Trichotillomania is a chronic psychiatric disorder that causes people to repeatedly pull out their own hair. Not only does it result in alopecia with no other underlying causes but it can have significant psychosocial ramifications and rare, but serious, complications. Though the reported prevalence rates are up to approximately 2%, it’s probable that you’ll come upon a patient suffering with this disorder at your practice, if you haven’t already.

To find out more about the best methods for diagnosing and treating this disorder, we spoke with Jon E. Grant, JD, MD, MPH, a leading trichotillomania researcher and part of the department of psychiatry and behavioral neuroscience at the University of Chicago.

Courtesy of Dr. Jon Grant

Defining trichotillomania

What were the earliest descriptions of trichotillomania in medical literature?

The first real discussion of it probably goes back to Hippocrates, but from a modern medical perspective, discussion began in the 19th century with reports from the French dermatologist François Hallopeau.

They didn’t really call them disorders then – it was long before the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) – but they described this in young men who kept pulling their hair for unclear reasons. These early case reports don’t provide a lot of psychological perspective, but they seem consistent with what we see now.

What are the diagnostic criteria for trichotillomania?

The current DSM-5 criteria are recurrent pulling out of hair, an inability to stop it, the pulling resulting in some noticeable thinning or hair loss, and that it causes some level of distress or some type of impairment in functioning.

At what age do most people experience an onset of symptoms?

Generally speaking, it’s in early adolescence, post puberty, around 12-15 years of age. Having said that, we do see children as young as 1-2 years who are pulling their hair, and we occasionally see somebody far older who is doing it for the first time, a sort of geriatric onset.
 

Overlap and differences with other disorders

You’ve written that although trichotillomania is grouped with obsessive-compulsive disorder (OCD) in the DSM-5, the thinking around that has recently shifted. Why is that?

At first, it was noticed that many of these people pulled their hair repetitively in an almost ritualized manner, perhaps every night before bed. That looked like a compulsion of OCD.

When DSM-5 came out in 2013, they grouped it with OCD. Yet people shifted to thinking that it’s kind of a cousin of OCD because it has this compulsive quality but doesn’t really have obsessive thinking that drives it. Many people just pull their hair. They’re not even always aware of it: sometimes yes, sometimes no.

We know that it has some links to OCD. You’ll see more OCD in folks with trichotillomania, but it clearly is not just the same as OCD. One of the biggest pieces of evidence for that is that our first-line treatment for OCD – a selective serotonin reuptake inhibitor antidepressant – does not really help hair pulling.

Having said that, if people are looking for help with trichotillomania, they often are best served by therapists and doctors who have a familiarity with OCD and have kept it on their radar over the past couple of decades.

How does trichotillomania overlap with skin picking disorder, which is another condition that you’ve closely researched?

It does have some overlap with skin picking in the sense that it often seems familial. For example, the mother may pull her hair and child picks their skin.

It also has a fair amount of comorbidity with skin picking. Many people who pull will pick a little bit or did at some point. Many people who pick pulled their hair at some point. It seems closely related to nail biting as well.

Studies have also shown that one of the things that runs in the histories of most families of people with trichotillomania might be substance abuse – alcohol or drug addiction.

All of this has led people to believe that there might be subtypes of trichotillomania: one that’s more like an OCD and one that’s more like an addiction. That’s similar to the debate with other mental health conditions, that there are probably multiple types of depression, multiple types of schizophrenia.

Is there a component of this that could be defined as self-harm?

That’s been its own debate. It doesn’t seem to have the same developmental trajectory that we see with self-harm, or even some of the personality features.

However, there may be a small segment of folks with trichotillomania that might more appropriately fit that category. For example, those with family histories of trauma, higher rates of posttraumatic stress disorder, or borderline personality. But it wouldn’t be the majority.

The problem is, if you look at some of the pediatrician data, they often group picking, pulling, and cutting. I think that’s far too all-inclusive.
 

A gap in clinician education

Are adolescent patients likely to self-report this behavior, or is it something that physicians need to suss out for themselves?

Clearly, if child psychologists, psychiatrists, or pediatricians see young people with patches of alopecia – eyebrows or eyelashes missing, head hair with spots – in addition to a dermatologic assessment, they should simply ask, “Do you pull your hair?”

But it’s interesting that with the internet, young people are much more likely to disclose and actually come forward and tell their parents that they think they have trichotillomania.

I also hear from a lot of the adolescents that they have to educate their doctors about trichotillomania because so often physicians don’t know much about it and will assume that it’s self-injury or just a symptom of anxiety. It’s a little bit of a flip from what we might have seen 20 years ago.

I’ve seen several patients who’ve said, basically, “I’m tired of no professionals seeming to know about this. I shouldn’t have to be educating my doctors about this.” I tell them that I completely agree. It’s a shame because if a doctor doesn’t know about it, then how can they get the appropriate care?

What are the complications that accompany trichotillomania?

A small percentage, maybe about 10%, will ingest their hair, much like people who bite and swallow their fingernails. The concern there is that because hair is nondigestible, it could create an intestinal plug that could rupture and be potentially life-threatening. That makes it all the more important to ask those who pull their hair what they do with the hair once they pull it.

However, with most people, the real problem is with self-esteem. Young people may not want to socialize, go on dates, or do other things they would normally do because of it. In adults, you may find that they’re far more educated than their job allows but don’t want to go to an interview because they don’t want to have somebody sit there and look at them and notice that perhaps they don’t have any eyebrows, or that they’re wearing a wig. Those psychosocial implications are huge for so many people.
 

Treatment options

In a 2021 study, you showed that nearly one-quarter of people with trichotillomania do naturally recover from it. What characteristics do they seem to have?

It’s interesting because we see natural recovery across many mental health problems: alcohol addition, gambling, OCD. The question then becomes why is that some people can seemingly just stop doing a behavior? Can we learn from those people?

We did see that those who naturally recovered were less likely to have some other mental health comorbidities. It seems like when you have other things such as skin picking or OCD plus trichotillomania, that it probably speaks to something that perhaps synergistically is keeping it going. But this is just a first study; learning how to harness and understand it is the next step.

What’s the goal of treating trichotillomania?

The desired goal is zero pulling. The realistic goal is more likely significantly reduced pulling that then leads to greater function in life, greater quality-of-life.

One doesn’t have to go from 100 to 0 in order to do that. I always tell people that maybe every now and then, every few months, when something is going on in life, you might find yourself pulling a hair or two. That’s okay. If you’re not pulling every day and it’s significantly reduced, we’ll call that a success. I think that setting reasonable goals at this point is really important.

And what would the treatment pathway look like for most patients?

The standard approach is probably some type of habit-reversal therapy, of which there have been many variants over the years. It involves doing something different with your hand, identifying the triggers that may set you off, and then doing something in response to those triggers that is not pulling and might neutralize whatever that anxious or stressed feeling is. That could be different with each person.

At this point, there is no drug approved by the U.S. Food and Drug Administration for trichotillomania. Our best approaches have included N-acetylcysteine, a glutamate modulator, which we’ve done research in.

That’s kind of a go-to option for people because its side-effect profile is generally innocuous. The data show that it could be beneficial in many people with very few, if any, side effects. That would be one “medication,” although it’s actually an over-the-counter vitamin. But we’re constantly looking for better and better treatments.

Do you have any final advice for clinicians or researchers?

Given how common it is, I don’t think clinicians should just see it as an innocuous little habit that people should be able to stop on their own. Clinicians should educate themselves about trichotillomania and know where the person should get the appropriate care.

From the research perspective, given the fact that we see this in animals of multiple species – that they overgroom – this seems to be deeply ingrained in us as animals. So when it comes to the underlying neuroscience, people should pay more attention because it probably has a lot to do with our understanding of habit and compulsive behaviors. It arguably can cut across a lot of different behaviors.

A version of this article first appeared on Medscape.com.

Trichotillomania is a chronic psychiatric disorder that causes people to repeatedly pull out their own hair. Not only does it result in alopecia with no other underlying causes but it can have significant psychosocial ramifications and rare, but serious, complications. Though the reported prevalence rates are up to approximately 2%, it’s probable that you’ll come upon a patient suffering with this disorder at your practice, if you haven’t already.

To find out more about the best methods for diagnosing and treating this disorder, we spoke with Jon E. Grant, JD, MD, MPH, a leading trichotillomania researcher and part of the department of psychiatry and behavioral neuroscience at the University of Chicago.

Courtesy of Dr. Jon Grant

Defining trichotillomania

What were the earliest descriptions of trichotillomania in medical literature?

The first real discussion of it probably goes back to Hippocrates, but from a modern medical perspective, discussion began in the 19th century with reports from the French dermatologist François Hallopeau.

They didn’t really call them disorders then – it was long before the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) – but they described this in young men who kept pulling their hair for unclear reasons. These early case reports don’t provide a lot of psychological perspective, but they seem consistent with what we see now.

What are the diagnostic criteria for trichotillomania?

The current DSM-5 criteria are recurrent pulling out of hair, an inability to stop it, the pulling resulting in some noticeable thinning or hair loss, and that it causes some level of distress or some type of impairment in functioning.

At what age do most people experience an onset of symptoms?

Generally speaking, it’s in early adolescence, post puberty, around 12-15 years of age. Having said that, we do see children as young as 1-2 years who are pulling their hair, and we occasionally see somebody far older who is doing it for the first time, a sort of geriatric onset.
 

Overlap and differences with other disorders

You’ve written that although trichotillomania is grouped with obsessive-compulsive disorder (OCD) in the DSM-5, the thinking around that has recently shifted. Why is that?

At first, it was noticed that many of these people pulled their hair repetitively in an almost ritualized manner, perhaps every night before bed. That looked like a compulsion of OCD.

When DSM-5 came out in 2013, they grouped it with OCD. Yet people shifted to thinking that it’s kind of a cousin of OCD because it has this compulsive quality but doesn’t really have obsessive thinking that drives it. Many people just pull their hair. They’re not even always aware of it: sometimes yes, sometimes no.

We know that it has some links to OCD. You’ll see more OCD in folks with trichotillomania, but it clearly is not just the same as OCD. One of the biggest pieces of evidence for that is that our first-line treatment for OCD – a selective serotonin reuptake inhibitor antidepressant – does not really help hair pulling.

Having said that, if people are looking for help with trichotillomania, they often are best served by therapists and doctors who have a familiarity with OCD and have kept it on their radar over the past couple of decades.

How does trichotillomania overlap with skin picking disorder, which is another condition that you’ve closely researched?

It does have some overlap with skin picking in the sense that it often seems familial. For example, the mother may pull her hair and child picks their skin.

It also has a fair amount of comorbidity with skin picking. Many people who pull will pick a little bit or did at some point. Many people who pick pulled their hair at some point. It seems closely related to nail biting as well.

Studies have also shown that one of the things that runs in the histories of most families of people with trichotillomania might be substance abuse – alcohol or drug addiction.

All of this has led people to believe that there might be subtypes of trichotillomania: one that’s more like an OCD and one that’s more like an addiction. That’s similar to the debate with other mental health conditions, that there are probably multiple types of depression, multiple types of schizophrenia.

Is there a component of this that could be defined as self-harm?

That’s been its own debate. It doesn’t seem to have the same developmental trajectory that we see with self-harm, or even some of the personality features.

However, there may be a small segment of folks with trichotillomania that might more appropriately fit that category. For example, those with family histories of trauma, higher rates of posttraumatic stress disorder, or borderline personality. But it wouldn’t be the majority.

The problem is, if you look at some of the pediatrician data, they often group picking, pulling, and cutting. I think that’s far too all-inclusive.
 

A gap in clinician education

Are adolescent patients likely to self-report this behavior, or is it something that physicians need to suss out for themselves?

Clearly, if child psychologists, psychiatrists, or pediatricians see young people with patches of alopecia – eyebrows or eyelashes missing, head hair with spots – in addition to a dermatologic assessment, they should simply ask, “Do you pull your hair?”

But it’s interesting that with the internet, young people are much more likely to disclose and actually come forward and tell their parents that they think they have trichotillomania.

I also hear from a lot of the adolescents that they have to educate their doctors about trichotillomania because so often physicians don’t know much about it and will assume that it’s self-injury or just a symptom of anxiety. It’s a little bit of a flip from what we might have seen 20 years ago.

I’ve seen several patients who’ve said, basically, “I’m tired of no professionals seeming to know about this. I shouldn’t have to be educating my doctors about this.” I tell them that I completely agree. It’s a shame because if a doctor doesn’t know about it, then how can they get the appropriate care?

What are the complications that accompany trichotillomania?

A small percentage, maybe about 10%, will ingest their hair, much like people who bite and swallow their fingernails. The concern there is that because hair is nondigestible, it could create an intestinal plug that could rupture and be potentially life-threatening. That makes it all the more important to ask those who pull their hair what they do with the hair once they pull it.

However, with most people, the real problem is with self-esteem. Young people may not want to socialize, go on dates, or do other things they would normally do because of it. In adults, you may find that they’re far more educated than their job allows but don’t want to go to an interview because they don’t want to have somebody sit there and look at them and notice that perhaps they don’t have any eyebrows, or that they’re wearing a wig. Those psychosocial implications are huge for so many people.
 

Treatment options

In a 2021 study, you showed that nearly one-quarter of people with trichotillomania do naturally recover from it. What characteristics do they seem to have?

It’s interesting because we see natural recovery across many mental health problems: alcohol addition, gambling, OCD. The question then becomes why is that some people can seemingly just stop doing a behavior? Can we learn from those people?

We did see that those who naturally recovered were less likely to have some other mental health comorbidities. It seems like when you have other things such as skin picking or OCD plus trichotillomania, that it probably speaks to something that perhaps synergistically is keeping it going. But this is just a first study; learning how to harness and understand it is the next step.

What’s the goal of treating trichotillomania?

The desired goal is zero pulling. The realistic goal is more likely significantly reduced pulling that then leads to greater function in life, greater quality-of-life.

One doesn’t have to go from 100 to 0 in order to do that. I always tell people that maybe every now and then, every few months, when something is going on in life, you might find yourself pulling a hair or two. That’s okay. If you’re not pulling every day and it’s significantly reduced, we’ll call that a success. I think that setting reasonable goals at this point is really important.

And what would the treatment pathway look like for most patients?

The standard approach is probably some type of habit-reversal therapy, of which there have been many variants over the years. It involves doing something different with your hand, identifying the triggers that may set you off, and then doing something in response to those triggers that is not pulling and might neutralize whatever that anxious or stressed feeling is. That could be different with each person.

At this point, there is no drug approved by the U.S. Food and Drug Administration for trichotillomania. Our best approaches have included N-acetylcysteine, a glutamate modulator, which we’ve done research in.

That’s kind of a go-to option for people because its side-effect profile is generally innocuous. The data show that it could be beneficial in many people with very few, if any, side effects. That would be one “medication,” although it’s actually an over-the-counter vitamin. But we’re constantly looking for better and better treatments.

Do you have any final advice for clinicians or researchers?

Given how common it is, I don’t think clinicians should just see it as an innocuous little habit that people should be able to stop on their own. Clinicians should educate themselves about trichotillomania and know where the person should get the appropriate care.

From the research perspective, given the fact that we see this in animals of multiple species – that they overgroom – this seems to be deeply ingrained in us as animals. So when it comes to the underlying neuroscience, people should pay more attention because it probably has a lot to do with our understanding of habit and compulsive behaviors. It arguably can cut across a lot of different behaviors.

A version of this article first appeared on Medscape.com.

Trichotillomania is a chronic psychiatric disorder that causes people to repeatedly pull out their own hair. Not only does it result in alopecia with no other underlying causes but it can have significant psychosocial ramifications and rare, but serious, complications. Though the reported prevalence rates are up to approximately 2%, it’s probable that you’ll come upon a patient suffering with this disorder at your practice, if you haven’t already.

To find out more about the best methods for diagnosing and treating this disorder, we spoke with Jon E. Grant, JD, MD, MPH, a leading trichotillomania researcher and part of the department of psychiatry and behavioral neuroscience at the University of Chicago.

Courtesy of Dr. Jon Grant

Defining trichotillomania

What were the earliest descriptions of trichotillomania in medical literature?

The first real discussion of it probably goes back to Hippocrates, but from a modern medical perspective, discussion began in the 19th century with reports from the French dermatologist François Hallopeau.

They didn’t really call them disorders then – it was long before the Diagnostic and Statistical Manual of Mental Disorders (DSM-5) – but they described this in young men who kept pulling their hair for unclear reasons. These early case reports don’t provide a lot of psychological perspective, but they seem consistent with what we see now.

What are the diagnostic criteria for trichotillomania?

The current DSM-5 criteria are recurrent pulling out of hair, an inability to stop it, the pulling resulting in some noticeable thinning or hair loss, and that it causes some level of distress or some type of impairment in functioning.

At what age do most people experience an onset of symptoms?

Generally speaking, it’s in early adolescence, post puberty, around 12-15 years of age. Having said that, we do see children as young as 1-2 years who are pulling their hair, and we occasionally see somebody far older who is doing it for the first time, a sort of geriatric onset.
 

Overlap and differences with other disorders

You’ve written that although trichotillomania is grouped with obsessive-compulsive disorder (OCD) in the DSM-5, the thinking around that has recently shifted. Why is that?

At first, it was noticed that many of these people pulled their hair repetitively in an almost ritualized manner, perhaps every night before bed. That looked like a compulsion of OCD.

When DSM-5 came out in 2013, they grouped it with OCD. Yet people shifted to thinking that it’s kind of a cousin of OCD because it has this compulsive quality but doesn’t really have obsessive thinking that drives it. Many people just pull their hair. They’re not even always aware of it: sometimes yes, sometimes no.

We know that it has some links to OCD. You’ll see more OCD in folks with trichotillomania, but it clearly is not just the same as OCD. One of the biggest pieces of evidence for that is that our first-line treatment for OCD – a selective serotonin reuptake inhibitor antidepressant – does not really help hair pulling.

Having said that, if people are looking for help with trichotillomania, they often are best served by therapists and doctors who have a familiarity with OCD and have kept it on their radar over the past couple of decades.

How does trichotillomania overlap with skin picking disorder, which is another condition that you’ve closely researched?

It does have some overlap with skin picking in the sense that it often seems familial. For example, the mother may pull her hair and child picks their skin.

It also has a fair amount of comorbidity with skin picking. Many people who pull will pick a little bit or did at some point. Many people who pick pulled their hair at some point. It seems closely related to nail biting as well.

Studies have also shown that one of the things that runs in the histories of most families of people with trichotillomania might be substance abuse – alcohol or drug addiction.

All of this has led people to believe that there might be subtypes of trichotillomania: one that’s more like an OCD and one that’s more like an addiction. That’s similar to the debate with other mental health conditions, that there are probably multiple types of depression, multiple types of schizophrenia.

Is there a component of this that could be defined as self-harm?

That’s been its own debate. It doesn’t seem to have the same developmental trajectory that we see with self-harm, or even some of the personality features.

However, there may be a small segment of folks with trichotillomania that might more appropriately fit that category. For example, those with family histories of trauma, higher rates of posttraumatic stress disorder, or borderline personality. But it wouldn’t be the majority.

