The Journal of Family Practice

When the Advisory Committee on Immunization Practices (ACIP) met in June and adopted recommendations for influenza vaccines for the 2023-2024 season, the major discussions focused on the timing of vaccine administration, the composition of the vaccine, and what (if any) special precautions are needed when administering an egg-based vaccine to a person with a history of egg allergy. Here are the takeaways.

When should flu vaccine be administered?

Influenza activity usually peaks between December and the end of March; only twice between 1982 and 2022 did it peak before December. Thus, most people should receive the vaccine in September or October, a recommendation that has not changed from last year. This is early enough to provide adequate protection in most influenza seasons, but late enough to allow protection to persist through the entire season. Vaccination should continue to be offered to those who are unvaccinated throughout the influenza season, as long as influenza viruses are circulating.

Earlier administration is not recommended for most people and is recommended against for those ages 65 years and older (because their immunity from the vaccine may wane faster) and for pregnant people in their first or second trimester (because the vaccine is more effective in preventing influenza in newborns if administered in the third trimester). Evidence regarding waning immunity is inconsistent; however, some studies have shown greater loss of immunity in the elderly compared to younger age groups, as time from vaccination increases.¹

What’s in this year’s vaccines?

The composition of the vaccines used in North America was determined by the World Health Organization in February, based on the most commonly circulating strains. All vaccines approved for use in the 2023-2024 season are quadrivalent and contain 1 influenza A (H1N1) strain, 1 influenza A (H3N2) strain, and 2 influenza B strains. The specifics of each strain are listed in TABLE 1.² The 2 influenza A strains are slightly different for the egg-based and non-egg-based vaccines.² There is no known effectiveness advantage of one antigen strain vs the other.

Should you take special precautions with egg allergy?

There is new wording to the recommendations on the use of egg-based influenza vaccines for those with a history of egg allergy (TABLE 2²). Previously, the ACIP had recommended that if an egg-based vaccine is given to a person with a history of egg allergy, it should be administered in an inpatient or outpatient medical setting (eg, hospital, clinic, health department, physician office) and should be supervised by a health care provider who is able to recognize and manage severe allergic reactions. These added precautions were out of step with other organizations, including the American Academy of Pediatrics and allergy-related specialty societies, all of whom recommend no special procedures or precautions when administering any influenza vaccine to those with a history of egg allergy.³

Why the change? Several factors contributed to ACIP’s decision to reword its recommendation. One is that the ovalbumin content of all current influenza vaccines ­(TABLE 3³) is considered too low to trigger an allergic reaction.

Another is the paucity of evidence that egg-based vaccines convey increased risk beyond that for any other vaccine. Although 1% to 3% of children are reported to have an egg allergy, there is no evidence that they are at increased risk for a serious allergic reaction if administered an egg-based vaccine.³ A systematic review of 31 studies (mostly low-quality observational studies and case series) conducted by the ACIP Influenza Work Group found no risk for severe anaphylaxis, hospitalization, or death, even in those with a history of an anaphylactic reaction to eggs.² A review of Vaccine Adverse Events Reporting System (VAERS) data identified 18 cases of reported anaphylaxis after receipt of an inactivated influenza vaccine over a 5-year period, but clinical review confirmed only 7.²

Continue to: And finally, appropriate precautions already...

And finally, appropriate precautions already are recommended for administration of any vaccine. The CDC guidance for best practices for administering vaccines states: “Although allergic reactions are a common concern for vaccine providers, these reactions are uncommon and anaphylaxis following vaccines is rare, occurring at a rate of approximately one per million doses for many vaccines. Epinephrine and equipment for managing an airway should be available for immediate use.”⁴

What does this mean in practice? Family physicians who administer influenza vaccines do not need to use special precautions for any influenza vaccine, or use non-egg-based vaccines, for those who have a history of egg allergy. However, they should be prepared to respond to a severe allergic reaction just as they would for any other vaccine. Any vestigial practices pertaining to egg allergy and influenza vaccines—such as vaccine skin testing prior to vaccination (with dilution of vaccine if positive), vaccination deferral or administration via alternative dosing protocols, and split dosing of vaccine—are unnecessary and should be abandoned. 

