of developmental delay (DD) and more than half of these children also have at least one mental health disorder, which makes behavior problems a common and ongoing challenge, Daniel M. Bagner, PhD, a psychologist at Florida International University, Miami, and colleagues wrote.
Clinic-based interventions such as parent-child interaction therapy (PCIT) have been effective for improving behavior in children with DD, the researchers said. PCIT involves in-session caregiver coaching using a 1-way mirror and a wireless earpiece worn by the caregiver.
Barriers to the use of PCIT, especially in marginalized and low-income communities, include transportation, clinician shortages, and stigma-related concerns about a clinic visit, the researchers wrote. Technology now allows for Internet-delivered PCIT to reach more children and families, but its effectiveness for children with DD has not been well studied.
In the new study, the researchers randomized 150 children with DD and externalizing behavior problems to up to 20 weeks of Internet-delivered parent-child interaction therapy (iPCIT) or to referral as usual (RAU, the control group). The children were randomized after completion of early intervention services within 3 months of their third birthday, and participated in the sessions with a parent or caregiver. Most of the participants were from economically disadvantaged households and underrepresented ethnic backgrounds.
The iPCIT intervention was conducted weekly with a remote therapist and lasted for 1-1.5 hours; approximately half of the families received the intervention in Spanish.
The primary outcome was rating on the Child Behavior Checklist (CBCL) and assessment of children and caregivers using the Dyadic Parent-Child Interaction Coding System, fourth edition (DPICS). Assessments occurred at baseline and at week 20 (post treatment), with follow ups at 6 and 12 months.
Scores on the CBCL in the iPCIT group decreased from a mean of 61.18 at baseline to 53.83 post intervention. Scores for the control group started at 64.05 and decreased to 59.49 post intervention. At 6-12 months, the scores for both groups remained stable.
Children who received iPCIT with their parent or caregiver also showed significantly lower levels of externalizing behavior problems, compared with the RAU controls post treatment, and at 6-month and 12-month follow-ups based on the Cohen d measure of standardized effect size for differences between groups.
Significantly more children in the iPCIT group showed clinically significant improvements in externalizing problems at post treatment, compared with the RAU group (74% vs. 42%; P < .001) and at 6 months’ follow-up (73% vs. 45%; P = .002). However, the differences from baseline were not significantly different between the two groups after 12 months, which suggests that the effects may wane over time, the researchers noted.
In addition, the rate of child compliance with parent commands, as measured by a cleanup task, approximately doubled by the 12-month follow-up among children in the iPCIT group versus an increase of approximately one-third in the RAU group.
For secondary outcome measures related to caregiver behaviors, the proportion of observed positive parenting behaviors increased in the iPCIT group during the course of the intervention (postintervention odds ratio, 1.10), and the proportion of controlling and critical behaviors decreased (postintervention OR, 1.40). Harsh and inconsistent discipline decreased in both groups based on self-reports, but the decrease was steeper in iPCIT families.
iPCIT did not have a greater impact than RAU in reducing caregiver stress. The researchers wrote that they were not surprised by the lack of stress reduction “given mixed findings on the impact of parenting interventions on stress in caregivers of children with DD.”
Data support iPCIT potential
Overall, the results support findings from previous studies of clinic-based PCIT for children with DD and previous studies of telehealth interventions for typically developing children, the researchers said.
“Moreover, iPCIT-treated children not only showed reductions in behavior problems, such as aggression, but demonstrated higher rates of following directions, which is especially important for children entering kindergarten,” they wrote.
The findings were limited by several factors including the narrow focus on the primary and secondary outcomes, the use of data from a single site in a single metropolitan area – which may limit generalizability – and the lack of comparison between iPCIT and a clinic-based PCIT control group, the researchers noted. The equipment in the current study was provided to families; therefore, differences in treatment response could not be attributed to differences in technology.
The study represents the first known randomized controlled trial to evaluate a telehealth parenting intervention for children with, according to the researchers. The results suggest that technology can be leveraged to help these patients, including those from ethnic minority families who may be underserved by clinic-based care in overcoming barriers to treatment such as transportation and availability of clinicians. Use of iPCIT could be a critical resource as young children with DD complete Part C services and enter the school system.
Practical pediatric takeaways
“This was a great study, well-designed and very important and helpful for pediatric providers,” Cathy Haut, DNP, CPNP-AC, CPNP-PC, a pediatric nurse practitioner in Rehoboth Beach, Del., said in an interview.
“Young children with developmental delay and/or mental and behavioral health disorders require early identification and intervention,” said Dr. Haut. However, obstacles to intervention include stigma or parental denial of the disorder, as well as more practical challenges related to transportation, time to access a clinic or office, potential long length of treatment, and cost.