The problem is, if you look at some of the pediatrician data, they often group picking, pulling, and cutting. I think that’s far too all-inclusive.
 

A gap in clinician education

Are adolescent patients likely to self-report this behavior, or is it something that physicians need to suss out for themselves?

Clearly, if child psychologists, psychiatrists, or pediatricians see young people with patches of alopecia – eyebrows or eyelashes missing, head hair with spots – in addition to a dermatologic assessment, they should simply ask, “Do you pull your hair?”

But it’s interesting that with the internet, young people are much more likely to disclose and actually come forward and tell their parents that they think they have trichotillomania.

I also hear from a lot of the adolescents that they have to educate their doctors about trichotillomania because so often physicians don’t know much about it and will assume that it’s self-injury or just a symptom of anxiety. It’s a little bit of a flip from what we might have seen 20 years ago.

I’ve seen several patients who’ve said, basically, “I’m tired of no professionals seeming to know about this. I shouldn’t have to be educating my doctors about this.” I tell them that I completely agree. It’s a shame because if a doctor doesn’t know about it, then how can they get the appropriate care?

What are the complications that accompany trichotillomania?

A small percentage, maybe about 10%, will ingest their hair, much like people who bite and swallow their fingernails. The concern there is that because hair is nondigestible, it could create an intestinal plug that could rupture and be potentially life-threatening. That makes it all the more important to ask those who pull their hair what they do with the hair once they pull it.

However, with most people, the real problem is with self-esteem. Young people may not want to socialize, go on dates, or do other things they would normally do because of it. In adults, you may find that they’re far more educated than their job allows but don’t want to go to an interview because they don’t want to have somebody sit there and look at them and notice that perhaps they don’t have any eyebrows, or that they’re wearing a wig. Those psychosocial implications are huge for so many people.
 

Treatment options

In a 2021 study, you showed that nearly one-quarter of people with trichotillomania do naturally recover from it. What characteristics do they seem to have?

It’s interesting because we see natural recovery across many mental health problems: alcohol addition, gambling, OCD. The question then becomes why is that some people can seemingly just stop doing a behavior? Can we learn from those people?

We did see that those who naturally recovered were less likely to have some other mental health comorbidities. It seems like when you have other things such as skin picking or OCD plus trichotillomania, that it probably speaks to something that perhaps synergistically is keeping it going. But this is just a first study; learning how to harness and understand it is the next step.

What’s the goal of treating trichotillomania?

The desired goal is zero pulling. The realistic goal is more likely significantly reduced pulling that then leads to greater function in life, greater quality-of-life.

One doesn’t have to go from 100 to 0 in order to do that. I always tell people that maybe every now and then, every few months, when something is going on in life, you might find yourself pulling a hair or two. That’s okay. If you’re not pulling every day and it’s significantly reduced, we’ll call that a success. I think that setting reasonable goals at this point is really important.

And what would the treatment pathway look like for most patients?

The standard approach is probably some type of habit-reversal therapy, of which there have been many variants over the years. It involves doing something different with your hand, identifying the triggers that may set you off, and then doing something in response to those triggers that is not pulling and might neutralize whatever that anxious or stressed feeling is. That could be different with each person.

At this point, there is no drug approved by the U.S. Food and Drug Administration for trichotillomania. Our best approaches have included N-acetylcysteine, a glutamate modulator, which we’ve done research in.

That’s kind of a go-to option for people because its side-effect profile is generally innocuous. The data show that it could be beneficial in many people with very few, if any, side effects. That would be one “medication,” although it’s actually an over-the-counter vitamin. But we’re constantly looking for better and better treatments.

Do you have any final advice for clinicians or researchers?

Given how common it is, I don’t think clinicians should just see it as an innocuous little habit that people should be able to stop on their own. Clinicians should educate themselves about trichotillomania and know where the person should get the appropriate care.

From the research perspective, given the fact that we see this in animals of multiple species – that they overgroom – this seems to be deeply ingrained in us as animals. So when it comes to the underlying neuroscience, people should pay more attention because it probably has a lot to do with our understanding of habit and compulsive behaviors. It arguably can cut across a lot of different behaviors.

A version of this article first appeared on Medscape.com.

Edema blisters are a common but often underreported entity most commonly seen on the lower extremities in the setting of acute edema. ¹ Reported risk factors and associations include chronic venous insufficiency, congestive heart failure, hereditary angioedema, and medications (eg, amlodipine). ^1,2 We report a newly described variant that we have termed anasarca-induced desquamation in which a patient sloughed the entire cutaneous surface of the body after gaining almost 40 pounds over 5 days.

Case Report

A 50-year-old man without a home was found minimally responsive in a yard. His core body temperature was 25.5 °C. He was profoundly acidotic (pH, <6.733 [reference range, 7.35–7.45]; lactic acid, 20.5 mmol/L [reference range, 0.5–2.2 mmol/L]) at admission. His medical history was notable for diabetes mellitus, hypertension, alcohol abuse, and pulmonary embolism. The patient was resuscitated with rewarming and intravenous fluids in the setting of acute renal insufficiency. By day 5 of the hospital stay, he had a net positive intake of 21.8 L and an 18-kg (39.7-lb) weight gain.

Dermatology was consulted for skin sloughing. Physical examination revealed nonpainful desquamation of the vermilion lip, periorbital skin, right shoulder, and hips without notable mucosal changes. Two 4-mm punch biopsies of the shoulder revealed an intracorneal split with desquamation of the stratum corneum and a mild dermal lymphocytic infiltrate, consistent with exfoliation secondary to edema or staphylococcal scalded skin syndrome (Figure 1). No staphylococcal growth was noted on blood, urine, nasal, wound, and ocular cultures throughout the hospital stay.

As the patient’s anasarca improved with diuretics and continuous renal replacement therapy, the entire cutaneous surface—head to toe—underwent desquamation, including the palms and soles. He was managed with supportive skin care. The anasarca healed completely with residual hypopigmentation (Figures 2 and 3).

Comment

Anasarca-induced desquamation represents a more diffuse form of a known entity: edema blisters. Occurring most commonly in the setting of acute exacerbation of chronic venous insufficiency, edema blisters can mimic other vesiculobullous conditions, such as bullous pemphigoid and herpes zoster.³

Pathogenesis of Edema Blisters—Edema develops in the skin when the capillary filtration rate, determined by the hydrostatic and oncotic pressures of the capillaries and interstitium, exceeds venous and lymphatic drainage. The appearance of edema blisters in the acute setting likely is related to the speed at which edema develops in skin.¹ Although edema blisters often are described as tense, there is a paucity of histologic data at the anatomical level of split in the skin.In our patient, desquamation was within the stratum corneum and likely multifactorial. His weight gain of nearly 40 lb, the result of intravenous instillation of fluids and low urine output, was undeniably a contributing factor. The anasarca was aggravated by hypoalbuminemia (2.1 g/dL) in the setting of known liver disease. Other possible contributing factors were hypotension, which required vasopressor therapy that led to hypoperfusion of the skin, and treatment of hypothermia, with resulting reactive vasodilation and capillary leak.

Management—Treatment of acute edema blisters is focused on the underlying cause of the edema. In a study of 13 patients with edema blisters, all had blisters on the legs that resolved with treatment, such as diuretics or compression therapy.¹

Anasarca-induced desquamation is an inherently benign condition that mimics potentially fatal disorders, such as Stevens-Johnson syndrome, staphylococcal scalded skin syndrome, and toxic shock syndrome. Therefore, patients presenting with diffuse superficial desquamation should be assessed for the mucosal changes of Stevens-Johnson syndrome and a history of acute edema in the affected areas to avoid potentially harmful empiric treatments, such as corticosteroids and intravenous antibiotics.

Conclusion

Anasarca-induced desquamation represents a more diffuse form of edema blisters. This desquamation can mimic a potentially fatal rash, such as Stevens-Johnson syndrome and staphylococcal scalded skin syndrome.

Edema blisters are a common but often underreported entity most commonly seen on the lower extremities in the setting of acute edema. ¹ Reported risk factors and associations include chronic venous insufficiency, congestive heart failure, hereditary angioedema, and medications (eg, amlodipine). ^1,2 We report a newly described variant that we have termed anasarca-induced desquamation in which a patient sloughed the entire cutaneous surface of the body after gaining almost 40 pounds over 5 days.

Case Report

A 50-year-old man without a home was found minimally responsive in a yard. His core body temperature was 25.5 °C. He was profoundly acidotic (pH, <6.733 [reference range, 7.35–7.45]; lactic acid, 20.5 mmol/L [reference range, 0.5–2.2 mmol/L]) at admission. His medical history was notable for diabetes mellitus, hypertension, alcohol abuse, and pulmonary embolism. The patient was resuscitated with rewarming and intravenous fluids in the setting of acute renal insufficiency. By day 5 of the hospital stay, he had a net positive intake of 21.8 L and an 18-kg (39.7-lb) weight gain.

Dermatology was consulted for skin sloughing. Physical examination revealed nonpainful desquamation of the vermilion lip, periorbital skin, right shoulder, and hips without notable mucosal changes. Two 4-mm punch biopsies of the shoulder revealed an intracorneal split with desquamation of the stratum corneum and a mild dermal lymphocytic infiltrate, consistent with exfoliation secondary to edema or staphylococcal scalded skin syndrome (Figure 1). No staphylococcal growth was noted on blood, urine, nasal, wound, and ocular cultures throughout the hospital stay.

As the patient’s anasarca improved with diuretics and continuous renal replacement therapy, the entire cutaneous surface—head to toe—underwent desquamation, including the palms and soles. He was managed with supportive skin care. The anasarca healed completely with residual hypopigmentation (Figures 2 and 3).

Comment

Anasarca-induced desquamation represents a more diffuse form of a known entity: edema blisters. Occurring most commonly in the setting of acute exacerbation of chronic venous insufficiency, edema blisters can mimic other vesiculobullous conditions, such as bullous pemphigoid and herpes zoster.³

Pathogenesis of Edema Blisters—Edema develops in the skin when the capillary filtration rate, determined by the hydrostatic and oncotic pressures of the capillaries and interstitium, exceeds venous and lymphatic drainage. The appearance of edema blisters in the acute setting likely is related to the speed at which edema develops in skin.¹ Although edema blisters often are described as tense, there is a paucity of histologic data at the anatomical level of split in the skin.In our patient, desquamation was within the stratum corneum and likely multifactorial. His weight gain of nearly 40 lb, the result of intravenous instillation of fluids and low urine output, was undeniably a contributing factor. The anasarca was aggravated by hypoalbuminemia (2.1 g/dL) in the setting of known liver disease. Other possible contributing factors were hypotension, which required vasopressor therapy that led to hypoperfusion of the skin, and treatment of hypothermia, with resulting reactive vasodilation and capillary leak.

Management—Treatment of acute edema blisters is focused on the underlying cause of the edema. In a study of 13 patients with edema blisters, all had blisters on the legs that resolved with treatment, such as diuretics or compression therapy.¹

Anasarca-induced desquamation is an inherently benign condition that mimics potentially fatal disorders, such as Stevens-Johnson syndrome, staphylococcal scalded skin syndrome, and toxic shock syndrome. Therefore, patients presenting with diffuse superficial desquamation should be assessed for the mucosal changes of Stevens-Johnson syndrome and a history of acute edema in the affected areas to avoid potentially harmful empiric treatments, such as corticosteroids and intravenous antibiotics.

Conclusion

Anasarca-induced desquamation represents a more diffuse form of edema blisters. This desquamation can mimic a potentially fatal rash, such as Stevens-Johnson syndrome and staphylococcal scalded skin syndrome.

Edema blisters are a common but often underreported entity most commonly seen on the lower extremities in the setting of acute edema. ¹ Reported risk factors and associations include chronic venous insufficiency, congestive heart failure, hereditary angioedema, and medications (eg, amlodipine). ^1,2 We report a newly described variant that we have termed anasarca-induced desquamation in which a patient sloughed the entire cutaneous surface of the body after gaining almost 40 pounds over 5 days.

Case Report

A 50-year-old man without a home was found minimally responsive in a yard. His core body temperature was 25.5 °C. He was profoundly acidotic (pH, <6.733 [reference range, 7.35–7.45]; lactic acid, 20.5 mmol/L [reference range, 0.5–2.2 mmol/L]) at admission. His medical history was notable for diabetes mellitus, hypertension, alcohol abuse, and pulmonary embolism. The patient was resuscitated with rewarming and intravenous fluids in the setting of acute renal insufficiency. By day 5 of the hospital stay, he had a net positive intake of 21.8 L and an 18-kg (39.7-lb) weight gain.

Dermatology was consulted for skin sloughing. Physical examination revealed nonpainful desquamation of the vermilion lip, periorbital skin, right shoulder, and hips without notable mucosal changes. Two 4-mm punch biopsies of the shoulder revealed an intracorneal split with desquamation of the stratum corneum and a mild dermal lymphocytic infiltrate, consistent with exfoliation secondary to edema or staphylococcal scalded skin syndrome (Figure 1). No staphylococcal growth was noted on blood, urine, nasal, wound, and ocular cultures throughout the hospital stay.

As the patient’s anasarca improved with diuretics and continuous renal replacement therapy, the entire cutaneous surface—head to toe—underwent desquamation, including the palms and soles. He was managed with supportive skin care. The anasarca healed completely with residual hypopigmentation (Figures 2 and 3).

Comment

Anasarca-induced desquamation represents a more diffuse form of a known entity: edema blisters. Occurring most commonly in the setting of acute exacerbation of chronic venous insufficiency, edema blisters can mimic other vesiculobullous conditions, such as bullous pemphigoid and herpes zoster.³

Pathogenesis of Edema Blisters—Edema develops in the skin when the capillary filtration rate, determined by the hydrostatic and oncotic pressures of the capillaries and interstitium, exceeds venous and lymphatic drainage. The appearance of edema blisters in the acute setting likely is related to the speed at which edema develops in skin.¹ Although edema blisters often are described as tense, there is a paucity of histologic data at the anatomical level of split in the skin.In our patient, desquamation was within the stratum corneum and likely multifactorial. His weight gain of nearly 40 lb, the result of intravenous instillation of fluids and low urine output, was undeniably a contributing factor. The anasarca was aggravated by hypoalbuminemia (2.1 g/dL) in the setting of known liver disease. Other possible contributing factors were hypotension, which required vasopressor therapy that led to hypoperfusion of the skin, and treatment of hypothermia, with resulting reactive vasodilation and capillary leak.

Management—Treatment of acute edema blisters is focused on the underlying cause of the edema. In a study of 13 patients with edema blisters, all had blisters on the legs that resolved with treatment, such as diuretics or compression therapy.¹

Anasarca-induced desquamation is an inherently benign condition that mimics potentially fatal disorders, such as Stevens-Johnson syndrome, staphylococcal scalded skin syndrome, and toxic shock syndrome. Therefore, patients presenting with diffuse superficial desquamation should be assessed for the mucosal changes of Stevens-Johnson syndrome and a history of acute edema in the affected areas to avoid potentially harmful empiric treatments, such as corticosteroids and intravenous antibiotics.

Conclusion

Anasarca-induced desquamation represents a more diffuse form of edema blisters. This desquamation can mimic a potentially fatal rash, such as Stevens-Johnson syndrome and staphylococcal scalded skin syndrome.

A ketogenic diet fed to mice with epithelial ovarian cancer led to significantly increased tumor growth and gut microbiome alterations, according to study recently presented at the annual meeting of the Society of Gynecologic Oncology.

“The keto diet is very popular, especially among patients who believe it may treat cancer by starving tumors of the fuel they need to grow, altering the immune system, and other anticancer effects,” said study leader Mariam AlHilli, MD, of the Cleveland Clinic.

The findings are surprising because in other studies the high-fat, zero-carb ketogenic diet has demonstrated tumor-suppressing effects. It has been under study as a possible adjuvant therapy for other cancers, such as glioblastoma, colon cancer, prostate cancer, and pancreatic cancer.

“While we don’t know yet whether these findings extend to patients, the results in animals indicate that instead of being protective, the keto diet appears to promote ovarian cancer growth and progression,” Dr. AlHilli said. In the present study, tumor bearing mice were fed a keto diet consisting of 10% protein, 0% carbohydrates, and 90% fat, while the high-fat diet was 10% protein, 15% carbohydrates, and 75% fat. The control diet consisted of 10% protein, 77% carbohydrates, and 13% fat. Epithelial ovarian cancer tumor growth was monitored weekly.

Over the 6- to 10-week course of study, a 9.1-fold increase from baseline in tumor growth was observed in the keto diet-fed mice (n = 20). Among mice fed a high-fat diet (n = 20) that included some carbohydrates, tumor growth increased 2.0-fold from baseline, and among control group mice (n = 20) fed a low-fat, high carbohydrate diet, tumor growth increased 3.1-fold.

The investigators observed several hallmarks of tumor progression: tumor associated macrophages were enriched significantly, activated lymphoid cells (natural killer cells) were significantly reduced (P < .001), and M2:M1 polarization trended higher. Also, in keto diet–fed mice, gene set enrichment analysis revealed that epithelial ovarian cancer tumors had increased angiogenesis and inflammatory responses, enhanced epithelial-to-mesenchymal transition phenotype, and altered lipid metabolism. Compared with high-fat diet–fed mice, the keto-fed mice had increases in lipid catalytic activity and catabolism, as well as decreases in lipid synthesis.

“The tumor increase could be mediated by the gut microbiome or by gene alterations or by metabolite levels that influence tumor growth. It’s possible that each cancer type is different. The composition of the diet may be a factor, as well as how tumors metabolize fat and ketones,” Dr. AlHilli said.

The results need to be confirmed in preclinical animal studies and in additional models, she added.

The study was funded by a K12 Grant and internal funding from Cleveland Clinic. Dr. AlHilli declared no relevant disclosures.

A ketogenic diet fed to mice with epithelial ovarian cancer led to significantly increased tumor growth and gut microbiome alterations, according to study recently presented at the annual meeting of the Society of Gynecologic Oncology.

“The keto diet is very popular, especially among patients who believe it may treat cancer by starving tumors of the fuel they need to grow, altering the immune system, and other anticancer effects,” said study leader Mariam AlHilli, MD, of the Cleveland Clinic.

The findings are surprising because in other studies the high-fat, zero-carb ketogenic diet has demonstrated tumor-suppressing effects. It has been under study as a possible adjuvant therapy for other cancers, such as glioblastoma, colon cancer, prostate cancer, and pancreatic cancer.

“While we don’t know yet whether these findings extend to patients, the results in animals indicate that instead of being protective, the keto diet appears to promote ovarian cancer growth and progression,” Dr. AlHilli said. In the present study, tumor bearing mice were fed a keto diet consisting of 10% protein, 0% carbohydrates, and 90% fat, while the high-fat diet was 10% protein, 15% carbohydrates, and 75% fat. The control diet consisted of 10% protein, 77% carbohydrates, and 13% fat. Epithelial ovarian cancer tumor growth was monitored weekly.