When the Advisory Committee on Immunization Practices (ACIP) met in June and adopted recommendations for influenza vaccines for the 2023-2024 season, the major discussions focused on the timing of vaccine administration, the composition of the vaccine, and what (if any) special precautions are needed when administering an egg-based vaccine to a person with a history of egg allergy. Here are the takeaways.

When should flu vaccine be administered?

Influenza activity usually peaks between December and the end of March; only twice between 1982 and 2022 did it peak before December. Thus, most people should receive the vaccine in September or October, a recommendation that has not changed from last year. This is early enough to provide adequate protection in most influenza seasons, but late enough to allow protection to persist through the entire season. Vaccination should continue to be offered to those who are unvaccinated throughout the influenza season, as long as influenza viruses are circulating.

Earlier administration is not recommended for most people and is recommended against for those ages 65 years and older (because their immunity from the vaccine may wane faster) and for pregnant people in their first or second trimester (because the vaccine is more effective in preventing influenza in newborns if administered in the third trimester). Evidence regarding waning immunity is inconsistent; however, some studies have shown greater loss of immunity in the elderly compared to younger age groups, as time from vaccination increases.¹

What’s in this year’s vaccines?

The composition of the vaccines used in North America was determined by the World Health Organization in February, based on the most commonly circulating strains. All vaccines approved for use in the 2023-2024 season are quadrivalent and contain 1 influenza A (H1N1) strain, 1 influenza A (H3N2) strain, and 2 influenza B strains. The specifics of each strain are listed in TABLE 1.² The 2 influenza A strains are slightly different for the egg-based and non-egg-based vaccines.² There is no known effectiveness advantage of one antigen strain vs the other.

Should you take special precautions with egg allergy?

There is new wording to the recommendations on the use of egg-based influenza vaccines for those with a history of egg allergy (TABLE 2²). Previously, the ACIP had recommended that if an egg-based vaccine is given to a person with a history of egg allergy, it should be administered in an inpatient or outpatient medical setting (eg, hospital, clinic, health department, physician office) and should be supervised by a health care provider who is able to recognize and manage severe allergic reactions. These added precautions were out of step with other organizations, including the American Academy of Pediatrics and allergy-related specialty societies, all of whom recommend no special procedures or precautions when administering any influenza vaccine to those with a history of egg allergy.³

Why the change? Several factors contributed to ACIP’s decision to reword its recommendation. One is that the ovalbumin content of all current influenza vaccines ­(TABLE 3³) is considered too low to trigger an allergic reaction.

Another is the paucity of evidence that egg-based vaccines convey increased risk beyond that for any other vaccine. Although 1% to 3% of children are reported to have an egg allergy, there is no evidence that they are at increased risk for a serious allergic reaction if administered an egg-based vaccine.³ A systematic review of 31 studies (mostly low-quality observational studies and case series) conducted by the ACIP Influenza Work Group found no risk for severe anaphylaxis, hospitalization, or death, even in those with a history of an anaphylactic reaction to eggs.² A review of Vaccine Adverse Events Reporting System (VAERS) data identified 18 cases of reported anaphylaxis after receipt of an inactivated influenza vaccine over a 5-year period, but clinical review confirmed only 7.²

Continue to: And finally, appropriate precautions already...

And finally, appropriate precautions already are recommended for administration of any vaccine. The CDC guidance for best practices for administering vaccines states: “Although allergic reactions are a common concern for vaccine providers, these reactions are uncommon and anaphylaxis following vaccines is rare, occurring at a rate of approximately one per million doses for many vaccines. Epinephrine and equipment for managing an airway should be available for immediate use.”⁴

What does this mean in practice? Family physicians who administer influenza vaccines do not need to use special precautions for any influenza vaccine, or use non-egg-based vaccines, for those who have a history of egg allergy. However, they should be prepared to respond to a severe allergic reaction just as they would for any other vaccine. Any vestigial practices pertaining to egg allergy and influenza vaccines—such as vaccine skin testing prior to vaccination (with dilution of vaccine if positive), vaccination deferral or administration via alternative dosing protocols, and split dosing of vaccine—are unnecessary and should be abandoned. 