“Despite availability of state programs for young children, follow up and continued services can be challenging to complete. Once the child outgrows the state program finding alternative therapy can be difficult with the current shortage of pediatric mental health providers,” Dr. Haut noted.
“I was surprised to see that this study treatment phase was completed prior to the COVID-19 pandemic, when telehealth was not as popular a mode for health care and was not utilized to the extent that it is now, especially for pediatric care,” said Dr. Haut. “I was not surprised at the results, as the traditional mode of PCIT includes therapy and training in a space that may not be as familiar to the child as their home environment, and would include live presence of the therapist/s, which may add to anxiety for both the parent and child.”
That almost half of the parents participating in the study had graduated from college and/or completed graduate degrees “may have contributed to some of the success of this study,” Dr. Haut noted.
Benefits and barriers
“The COVID-19 pandemic brought significant change to the frequency of use and overall success of telehealth services,” Dr. Haut said. “Additional provider education in aspects such as provider technique and the use of medical devices with improved specific health care technology assisted in advancing the experience and opportunity for successful telehealth visits. Telehealth therapy offers a cost-effective option for any pediatric patients and for providers, as the time and space commitment for the patient visit can be considerably less than live office visits.
“Unfortunately, there are still overall barriers that I have personally experienced with telehealth, including interruptions in connectivity, background noise, and lack of an available computer or tablet; and with the use of cell phones not always allowing full inclusion of the caregiver and child,” said Dr. Haut. Children with DD, behavioral problems, or other mental health disorders may pose challenges for parents to manage at home while simultaneously trying to fully focus on the therapy in an online setting.
Although the current study is encouraging, “larger studies focused on specific or individual pediatric mental health and/or behavioral disorders may offer more information for providers, and better document the success of telehealth delivery of services,” Dr. Haut said.
The study was supported by the National Institute of Child Health and Human Development. Dr. Bagner disclosed funding from the National Institutes of Health. He also disclosed personal fees from PCIT International to train clinicians in PCIT supported by a grant from the Florida Department of Children and Families outside the current study. Dr. Haut had no financial conflicts to disclose, but serves on the editorial advisory board of Pediatric News.
The children received the therapy with their parents or caregivers, who were more likely to demonstrate positive parenting behaviors than parents in the control group, authors of the new research published in JAMA Pediatrics found.
Approximately 13% of children have some form of developmental delay (DD) and more than half of these children also have at least one mental health disorder, which makes behavior problems a common and ongoing challenge, Daniel M. Bagner, PhD, a psychologist at Florida International University, Miami, and colleagues wrote.
Clinic-based interventions such as parent-child interaction therapy (PCIT) have been effective for improving behavior in children with DD, the researchers said. PCIT involves in-session caregiver coaching using a 1-way mirror and a wireless earpiece worn by the caregiver.
Barriers to the use of PCIT, especially in marginalized and low-income communities, include transportation, clinician shortages, and stigma-related concerns about a clinic visit, the researchers wrote. Technology now allows for Internet-delivered PCIT to reach more children and families, but its effectiveness for children with DD has not been well studied.
In the new study, the researchers randomized 150 children with DD and externalizing behavior problems to up to 20 weeks of Internet-delivered parent-child interaction therapy (iPCIT) or to referral as usual (RAU, the control group). The children were randomized after completion of early intervention services within 3 months of their third birthday, and participated in the sessions with a parent or caregiver. Most of the participants were from economically disadvantaged households and underrepresented ethnic backgrounds.
The iPCIT intervention was conducted weekly with a remote therapist and lasted for 1-1.5 hours; approximately half of the families received the intervention in Spanish.
The primary outcome was rating on the Child Behavior Checklist (CBCL) and assessment of children and caregivers using the Dyadic Parent-Child Interaction Coding System, fourth edition (DPICS). Assessments occurred at baseline and at week 20 (post treatment), with follow ups at 6 and 12 months.
Scores on the CBCL in the iPCIT group decreased from a mean of 61.18 at baseline to 53.83 post intervention. Scores for the control group started at 64.05 and decreased to 59.49 post intervention. At 6-12 months, the scores for both groups remained stable.
Children who received iPCIT with their parent or caregiver also showed significantly lower levels of externalizing behavior problems, compared with the RAU controls post treatment, and at 6-month and 12-month follow-ups based on the Cohen d measure of standardized effect size for differences between groups.
Significantly more children in the iPCIT group showed clinically significant improvements in externalizing problems at post treatment, compared with the RAU group (74% vs. 42%; P < .001) and at 6 months’ follow-up (73% vs. 45%; P = .002). However, the differences from baseline were not significantly different between the two groups after 12 months, which suggests that the effects may wane over time, the researchers noted.