Over the 6- to 10-week course of study, a 9.1-fold increase from baseline in tumor growth was observed in the keto diet-fed mice (n = 20). Among mice fed a high-fat diet (n = 20) that included some carbohydrates, tumor growth increased 2.0-fold from baseline, and among control group mice (n = 20) fed a low-fat, high carbohydrate diet, tumor growth increased 3.1-fold.

The investigators observed several hallmarks of tumor progression: tumor associated macrophages were enriched significantly, activated lymphoid cells (natural killer cells) were significantly reduced (P < .001), and M2:M1 polarization trended higher. Also, in keto diet–fed mice, gene set enrichment analysis revealed that epithelial ovarian cancer tumors had increased angiogenesis and inflammatory responses, enhanced epithelial-to-mesenchymal transition phenotype, and altered lipid metabolism. Compared with high-fat diet–fed mice, the keto-fed mice had increases in lipid catalytic activity and catabolism, as well as decreases in lipid synthesis.

“The tumor increase could be mediated by the gut microbiome or by gene alterations or by metabolite levels that influence tumor growth. It’s possible that each cancer type is different. The composition of the diet may be a factor, as well as how tumors metabolize fat and ketones,” Dr. AlHilli said.

The results need to be confirmed in preclinical animal studies and in additional models, she added.

The study was funded by a K12 Grant and internal funding from Cleveland Clinic. Dr. AlHilli declared no relevant disclosures.

A ketogenic diet fed to mice with epithelial ovarian cancer led to significantly increased tumor growth and gut microbiome alterations, according to study recently presented at the annual meeting of the Society of Gynecologic Oncology.

“The keto diet is very popular, especially among patients who believe it may treat cancer by starving tumors of the fuel they need to grow, altering the immune system, and other anticancer effects,” said study leader Mariam AlHilli, MD, of the Cleveland Clinic.

The findings are surprising because in other studies the high-fat, zero-carb ketogenic diet has demonstrated tumor-suppressing effects. It has been under study as a possible adjuvant therapy for other cancers, such as glioblastoma, colon cancer, prostate cancer, and pancreatic cancer.

“While we don’t know yet whether these findings extend to patients, the results in animals indicate that instead of being protective, the keto diet appears to promote ovarian cancer growth and progression,” Dr. AlHilli said. In the present study, tumor bearing mice were fed a keto diet consisting of 10% protein, 0% carbohydrates, and 90% fat, while the high-fat diet was 10% protein, 15% carbohydrates, and 75% fat. The control diet consisted of 10% protein, 77% carbohydrates, and 13% fat. Epithelial ovarian cancer tumor growth was monitored weekly.

Over the 6- to 10-week course of study, a 9.1-fold increase from baseline in tumor growth was observed in the keto diet-fed mice (n = 20). Among mice fed a high-fat diet (n = 20) that included some carbohydrates, tumor growth increased 2.0-fold from baseline, and among control group mice (n = 20) fed a low-fat, high carbohydrate diet, tumor growth increased 3.1-fold.

The investigators observed several hallmarks of tumor progression: tumor associated macrophages were enriched significantly, activated lymphoid cells (natural killer cells) were significantly reduced (P < .001), and M2:M1 polarization trended higher. Also, in keto diet–fed mice, gene set enrichment analysis revealed that epithelial ovarian cancer tumors had increased angiogenesis and inflammatory responses, enhanced epithelial-to-mesenchymal transition phenotype, and altered lipid metabolism. Compared with high-fat diet–fed mice, the keto-fed mice had increases in lipid catalytic activity and catabolism, as well as decreases in lipid synthesis.

“The tumor increase could be mediated by the gut microbiome or by gene alterations or by metabolite levels that influence tumor growth. It’s possible that each cancer type is different. The composition of the diet may be a factor, as well as how tumors metabolize fat and ketones,” Dr. AlHilli said.

The results need to be confirmed in preclinical animal studies and in additional models, she added.

The study was funded by a K12 Grant and internal funding from Cleveland Clinic. Dr. AlHilli declared no relevant disclosures.

An artificial intelligence (AI) model successfully predicted which high-grade serous ovarian cancer patients would have excellent responses to laparoscopic surgery. The model, using still-frame images from pretreatment laparoscopic surgical videos, had an overall accuracy rate of 93%, according to the pilot study’s first author, Deanna Glassman, MD, an oncologic fellow at the University of Texas MD Anderson Cancer Center, Houston.

Dr. Glassman described her research in a presentation given at the annual meeting of the Society of Gynecologic Oncology.

While the AI model successfully identified all excellent-response patients, it did classify about a third of patients with poor responses as excellent responses. The smaller number of images in the poor-response category, Dr. Glassman speculated, may explain the misclassification.

Researchers took 435 representative still-frame images from pretreatment laparoscopic surgical videos of 113 patients with pathologically proven high-grade serous ovarian cancer. Using 70% of the images to train the model, they used 10% for validation and 20% for the actual testing. They developed the AI model with images from four anatomical locations (diaphragm, omentum, peritoneum, and pelvis), training it using deep learning and neural networks to extract morphological disease patterns for correlation with either of two outcomes: excellent response or poor response. An excellent response was defined as progression-free survival of 12 months or more, and poor response as PFS of 6 months or less. In the retrospective study of images, after excluding 32 gray-zone patients, 75 patients (66%) had durable responses to therapy and 6 (5%) had poor responses.

The PFS was 19 months in the excellent-response group and 3 months in the poor-response group.

Clinicians have often observed differences in gross morphology within the single histologic diagnosis of high-grade serous ovarian cancer. The research intent was to determine if AI could detect these distinct morphological patterns in the still frame images taken at the time of laparoscopy, and correlate them with the eventual clinical outcomes. Dr. Glassman and colleagues are currently validating the model with a much larger cohort, and will look into clinical testing.

“The big-picture goal,” Dr. Glassman said in an interview, “would be to utilize the model to predict which patients would do well with traditional standard of care treatments and those who wouldn’t do well so that we can personalize the treatment plan for those patients with alternative agents and therapies.”

Once validated, the model could also be employed to identify patterns of disease in other gynecologic cancers or distinguish between viable and necrosed malignant tissue.

The study’s predominant limitation was the small sample size which is being addressed in a larger ongoing study.

Funding was provided by a T32 grant, MD Anderson Cancer Center Support Grant, MD Anderson Ovarian Cancer Moon Shot, SPORE in Ovarian Cancer, the American Cancer Society, and the Ovarian Cancer Research Alliance. Dr. Glassman declared no relevant financial relationships.

An artificial intelligence (AI) model successfully predicted which high-grade serous ovarian cancer patients would have excellent responses to laparoscopic surgery. The model, using still-frame images from pretreatment laparoscopic surgical videos, had an overall accuracy rate of 93%, according to the pilot study’s first author, Deanna Glassman, MD, an oncologic fellow at the University of Texas MD Anderson Cancer Center, Houston.

Dr. Glassman described her research in a presentation given at the annual meeting of the Society of Gynecologic Oncology.

While the AI model successfully identified all excellent-response patients, it did classify about a third of patients with poor responses as excellent responses. The smaller number of images in the poor-response category, Dr. Glassman speculated, may explain the misclassification.

Researchers took 435 representative still-frame images from pretreatment laparoscopic surgical videos of 113 patients with pathologically proven high-grade serous ovarian cancer. Using 70% of the images to train the model, they used 10% for validation and 20% for the actual testing. They developed the AI model with images from four anatomical locations (diaphragm, omentum, peritoneum, and pelvis), training it using deep learning and neural networks to extract morphological disease patterns for correlation with either of two outcomes: excellent response or poor response. An excellent response was defined as progression-free survival of 12 months or more, and poor response as PFS of 6 months or less. In the retrospective study of images, after excluding 32 gray-zone patients, 75 patients (66%) had durable responses to therapy and 6 (5%) had poor responses.

The PFS was 19 months in the excellent-response group and 3 months in the poor-response group.

Clinicians have often observed differences in gross morphology within the single histologic diagnosis of high-grade serous ovarian cancer. The research intent was to determine if AI could detect these distinct morphological patterns in the still frame images taken at the time of laparoscopy, and correlate them with the eventual clinical outcomes. Dr. Glassman and colleagues are currently validating the model with a much larger cohort, and will look into clinical testing.

“The big-picture goal,” Dr. Glassman said in an interview, “would be to utilize the model to predict which patients would do well with traditional standard of care treatments and those who wouldn’t do well so that we can personalize the treatment plan for those patients with alternative agents and therapies.”

Once validated, the model could also be employed to identify patterns of disease in other gynecologic cancers or distinguish between viable and necrosed malignant tissue.

The study’s predominant limitation was the small sample size which is being addressed in a larger ongoing study.

Funding was provided by a T32 grant, MD Anderson Cancer Center Support Grant, MD Anderson Ovarian Cancer Moon Shot, SPORE in Ovarian Cancer, the American Cancer Society, and the Ovarian Cancer Research Alliance. Dr. Glassman declared no relevant financial relationships.

An artificial intelligence (AI) model successfully predicted which high-grade serous ovarian cancer patients would have excellent responses to laparoscopic surgery. The model, using still-frame images from pretreatment laparoscopic surgical videos, had an overall accuracy rate of 93%, according to the pilot study’s first author, Deanna Glassman, MD, an oncologic fellow at the University of Texas MD Anderson Cancer Center, Houston.

Dr. Glassman described her research in a presentation given at the annual meeting of the Society of Gynecologic Oncology.

While the AI model successfully identified all excellent-response patients, it did classify about a third of patients with poor responses as excellent responses. The smaller number of images in the poor-response category, Dr. Glassman speculated, may explain the misclassification.

Researchers took 435 representative still-frame images from pretreatment laparoscopic surgical videos of 113 patients with pathologically proven high-grade serous ovarian cancer. Using 70% of the images to train the model, they used 10% for validation and 20% for the actual testing. They developed the AI model with images from four anatomical locations (diaphragm, omentum, peritoneum, and pelvis), training it using deep learning and neural networks to extract morphological disease patterns for correlation with either of two outcomes: excellent response or poor response. An excellent response was defined as progression-free survival of 12 months or more, and poor response as PFS of 6 months or less. In the retrospective study of images, after excluding 32 gray-zone patients, 75 patients (66%) had durable responses to therapy and 6 (5%) had poor responses.

The PFS was 19 months in the excellent-response group and 3 months in the poor-response group.

Clinicians have often observed differences in gross morphology within the single histologic diagnosis of high-grade serous ovarian cancer. The research intent was to determine if AI could detect these distinct morphological patterns in the still frame images taken at the time of laparoscopy, and correlate them with the eventual clinical outcomes. Dr. Glassman and colleagues are currently validating the model with a much larger cohort, and will look into clinical testing.

“The big-picture goal,” Dr. Glassman said in an interview, “would be to utilize the model to predict which patients would do well with traditional standard of care treatments and those who wouldn’t do well so that we can personalize the treatment plan for those patients with alternative agents and therapies.”

Once validated, the model could also be employed to identify patterns of disease in other gynecologic cancers or distinguish between viable and necrosed malignant tissue.

The study’s predominant limitation was the small sample size which is being addressed in a larger ongoing study.

Funding was provided by a T32 grant, MD Anderson Cancer Center Support Grant, MD Anderson Ovarian Cancer Moon Shot, SPORE in Ovarian Cancer, the American Cancer Society, and the Ovarian Cancer Research Alliance. Dr. Glassman declared no relevant financial relationships.

A humanized mouse model suggests that head and neck cancer growth may stem from chronic stress. The study found that animals had immunophenotypic changes and a greater propensity towards tumor growth and metastasis.

It is not uncommon for low-income patients with head and neck cancer to present with more aggressive disease at diagnosis. Other studies have shown this may be caused by the lack of access to health care services or poor quality care. but the difference remains even after adjusting for these factors, according to researchers writing in Head and Neck.

Led by Heather A. Himburg, PhD, associate professor of radiation oncology with the Medical College of Wisconsin, Milwaukee, researchers conducted a study of head and neck cancer models in which tumor cells were implanted into a mouse with a humanized immune system.

Their theory was that psychosocial stress may contribute to the growth of head and neck tumors. The stress of poverty, social deprivation and social isolation can lead to the up-regulation of proinflammatory markers in circulating blood leukocytes, and this has been tied to worse outcomes in hematologic malignancies and breast cancer. Many such studies examined social adversity and found an association with greater tumor growth rates and treatment resistance.

Other researchers have used mouse models to study the phenomenon, but the results have been inconclusive. For example, some research linked the beta-adrenergic pathway to head and neck cancer, but clinical trials of beta-blockers showed no benefit, and even potential harm, for patients with head and neck cancers. Those results imply that this pathway does not drive tumor growth and metastasis in the presence of chronic stress.

Previous research used immunocompromised or nonhumanized mice. However, neither type of model reproduces the human tumor microenvironment, which may contribute to ensuing clinical failures. In the new study, researchers describe results from a preclinical model created using a human head and neck cancer xenograft in a mouse with a humanized immune system.
 

How the study was conducted

The animals were randomly assigned to normal housing of two or three animals from the same litter to a cage, or social isolation from littermates. There were five male and five female animals in each arm, and the animals were housed in their separate conditions for 4 weeks before tumor implantation.

The isolated animals experienced increased growth and metastasis of the xenografts, compared with controls. The results are consistent with findings in immunodeficient or syngeneic mice, but the humanized nature of the new model could lead to better translation of findings into clinical studies. “The humanized model system in this study demonstrated the presence of both human myeloid and lymphoid lineages as well as expression of at least 40 human cytokines. These data indicate that our model is likely to well-represent the human condition and better predict human clinical responses as compared to both immunodeficient and syngeneic models,” the authors wrote.

The researchers also found that chronic stress may act through an immunoregulatory effect, since there was greater human immune infiltrate into the tumors of stressed animals. Increased presence of regulatory components like myeloid-derived suppressor cells or regulatory T cells, or eroded function of tumor-infiltrating lymphocytes, might explain this finding. The researchers also identified a proinflammatory change in peripheral blood monocular cells in the stressed group. When they analyzed samples from patients who were low income earners of less than $45,000 in annual household income, they found a similar pattern. “This suggests that chronic socioeconomic stress may induce a similar proinflammatory immune state as our chronic stress model system,” the authors wrote.

Tumors were also different between the two groups of mice. Tumors in stressed animals had a higher percentage of cancer stem cells, which is associated with more aggressive tumors and worse disease-free survival. The researchers suggested that up-regulated levels of the chemokine SDF-1 seen in the stressed animals may be driving the higher proportion of stem cells through its effects on the CXCR4 receptor, which is expressed by stem cells in various organs and may cause migration, proliferation, and cell survival.

The study was funded by an endowment from Advancing a Healthier Wisconsin and a grant from the National Center for Advancing Translational Sciences. The authors reported no conflicts of interest.

A humanized mouse model suggests that head and neck cancer growth may stem from chronic stress. The study found that animals had immunophenotypic changes and a greater propensity towards tumor growth and metastasis.

It is not uncommon for low-income patients with head and neck cancer to present with more aggressive disease at diagnosis. Other studies have shown this may be caused by the lack of access to health care services or poor quality care. but the difference remains even after adjusting for these factors, according to researchers writing in Head and Neck.

Led by Heather A. Himburg, PhD, associate professor of radiation oncology with the Medical College of Wisconsin, Milwaukee, researchers conducted a study of head and neck cancer models in which tumor cells were implanted into a mouse with a humanized immune system.

Their theory was that psychosocial stress may contribute to the growth of head and neck tumors. The stress of poverty, social deprivation and social isolation can lead to the up-regulation of proinflammatory markers in circulating blood leukocytes, and this has been tied to worse outcomes in hematologic malignancies and breast cancer. Many such studies examined social adversity and found an association with greater tumor growth rates and treatment resistance.

Other researchers have used mouse models to study the phenomenon, but the results have been inconclusive. For example, some research linked the beta-adrenergic pathway to head and neck cancer, but clinical trials of beta-blockers showed no benefit, and even potential harm, for patients with head and neck cancers. Those results imply that this pathway does not drive tumor growth and metastasis in the presence of chronic stress.

Previous research used immunocompromised or nonhumanized mice. However, neither type of model reproduces the human tumor microenvironment, which may contribute to ensuing clinical failures. In the new study, researchers describe results from a preclinical model created using a human head and neck cancer xenograft in a mouse with a humanized immune system.
 

How the study was conducted

The animals were randomly assigned to normal housing of two or three animals from the same litter to a cage, or social isolation from littermates. There were five male and five female animals in each arm, and the animals were housed in their separate conditions for 4 weeks before tumor implantation.

The isolated animals experienced increased growth and metastasis of the xenografts, compared with controls. The results are consistent with findings in immunodeficient or syngeneic mice, but the humanized nature of the new model could lead to better translation of findings into clinical studies. “The humanized model system in this study demonstrated the presence of both human myeloid and lymphoid lineages as well as expression of at least 40 human cytokines. These data indicate that our model is likely to well-represent the human condition and better predict human clinical responses as compared to both immunodeficient and syngeneic models,” the authors wrote.

The researchers also found that chronic stress may act through an immunoregulatory effect, since there was greater human immune infiltrate into the tumors of stressed animals. Increased presence of regulatory components like myeloid-derived suppressor cells or regulatory T cells, or eroded function of tumor-infiltrating lymphocytes, might explain this finding. The researchers also identified a proinflammatory change in peripheral blood monocular cells in the stressed group. When they analyzed samples from patients who were low income earners of less than $45,000 in annual household income, they found a similar pattern. “This suggests that chronic socioeconomic stress may induce a similar proinflammatory immune state as our chronic stress model system,” the authors wrote.

Tumors were also different between the two groups of mice. Tumors in stressed animals had a higher percentage of cancer stem cells, which is associated with more aggressive tumors and worse disease-free survival. The researchers suggested that up-regulated levels of the chemokine SDF-1 seen in the stressed animals may be driving the higher proportion of stem cells through its effects on the CXCR4 receptor, which is expressed by stem cells in various organs and may cause migration, proliferation, and cell survival.

The study was funded by an endowment from Advancing a Healthier Wisconsin and a grant from the National Center for Advancing Translational Sciences. The authors reported no conflicts of interest.

A humanized mouse model suggests that head and neck cancer growth may stem from chronic stress. The study found that animals had immunophenotypic changes and a greater propensity towards tumor growth and metastasis.

It is not uncommon for low-income patients with head and neck cancer to present with more aggressive disease at diagnosis. Other studies have shown this may be caused by the lack of access to health care services or poor quality care. but the difference remains even after adjusting for these factors, according to researchers writing in Head and Neck.

Led by Heather A. Himburg, PhD, associate professor of radiation oncology with the Medical College of Wisconsin, Milwaukee, researchers conducted a study of head and neck cancer models in which tumor cells were implanted into a mouse with a humanized immune system.

Their theory was that psychosocial stress may contribute to the growth of head and neck tumors. The stress of poverty, social deprivation and social isolation can lead to the up-regulation of proinflammatory markers in circulating blood leukocytes, and this has been tied to worse outcomes in hematologic malignancies and breast cancer. Many such studies examined social adversity and found an association with greater tumor growth rates and treatment resistance.