When the Advisory Committee on Immunization Practices (ACIP) met in June and adopted recommendations for influenza vaccines for the 2023-2024 season, the major discussions focused on the timing of vaccine administration, the composition of the vaccine, and what (if any) special precautions are needed when administering an egg-based vaccine to a person with a history of egg allergy. Here are the takeaways.

When should flu vaccine be administered?

Influenza activity usually peaks between December and the end of March; only twice between 1982 and 2022 did it peak before December. Thus, most people should receive the vaccine in September or October, a recommendation that has not changed from last year. This is early enough to provide adequate protection in most influenza seasons, but late enough to allow protection to persist through the entire season. Vaccination should continue to be offered to those who are unvaccinated throughout the influenza season, as long as influenza viruses are circulating.

Earlier administration is not recommended for most people and is recommended against for those ages 65 years and older (because their immunity from the vaccine may wane faster) and for pregnant people in their first or second trimester (because the vaccine is more effective in preventing influenza in newborns if administered in the third trimester). Evidence regarding waning immunity is inconsistent; however, some studies have shown greater loss of immunity in the elderly compared to younger age groups, as time from vaccination increases.¹

What’s in this year’s vaccines?

The composition of the vaccines used in North America was determined by the World Health Organization in February, based on the most commonly circulating strains. All vaccines approved for use in the 2023-2024 season are quadrivalent and contain 1 influenza A (H1N1) strain, 1 influenza A (H3N2) strain, and 2 influenza B strains. The specifics of each strain are listed in TABLE 1.² The 2 influenza A strains are slightly different for the egg-based and non-egg-based vaccines.² There is no known effectiveness advantage of one antigen strain vs the other.

Should you take special precautions with egg allergy?

There is new wording to the recommendations on the use of egg-based influenza vaccines for those with a history of egg allergy (TABLE 2²). Previously, the ACIP had recommended that if an egg-based vaccine is given to a person with a history of egg allergy, it should be administered in an inpatient or outpatient medical setting (eg, hospital, clinic, health department, physician office) and should be supervised by a health care provider who is able to recognize and manage severe allergic reactions. These added precautions were out of step with other organizations, including the American Academy of Pediatrics and allergy-related specialty societies, all of whom recommend no special procedures or precautions when administering any influenza vaccine to those with a history of egg allergy.³

Why the change? Several factors contributed to ACIP’s decision to reword its recommendation. One is that the ovalbumin content of all current influenza vaccines ­(TABLE 3³) is considered too low to trigger an allergic reaction.

Another is the paucity of evidence that egg-based vaccines convey increased risk beyond that for any other vaccine. Although 1% to 3% of children are reported to have an egg allergy, there is no evidence that they are at increased risk for a serious allergic reaction if administered an egg-based vaccine.³ A systematic review of 31 studies (mostly low-quality observational studies and case series) conducted by the ACIP Influenza Work Group found no risk for severe anaphylaxis, hospitalization, or death, even in those with a history of an anaphylactic reaction to eggs.² A review of Vaccine Adverse Events Reporting System (VAERS) data identified 18 cases of reported anaphylaxis after receipt of an inactivated influenza vaccine over a 5-year period, but clinical review confirmed only 7.²

Continue to: And finally, appropriate precautions already...

And finally, appropriate precautions already are recommended for administration of any vaccine. The CDC guidance for best practices for administering vaccines states: “Although allergic reactions are a common concern for vaccine providers, these reactions are uncommon and anaphylaxis following vaccines is rare, occurring at a rate of approximately one per million doses for many vaccines. Epinephrine and equipment for managing an airway should be available for immediate use.”⁴

What does this mean in practice? Family physicians who administer influenza vaccines do not need to use special precautions for any influenza vaccine, or use non-egg-based vaccines, for those who have a history of egg allergy. However, they should be prepared to respond to a severe allergic reaction just as they would for any other vaccine. Any vestigial practices pertaining to egg allergy and influenza vaccines—such as vaccine skin testing prior to vaccination (with dilution of vaccine if positive), vaccination deferral or administration via alternative dosing protocols, and split dosing of vaccine—are unnecessary and should be abandoned. 

Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.¹ Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”² Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.³ Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.⁴

In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.⁵ In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.⁴ The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.⁶

Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.⁷ Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.⁸ Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.