In addition, the rate of child compliance with parent commands, as measured by a cleanup task, approximately doubled by the 12-month follow-up among children in the iPCIT group versus an increase of approximately one-third in the RAU group.
For secondary outcome measures related to caregiver behaviors, the proportion of observed positive parenting behaviors increased in the iPCIT group during the course of the intervention (postintervention odds ratio, 1.10), and the proportion of controlling and critical behaviors decreased (postintervention OR, 1.40). Harsh and inconsistent discipline decreased in both groups based on self-reports, but the decrease was steeper in iPCIT families.
iPCIT did not have a greater impact than RAU in reducing caregiver stress. The researchers wrote that they were not surprised by the lack of stress reduction “given mixed findings on the impact of parenting interventions on stress in caregivers of children with DD.”
Data support iPCIT potential
Overall, the results support findings from previous studies of clinic-based PCIT for children with DD and previous studies of telehealth interventions for typically developing children, the researchers said.
“Moreover, iPCIT-treated children not only showed reductions in behavior problems, such as aggression, but demonstrated higher rates of following directions, which is especially important for children entering kindergarten,” they wrote.
The findings were limited by several factors including the narrow focus on the primary and secondary outcomes, the use of data from a single site in a single metropolitan area – which may limit generalizability – and the lack of comparison between iPCIT and a clinic-based PCIT control group, the researchers noted. The equipment in the current study was provided to families; therefore, differences in treatment response could not be attributed to differences in technology.
The study represents the first known randomized controlled trial to evaluate a telehealth parenting intervention for children with, according to the researchers. The results suggest that technology can be leveraged to help these patients, including those from ethnic minority families who may be underserved by clinic-based care in overcoming barriers to treatment such as transportation and availability of clinicians. Use of iPCIT could be a critical resource as young children with DD complete Part C services and enter the school system.
Practical pediatric takeaways
“This was a great study, well-designed and very important and helpful for pediatric providers,” Cathy Haut, DNP, CPNP-AC, CPNP-PC, a pediatric nurse practitioner in Rehoboth Beach, Del., said in an interview.
“Young children with developmental delay and/or mental and behavioral health disorders require early identification and intervention,” said Dr. Haut. However, obstacles to intervention include stigma or parental denial of the disorder, as well as more practical challenges related to transportation, time to access a clinic or office, potential long length of treatment, and cost.
“Despite availability of state programs for young children, follow up and continued services can be challenging to complete. Once the child outgrows the state program finding alternative therapy can be difficult with the current shortage of pediatric mental health providers,” Dr. Haut noted.
“I was surprised to see that this study treatment phase was completed prior to the COVID-19 pandemic, when telehealth was not as popular a mode for health care and was not utilized to the extent that it is now, especially for pediatric care,” said Dr. Haut. “I was not surprised at the results, as the traditional mode of PCIT includes therapy and training in a space that may not be as familiar to the child as their home environment, and would include live presence of the therapist/s, which may add to anxiety for both the parent and child.”
That almost half of the parents participating in the study had graduated from college and/or completed graduate degrees “may have contributed to some of the success of this study,” Dr. Haut noted.
Benefits and barriers
“The COVID-19 pandemic brought significant change to the frequency of use and overall success of telehealth services,” Dr. Haut said. “Additional provider education in aspects such as provider technique and the use of medical devices with improved specific health care technology assisted in advancing the experience and opportunity for successful telehealth visits. Telehealth therapy offers a cost-effective option for any pediatric patients and for providers, as the time and space commitment for the patient visit can be considerably less than live office visits.
“Unfortunately, there are still overall barriers that I have personally experienced with telehealth, including interruptions in connectivity, background noise, and lack of an available computer or tablet; and with the use of cell phones not always allowing full inclusion of the caregiver and child,” said Dr. Haut. Children with DD, behavioral problems, or other mental health disorders may pose challenges for parents to manage at home while simultaneously trying to fully focus on the therapy in an online setting.
Although the current study is encouraging, “larger studies focused on specific or individual pediatric mental health and/or behavioral disorders may offer more information for providers, and better document the success of telehealth delivery of services,” Dr. Haut said.
The study was supported by the National Institute of Child Health and Human Development. Dr. Bagner disclosed funding from the National Institutes of Health. He also disclosed personal fees from PCIT International to train clinicians in PCIT supported by a grant from the Florida Department of Children and Families outside the current study. Dr. Haut had no financial conflicts to disclose, but serves on the editorial advisory board of Pediatric News.
FROM JAMA PEDIATRICS