Other researchers have used mouse models to study the phenomenon, but the results have been inconclusive. For example, some research linked the beta-adrenergic pathway to head and neck cancer, but clinical trials of beta-blockers showed no benefit, and even potential harm, for patients with head and neck cancers. Those results imply that this pathway does not drive tumor growth and metastasis in the presence of chronic stress.

Previous research used immunocompromised or nonhumanized mice. However, neither type of model reproduces the human tumor microenvironment, which may contribute to ensuing clinical failures. In the new study, researchers describe results from a preclinical model created using a human head and neck cancer xenograft in a mouse with a humanized immune system.
 

How the study was conducted

The animals were randomly assigned to normal housing of two or three animals from the same litter to a cage, or social isolation from littermates. There were five male and five female animals in each arm, and the animals were housed in their separate conditions for 4 weeks before tumor implantation.

The isolated animals experienced increased growth and metastasis of the xenografts, compared with controls. The results are consistent with findings in immunodeficient or syngeneic mice, but the humanized nature of the new model could lead to better translation of findings into clinical studies. “The humanized model system in this study demonstrated the presence of both human myeloid and lymphoid lineages as well as expression of at least 40 human cytokines. These data indicate that our model is likely to well-represent the human condition and better predict human clinical responses as compared to both immunodeficient and syngeneic models,” the authors wrote.

The researchers also found that chronic stress may act through an immunoregulatory effect, since there was greater human immune infiltrate into the tumors of stressed animals. Increased presence of regulatory components like myeloid-derived suppressor cells or regulatory T cells, or eroded function of tumor-infiltrating lymphocytes, might explain this finding. The researchers also identified a proinflammatory change in peripheral blood monocular cells in the stressed group. When they analyzed samples from patients who were low income earners of less than $45,000 in annual household income, they found a similar pattern. “This suggests that chronic socioeconomic stress may induce a similar proinflammatory immune state as our chronic stress model system,” the authors wrote.

Tumors were also different between the two groups of mice. Tumors in stressed animals had a higher percentage of cancer stem cells, which is associated with more aggressive tumors and worse disease-free survival. The researchers suggested that up-regulated levels of the chemokine SDF-1 seen in the stressed animals may be driving the higher proportion of stem cells through its effects on the CXCR4 receptor, which is expressed by stem cells in various organs and may cause migration, proliferation, and cell survival.

The study was funded by an endowment from Advancing a Healthier Wisconsin and a grant from the National Center for Advancing Translational Sciences. The authors reported no conflicts of interest.

SEATTLE – A novel therapy for ataxia telangiectasia that delivers dexamethasone sodium phosphate (DSP) through autologous red blood cells has shown promise in a phase 3 clinical trial.

The disease is an autosomal recessive disorder caused by mutations in the ATM gene, which is critical to the response to cellular insults such as DNA breaks, oxidative damage, and other forms of stress. The result is clinical manifestations that range from a suppressed immune system to organ damage and neurological symptoms that typically lead patients to be wheelchair bound by their teenage years.

“It’s really multisystem and a very, very difficult disease for people to live with,” Howard M. Lederman, MD, PhD, said in an interview. Dr. Lederman is a coauthor of the study, which was presented by Stefan Zielen, PhD, professor at the University of Goethe, at the 2022 annual meeting of the American Academy of Neurology.

Various therapies have been developed to improve immunodeficiency, lung disease, and some of the other clinical aspects of the condition, but there is no treatment for its neurological effects. “There’s not really been a good animal model, which has been a big problem in trying to test drugs and design treatment trials,” said Dr. Lederman, professor of pediatrics and medicine at Johns Hopkins University, Baltimore.

The new results may change that. “In the children under the age of 9, there was really a very clear slowdown in the neurodegeneration, and specifically the time that it took for them to lose the ability to ambulate. It’s very exciting, because it’s the first time that anybody has really shown in a double-blind, placebo-controlled, large phase 3 study that any drug has been able to do this. And there were really no steroid side effects, which is the other really remarkable thing about this study,” said Dr. Lederman.

The therapy grew out of a study by researchers in Italy who treated pediatric ataxia telangiectasia patients with corticosteroids and found some transitory improvements in gross motor function, but concerns about long-term exposure to steroids limited its application. EryDel, which specializes in encapsulating therapeutics in red blood cells, became interested and developed a formulation using the patient’s own red blood cells infused with DSP. Reinfused to the patients, the red blood cells slowly release the steroid.

It isn’t clear how dexamethasone works. There are data suggesting that it might lead to transcription of small pieces of the ATM protein, “but that has really not been nailed down in any way at this point. Corticosteroids act on all kinds of cells in all kinds of ways, and so there might be a little bit of this so-called mini-ATM that’s produced, but that may or may not be related to the way in which corticosteroids have a beneficial effect on the rate of neurodegeneration,” said Dr. Lederman.

The treatment process is not easy. Children must have 50-60 cc of blood removed. Red blood cells treated to become porous are exposed to DSP, and then resealed. Then the cells are reinfused. “The whole process takes from beginning to end probably about 3 hours, with a really experienced team of people doing it. And it’s limiting because it’s not easy to put in an IV and take 50 or 60 cc of blood out of children much younger than 5 or 6. The process is now being modified to see whether we could do it with 20 to 30 cc instead,” said Dr. Lederman.
 

A ‘promising and impressive’ study

The study is promising, according to Nicholas Johnson, MD, who comoderated the session where the study was presented. “They were able to show a slower rate of neurological degeneration or duration on both the lower and higher dose compared with the placebo. This is promising and impressive, in the sense that it’s a really large (trial) for a rare condition,” Dr. Johnson, vice chair of research at Virginia Commonwealth University, Richmond, said in an interview.

The study included 164 patients Europe, Australia, Israel, Tunisia, India, and the United States, who received 5-10 mg dexamethasone, 14-22 mg DSP, or placebo. Mean ages in each group ranged from 9.6 to 10.4 years.

In an intention-to-treat analysis, modified International Cooperative Ataxia Rating Scale (mICARS) scores trended toward improvement in the low-dose (–1.37; P = .0847) and high-dose groups (–1.40; P = .0765) when determined by central raters during the COVID-19 pandemic. There was also a trend toward improvement when determined by local raters in the low dose group (–1.73; P = .0720) and a statistically significant change in the high dose group (–2.11; P = .0277). The researchers noted some inconsistency between local and central raters, due to inconsistency of videography and language challenges for central raters.

An intention-to-treat analysis of a subgroup of 89 patients age 6-9, who were compared with natural history data from 245 patients, found a deterioration of mICARS of 3.7 per year, compared with 0.92 in the high-dose group, for a reduction of 75% (P = .020). In the high-dose group, 51.7% had a minimal or significant improvement compared with baseline according to the Clinical Global Impression of Change, as did 29.0% on low dose, and 27.6% in the placebo group.

SEATTLE – A novel therapy for ataxia telangiectasia that delivers dexamethasone sodium phosphate (DSP) through autologous red blood cells has shown promise in a phase 3 clinical trial.

The disease is an autosomal recessive disorder caused by mutations in the ATM gene, which is critical to the response to cellular insults such as DNA breaks, oxidative damage, and other forms of stress. The result is clinical manifestations that range from a suppressed immune system to organ damage and neurological symptoms that typically lead patients to be wheelchair bound by their teenage years.

“It’s really multisystem and a very, very difficult disease for people to live with,” Howard M. Lederman, MD, PhD, said in an interview. Dr. Lederman is a coauthor of the study, which was presented by Stefan Zielen, PhD, professor at the University of Goethe, at the 2022 annual meeting of the American Academy of Neurology.

Various therapies have been developed to improve immunodeficiency, lung disease, and some of the other clinical aspects of the condition, but there is no treatment for its neurological effects. “There’s not really been a good animal model, which has been a big problem in trying to test drugs and design treatment trials,” said Dr. Lederman, professor of pediatrics and medicine at Johns Hopkins University, Baltimore.

The new results may change that. “In the children under the age of 9, there was really a very clear slowdown in the neurodegeneration, and specifically the time that it took for them to lose the ability to ambulate. It’s very exciting, because it’s the first time that anybody has really shown in a double-blind, placebo-controlled, large phase 3 study that any drug has been able to do this. And there were really no steroid side effects, which is the other really remarkable thing about this study,” said Dr. Lederman.

The therapy grew out of a study by researchers in Italy who treated pediatric ataxia telangiectasia patients with corticosteroids and found some transitory improvements in gross motor function, but concerns about long-term exposure to steroids limited its application. EryDel, which specializes in encapsulating therapeutics in red blood cells, became interested and developed a formulation using the patient’s own red blood cells infused with DSP. Reinfused to the patients, the red blood cells slowly release the steroid.

It isn’t clear how dexamethasone works. There are data suggesting that it might lead to transcription of small pieces of the ATM protein, “but that has really not been nailed down in any way at this point. Corticosteroids act on all kinds of cells in all kinds of ways, and so there might be a little bit of this so-called mini-ATM that’s produced, but that may or may not be related to the way in which corticosteroids have a beneficial effect on the rate of neurodegeneration,” said Dr. Lederman.

The treatment process is not easy. Children must have 50-60 cc of blood removed. Red blood cells treated to become porous are exposed to DSP, and then resealed. Then the cells are reinfused. “The whole process takes from beginning to end probably about 3 hours, with a really experienced team of people doing it. And it’s limiting because it’s not easy to put in an IV and take 50 or 60 cc of blood out of children much younger than 5 or 6. The process is now being modified to see whether we could do it with 20 to 30 cc instead,” said Dr. Lederman.
 

A ‘promising and impressive’ study

The study is promising, according to Nicholas Johnson, MD, who comoderated the session where the study was presented. “They were able to show a slower rate of neurological degeneration or duration on both the lower and higher dose compared with the placebo. This is promising and impressive, in the sense that it’s a really large (trial) for a rare condition,” Dr. Johnson, vice chair of research at Virginia Commonwealth University, Richmond, said in an interview.

The study included 164 patients Europe, Australia, Israel, Tunisia, India, and the United States, who received 5-10 mg dexamethasone, 14-22 mg DSP, or placebo. Mean ages in each group ranged from 9.6 to 10.4 years.

In an intention-to-treat analysis, modified International Cooperative Ataxia Rating Scale (mICARS) scores trended toward improvement in the low-dose (–1.37; P = .0847) and high-dose groups (–1.40; P = .0765) when determined by central raters during the COVID-19 pandemic. There was also a trend toward improvement when determined by local raters in the low dose group (–1.73; P = .0720) and a statistically significant change in the high dose group (–2.11; P = .0277). The researchers noted some inconsistency between local and central raters, due to inconsistency of videography and language challenges for central raters.

An intention-to-treat analysis of a subgroup of 89 patients age 6-9, who were compared with natural history data from 245 patients, found a deterioration of mICARS of 3.7 per year, compared with 0.92 in the high-dose group, for a reduction of 75% (P = .020). In the high-dose group, 51.7% had a minimal or significant improvement compared with baseline according to the Clinical Global Impression of Change, as did 29.0% on low dose, and 27.6% in the placebo group.

SEATTLE – A novel therapy for ataxia telangiectasia that delivers dexamethasone sodium phosphate (DSP) through autologous red blood cells has shown promise in a phase 3 clinical trial.

The disease is an autosomal recessive disorder caused by mutations in the ATM gene, which is critical to the response to cellular insults such as DNA breaks, oxidative damage, and other forms of stress. The result is clinical manifestations that range from a suppressed immune system to organ damage and neurological symptoms that typically lead patients to be wheelchair bound by their teenage years.

“It’s really multisystem and a very, very difficult disease for people to live with,” Howard M. Lederman, MD, PhD, said in an interview. Dr. Lederman is a coauthor of the study, which was presented by Stefan Zielen, PhD, professor at the University of Goethe, at the 2022 annual meeting of the American Academy of Neurology.

Various therapies have been developed to improve immunodeficiency, lung disease, and some of the other clinical aspects of the condition, but there is no treatment for its neurological effects. “There’s not really been a good animal model, which has been a big problem in trying to test drugs and design treatment trials,” said Dr. Lederman, professor of pediatrics and medicine at Johns Hopkins University, Baltimore.

The new results may change that. “In the children under the age of 9, there was really a very clear slowdown in the neurodegeneration, and specifically the time that it took for them to lose the ability to ambulate. It’s very exciting, because it’s the first time that anybody has really shown in a double-blind, placebo-controlled, large phase 3 study that any drug has been able to do this. And there were really no steroid side effects, which is the other really remarkable thing about this study,” said Dr. Lederman.

The therapy grew out of a study by researchers in Italy who treated pediatric ataxia telangiectasia patients with corticosteroids and found some transitory improvements in gross motor function, but concerns about long-term exposure to steroids limited its application. EryDel, which specializes in encapsulating therapeutics in red blood cells, became interested and developed a formulation using the patient’s own red blood cells infused with DSP. Reinfused to the patients, the red blood cells slowly release the steroid.

It isn’t clear how dexamethasone works. There are data suggesting that it might lead to transcription of small pieces of the ATM protein, “but that has really not been nailed down in any way at this point. Corticosteroids act on all kinds of cells in all kinds of ways, and so there might be a little bit of this so-called mini-ATM that’s produced, but that may or may not be related to the way in which corticosteroids have a beneficial effect on the rate of neurodegeneration,” said Dr. Lederman.

The treatment process is not easy. Children must have 50-60 cc of blood removed. Red blood cells treated to become porous are exposed to DSP, and then resealed. Then the cells are reinfused. “The whole process takes from beginning to end probably about 3 hours, with a really experienced team of people doing it. And it’s limiting because it’s not easy to put in an IV and take 50 or 60 cc of blood out of children much younger than 5 or 6. The process is now being modified to see whether we could do it with 20 to 30 cc instead,” said Dr. Lederman.
 

A ‘promising and impressive’ study

The study is promising, according to Nicholas Johnson, MD, who comoderated the session where the study was presented. “They were able to show a slower rate of neurological degeneration or duration on both the lower and higher dose compared with the placebo. This is promising and impressive, in the sense that it’s a really large (trial) for a rare condition,” Dr. Johnson, vice chair of research at Virginia Commonwealth University, Richmond, said in an interview.

The study included 164 patients Europe, Australia, Israel, Tunisia, India, and the United States, who received 5-10 mg dexamethasone, 14-22 mg DSP, or placebo. Mean ages in each group ranged from 9.6 to 10.4 years.

In an intention-to-treat analysis, modified International Cooperative Ataxia Rating Scale (mICARS) scores trended toward improvement in the low-dose (–1.37; P = .0847) and high-dose groups (–1.40; P = .0765) when determined by central raters during the COVID-19 pandemic. There was also a trend toward improvement when determined by local raters in the low dose group (–1.73; P = .0720) and a statistically significant change in the high dose group (–2.11; P = .0277). The researchers noted some inconsistency between local and central raters, due to inconsistency of videography and language challenges for central raters.

An intention-to-treat analysis of a subgroup of 89 patients age 6-9, who were compared with natural history data from 245 patients, found a deterioration of mICARS of 3.7 per year, compared with 0.92 in the high-dose group, for a reduction of 75% (P = .020). In the high-dose group, 51.7% had a minimal or significant improvement compared with baseline according to the Clinical Global Impression of Change, as did 29.0% on low dose, and 27.6% in the placebo group.

Despite the availability of effective direct-acting antivirals, very few a mothers with opioid use disorder (OUD) and hepatitis C virus (HCV) during pregnancy received follow-up care or treatment for the infection within 6 months of giving birth, a retrospective study of Medicaid maternity patients found.

The study pooled data on 23,780 Medicaid-enrolled pregnant women with OUD who had a live or stillbirth during 2016-2019 and were followed for 6 months after delivery. Among these women – drawn from six states in the Medicaid Outcomes Distributed Research Network – the pooled average probability of HCV testing during pregnancy was 70.3% (95% confidence interval, 61.5%-79.1%). Of these, 30.9% (95% CI, 23.8%-38%) tested positive. At 60 days postpartum, just 3.2% (95% CI, 2.6%-3.8%) had a follow-up visit or treatment for HCV. In a subset of patients followed for 6 months, only 5.9% (95% CI, 4.9%-6.9%) had any HCV follow-up visit or medication within 6 months of delivery.

While HCV screening and diagnosis rates varied across states, postpartum follow-up rates were universally low. The results suggest a need to improve the cascade of postpartum care for HCV and, ultimately perhaps, introduce antenatal HCV treatment, as is currently given safely for HIV, if current clinical research establishes safety, according to Marian P. Jarlenski, PhD, MPH, an associate professor of public health policy and management at the University of Pittsburgh. The study was published in Obstetrics & Gynecology.

HCV infection has risen substantially in people of reproductive age in tandem with an increase in OUDs. HCV is transmitted from an infected mother to her baby in about 6% of cases, according to the Centers for Disease Control and Prevention, which in 2020 expanded its HCV screening recommendations to include all pregnant women. Currently no treatment for HCV during pregnancy has been approved.

In light of those recent recommendations, Dr. Jarlenski said in an interview that her group was “interested in looking at high-risk screened people and estimating what proportion received follow-up care and treatment for HCV. What is the promise of screening? The promise is that you can treat. Otherwise why screen?”

She acknowledged, however, that the postpartum period is a challenging time for a mother to seek health information or care for herself, whether she’s a new parent or has other children in the home. Nevertheless, the low rate of follow-up and treatment was unexpected. “Even the 70% rate of screening was low – we felt it should have been closer to 100% – but the follow-up rate was surprisingly low,” Dr. Jarlenski said.

Mishka Terplan, MD, MPH, medical director of Friends Research Institute in Baltimore, was not surprised at the low follow-up rate. “The cascade of care for hep C is demoralizing,” said Dr. Terplan, who was not involved in the study. “We know that hep C is syndemic with OUD and other opioid crises and we know that screening is effective for identifying hep C and that antiviral medications are now more effective and less toxic than ever before. But despite this, we’re failing pregnant women and their kids at every step along the cascade. We do a better job with initial testing than with the follow-up testing. We do a horrible job with postpartum medication initiation.”

He pointed to the systemic challenges mothers face in getting postpartum HCV care. “They may be transferred to a subspecialist for treatment, and this transfer is compounded by issues of insurance coverage and eligibility.” With the onus on new mothers to submit the paperwork, “the idea that mothers would be able to initiate much less continue postpartum treatment is absurd,” Dr. Terplan said.

He added that the children born to HCV-positive mothers need surveillance as well, but data suggest that the rates of newborn testing are also low. “There’s a preventable public health burden in all of this.”

The obvious way to increase eradicative therapy would be to treat women while they are getting antenatal care. A small phase 1 trial found that all pregnant participants who were HCV positive and given antivirals in their second trimester were safely treated and gave birth to healthy babies.

“If larger trials prove this treatment is safe and effective, then these results should be communicated to care providers and pregnant patients,” Dr. Jarlenski said. Otherwise, the public health potential of universal screening in pregnancy will not be realized.