How insufficient sleep raises the risk for obesity

Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.² The recommended sleep duration for children is longer, and it varies by age.⁹ The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.

Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.¹⁰ Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.

Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

In a 2004 study by Spiegel et al,¹¹ leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and ­appetite—especially for calorie-dense foods with high carbohydrate content.

Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.⁸ Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.¹²

Continue to: Other sleep characteristics weakly correlated with obesity

Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.⁸ Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8 pm¹³; late-night snacks are a part of this sleep–obesity equation.¹⁴

Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.¹⁵ Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.

It is a cycle of poor sleep causing obesity and obesity causing poor sleep.

Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.¹⁶ This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.¹⁶ This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.

Sleep, and its many components, play an integral role in the prevention and treatment of obesity.¹⁷ Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

The sleep–obesity link in children and the elderly

Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).¹⁸ According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.¹⁹

Continue to: Although poor sleep is associated...

Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.²⁰ Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.²¹ A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity ­C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.²² Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.

Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.²³ The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.²⁴ Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.²⁴

The consequence: A vicious cycle

Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.²⁵ These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.^8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.⁸

OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.^8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.²⁸ However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.²⁸ Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.²⁹

Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.

OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.³⁰ Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.³¹ Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.³² A positive result with a screening tool should be confirmed with polysomnography.³²

Continue to: Intervention for OSA

Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).³³ OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).^33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).^33,34

Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.^33,34

Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.³⁵ Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.³⁶ Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.³⁷ Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.³⁶ There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”³⁸

Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.

Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.³⁹ People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.⁴⁰

Continue to: In contrast, those with alcohol...

In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.⁴⁰ Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.⁴¹

Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.⁴² In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.⁴³ Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.

Treatment and tools to improve sleep in patients with obesity

Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 1⁴⁴). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.^17,45

It falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia.

Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of ­moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.⁴⁶ However, approximately 300 minutes of moderate-intensity activity per week is suggested for successful weight loss with exercise alone.⁴⁷

Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.⁴⁸ Still, physical activity is essential in helping maintain and prevent weight regain.

Continue to: Nonpharmacologic interventions

Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene(TABLE 2^49,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.⁵¹ Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.⁵²

Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.⁵³

Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.^51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.⁵⁴ Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.

CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu

Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.¹ Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”² Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.³ Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.⁴

In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.⁵ In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.⁴ The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.⁶

Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.⁷ Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.⁸ Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.

How insufficient sleep raises the risk for obesity

Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.² The recommended sleep duration for children is longer, and it varies by age.⁹ The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.

Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.¹⁰ Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.

Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

In a 2004 study by Spiegel et al,¹¹ leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and ­appetite—especially for calorie-dense foods with high carbohydrate content.

Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.⁸ Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.¹²

Continue to: Other sleep characteristics weakly correlated with obesity

Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.⁸ Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8 pm¹³; late-night snacks are a part of this sleep–obesity equation.¹⁴

Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.¹⁵ Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.

It is a cycle of poor sleep causing obesity and obesity causing poor sleep.

Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.¹⁶ This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.¹⁶ This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.

Sleep, and its many components, play an integral role in the prevention and treatment of obesity.¹⁷ Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

The sleep–obesity link in children and the elderly

Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).¹⁸ According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.¹⁹

Continue to: Although poor sleep is associated...

Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.²⁰ Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.²¹ A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity ­C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.²² Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.

Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.²³ The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.²⁴ Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.²⁴

The consequence: A vicious cycle

Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.²⁵ These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.^8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.⁸

OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.^8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.²⁸ However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.²⁸ Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.²⁹

Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.

OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.³⁰ Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.³¹ Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.³² A positive result with a screening tool should be confirmed with polysomnography.³²

Continue to: Intervention for OSA

Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).³³ OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).^33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).^33,34

Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.^33,34

Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.³⁵ Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.³⁶ Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.³⁷ Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.³⁶ There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”³⁸

Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.

Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.³⁹ People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.⁴⁰

Continue to: In contrast, those with alcohol...

In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.⁴⁰ Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.⁴¹

Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.⁴² In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.⁴³ Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.

Treatment and tools to improve sleep in patients with obesity

Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 1⁴⁴). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.^17,45

It falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia.

Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of ­moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.⁴⁶ However, approximately 300 minutes of moderate-intensity activity per week is suggested for successful weight loss with exercise alone.⁴⁷

Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.⁴⁸ Still, physical activity is essential in helping maintain and prevent weight regain.