This research was supported by the National Institute of Drug Abuse and by the Delaware Division of Medicaid and Medical Assistance and the University of Delaware, Center for Community Research & Service. Dr. Jarlenski disclosed no competing interests. One coauthor disclosed grant funding through her institution from Gilead Sciences and Organon unrelated to this work. Dr. Terplan reported no relevant competing interests.

Despite the availability of effective direct-acting antivirals, very few a mothers with opioid use disorder (OUD) and hepatitis C virus (HCV) during pregnancy received follow-up care or treatment for the infection within 6 months of giving birth, a retrospective study of Medicaid maternity patients found.

The study pooled data on 23,780 Medicaid-enrolled pregnant women with OUD who had a live or stillbirth during 2016-2019 and were followed for 6 months after delivery. Among these women – drawn from six states in the Medicaid Outcomes Distributed Research Network – the pooled average probability of HCV testing during pregnancy was 70.3% (95% confidence interval, 61.5%-79.1%). Of these, 30.9% (95% CI, 23.8%-38%) tested positive. At 60 days postpartum, just 3.2% (95% CI, 2.6%-3.8%) had a follow-up visit or treatment for HCV. In a subset of patients followed for 6 months, only 5.9% (95% CI, 4.9%-6.9%) had any HCV follow-up visit or medication within 6 months of delivery.

While HCV screening and diagnosis rates varied across states, postpartum follow-up rates were universally low. The results suggest a need to improve the cascade of postpartum care for HCV and, ultimately perhaps, introduce antenatal HCV treatment, as is currently given safely for HIV, if current clinical research establishes safety, according to Marian P. Jarlenski, PhD, MPH, an associate professor of public health policy and management at the University of Pittsburgh. The study was published in Obstetrics & Gynecology.

HCV infection has risen substantially in people of reproductive age in tandem with an increase in OUDs. HCV is transmitted from an infected mother to her baby in about 6% of cases, according to the Centers for Disease Control and Prevention, which in 2020 expanded its HCV screening recommendations to include all pregnant women. Currently no treatment for HCV during pregnancy has been approved.

In light of those recent recommendations, Dr. Jarlenski said in an interview that her group was “interested in looking at high-risk screened people and estimating what proportion received follow-up care and treatment for HCV. What is the promise of screening? The promise is that you can treat. Otherwise why screen?”

She acknowledged, however, that the postpartum period is a challenging time for a mother to seek health information or care for herself, whether she’s a new parent or has other children in the home. Nevertheless, the low rate of follow-up and treatment was unexpected. “Even the 70% rate of screening was low – we felt it should have been closer to 100% – but the follow-up rate was surprisingly low,” Dr. Jarlenski said.

Mishka Terplan, MD, MPH, medical director of Friends Research Institute in Baltimore, was not surprised at the low follow-up rate. “The cascade of care for hep C is demoralizing,” said Dr. Terplan, who was not involved in the study. “We know that hep C is syndemic with OUD and other opioid crises and we know that screening is effective for identifying hep C and that antiviral medications are now more effective and less toxic than ever before. But despite this, we’re failing pregnant women and their kids at every step along the cascade. We do a better job with initial testing than with the follow-up testing. We do a horrible job with postpartum medication initiation.”

He pointed to the systemic challenges mothers face in getting postpartum HCV care. “They may be transferred to a subspecialist for treatment, and this transfer is compounded by issues of insurance coverage and eligibility.” With the onus on new mothers to submit the paperwork, “the idea that mothers would be able to initiate much less continue postpartum treatment is absurd,” Dr. Terplan said.

He added that the children born to HCV-positive mothers need surveillance as well, but data suggest that the rates of newborn testing are also low. “There’s a preventable public health burden in all of this.”

The obvious way to increase eradicative therapy would be to treat women while they are getting antenatal care. A small phase 1 trial found that all pregnant participants who were HCV positive and given antivirals in their second trimester were safely treated and gave birth to healthy babies.

“If larger trials prove this treatment is safe and effective, then these results should be communicated to care providers and pregnant patients,” Dr. Jarlenski said. Otherwise, the public health potential of universal screening in pregnancy will not be realized.

This research was supported by the National Institute of Drug Abuse and by the Delaware Division of Medicaid and Medical Assistance and the University of Delaware, Center for Community Research & Service. Dr. Jarlenski disclosed no competing interests. One coauthor disclosed grant funding through her institution from Gilead Sciences and Organon unrelated to this work. Dr. Terplan reported no relevant competing interests.

Despite the availability of effective direct-acting antivirals, very few a mothers with opioid use disorder (OUD) and hepatitis C virus (HCV) during pregnancy received follow-up care or treatment for the infection within 6 months of giving birth, a retrospective study of Medicaid maternity patients found.

The study pooled data on 23,780 Medicaid-enrolled pregnant women with OUD who had a live or stillbirth during 2016-2019 and were followed for 6 months after delivery. Among these women – drawn from six states in the Medicaid Outcomes Distributed Research Network – the pooled average probability of HCV testing during pregnancy was 70.3% (95% confidence interval, 61.5%-79.1%). Of these, 30.9% (95% CI, 23.8%-38%) tested positive. At 60 days postpartum, just 3.2% (95% CI, 2.6%-3.8%) had a follow-up visit or treatment for HCV. In a subset of patients followed for 6 months, only 5.9% (95% CI, 4.9%-6.9%) had any HCV follow-up visit or medication within 6 months of delivery.

While HCV screening and diagnosis rates varied across states, postpartum follow-up rates were universally low. The results suggest a need to improve the cascade of postpartum care for HCV and, ultimately perhaps, introduce antenatal HCV treatment, as is currently given safely for HIV, if current clinical research establishes safety, according to Marian P. Jarlenski, PhD, MPH, an associate professor of public health policy and management at the University of Pittsburgh. The study was published in Obstetrics & Gynecology.

HCV infection has risen substantially in people of reproductive age in tandem with an increase in OUDs. HCV is transmitted from an infected mother to her baby in about 6% of cases, according to the Centers for Disease Control and Prevention, which in 2020 expanded its HCV screening recommendations to include all pregnant women. Currently no treatment for HCV during pregnancy has been approved.

In light of those recent recommendations, Dr. Jarlenski said in an interview that her group was “interested in looking at high-risk screened people and estimating what proportion received follow-up care and treatment for HCV. What is the promise of screening? The promise is that you can treat. Otherwise why screen?”

She acknowledged, however, that the postpartum period is a challenging time for a mother to seek health information or care for herself, whether she’s a new parent or has other children in the home. Nevertheless, the low rate of follow-up and treatment was unexpected. “Even the 70% rate of screening was low – we felt it should have been closer to 100% – but the follow-up rate was surprisingly low,” Dr. Jarlenski said.

Mishka Terplan, MD, MPH, medical director of Friends Research Institute in Baltimore, was not surprised at the low follow-up rate. “The cascade of care for hep C is demoralizing,” said Dr. Terplan, who was not involved in the study. “We know that hep C is syndemic with OUD and other opioid crises and we know that screening is effective for identifying hep C and that antiviral medications are now more effective and less toxic than ever before. But despite this, we’re failing pregnant women and their kids at every step along the cascade. We do a better job with initial testing than with the follow-up testing. We do a horrible job with postpartum medication initiation.”

He pointed to the systemic challenges mothers face in getting postpartum HCV care. “They may be transferred to a subspecialist for treatment, and this transfer is compounded by issues of insurance coverage and eligibility.” With the onus on new mothers to submit the paperwork, “the idea that mothers would be able to initiate much less continue postpartum treatment is absurd,” Dr. Terplan said.

He added that the children born to HCV-positive mothers need surveillance as well, but data suggest that the rates of newborn testing are also low. “There’s a preventable public health burden in all of this.”

The obvious way to increase eradicative therapy would be to treat women while they are getting antenatal care. A small phase 1 trial found that all pregnant participants who were HCV positive and given antivirals in their second trimester were safely treated and gave birth to healthy babies.

“If larger trials prove this treatment is safe and effective, then these results should be communicated to care providers and pregnant patients,” Dr. Jarlenski said. Otherwise, the public health potential of universal screening in pregnancy will not be realized.

This research was supported by the National Institute of Drug Abuse and by the Delaware Division of Medicaid and Medical Assistance and the University of Delaware, Center for Community Research & Service. Dr. Jarlenski disclosed no competing interests. One coauthor disclosed grant funding through her institution from Gilead Sciences and Organon unrelated to this work. Dr. Terplan reported no relevant competing interests.

Restless legs syndrome occurred in approximately 40% of adults with X-linked adrenoleukodystrophy, based on data from 32 individuals.

Patients with X-linked adrenoleukodystrophy (ALD), a neurodegenerative disease, often experience gait and balance problems, as well as leg discomfort, sleep disturbances, and pain, wrote John W. Winkelman, MD, of Massachusetts General Hospital, Boston, and colleagues. Restless legs syndrome (RLS) has been associated with neurological conditions including Parkinson’s disease, but the prevalence of RLS in ALD patients has not been examined, they said.

Courtesy Brigham and Women&#039;s Hospital

In a pilot study published in Sleep Medicine, the researchers identified 21 women and 11 men with ALD who were treated at a single center. The median age of the patients was 45.9 years. Twenty-seven patients had symptoms of myelopathy, with a median age of onset of 34 years.

The researchers assessed RLS severity using questionnaires and the Hopkins Telephone Diagnostic Interview (HTDI), a validated RLS assessment tool. They also reviewed patients’ charts for data on neurological examinations, functional gait measures, and laboratory assessments. Functional gait assessments included the 25-Foot Walk test (25-FW), the Timed Up and Go test (TUG), and Six Minute Walk test (6MW).

Thirteen patients (10 women and 3 men) met criteria for RLS based on the HTDI. The median age of RLS onset was 35 years. Six RLS patients (46.2%) reported using medication to relieve symptoms, and eight RLS patients had a history of antidepressant use.

In addition, six patients with RLS reported a history of anemia or iron deficiency. Ferritin levels were available for 14 patients: 8 women with RLS and 4 women and 2 men without RLS; the mean ferritin levels were 74.0 mcg/L in RLS patients and 99.5 mcg/L in those without RLS.

Of the seven ALD patients with brain lesions, all were men, only two were diagnosed with RLS, and all seven cases were mild, the researchers noted.

Overall, patients with RLS had more neurological signs and symptoms than those without RLS; the most significant were pain and gait difficulty. However, patients with RLS also were more likely than were those without RLS to report spasticity, muscle weakness, impaired coordination, hyperreflexia, impaired sensation, and paraesthesia, as well as bladder, bowel, and erectile dysfunction.

The 40.6% prevalence of RLS in patients with ALD is notably higher than that of the general population, in which the prevalence of RLS is 5%-10%, the researchers wrote in their discussion.

“Consistent with patterns observed in the general population, risk factors for RLS in this cohort of adults with ALD included female gender, increased age, lower iron indices, and use of serotonergic antidepressants,” they said.

The study findings were limited by several factors including the small size and the possible contribution of antidepressant use to the high rate of RLS, the researchers noted.

“Awareness of RLS in patients with ALD would allow for its effective treatment, which may improve the functional impairments as well as quality of life, mood, and anxiety issues in those with ALD,” they concluded.

The study received no outside funding.

Dr. Winkelman disclosed ties with Advance Medical, Avadel, Disc Medicine, Eisai, Emalex, Idorsia, Noctrix, UpToDate, and Merck Pharmaceuticals, as well as research support from the National Institute on Drug Abuse and the Baszucki Brain Research Foundation. The study also was supported by grants from the National Institute of Neurological Disorders and Stroke, the European Leukodystrophy Association, the Arrivederci Foundation, the Leblang Foundation, and the Hammer Family Fund Journal Preproof for ALD Research and Therapies for Women.

Restless legs syndrome occurred in approximately 40% of adults with X-linked adrenoleukodystrophy, based on data from 32 individuals.

Patients with X-linked adrenoleukodystrophy (ALD), a neurodegenerative disease, often experience gait and balance problems, as well as leg discomfort, sleep disturbances, and pain, wrote John W. Winkelman, MD, of Massachusetts General Hospital, Boston, and colleagues. Restless legs syndrome (RLS) has been associated with neurological conditions including Parkinson’s disease, but the prevalence of RLS in ALD patients has not been examined, they said.

Courtesy Brigham and Women&#039;s Hospital

In a pilot study published in Sleep Medicine, the researchers identified 21 women and 11 men with ALD who were treated at a single center. The median age of the patients was 45.9 years. Twenty-seven patients had symptoms of myelopathy, with a median age of onset of 34 years.

The researchers assessed RLS severity using questionnaires and the Hopkins Telephone Diagnostic Interview (HTDI), a validated RLS assessment tool. They also reviewed patients’ charts for data on neurological examinations, functional gait measures, and laboratory assessments. Functional gait assessments included the 25-Foot Walk test (25-FW), the Timed Up and Go test (TUG), and Six Minute Walk test (6MW).

Thirteen patients (10 women and 3 men) met criteria for RLS based on the HTDI. The median age of RLS onset was 35 years. Six RLS patients (46.2%) reported using medication to relieve symptoms, and eight RLS patients had a history of antidepressant use.

In addition, six patients with RLS reported a history of anemia or iron deficiency. Ferritin levels were available for 14 patients: 8 women with RLS and 4 women and 2 men without RLS; the mean ferritin levels were 74.0 mcg/L in RLS patients and 99.5 mcg/L in those without RLS.

Of the seven ALD patients with brain lesions, all were men, only two were diagnosed with RLS, and all seven cases were mild, the researchers noted.

Overall, patients with RLS had more neurological signs and symptoms than those without RLS; the most significant were pain and gait difficulty. However, patients with RLS also were more likely than were those without RLS to report spasticity, muscle weakness, impaired coordination, hyperreflexia, impaired sensation, and paraesthesia, as well as bladder, bowel, and erectile dysfunction.

The 40.6% prevalence of RLS in patients with ALD is notably higher than that of the general population, in which the prevalence of RLS is 5%-10%, the researchers wrote in their discussion.

“Consistent with patterns observed in the general population, risk factors for RLS in this cohort of adults with ALD included female gender, increased age, lower iron indices, and use of serotonergic antidepressants,” they said.

The study findings were limited by several factors including the small size and the possible contribution of antidepressant use to the high rate of RLS, the researchers noted.

“Awareness of RLS in patients with ALD would allow for its effective treatment, which may improve the functional impairments as well as quality of life, mood, and anxiety issues in those with ALD,” they concluded.

The study received no outside funding.

Dr. Winkelman disclosed ties with Advance Medical, Avadel, Disc Medicine, Eisai, Emalex, Idorsia, Noctrix, UpToDate, and Merck Pharmaceuticals, as well as research support from the National Institute on Drug Abuse and the Baszucki Brain Research Foundation. The study also was supported by grants from the National Institute of Neurological Disorders and Stroke, the European Leukodystrophy Association, the Arrivederci Foundation, the Leblang Foundation, and the Hammer Family Fund Journal Preproof for ALD Research and Therapies for Women.

Restless legs syndrome occurred in approximately 40% of adults with X-linked adrenoleukodystrophy, based on data from 32 individuals.

Patients with X-linked adrenoleukodystrophy (ALD), a neurodegenerative disease, often experience gait and balance problems, as well as leg discomfort, sleep disturbances, and pain, wrote John W. Winkelman, MD, of Massachusetts General Hospital, Boston, and colleagues. Restless legs syndrome (RLS) has been associated with neurological conditions including Parkinson’s disease, but the prevalence of RLS in ALD patients has not been examined, they said.

Courtesy Brigham and Women&#039;s Hospital

In a pilot study published in Sleep Medicine, the researchers identified 21 women and 11 men with ALD who were treated at a single center. The median age of the patients was 45.9 years. Twenty-seven patients had symptoms of myelopathy, with a median age of onset of 34 years.

The researchers assessed RLS severity using questionnaires and the Hopkins Telephone Diagnostic Interview (HTDI), a validated RLS assessment tool. They also reviewed patients’ charts for data on neurological examinations, functional gait measures, and laboratory assessments. Functional gait assessments included the 25-Foot Walk test (25-FW), the Timed Up and Go test (TUG), and Six Minute Walk test (6MW).

Thirteen patients (10 women and 3 men) met criteria for RLS based on the HTDI. The median age of RLS onset was 35 years. Six RLS patients (46.2%) reported using medication to relieve symptoms, and eight RLS patients had a history of antidepressant use.

In addition, six patients with RLS reported a history of anemia or iron deficiency. Ferritin levels were available for 14 patients: 8 women with RLS and 4 women and 2 men without RLS; the mean ferritin levels were 74.0 mcg/L in RLS patients and 99.5 mcg/L in those without RLS.

Of the seven ALD patients with brain lesions, all were men, only two were diagnosed with RLS, and all seven cases were mild, the researchers noted.

Overall, patients with RLS had more neurological signs and symptoms than those without RLS; the most significant were pain and gait difficulty. However, patients with RLS also were more likely than were those without RLS to report spasticity, muscle weakness, impaired coordination, hyperreflexia, impaired sensation, and paraesthesia, as well as bladder, bowel, and erectile dysfunction.

The 40.6% prevalence of RLS in patients with ALD is notably higher than that of the general population, in which the prevalence of RLS is 5%-10%, the researchers wrote in their discussion.

“Consistent with patterns observed in the general population, risk factors for RLS in this cohort of adults with ALD included female gender, increased age, lower iron indices, and use of serotonergic antidepressants,” they said.

The study findings were limited by several factors including the small size and the possible contribution of antidepressant use to the high rate of RLS, the researchers noted.

“Awareness of RLS in patients with ALD would allow for its effective treatment, which may improve the functional impairments as well as quality of life, mood, and anxiety issues in those with ALD,” they concluded.

The study received no outside funding.

Dr. Winkelman disclosed ties with Advance Medical, Avadel, Disc Medicine, Eisai, Emalex, Idorsia, Noctrix, UpToDate, and Merck Pharmaceuticals, as well as research support from the National Institute on Drug Abuse and the Baszucki Brain Research Foundation. The study also was supported by grants from the National Institute of Neurological Disorders and Stroke, the European Leukodystrophy Association, the Arrivederci Foundation, the Leblang Foundation, and the Hammer Family Fund Journal Preproof for ALD Research and Therapies for Women.

Individuals with a prior diagnosis of pneumonia were significantly more likely to develop chronic otitis media (COM) than were those without a history of pneumonia, based on data from a nationwide cohort study of more than 100,000 patients.

“Recently, middle ear diseases, including COM, have been recognized as respiratory tract diseases beyond the pathophysiological concepts of ventilation dysfunction, with recurrent infection that occurs from anatomically adjacent structures such as the middle ear, mastoid cavity, and eustachian tube,” but the potential link between pneumonia and chronic otitis media and adults in particular has not been examined, wrote Sung Kyun Kim, MD, of Hallym University, Dongtan, South Korea, and colleagues.

In a study recently published in the International Journal of Infectious Diseases, the researchers identified 23,436 adults with COM and 93,744 controls aged 40 years and older from a Korean health insurance database between 2002 and 2015.

The overall incidence of pneumonia in the study population was significantly higher in the COM group compared with controls (9.3% vs. 7.2%, P <.001). The odds ratios of pneumonia were significantly higher in the COM group compared with controls, and a history of pneumonia increased the odds of COM regardless of sex and across all ages.

Pneumonia was defined as when a patient had a diagnosis of pneumonia based on ICD-10 codes and underwent a chest x-ray or chest CT scan. Chronic otitis media was defined as when a patient had a diagnosis based on ICD-10 codes at least two times with one of the following conditions: chronic serous otitis media, chronic mucoid otitis media, other chronic nonsuppurative otitis media, unspecified nonsuppurative otitis media, chronic tubotympanic suppurative otitis media, chronic atticoantral suppurative otitis media, other chronic suppurative otitis media, or unspecified suppurative otitis media.

Age groups were divided into 5-year intervals, and patients were classified into income groups and rural vs. urban residence.

In a further sensitivity analysis, individuals who were diagnosed with pneumonia five or more times before the index date had a significantly higher odds ratio for COM compared with those with less than five diagnoses of pneumonia (adjusted odds ratio, 1.34; P < .001).

Microbiome dysbiosis may explain part of the connection between pneumonia and COM, the researchers wrote in their discussion. Pathogens in the lungs can prompt changes in the microbiome dynamics, as might the use of antibiotics, they said. In addition, “Mucus plugging in the airway caused by pneumonia induces hypoxic conditions and leads to the expression of inflammatory markers in the eustachian tube and middle ear mucosa,” they noted.

The study findings were limited by several factors, including the retrospective design and lack of data on microbiological cultures for antibiotic susceptibility, radiologic findings on the severity of pneumonia, results of pulmonary function tests, and hearing thresholds, the researchers noted. Other limitations were the exclusion of the frequency of upper respiratory infections and antibiotic use due to lack of data, they said.

However, the results show an association between pneumonia diagnoses and increased incidence of COM, which suggests a novel perspective that “infection of the lower respiratory tract may affect the function of the eustachian tube and the middle ear to later cause COM,” they concluded.

The study received no outside funding. The researchers have disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Individuals with a prior diagnosis of pneumonia were significantly more likely to develop chronic otitis media (COM) than were those without a history of pneumonia, based on data from a nationwide cohort study of more than 100,000 patients.

“Recently, middle ear diseases, including COM, have been recognized as respiratory tract diseases beyond the pathophysiological concepts of ventilation dysfunction, with recurrent infection that occurs from anatomically adjacent structures such as the middle ear, mastoid cavity, and eustachian tube,” but the potential link between pneumonia and chronic otitis media and adults in particular has not been examined, wrote Sung Kyun Kim, MD, of Hallym University, Dongtan, South Korea, and colleagues.

In a study recently published in the International Journal of Infectious Diseases, the researchers identified 23,436 adults with COM and 93,744 controls aged 40 years and older from a Korean health insurance database between 2002 and 2015.

The overall incidence of pneumonia in the study population was significantly higher in the COM group compared with controls (9.3% vs. 7.2%, P <.001). The odds ratios of pneumonia were significantly higher in the COM group compared with controls, and a history of pneumonia increased the odds of COM regardless of sex and across all ages.

Pneumonia was defined as when a patient had a diagnosis of pneumonia based on ICD-10 codes and underwent a chest x-ray or chest CT scan. Chronic otitis media was defined as when a patient had a diagnosis based on ICD-10 codes at least two times with one of the following conditions: chronic serous otitis media, chronic mucoid otitis media, other chronic nonsuppurative otitis media, unspecified nonsuppurative otitis media, chronic tubotympanic suppurative otitis media, chronic atticoantral suppurative otitis media, other chronic suppurative otitis media, or unspecified suppurative otitis media.

Age groups were divided into 5-year intervals, and patients were classified into income groups and rural vs. urban residence.

In a further sensitivity analysis, individuals who were diagnosed with pneumonia five or more times before the index date had a significantly higher odds ratio for COM compared with those with less than five diagnoses of pneumonia (adjusted odds ratio, 1.34; P < .001).

Microbiome dysbiosis may explain part of the connection between pneumonia and COM, the researchers wrote in their discussion. Pathogens in the lungs can prompt changes in the microbiome dynamics, as might the use of antibiotics, they said. In addition, “Mucus plugging in the airway caused by pneumonia induces hypoxic conditions and leads to the expression of inflammatory markers in the eustachian tube and middle ear mucosa,” they noted.

The study findings were limited by several factors, including the retrospective design and lack of data on microbiological cultures for antibiotic susceptibility, radiologic findings on the severity of pneumonia, results of pulmonary function tests, and hearing thresholds, the researchers noted. Other limitations were the exclusion of the frequency of upper respiratory infections and antibiotic use due to lack of data, they said.

However, the results show an association between pneumonia diagnoses and increased incidence of COM, which suggests a novel perspective that “infection of the lower respiratory tract may affect the function of the eustachian tube and the middle ear to later cause COM,” they concluded.

The study received no outside funding. The researchers have disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Individuals with a prior diagnosis of pneumonia were significantly more likely to develop chronic otitis media (COM) than were those without a history of pneumonia, based on data from a nationwide cohort study of more than 100,000 patients.

“Recently, middle ear diseases, including COM, have been recognized as respiratory tract diseases beyond the pathophysiological concepts of ventilation dysfunction, with recurrent infection that occurs from anatomically adjacent structures such as the middle ear, mastoid cavity, and eustachian tube,” but the potential link between pneumonia and chronic otitis media and adults in particular has not been examined, wrote Sung Kyun Kim, MD, of Hallym University, Dongtan, South Korea, and colleagues.

In a study recently published in the International Journal of Infectious Diseases, the researchers identified 23,436 adults with COM and 93,744 controls aged 40 years and older from a Korean health insurance database between 2002 and 2015.

The overall incidence of pneumonia in the study population was significantly higher in the COM group compared with controls (9.3% vs. 7.2%, P <.001). The odds ratios of pneumonia were significantly higher in the COM group compared with controls, and a history of pneumonia increased the odds of COM regardless of sex and across all ages.

Pneumonia was defined as when a patient had a diagnosis of pneumonia based on ICD-10 codes and underwent a chest x-ray or chest CT scan. Chronic otitis media was defined as when a patient had a diagnosis based on ICD-10 codes at least two times with one of the following conditions: chronic serous otitis media, chronic mucoid otitis media, other chronic nonsuppurative otitis media, unspecified nonsuppurative otitis media, chronic tubotympanic suppurative otitis media, chronic atticoantral suppurative otitis media, other chronic suppurative otitis media, or unspecified suppurative otitis media.

Age groups were divided into 5-year intervals, and patients were classified into income groups and rural vs. urban residence.

In a further sensitivity analysis, individuals who were diagnosed with pneumonia five or more times before the index date had a significantly higher odds ratio for COM compared with those with less than five diagnoses of pneumonia (adjusted odds ratio, 1.34; P < .001).

Microbiome dysbiosis may explain part of the connection between pneumonia and COM, the researchers wrote in their discussion. Pathogens in the lungs can prompt changes in the microbiome dynamics, as might the use of antibiotics, they said. In addition, “Mucus plugging in the airway caused by pneumonia induces hypoxic conditions and leads to the expression of inflammatory markers in the eustachian tube and middle ear mucosa,” they noted.

The study findings were limited by several factors, including the retrospective design and lack of data on microbiological cultures for antibiotic susceptibility, radiologic findings on the severity of pneumonia, results of pulmonary function tests, and hearing thresholds, the researchers noted. Other limitations were the exclusion of the frequency of upper respiratory infections and antibiotic use due to lack of data, they said.

However, the results show an association between pneumonia diagnoses and increased incidence of COM, which suggests a novel perspective that “infection of the lower respiratory tract may affect the function of the eustachian tube and the middle ear to later cause COM,” they concluded.

The study received no outside funding. The researchers have disclosed no relevant financial relationships.

A version of this article first appeared on Medscape.com.

The medicated intrauterine devices (IUDs), including the levonorgestrel-releasing IUD (LNG-IUD) (Mirena, Kyleena, Skyla, and Liletta) and the copper IUD (Cu-IUD; Paragard), are remarkably effective contraceptives. For the 52-mg LNG-IUD (Mirena, Liletta) the pregnancy rate over 6 years of use averaged less than 0.2% per year.^1,2 For the Cu-IUD, the pregnancy rate over 10 years of use averaged 0.5% per year for the first 3 years of use and 0.2% per year over the following 7 years of use.³ IUD perforation of the uterus, expulsion, and malposition are recognized complications of IUD use. Our understanding of the prevalence and management of malpositioned IUDs is evolving and the main focus of this editorial.

Complete and partial uterus perforation

A complete uterine perforation occurs when the entire IUD is outside the walls of the uterus. A partial uterine perforation occurs when the IUD is outside the uterine cavity, but a portion of the IUD remains in the myometrium. When uterine perforation is suspected, ultrasound can determine if the IUD is properly sited within the uterus. If ultrasonography does not detect the IUD within the uterus, an x-ray of the pelvis and abdomen should be obtained to determine if the IUD is in the peritoneal cavity. If both an ultrasound and a pelvic-abdominal x-ray do not detect the IUD, the IUD was probably expelled from the patient.

Uterine perforation is uncommon and occurs once in every 500 to 1,000 insertions in non-breastfeeding women.^4-8 The most common symptoms reported by patients with a perforated IUD are pain and/or bleeding.⁸ Investigators in the European Active Surveillance Study on Intrauterine Devices (EURAS) enrolled more than 60,000 patients who had an IUD insertion and followed them for 12 months with more than 39,000 followed for up to 60 months.^7,8 The uterine perforation rate per 1,000 IUD insertions in non-breastfeeding women with 60 months of follow-up was 1.6 for the LNG-IUD and 0.8 for the Cu-IUD.⁸ The rate of uterine perforation was much higher in women who are breastfeeding or recently postpartum. In the EURAS study after 60 months of follow-up, the perforation rate per 1,000 insertions among breastfeeding women was 7.9 for the LNG-IUS and 4.7 for the Cu-IUD.⁸

Remarkably very few IUD perforations were detected at the time of insertion, including only 2% of the LNG-IUD insertions and 17% of the Cu-IUD insertions.⁸ Many perforations were not detected until more than 12 months following insertion, including 32% of the LNG-IUD insertions and 22% of the Cu-IUD insertions.⁸ Obviously, an IUD that has completely perforated the uterus and resides in the peritoneal cavity is not an effective contraceptive. For some patients, the IUD perforation was initially diagnosed after they became pregnant, and imaging studies to locate the IUD and assess the pregnancy were initiated. Complete perforation is usually treated with laparoscopy to remove the IUD and reduce the risk of injury to intra-abdominal organs.

Patients with an IUD partial perforation may present with pelvic pain or abnormal uterine bleeding.⁹ An ultrasound study to explore the cause of the presenting symptom may detect the partial perforation. It is estimated that approximately 20% of cases of IUD perforation are partial perforation.⁹ Over time, a partial perforation may progress to a complete perforation. In some cases of partial perforation, the IUD string may still be visible in the cervix, and the IUD may be removed by pulling on the strings.⁸ Hysteroscopy and/or laparoscopy may be needed to remove a partially perforated IUD. Following a partial or complete IUD perforation, if the patient desires to continue with IUD contraception, it would be wise to insert a new IUD under ultrasound guidance or assess proper placement with a postplacement ultrasound.

Continue to: Expulsion...

IUD expulsion occurs in approximately 3% to 11% of patients.^10-13 The age of the patient influences the rate of expulsion. In a study of 2,748 patients with a Cu-IUD, the rate of expulsion by age for patients <20 years, 20–24 years, 25–29 years, 30–34 years, and ≥35 years was 8.2%, 3.2%, 3.0%, 2.3%, and 1.8%, respectively.¹⁰ In this study, age did not influence the rate of IUD removal for pelvic pain or abnormal bleeding, which was 4% to 5% across all age groups.¹⁰ In a study of 5,403 patients with an IUD, the rate of IUD expulsion by age for patients <20 years, 20–29 years, and 30–45 years was 14.6%, 7.3%, and 7.2%, respectively.¹² In this study, the 3-year cumulative rate of expulsion was 10.2%.¹² There was no statistically significant difference in the 3-year cumulative rate of expulsion for the 52-mg LNG-IUD (10.1%) and Cu-IUD (10.7%).¹²

The majority of patients who have an IUD expulsion recognize the event and seek additional contraception care. A few patients first recognize the IUD expulsion when they become pregnant, and imaging studies detect no IUD in the uterus or the peritoneal cavity. In a study of more than 17,000 patients using an LNG-IUD, 108 pregnancies were reported. Seven pregnancies occurred in patients who did not realize their IUD was expelled.¹⁴ Patients who have had an IUD expulsion and receive a new IUD are at increased risk for re-expulsion. For these patients, reinsertion of an IUD could be performed under ultrasound guidance to ensure and document optimal initial IUD position within the uterus, or ultrasound can be obtained postinsertion to document appropriate IUD position.

Malposition—prevalence and management

Our understanding of the prevalence and management of a malpositioned IUD is evolving. For the purposes of this discussion a malpositioned IUD is defined as being in the uterus, but not properly positioned within the uterine cavity. Perforation into the peritoneal cavity and complete expulsion of an IUD are considered separate entities. However, a malpositioned IUD within the uterus may eventually perforate the uterus or be expelled from the body. For example, an IUD embedded in the uterine wall may eventually work its way through the wall and become perforated, residing in the peritoneal cavity. An IUD with the stem in the cervix below the internal os may eventually be expelled from the uterus and leave the body through the vagina.

High-quality ultrasonography, including 2-dimensional (2-D) ultrasound with videoclips or 3-dimensional (3-D) ultrasound with coronal views, has greatly advanced our understanding of the prevalence and characteristics of a malpositioned IUD.^15-18 Ultrasound features of an IUD correctly placed within the uterus include:

• the IUD is in the uterus
• the shaft is in the midline of the uterine cavity
• the shaft of the IUD is not in the endocervix
• the IUD arms are at a 90-degree angle from the shaft
• the top of the IUD is within 2 cm of the fundus
• the IUD is not rotated outside of the cornual plane, inverted or transverse.

Ultrasound imaging has identified multiple types of malpositioned IUDs, including:

• IUD embedded in the myometrium—a portion of the IUD is embedded in the uterine wall
• low-lying IUD—the IUD is low in the uterine cavity but not in the endocervix
• IUD in the endocervix—the stem is in the endocervical canal
• rotated—the IUD is rotated outside the cornual plane
• malpositioned arms—the arms are not at a 90-degree angle to the stem
• the IUD is inverted, transverse, or laterally displaced.

IUD malposition is highly prevalent and has been identified in 10% to 20% of convenience cohorts in which an ultrasound study was performed.^15-18

Benacerraf, Shipp, and Bromley were among the first experts to use ultrasound to detect the high prevalence of malpositioned IUDs among a convenience sample of 167 patients with an IUD undergoing ultrasound for a variety of indications. Using 3-D ultrasound, including reconstructed coronal views, they identified 28 patients (17%) with a malpositioned IUD based on the detection of the IUD “poking into the substance of the uterus or cervix.” Among the patients with a malpositioned IUD, the principal indication for the ultrasound study was pelvic pain (39%) or abnormal uterine bleeding (36%). Among women with a normally sited IUD, pelvic pain (19%) or abnormal uterine bleeding (15%) were less often the principal indication for the ultrasound.¹⁵ The malpositioned IUD was removed in 21 of the 28 cases and the symptoms of pelvic pain or abnormal bleeding resolved in 20 of the 21 patients.¹⁵

Other investigators have confirmed the observation that IUD malposition is common.^16-18 In a retrospective study of 1,748 pelvic ultrasounds performed for any indication where an IUD was present, after excluding 13 patients who were determined to have expelled their IUD (13) and 13 patients with a perforated IUD, 156 patients (8.9%) were diagnosed as having a malpositioned IUD.¹⁶ IUD malposition was diagnosed when the IUD was in the uterus but positioned in the lower uterine segment, cervix, rotated or embedded in the uterus. An IUD in the lower uterine segment or cervix was detected in 133 patients, representing 85% of cases. Among these cases, 29 IUDs were also embedded and/or rotated, indicating that some IUDs have multiple causes of the malposition. Twenty-one IUDs were near the fundus but embedded and/or rotated. Controls with a normally-sited IUD were selected for comparison to the case group. Among IUD users, the identification of suspected adenomyosis on the ultrasound was associated with an increased risk of IUD malposition (odds ratio [OR], 3.04; 95% confidence interval [CI], 1.08-8.52).¹⁶ In this study, removal of a malpositioned LNG-IUD, without initiating a highly reliable contraceptive was associated with an increased risk of pregnancy. It is important to initiate a highly reliable form of contraception if the plan is to remove a malpositioned IUD.^16,19

In a study of 1,253 pelvic ultrasounds performed for any indication where an IUD was identified in the uterus, 263 IUDs (19%) were determined to be malpositioned.¹⁷ In this study the location of the malpositioned IUDs included¹⁷:

• the lower uterine segment not extending into the cervix (38%)
• in the lower uterine segment extending into the cervix (22%)
• in the cervix (26%)
• rotated axis of the IUD (12%)
• other (2%).

Among the 236 malpositioned IUDs, 24% appeared to be embedded in the uterine wall.¹⁷ Compared with patients with a normally-sited IUD on ultrasound, patients with a malpositioned IUD more frequently reported vaginal bleeding (30% vs 19%; P<.005) and pelvic pain (43% vs 30%; P<.002), similar to the findings in the Benacerraf et al. study.¹⁴

Connolly and Fox¹⁸ designed an innovative study to determine the rate of malpositioned IUDs using 2-D ultrasound to ensure proper IUD placement at the time of insertion with a follow-up 3-D ultrasound 8 weeks after insertion to assess IUD position within the uterus. At the 8-week 3-D ultrasound, among 763 women, 16.6% of the IUDs were malpositioned.¹⁸ In this study, IUD position was determined to be correct if all the following features were identified:

• the IUD shaft was in the midline of the uterine cavity
• the IUD arms were at 90 degrees from the stem
• the top of the IUD was within 3 to 4 mm of the fundus
• the IUD was not rotated, inverted or transverse.

IUD malpositions were categorized as:

• embedded in the uterine wall
• low in the uterine cavity
• in the endocervical canal
• misaligned
• perforated
• expulsed.

At the 8-week follow-up, 636 patients (83.4%) had an IUD that was correctly positioned.¹⁸ In 127 patients (16.6%) IUD malposition was identified, with some patients having more than one type of malposition. The types of malposition identified were:

• embedded in the myometrium (54%)
• misaligned, including rotated, laterally displaced, inverted, transverse or arms not deployed (47%)
• low in the uterine cavity (39%)
• in the endocervical canal (14%)
• perforated (3%)
• expulsion (0%).