Continue to: Nonpharmacologic interventions

Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene(TABLE 2^49,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.⁵¹ Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.⁵²

Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.⁵³

Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.^51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.⁵⁴ Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.

CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu

Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.¹ Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”² Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.³ Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.⁴

In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.⁵ In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.⁴ The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.⁶

Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.⁷ Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.⁸ Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.

How insufficient sleep raises the risk for obesity

Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.² The recommended sleep duration for children is longer, and it varies by age.⁹ The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.

Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.¹⁰ Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.

Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

In a 2004 study by Spiegel et al,¹¹ leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and ­appetite—especially for calorie-dense foods with high carbohydrate content.

Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.⁸ Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.¹²

Continue to: Other sleep characteristics weakly correlated with obesity

Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.⁸ Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8 pm¹³; late-night snacks are a part of this sleep–obesity equation.¹⁴

Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.¹⁵ Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.

It is a cycle of poor sleep causing obesity and obesity causing poor sleep.

Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.¹⁶ This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.¹⁶ This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.

Sleep, and its many components, play an integral role in the prevention and treatment of obesity.¹⁷ Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.

The sleep–obesity link in children and the elderly

Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).¹⁸ According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.¹⁹

Continue to: Although poor sleep is associated...

Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.²⁰ Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.²¹ A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity ­C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.²² Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.

Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.²³ The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.²⁴ Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.²⁴

The consequence: A vicious cycle

Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.²⁵ These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.^8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.⁸

OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.^8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.²⁸ However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.²⁸ Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.²⁹

Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.

OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.³⁰ Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.³¹ Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.³² A positive result with a screening tool should be confirmed with polysomnography.³²

Continue to: Intervention for OSA

Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).³³ OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).^33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).^33,34

Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.^33,34

Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.³⁵ Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.³⁶ Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.³⁷ Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.³⁶ There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”³⁸

Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.

Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.³⁹ People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.⁴⁰

Continue to: In contrast, those with alcohol...

In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.⁴⁰ Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.⁴¹

Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.⁴² In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.⁴³ Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.

Treatment and tools to improve sleep in patients with obesity

Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 1⁴⁴). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.^17,45

It falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia.

Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of ­moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.⁴⁶ However, approximately 300 minutes of moderate-intensity activity per week is suggested for successful weight loss with exercise alone.⁴⁷

Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.⁴⁸ Still, physical activity is essential in helping maintain and prevent weight regain.

Continue to: Nonpharmacologic interventions

Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene(TABLE 2^49,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.⁵¹ Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.⁵²

Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.⁵³

Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.^51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.⁵⁴ Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.

CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu

A shave biopsy revealed acanthosis, papillomatosis, hyperkeratosis, hypergranulosis, parakeratosis, and cytoplasmic viral-like inclusions without atypia, consistent with a diagnosis of a common wart. The biopsy ruled out other possible diagnoses, which included keratoacanthoma, seborrheic keratosis, and squamous cell carcinoma.

Cutaneous warts can manifest as common warts (verruca vulgaris), plantar warts (verruca plantaris), or plane warts (verruca plana). These benign skin lesions are caused by human papillomavirus and can manifest in areas of skin trauma; this is known as the Koebner phenomenon. Most warts can be diagnosed through clinical history and examination. Dermoscopy, if performed, may reveal thrombosed capillaries as dotted structures, but there is an increased risk of cross-contamination.¹ That said, some dermatoscopes have disposable covers or can be cleaned with antiviral, antibacterial wipes. If the diagnosis is unclear or the exam is clinically suspicious, a biopsy may be required.

Cases with progressive enlargement and extensive involvement of the skin (as was seen here) are generally associated with certain predisposing conditions, such as atopic dermatitis and immunosuppression.² Our patient screened negative for HIV infection, and further evaluation did not reveal any concerns for immunosuppression.

Treatment for a common wart depends on patient characteristics, preferences, cost, and possible adverse effects. Standard treatment options are topical salicylic acid and cryotherapy with liquid nitrogen. Depending on the location and type of the wart, multiple treatments may be required, and recurrences are common. Intralesional injection with bleomycin, 5‐fluorouracil, or cidofovir is often used for recurrent and refractory warts.