Recall that all of these patients had a 2-D ultrasound at the time of insertion that identified the IUD as correctly placed. This suggests that during the 8 weeks following IUD placement there were changes in the location of the IUD or that 2-D ultrasound has lower sensitivity than 3-D ultrasound to detect malposition. Of note, at the 8-week follow-up, bleeding or pain was reported by 36% of the patients with a malpositioned IUD and 20% of patients with a correctly positioned IUD.¹⁷ Sixty-seven of the 127 malpositioned IUDs “required” removal, but the precise reasons for the removals were not delineated. The investigators concluded that 3-D ultrasonography is useful for the detection of IUD malposition and could be considered as part of ongoing IUD care, if symptoms of pain or bleeding occur.¹⁸

Continue to: IUD malposition following postplacental insertion...

IUD malposition following postplacental insertion

IUD malposition is common in patients who have had a postplacental insertion. Ultrasound imaging plays an important role in detecting IUD expulsion and malposition in these cases. Postplacental IUD insertion is defined as the placement of an IUD within 10 minutes following delivery of the placenta. Postplacental IUD insertion can be performed following a vaginal or cesarean birth and with a Cu-IUD or LNG-IUD. The good news is that postplacental IUD insertion reduces the risk of unplanned pregnancy in the years following birth. However, postplacental IUD insertion is associated with a high rate of IUD malposition.

In a study of 162 patients who had postplacental insertion of a Cu-IUD following a vaginal birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 8%, partial expulsion in 16%, and malposition in 15%.²⁰ The IUD was correctly sited in 56% of patients. Seven patients (4%) had the IUD removed, and 1 patient had a perforated IUD. Among the 25 malpositioned IUDs, 14 were not within 1 cm of the fundus, and 11 were rotated outside of the axis of the cornuas. In this study partial expulsion was defined as an IUD protruding from the external cervical os on physical exam or demonstration of the distal tip of the IUD below the internal os of the cervix on ultrasound. Malposition was defined as an IUD that was >1 cm from the fundus or in an abnormal location or axis, but not partially expelled.

In a study of 69 patients who had postplacental insertion of a Cu-IUD following a cesarean birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 3%, partial expulsion (stem in the cervix below the internal os) in 4% and malposition in 30%.²⁰ The IUD was correctly positioned in 59% of the patients.²¹ The IUD had been electively removed in 3%. Among the 21 patients with a malpositioned IUD, 10 were rotated within the uterine cavity, 6 were inverted (upside down), 3 were low-lying, and 2 were transverse.²¹ Given the relatively high rate of IUD malposition following postplacental insertion, it may be useful to perform a pelvic ultrasound at a postpartum visit to assess the location of the IUD, if ultrasonography is available.

Management of the malpositioned IUD

There are no consensus guidelines on how to care for a patient with a malpositioned IUD. Clinicians need to use their best judgment and engage the patient in joint decision making when managing a malpositioned IUD. When an IUD is malpositioned and the patient has bothersome symptoms of pelvic pain or abnormal bleeding that have not responded to standard interventions, consideration may be given to a remove and replace strategy. When the stem of the IUD is below the level of the internal os on ultrasound or visible at the external os on physical examination, consideration should be given to removing and replacing the IUD. However, if the IUD is removed without replacement or the initiation of a highly reliable contraceptive, the risk of unplanned pregnancy is considerable.^16,19

IUD totally or partially within the cervix or low-lying. When an IUD is in the cervix, the contraceptive efficacy of the IUD may be diminished, especially with a Cu-IUD.²² In these cases, removing and replacing the IUD is an option. In a survey of 20 expert clinicians, >80% recommended replacing an IUD that was totally or partially in the cervical canal.²³ But most of the experts would not replace an IUD that was incidentally noted on ultrasound to be low-lying, being positioned more than 2 cm below the fundus, with no portion of the IUD in the cervical canal. In the same survey, for patients with a low-lying IUD and pelvic pain or bleeding, the majority of experts reported that they would explore other causes of bleeding and pelvic pain not related to the IUD itself and not replace the IUD, but 30% of the experts reported that they would remove and replace the device.²³

IUD embedded in the myometrium with pelvic pain. Based on my clinical experience, when a patient has persistent pelvic pain following the insertion of an IUD and the pain does not resolve with standard measures including medication, an ultrasound study is warranted to assess the position of the IUD. If the ultrasound demonstrates that an arm of the IUD is embedded in the myometrium, removal of the IUD may be associated with resolution of the pain. Reinsertion of an IUD under ultrasound guidance may result in a correctly-sited IUD with no recurrence of pelvic pain.

IUD rotated within the uterus with no pain or abnormal bleeding. For an IUD that is near the fundus and rotated on its axis within the uterus, if the patient has no symptoms of pain or abnormal bleeding, my recommendation to the patient would be to leave the device in situ.

Without available guidelines, engage in clinician-patient discussion

It is clear that IUD malposition is common, occurring in 10% to 20% of patients with an IUD. High-quality ultrasound imaging is helpful in detecting IUD malposition, including 2-D ultrasound with videoclips and/or 3-D ultrasound with coronal reconstruction. More data are needed to identify the best options for managing various types of malpositioned IUDs in patients with and without bothersome symptoms such as pain and bleeding. Until consensus guidelines are developed, clinicians need to engage the patient in a discussion of how to best manage the malpositioned IUD. Medicated IUDs and progestin subdermal implants are our two most effective reversible contraceptives. They are among the most important advances in health care over the past half-century. ●

The medicated intrauterine devices (IUDs), including the levonorgestrel-releasing IUD (LNG-IUD) (Mirena, Kyleena, Skyla, and Liletta) and the copper IUD (Cu-IUD; Paragard), are remarkably effective contraceptives. For the 52-mg LNG-IUD (Mirena, Liletta) the pregnancy rate over 6 years of use averaged less than 0.2% per year.^1,2 For the Cu-IUD, the pregnancy rate over 10 years of use averaged 0.5% per year for the first 3 years of use and 0.2% per year over the following 7 years of use.³ IUD perforation of the uterus, expulsion, and malposition are recognized complications of IUD use. Our understanding of the prevalence and management of malpositioned IUDs is evolving and the main focus of this editorial.

Complete and partial uterus perforation

A complete uterine perforation occurs when the entire IUD is outside the walls of the uterus. A partial uterine perforation occurs when the IUD is outside the uterine cavity, but a portion of the IUD remains in the myometrium. When uterine perforation is suspected, ultrasound can determine if the IUD is properly sited within the uterus. If ultrasonography does not detect the IUD within the uterus, an x-ray of the pelvis and abdomen should be obtained to determine if the IUD is in the peritoneal cavity. If both an ultrasound and a pelvic-abdominal x-ray do not detect the IUD, the IUD was probably expelled from the patient.

Uterine perforation is uncommon and occurs once in every 500 to 1,000 insertions in non-breastfeeding women.^4-8 The most common symptoms reported by patients with a perforated IUD are pain and/or bleeding.⁸ Investigators in the European Active Surveillance Study on Intrauterine Devices (EURAS) enrolled more than 60,000 patients who had an IUD insertion and followed them for 12 months with more than 39,000 followed for up to 60 months.^7,8 The uterine perforation rate per 1,000 IUD insertions in non-breastfeeding women with 60 months of follow-up was 1.6 for the LNG-IUD and 0.8 for the Cu-IUD.⁸ The rate of uterine perforation was much higher in women who are breastfeeding or recently postpartum. In the EURAS study after 60 months of follow-up, the perforation rate per 1,000 insertions among breastfeeding women was 7.9 for the LNG-IUS and 4.7 for the Cu-IUD.⁸

Remarkably very few IUD perforations were detected at the time of insertion, including only 2% of the LNG-IUD insertions and 17% of the Cu-IUD insertions.⁸ Many perforations were not detected until more than 12 months following insertion, including 32% of the LNG-IUD insertions and 22% of the Cu-IUD insertions.⁸ Obviously, an IUD that has completely perforated the uterus and resides in the peritoneal cavity is not an effective contraceptive. For some patients, the IUD perforation was initially diagnosed after they became pregnant, and imaging studies to locate the IUD and assess the pregnancy were initiated. Complete perforation is usually treated with laparoscopy to remove the IUD and reduce the risk of injury to intra-abdominal organs.

Patients with an IUD partial perforation may present with pelvic pain or abnormal uterine bleeding.⁹ An ultrasound study to explore the cause of the presenting symptom may detect the partial perforation. It is estimated that approximately 20% of cases of IUD perforation are partial perforation.⁹ Over time, a partial perforation may progress to a complete perforation. In some cases of partial perforation, the IUD string may still be visible in the cervix, and the IUD may be removed by pulling on the strings.⁸ Hysteroscopy and/or laparoscopy may be needed to remove a partially perforated IUD. Following a partial or complete IUD perforation, if the patient desires to continue with IUD contraception, it would be wise to insert a new IUD under ultrasound guidance or assess proper placement with a postplacement ultrasound.

Continue to: Expulsion...

IUD expulsion occurs in approximately 3% to 11% of patients.^10-13 The age of the patient influences the rate of expulsion. In a study of 2,748 patients with a Cu-IUD, the rate of expulsion by age for patients <20 years, 20–24 years, 25–29 years, 30–34 years, and ≥35 years was 8.2%, 3.2%, 3.0%, 2.3%, and 1.8%, respectively.¹⁰ In this study, age did not influence the rate of IUD removal for pelvic pain or abnormal bleeding, which was 4% to 5% across all age groups.¹⁰ In a study of 5,403 patients with an IUD, the rate of IUD expulsion by age for patients <20 years, 20–29 years, and 30–45 years was 14.6%, 7.3%, and 7.2%, respectively.¹² In this study, the 3-year cumulative rate of expulsion was 10.2%.¹² There was no statistically significant difference in the 3-year cumulative rate of expulsion for the 52-mg LNG-IUD (10.1%) and Cu-IUD (10.7%).¹²

The majority of patients who have an IUD expulsion recognize the event and seek additional contraception care. A few patients first recognize the IUD expulsion when they become pregnant, and imaging studies detect no IUD in the uterus or the peritoneal cavity. In a study of more than 17,000 patients using an LNG-IUD, 108 pregnancies were reported. Seven pregnancies occurred in patients who did not realize their IUD was expelled.¹⁴ Patients who have had an IUD expulsion and receive a new IUD are at increased risk for re-expulsion. For these patients, reinsertion of an IUD could be performed under ultrasound guidance to ensure and document optimal initial IUD position within the uterus, or ultrasound can be obtained postinsertion to document appropriate IUD position.

Malposition—prevalence and management

Our understanding of the prevalence and management of a malpositioned IUD is evolving. For the purposes of this discussion a malpositioned IUD is defined as being in the uterus, but not properly positioned within the uterine cavity. Perforation into the peritoneal cavity and complete expulsion of an IUD are considered separate entities. However, a malpositioned IUD within the uterus may eventually perforate the uterus or be expelled from the body. For example, an IUD embedded in the uterine wall may eventually work its way through the wall and become perforated, residing in the peritoneal cavity. An IUD with the stem in the cervix below the internal os may eventually be expelled from the uterus and leave the body through the vagina.

High-quality ultrasonography, including 2-dimensional (2-D) ultrasound with videoclips or 3-dimensional (3-D) ultrasound with coronal views, has greatly advanced our understanding of the prevalence and characteristics of a malpositioned IUD.^15-18 Ultrasound features of an IUD correctly placed within the uterus include:

• the IUD is in the uterus
• the shaft is in the midline of the uterine cavity
• the shaft of the IUD is not in the endocervix
• the IUD arms are at a 90-degree angle from the shaft
• the top of the IUD is within 2 cm of the fundus
• the IUD is not rotated outside of the cornual plane, inverted or transverse.

Ultrasound imaging has identified multiple types of malpositioned IUDs, including:

• IUD embedded in the myometrium—a portion of the IUD is embedded in the uterine wall
• low-lying IUD—the IUD is low in the uterine cavity but not in the endocervix
• IUD in the endocervix—the stem is in the endocervical canal
• rotated—the IUD is rotated outside the cornual plane
• malpositioned arms—the arms are not at a 90-degree angle to the stem
• the IUD is inverted, transverse, or laterally displaced.

IUD malposition is highly prevalent and has been identified in 10% to 20% of convenience cohorts in which an ultrasound study was performed.^15-18

Benacerraf, Shipp, and Bromley were among the first experts to use ultrasound to detect the high prevalence of malpositioned IUDs among a convenience sample of 167 patients with an IUD undergoing ultrasound for a variety of indications. Using 3-D ultrasound, including reconstructed coronal views, they identified 28 patients (17%) with a malpositioned IUD based on the detection of the IUD “poking into the substance of the uterus or cervix.” Among the patients with a malpositioned IUD, the principal indication for the ultrasound study was pelvic pain (39%) or abnormal uterine bleeding (36%). Among women with a normally sited IUD, pelvic pain (19%) or abnormal uterine bleeding (15%) were less often the principal indication for the ultrasound.¹⁵ The malpositioned IUD was removed in 21 of the 28 cases and the symptoms of pelvic pain or abnormal bleeding resolved in 20 of the 21 patients.¹⁵

Other investigators have confirmed the observation that IUD malposition is common.^16-18 In a retrospective study of 1,748 pelvic ultrasounds performed for any indication where an IUD was present, after excluding 13 patients who were determined to have expelled their IUD (13) and 13 patients with a perforated IUD, 156 patients (8.9%) were diagnosed as having a malpositioned IUD.¹⁶ IUD malposition was diagnosed when the IUD was in the uterus but positioned in the lower uterine segment, cervix, rotated or embedded in the uterus. An IUD in the lower uterine segment or cervix was detected in 133 patients, representing 85% of cases. Among these cases, 29 IUDs were also embedded and/or rotated, indicating that some IUDs have multiple causes of the malposition. Twenty-one IUDs were near the fundus but embedded and/or rotated. Controls with a normally-sited IUD were selected for comparison to the case group. Among IUD users, the identification of suspected adenomyosis on the ultrasound was associated with an increased risk of IUD malposition (odds ratio [OR], 3.04; 95% confidence interval [CI], 1.08-8.52).¹⁶ In this study, removal of a malpositioned LNG-IUD, without initiating a highly reliable contraceptive was associated with an increased risk of pregnancy. It is important to initiate a highly reliable form of contraception if the plan is to remove a malpositioned IUD.^16,19

In a study of 1,253 pelvic ultrasounds performed for any indication where an IUD was identified in the uterus, 263 IUDs (19%) were determined to be malpositioned.¹⁷ In this study the location of the malpositioned IUDs included¹⁷:

• the lower uterine segment not extending into the cervix (38%)
• in the lower uterine segment extending into the cervix (22%)
• in the cervix (26%)
• rotated axis of the IUD (12%)
• other (2%).

Among the 236 malpositioned IUDs, 24% appeared to be embedded in the uterine wall.¹⁷ Compared with patients with a normally-sited IUD on ultrasound, patients with a malpositioned IUD more frequently reported vaginal bleeding (30% vs 19%; P<.005) and pelvic pain (43% vs 30%; P<.002), similar to the findings in the Benacerraf et al. study.¹⁴

Connolly and Fox¹⁸ designed an innovative study to determine the rate of malpositioned IUDs using 2-D ultrasound to ensure proper IUD placement at the time of insertion with a follow-up 3-D ultrasound 8 weeks after insertion to assess IUD position within the uterus. At the 8-week 3-D ultrasound, among 763 women, 16.6% of the IUDs were malpositioned.¹⁸ In this study, IUD position was determined to be correct if all the following features were identified:

• the IUD shaft was in the midline of the uterine cavity
• the IUD arms were at 90 degrees from the stem
• the top of the IUD was within 3 to 4 mm of the fundus
• the IUD was not rotated, inverted or transverse.

IUD malpositions were categorized as:

• embedded in the uterine wall
• low in the uterine cavity
• in the endocervical canal
• misaligned
• perforated
• expulsed.

At the 8-week follow-up, 636 patients (83.4%) had an IUD that was correctly positioned.¹⁸ In 127 patients (16.6%) IUD malposition was identified, with some patients having more than one type of malposition. The types of malposition identified were:

• embedded in the myometrium (54%)
• misaligned, including rotated, laterally displaced, inverted, transverse or arms not deployed (47%)
• low in the uterine cavity (39%)
• in the endocervical canal (14%)
• perforated (3%)
• expulsion (0%).

Recall that all of these patients had a 2-D ultrasound at the time of insertion that identified the IUD as correctly placed. This suggests that during the 8 weeks following IUD placement there were changes in the location of the IUD or that 2-D ultrasound has lower sensitivity than 3-D ultrasound to detect malposition. Of note, at the 8-week follow-up, bleeding or pain was reported by 36% of the patients with a malpositioned IUD and 20% of patients with a correctly positioned IUD.¹⁷ Sixty-seven of the 127 malpositioned IUDs “required” removal, but the precise reasons for the removals were not delineated. The investigators concluded that 3-D ultrasonography is useful for the detection of IUD malposition and could be considered as part of ongoing IUD care, if symptoms of pain or bleeding occur.¹⁸

Continue to: IUD malposition following postplacental insertion...

IUD malposition following postplacental insertion

IUD malposition is common in patients who have had a postplacental insertion. Ultrasound imaging plays an important role in detecting IUD expulsion and malposition in these cases. Postplacental IUD insertion is defined as the placement of an IUD within 10 minutes following delivery of the placenta. Postplacental IUD insertion can be performed following a vaginal or cesarean birth and with a Cu-IUD or LNG-IUD. The good news is that postplacental IUD insertion reduces the risk of unplanned pregnancy in the years following birth. However, postplacental IUD insertion is associated with a high rate of IUD malposition.

In a study of 162 patients who had postplacental insertion of a Cu-IUD following a vaginal birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 8%, partial expulsion in 16%, and malposition in 15%.²⁰ The IUD was correctly sited in 56% of patients. Seven patients (4%) had the IUD removed, and 1 patient had a perforated IUD. Among the 25 malpositioned IUDs, 14 were not within 1 cm of the fundus, and 11 were rotated outside of the axis of the cornuas. In this study partial expulsion was defined as an IUD protruding from the external cervical os on physical exam or demonstration of the distal tip of the IUD below the internal os of the cervix on ultrasound. Malposition was defined as an IUD that was >1 cm from the fundus or in an abnormal location or axis, but not partially expelled.

In a study of 69 patients who had postplacental insertion of a Cu-IUD following a cesarean birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 3%, partial expulsion (stem in the cervix below the internal os) in 4% and malposition in 30%.²⁰ The IUD was correctly positioned in 59% of the patients.²¹ The IUD had been electively removed in 3%. Among the 21 patients with a malpositioned IUD, 10 were rotated within the uterine cavity, 6 were inverted (upside down), 3 were low-lying, and 2 were transverse.²¹ Given the relatively high rate of IUD malposition following postplacental insertion, it may be useful to perform a pelvic ultrasound at a postpartum visit to assess the location of the IUD, if ultrasonography is available.

Management of the malpositioned IUD

There are no consensus guidelines on how to care for a patient with a malpositioned IUD. Clinicians need to use their best judgment and engage the patient in joint decision making when managing a malpositioned IUD. When an IUD is malpositioned and the patient has bothersome symptoms of pelvic pain or abnormal bleeding that have not responded to standard interventions, consideration may be given to a remove and replace strategy. When the stem of the IUD is below the level of the internal os on ultrasound or visible at the external os on physical examination, consideration should be given to removing and replacing the IUD. However, if the IUD is removed without replacement or the initiation of a highly reliable contraceptive, the risk of unplanned pregnancy is considerable.^16,19

IUD totally or partially within the cervix or low-lying. When an IUD is in the cervix, the contraceptive efficacy of the IUD may be diminished, especially with a Cu-IUD.²² In these cases, removing and replacing the IUD is an option. In a survey of 20 expert clinicians, >80% recommended replacing an IUD that was totally or partially in the cervical canal.²³ But most of the experts would not replace an IUD that was incidentally noted on ultrasound to be low-lying, being positioned more than 2 cm below the fundus, with no portion of the IUD in the cervical canal. In the same survey, for patients with a low-lying IUD and pelvic pain or bleeding, the majority of experts reported that they would explore other causes of bleeding and pelvic pain not related to the IUD itself and not replace the IUD, but 30% of the experts reported that they would remove and replace the device.²³

IUD embedded in the myometrium with pelvic pain. Based on my clinical experience, when a patient has persistent pelvic pain following the insertion of an IUD and the pain does not resolve with standard measures including medication, an ultrasound study is warranted to assess the position of the IUD. If the ultrasound demonstrates that an arm of the IUD is embedded in the myometrium, removal of the IUD may be associated with resolution of the pain. Reinsertion of an IUD under ultrasound guidance may result in a correctly-sited IUD with no recurrence of pelvic pain.

IUD rotated within the uterus with no pain or abnormal bleeding. For an IUD that is near the fundus and rotated on its axis within the uterus, if the patient has no symptoms of pain or abnormal bleeding, my recommendation to the patient would be to leave the device in situ.

Without available guidelines, engage in clinician-patient discussion

It is clear that IUD malposition is common, occurring in 10% to 20% of patients with an IUD. High-quality ultrasound imaging is helpful in detecting IUD malposition, including 2-D ultrasound with videoclips and/or 3-D ultrasound with coronal reconstruction. More data are needed to identify the best options for managing various types of malpositioned IUDs in patients with and without bothersome symptoms such as pain and bleeding. Until consensus guidelines are developed, clinicians need to engage the patient in a discussion of how to best manage the malpositioned IUD. Medicated IUDs and progestin subdermal implants are our two most effective reversible contraceptives. They are among the most important advances in health care over the past half-century. ●

The medicated intrauterine devices (IUDs), including the levonorgestrel-releasing IUD (LNG-IUD) (Mirena, Kyleena, Skyla, and Liletta) and the copper IUD (Cu-IUD; Paragard), are remarkably effective contraceptives. For the 52-mg LNG-IUD (Mirena, Liletta) the pregnancy rate over 6 years of use averaged less than 0.2% per year.^1,2 For the Cu-IUD, the pregnancy rate over 10 years of use averaged 0.5% per year for the first 3 years of use and 0.2% per year over the following 7 years of use.³ IUD perforation of the uterus, expulsion, and malposition are recognized complications of IUD use. Our understanding of the prevalence and management of malpositioned IUDs is evolving and the main focus of this editorial.

Complete and partial uterus perforation

A complete uterine perforation occurs when the entire IUD is outside the walls of the uterus. A partial uterine perforation occurs when the IUD is outside the uterine cavity, but a portion of the IUD remains in the myometrium. When uterine perforation is suspected, ultrasound can determine if the IUD is properly sited within the uterus. If ultrasonography does not detect the IUD within the uterus, an x-ray of the pelvis and abdomen should be obtained to determine if the IUD is in the peritoneal cavity. If both an ultrasound and a pelvic-abdominal x-ray do not detect the IUD, the IUD was probably expelled from the patient.

Uterine perforation is uncommon and occurs once in every 500 to 1,000 insertions in non-breastfeeding women.^4-8 The most common symptoms reported by patients with a perforated IUD are pain and/or bleeding.⁸ Investigators in the European Active Surveillance Study on Intrauterine Devices (EURAS) enrolled more than 60,000 patients who had an IUD insertion and followed them for 12 months with more than 39,000 followed for up to 60 months.^7,8 The uterine perforation rate per 1,000 IUD insertions in non-breastfeeding women with 60 months of follow-up was 1.6 for the LNG-IUD and 0.8 for the Cu-IUD.⁸ The rate of uterine perforation was much higher in women who are breastfeeding or recently postpartum. In the EURAS study after 60 months of follow-up, the perforation rate per 1,000 insertions among breastfeeding women was 7.9 for the LNG-IUS and 4.7 for the Cu-IUD.⁸

Remarkably very few IUD perforations were detected at the time of insertion, including only 2% of the LNG-IUD insertions and 17% of the Cu-IUD insertions.⁸ Many perforations were not detected until more than 12 months following insertion, including 32% of the LNG-IUD insertions and 22% of the Cu-IUD insertions.⁸ Obviously, an IUD that has completely perforated the uterus and resides in the peritoneal cavity is not an effective contraceptive. For some patients, the IUD perforation was initially diagnosed after they became pregnant, and imaging studies to locate the IUD and assess the pregnancy were initiated. Complete perforation is usually treated with laparoscopy to remove the IUD and reduce the risk of injury to intra-abdominal organs.

Patients with an IUD partial perforation may present with pelvic pain or abnormal uterine bleeding.⁹ An ultrasound study to explore the cause of the presenting symptom may detect the partial perforation. It is estimated that approximately 20% of cases of IUD perforation are partial perforation.⁹ Over time, a partial perforation may progress to a complete perforation. In some cases of partial perforation, the IUD string may still be visible in the cervix, and the IUD may be removed by pulling on the strings.⁸ Hysteroscopy and/or laparoscopy may be needed to remove a partially perforated IUD. Following a partial or complete IUD perforation, if the patient desires to continue with IUD contraception, it would be wise to insert a new IUD under ultrasound guidance or assess proper placement with a postplacement ultrasound.

Continue to: Expulsion...

IUD expulsion occurs in approximately 3% to 11% of patients.^10-13 The age of the patient influences the rate of expulsion. In a study of 2,748 patients with a Cu-IUD, the rate of expulsion by age for patients <20 years, 20–24 years, 25–29 years, 30–34 years, and ≥35 years was 8.2%, 3.2%, 3.0%, 2.3%, and 1.8%, respectively.¹⁰ In this study, age did not influence the rate of IUD removal for pelvic pain or abnormal bleeding, which was 4% to 5% across all age groups.¹⁰ In a study of 5,403 patients with an IUD, the rate of IUD expulsion by age for patients <20 years, 20–29 years, and 30–45 years was 14.6%, 7.3%, and 7.2%, respectively.¹² In this study, the 3-year cumulative rate of expulsion was 10.2%.¹² There was no statistically significant difference in the 3-year cumulative rate of expulsion for the 52-mg LNG-IUD (10.1%) and Cu-IUD (10.7%).¹²

The majority of patients who have an IUD expulsion recognize the event and seek additional contraception care. A few patients first recognize the IUD expulsion when they become pregnant, and imaging studies detect no IUD in the uterus or the peritoneal cavity. In a study of more than 17,000 patients using an LNG-IUD, 108 pregnancies were reported. Seven pregnancies occurred in patients who did not realize their IUD was expelled.¹⁴ Patients who have had an IUD expulsion and receive a new IUD are at increased risk for re-expulsion. For these patients, reinsertion of an IUD could be performed under ultrasound guidance to ensure and document optimal initial IUD position within the uterus, or ultrasound can be obtained postinsertion to document appropriate IUD position.

Malposition—prevalence and management

Our understanding of the prevalence and management of a malpositioned IUD is evolving. For the purposes of this discussion a malpositioned IUD is defined as being in the uterus, but not properly positioned within the uterine cavity. Perforation into the peritoneal cavity and complete expulsion of an IUD are considered separate entities. However, a malpositioned IUD within the uterus may eventually perforate the uterus or be expelled from the body. For example, an IUD embedded in the uterine wall may eventually work its way through the wall and become perforated, residing in the peritoneal cavity. An IUD with the stem in the cervix below the internal os may eventually be expelled from the uterus and leave the body through the vagina.

High-quality ultrasonography, including 2-dimensional (2-D) ultrasound with videoclips or 3-dimensional (3-D) ultrasound with coronal views, has greatly advanced our understanding of the prevalence and characteristics of a malpositioned IUD.^15-18 Ultrasound features of an IUD correctly placed within the uterus include:

• the IUD is in the uterus
• the shaft is in the midline of the uterine cavity
• the shaft of the IUD is not in the endocervix
• the IUD arms are at a 90-degree angle from the shaft
• the top of the IUD is within 2 cm of the fundus
• the IUD is not rotated outside of the cornual plane, inverted or transverse.

Ultrasound imaging has identified multiple types of malpositioned IUDs, including:

• IUD embedded in the myometrium—a portion of the IUD is embedded in the uterine wall
• low-lying IUD—the IUD is low in the uterine cavity but not in the endocervix
• IUD in the endocervix—the stem is in the endocervical canal
• rotated—the IUD is rotated outside the cornual plane
• malpositioned arms—the arms are not at a 90-degree angle to the stem
• the IUD is inverted, transverse, or laterally displaced.

IUD malposition is highly prevalent and has been identified in 10% to 20% of convenience cohorts in which an ultrasound study was performed.^15-18

Benacerraf, Shipp, and Bromley were among the first experts to use ultrasound to detect the high prevalence of malpositioned IUDs among a convenience sample of 167 patients with an IUD undergoing ultrasound for a variety of indications. Using 3-D ultrasound, including reconstructed coronal views, they identified 28 patients (17%) with a malpositioned IUD based on the detection of the IUD “poking into the substance of the uterus or cervix.” Among the patients with a malpositioned IUD, the principal indication for the ultrasound study was pelvic pain (39%) or abnormal uterine bleeding (36%). Among women with a normally sited IUD, pelvic pain (19%) or abnormal uterine bleeding (15%) were less often the principal indication for the ultrasound.¹⁵ The malpositioned IUD was removed in 21 of the 28 cases and the symptoms of pelvic pain or abnormal bleeding resolved in 20 of the 21 patients.¹⁵

Other investigators have confirmed the observation that IUD malposition is common.^16-18 In a retrospective study of 1,748 pelvic ultrasounds performed for any indication where an IUD was present, after excluding 13 patients who were determined to have expelled their IUD (13) and 13 patients with a perforated IUD, 156 patients (8.9%) were diagnosed as having a malpositioned IUD.¹⁶ IUD malposition was diagnosed when the IUD was in the uterus but positioned in the lower uterine segment, cervix, rotated or embedded in the uterus. An IUD in the lower uterine segment or cervix was detected in 133 patients, representing 85% of cases. Among these cases, 29 IUDs were also embedded and/or rotated, indicating that some IUDs have multiple causes of the malposition. Twenty-one IUDs were near the fundus but embedded and/or rotated. Controls with a normally-sited IUD were selected for comparison to the case group. Among IUD users, the identification of suspected adenomyosis on the ultrasound was associated with an increased risk of IUD malposition (odds ratio [OR], 3.04; 95% confidence interval [CI], 1.08-8.52).¹⁶ In this study, removal of a malpositioned LNG-IUD, without initiating a highly reliable contraceptive was associated with an increased risk of pregnancy. It is important to initiate a highly reliable form of contraception if the plan is to remove a malpositioned IUD.^16,19

In a study of 1,253 pelvic ultrasounds performed for any indication where an IUD was identified in the uterus, 263 IUDs (19%) were determined to be malpositioned.¹⁷ In this study the location of the malpositioned IUDs included¹⁷:

• the lower uterine segment not extending into the cervix (38%)
• in the lower uterine segment extending into the cervix (22%)
• in the cervix (26%)
• rotated axis of the IUD (12%)
• other (2%).

Among the 236 malpositioned IUDs, 24% appeared to be embedded in the uterine wall.¹⁷ Compared with patients with a normally-sited IUD on ultrasound, patients with a malpositioned IUD more frequently reported vaginal bleeding (30% vs 19%; P<.005) and pelvic pain (43% vs 30%; P<.002), similar to the findings in the Benacerraf et al. study.¹⁴

Connolly and Fox¹⁸ designed an innovative study to determine the rate of malpositioned IUDs using 2-D ultrasound to ensure proper IUD placement at the time of insertion with a follow-up 3-D ultrasound 8 weeks after insertion to assess IUD position within the uterus. At the 8-week 3-D ultrasound, among 763 women, 16.6% of the IUDs were malpositioned.¹⁸ In this study, IUD position was determined to be correct if all the following features were identified:

• the IUD shaft was in the midline of the uterine cavity
• the IUD arms were at 90 degrees from the stem
• the top of the IUD was within 3 to 4 mm of the fundus
• the IUD was not rotated, inverted or transverse.

IUD malpositions were categorized as:

• embedded in the uterine wall
• low in the uterine cavity
• in the endocervical canal
• misaligned
• perforated
• expulsed.

At the 8-week follow-up, 636 patients (83.4%) had an IUD that was correctly positioned.¹⁸ In 127 patients (16.6%) IUD malposition was identified, with some patients having more than one type of malposition. The types of malposition identified were:

• embedded in the myometrium (54%)
• misaligned, including rotated, laterally displaced, inverted, transverse or arms not deployed (47%)
• low in the uterine cavity (39%)
• in the endocervical canal (14%)
• perforated (3%)
• expulsion (0%).

Recall that all of these patients had a 2-D ultrasound at the time of insertion that identified the IUD as correctly placed. This suggests that during the 8 weeks following IUD placement there were changes in the location of the IUD or that 2-D ultrasound has lower sensitivity than 3-D ultrasound to detect malposition. Of note, at the 8-week follow-up, bleeding or pain was reported by 36% of the patients with a malpositioned IUD and 20% of patients with a correctly positioned IUD.¹⁷ Sixty-seven of the 127 malpositioned IUDs “required” removal, but the precise reasons for the removals were not delineated. The investigators concluded that 3-D ultrasonography is useful for the detection of IUD malposition and could be considered as part of ongoing IUD care, if symptoms of pain or bleeding occur.¹⁸

Continue to: IUD malposition following postplacental insertion...

IUD malposition following postplacental insertion

IUD malposition is common in patients who have had a postplacental insertion. Ultrasound imaging plays an important role in detecting IUD expulsion and malposition in these cases. Postplacental IUD insertion is defined as the placement of an IUD within 10 minutes following delivery of the placenta. Postplacental IUD insertion can be performed following a vaginal or cesarean birth and with a Cu-IUD or LNG-IUD. The good news is that postplacental IUD insertion reduces the risk of unplanned pregnancy in the years following birth. However, postplacental IUD insertion is associated with a high rate of IUD malposition.

In a study of 162 patients who had postplacental insertion of a Cu-IUD following a vaginal birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 8%, partial expulsion in 16%, and malposition in 15%.²⁰ The IUD was correctly sited in 56% of patients. Seven patients (4%) had the IUD removed, and 1 patient had a perforated IUD. Among the 25 malpositioned IUDs, 14 were not within 1 cm of the fundus, and 11 were rotated outside of the axis of the cornuas. In this study partial expulsion was defined as an IUD protruding from the external cervical os on physical exam or demonstration of the distal tip of the IUD below the internal os of the cervix on ultrasound. Malposition was defined as an IUD that was >1 cm from the fundus or in an abnormal location or axis, but not partially expelled.

In a study of 69 patients who had postplacental insertion of a Cu-IUD following a cesarean birth, ultrasound and physical examination at 6 months demonstrated complete IUD expulsion in 3%, partial expulsion (stem in the cervix below the internal os) in 4% and malposition in 30%.²⁰ The IUD was correctly positioned in 59% of the patients.²¹ The IUD had been electively removed in 3%. Among the 21 patients with a malpositioned IUD, 10 were rotated within the uterine cavity, 6 were inverted (upside down), 3 were low-lying, and 2 were transverse.²¹ Given the relatively high rate of IUD malposition following postplacental insertion, it may be useful to perform a pelvic ultrasound at a postpartum visit to assess the location of the IUD, if ultrasonography is available.

Management of the malpositioned IUD

There are no consensus guidelines on how to care for a patient with a malpositioned IUD. Clinicians need to use their best judgment and engage the patient in joint decision making when managing a malpositioned IUD. When an IUD is malpositioned and the patient has bothersome symptoms of pelvic pain or abnormal bleeding that have not responded to standard interventions, consideration may be given to a remove and replace strategy. When the stem of the IUD is below the level of the internal os on ultrasound or visible at the external os on physical examination, consideration should be given to removing and replacing the IUD. However, if the IUD is removed without replacement or the initiation of a highly reliable contraceptive, the risk of unplanned pregnancy is considerable.^16,19

IUD totally or partially within the cervix or low-lying. When an IUD is in the cervix, the contraceptive efficacy of the IUD may be diminished, especially with a Cu-IUD.²² In these cases, removing and replacing the IUD is an option. In a survey of 20 expert clinicians, >80% recommended replacing an IUD that was totally or partially in the cervical canal.²³ But most of the experts would not replace an IUD that was incidentally noted on ultrasound to be low-lying, being positioned more than 2 cm below the fundus, with no portion of the IUD in the cervical canal. In the same survey, for patients with a low-lying IUD and pelvic pain or bleeding, the majority of experts reported that they would explore other causes of bleeding and pelvic pain not related to the IUD itself and not replace the IUD, but 30% of the experts reported that they would remove and replace the device.²³

IUD embedded in the myometrium with pelvic pain. Based on my clinical experience, when a patient has persistent pelvic pain following the insertion of an IUD and the pain does not resolve with standard measures including medication, an ultrasound study is warranted to assess the position of the IUD. If the ultrasound demonstrates that an arm of the IUD is embedded in the myometrium, removal of the IUD may be associated with resolution of the pain. Reinsertion of an IUD under ultrasound guidance may result in a correctly-sited IUD with no recurrence of pelvic pain.

IUD rotated within the uterus with no pain or abnormal bleeding. For an IUD that is near the fundus and rotated on its axis within the uterus, if the patient has no symptoms of pain or abnormal bleeding, my recommendation to the patient would be to leave the device in situ.

Without available guidelines, engage in clinician-patient discussion

It is clear that IUD malposition is common, occurring in 10% to 20% of patients with an IUD. High-quality ultrasound imaging is helpful in detecting IUD malposition, including 2-D ultrasound with videoclips and/or 3-D ultrasound with coronal reconstruction. More data are needed to identify the best options for managing various types of malpositioned IUDs in patients with and without bothersome symptoms such as pain and bleeding. Until consensus guidelines are developed, clinicians need to engage the patient in a discussion of how to best manage the malpositioned IUD. Medicated IUDs and progestin subdermal implants are our two most effective reversible contraceptives. They are among the most important advances in health care over the past half-century. ●