Patients unable to tolerate cryotherapy or local injections may benefit from thermotherapy by heating the wart with a pulsed dye laser.³ Observation is also a reasonable course of action for new warts, as they may spontaneously resolve within a year.

In this case, the patient opted for over-the-counter salicylic acid 17% to be applied nightly until resolution. Cryosurgery would be a next step for him if the lesion does not resolve after 3 months of treatment.

‌

Image courtesy of Faryal Tahir, MD. Text courtesy of Faryal Tahir, MD, Assistant Professor, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

A shave biopsy revealed acanthosis, papillomatosis, hyperkeratosis, hypergranulosis, parakeratosis, and cytoplasmic viral-like inclusions without atypia, consistent with a diagnosis of a common wart. The biopsy ruled out other possible diagnoses, which included keratoacanthoma, seborrheic keratosis, and squamous cell carcinoma.

Cutaneous warts can manifest as common warts (verruca vulgaris), plantar warts (verruca plantaris), or plane warts (verruca plana). These benign skin lesions are caused by human papillomavirus and can manifest in areas of skin trauma; this is known as the Koebner phenomenon. Most warts can be diagnosed through clinical history and examination. Dermoscopy, if performed, may reveal thrombosed capillaries as dotted structures, but there is an increased risk of cross-contamination.¹ That said, some dermatoscopes have disposable covers or can be cleaned with antiviral, antibacterial wipes. If the diagnosis is unclear or the exam is clinically suspicious, a biopsy may be required.

Cases with progressive enlargement and extensive involvement of the skin (as was seen here) are generally associated with certain predisposing conditions, such as atopic dermatitis and immunosuppression.² Our patient screened negative for HIV infection, and further evaluation did not reveal any concerns for immunosuppression.

Treatment for a common wart depends on patient characteristics, preferences, cost, and possible adverse effects. Standard treatment options are topical salicylic acid and cryotherapy with liquid nitrogen. Depending on the location and type of the wart, multiple treatments may be required, and recurrences are common. Intralesional injection with bleomycin, 5‐fluorouracil, or cidofovir is often used for recurrent and refractory warts.

Patients unable to tolerate cryotherapy or local injections may benefit from thermotherapy by heating the wart with a pulsed dye laser.³ Observation is also a reasonable course of action for new warts, as they may spontaneously resolve within a year.

In this case, the patient opted for over-the-counter salicylic acid 17% to be applied nightly until resolution. Cryosurgery would be a next step for him if the lesion does not resolve after 3 months of treatment.

‌

Image courtesy of Faryal Tahir, MD. Text courtesy of Faryal Tahir, MD, Assistant Professor, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

A shave biopsy revealed acanthosis, papillomatosis, hyperkeratosis, hypergranulosis, parakeratosis, and cytoplasmic viral-like inclusions without atypia, consistent with a diagnosis of a common wart. The biopsy ruled out other possible diagnoses, which included keratoacanthoma, seborrheic keratosis, and squamous cell carcinoma.

Cutaneous warts can manifest as common warts (verruca vulgaris), plantar warts (verruca plantaris), or plane warts (verruca plana). These benign skin lesions are caused by human papillomavirus and can manifest in areas of skin trauma; this is known as the Koebner phenomenon. Most warts can be diagnosed through clinical history and examination. Dermoscopy, if performed, may reveal thrombosed capillaries as dotted structures, but there is an increased risk of cross-contamination.¹ That said, some dermatoscopes have disposable covers or can be cleaned with antiviral, antibacterial wipes. If the diagnosis is unclear or the exam is clinically suspicious, a biopsy may be required.

Cases with progressive enlargement and extensive involvement of the skin (as was seen here) are generally associated with certain predisposing conditions, such as atopic dermatitis and immunosuppression.² Our patient screened negative for HIV infection, and further evaluation did not reveal any concerns for immunosuppression.

Treatment for a common wart depends on patient characteristics, preferences, cost, and possible adverse effects. Standard treatment options are topical salicylic acid and cryotherapy with liquid nitrogen. Depending on the location and type of the wart, multiple treatments may be required, and recurrences are common. Intralesional injection with bleomycin, 5‐fluorouracil, or cidofovir is often used for recurrent and refractory warts.

Patients unable to tolerate cryotherapy or local injections may benefit from thermotherapy by heating the wart with a pulsed dye laser.³ Observation is also a reasonable course of action for new warts, as they may spontaneously resolve within a year.

In this case, the patient opted for over-the-counter salicylic acid 17% to be applied nightly until resolution. Cryosurgery would be a next step for him if the lesion does not resolve after 3 months of treatment.

‌

Image courtesy of Faryal Tahir, MD. Text courtesy of Faryal Tahir, MD, Assistant Professor, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

The US Preventive Services Task Force (USPSTF) recently released their final recommendation update on the use of antiretroviral therapy to prevent HIV infection in adolescents and adults who are at increased risk.¹ The Task Force last addressed this topic in 2019; since then, 2 additional antiretroviral regimens have been approved for preexposure prophylaxis (PrEP). The update also includes revised wording on who should consider receiving PrEP.

HIV remains a significant public health problem in the United States. The Centers for Disease Control and Prevention (CDC) estimates that 1.2 million people in the United States are living with HIV, and approximately 30,000 new infections occur each year.² Men who have sex with men account for 68% of new infections, and there are marked racial disparities in both incidence and prevalence of infection, with Black/African Americans accounting for 42% of new infections.²

PrEP decreases the risk for HIV by about 50% overall, with higher rates of protection correlated to higher adherence (close to 100% protection with daily adherence to oral regimens).³ The 3 approved regimens for PrEP are outlined in TABLE 1³.

Who’s at increased risk? The USPSTF did not find any risk assessment tools with proven accuracy in identifying those at increased risk for HIV infection but did document risk factors and behaviors that can be used to predict risk. They encourage discussion about HIV prevention with all adults and adolescents who are sexually active or who inject drugs.

Those people for whom the Task Force recommends considering PrEP are listed in TABLE 2¹. However, the USPSTF recommends providing PrEP to anyone who requests it, as they may not want to disclose their risk factors.

What to keep in mind. Family physicians are encouraged to read the full USPSTF report and refer to CDC guidelines on prescribing PrEP, which provide details on each regimen and the routine laboratory testing that should be performed.⁴ The most important clinical considerations described in the USPSTF report are:

• Before starting PrEP, document a negative HIV antigen/antibody test result and continue to test for HIV every 3 months. PrEP regimens should not be used to treat HIV.
• Document a negative HIV RNA assay if the patient has taken oral PrEP in the past 3 months or injectable PrEP in the past 12 months.
• At PrEP initiation, consider ordering other recommended tests, such as those for kidney function, chronic hepatitis B infection (if using tenofovir disoproxil fumarate/emtricitabine), lipid levels (if using tenofovir alafenamide/emtricitabine), and other sexually transmitted infection (STIs).
• Encourage the use of condoms, as PrEP does not protect from other STIs.
• Follow up regularly, and at each patient visit stress the need for medication adherence to achieve maximum protection.

The US Preventive Services Task Force (USPSTF) recently released their final recommendation update on the use of antiretroviral therapy to prevent HIV infection in adolescents and adults who are at increased risk.¹ The Task Force last addressed this topic in 2019; since then, 2 additional antiretroviral regimens have been approved for preexposure prophylaxis (PrEP). The update also includes revised wording on who should consider receiving PrEP.

HIV remains a significant public health problem in the United States. The Centers for Disease Control and Prevention (CDC) estimates that 1.2 million people in the United States are living with HIV, and approximately 30,000 new infections occur each year.² Men who have sex with men account for 68% of new infections, and there are marked racial disparities in both incidence and prevalence of infection, with Black/African Americans accounting for 42% of new infections.²

PrEP decreases the risk for HIV by about 50% overall, with higher rates of protection correlated to higher adherence (close to 100% protection with daily adherence to oral regimens).³ The 3 approved regimens for PrEP are outlined in TABLE 1³.

Who’s at increased risk? The USPSTF did not find any risk assessment tools with proven accuracy in identifying those at increased risk for HIV infection but did document risk factors and behaviors that can be used to predict risk. They encourage discussion about HIV prevention with all adults and adolescents who are sexually active or who inject drugs.

Those people for whom the Task Force recommends considering PrEP are listed in TABLE 2¹. However, the USPSTF recommends providing PrEP to anyone who requests it, as they may not want to disclose their risk factors.

What to keep in mind. Family physicians are encouraged to read the full USPSTF report and refer to CDC guidelines on prescribing PrEP, which provide details on each regimen and the routine laboratory testing that should be performed.⁴ The most important clinical considerations described in the USPSTF report are:

• Before starting PrEP, document a negative HIV antigen/antibody test result and continue to test for HIV every 3 months. PrEP regimens should not be used to treat HIV.
• Document a negative HIV RNA assay if the patient has taken oral PrEP in the past 3 months or injectable PrEP in the past 12 months.
• At PrEP initiation, consider ordering other recommended tests, such as those for kidney function, chronic hepatitis B infection (if using tenofovir disoproxil fumarate/emtricitabine), lipid levels (if using tenofovir alafenamide/emtricitabine), and other sexually transmitted infection (STIs).
• Encourage the use of condoms, as PrEP does not protect from other STIs.
• Follow up regularly, and at each patient visit stress the need for medication adherence to achieve maximum protection.

The US Preventive Services Task Force (USPSTF) recently released their final recommendation update on the use of antiretroviral therapy to prevent HIV infection in adolescents and adults who are at increased risk.¹ The Task Force last addressed this topic in 2019; since then, 2 additional antiretroviral regimens have been approved for preexposure prophylaxis (PrEP). The update also includes revised wording on who should consider receiving PrEP.

HIV remains a significant public health problem in the United States. The Centers for Disease Control and Prevention (CDC) estimates that 1.2 million people in the United States are living with HIV, and approximately 30,000 new infections occur each year.² Men who have sex with men account for 68% of new infections, and there are marked racial disparities in both incidence and prevalence of infection, with Black/African Americans accounting for 42% of new infections.²

PrEP decreases the risk for HIV by about 50% overall, with higher rates of protection correlated to higher adherence (close to 100% protection with daily adherence to oral regimens).³ The 3 approved regimens for PrEP are outlined in TABLE 1³.

Who’s at increased risk? The USPSTF did not find any risk assessment tools with proven accuracy in identifying those at increased risk for HIV infection but did document risk factors and behaviors that can be used to predict risk. They encourage discussion about HIV prevention with all adults and adolescents who are sexually active or who inject drugs.

Those people for whom the Task Force recommends considering PrEP are listed in TABLE 2¹. However, the USPSTF recommends providing PrEP to anyone who requests it, as they may not want to disclose their risk factors.

What to keep in mind. Family physicians are encouraged to read the full USPSTF report and refer to CDC guidelines on prescribing PrEP, which provide details on each regimen and the routine laboratory testing that should be performed.⁴ The most important clinical considerations described in the USPSTF report are:

• Before starting PrEP, document a negative HIV antigen/antibody test result and continue to test for HIV every 3 months. PrEP regimens should not be used to treat HIV.
• Document a negative HIV RNA assay if the patient has taken oral PrEP in the past 3 months or injectable PrEP in the past 12 months.
• At PrEP initiation, consider ordering other recommended tests, such as those for kidney function, chronic hepatitis B infection (if using tenofovir disoproxil fumarate/emtricitabine), lipid levels (if using tenofovir alafenamide/emtricitabine), and other sexually transmitted infection (STIs).
• Encourage the use of condoms, as PrEP does not protect from other STIs.
• Follow up regularly, and at each patient visit stress the need for medication adherence to achieve maximum protection.

The patient’s multiple pink, subtly annular patches after recent travel to Lyme-endemic areas of the United States demonstrated a classic manifestation of disseminated Lyme disease. An enzyme-linked immunosorbent assay was positive for Borrelia burgdorferi IgM and IgG antibodies, confirming an acute infection.

While not usually necessary, skin biopsy shows a nonspecific perivascular cellular infiltrate that may be comprised of histiocytes, lymphocytes, and plasma cells. Spirochetes are not typically seen, but they may be identified with antibody-labeled or silver stains.

Lyme disease initially manifests as localized disease with erythema migrans, a targetoid lesion on the skin that appears at the site of the tick bite. This initial stage develops within the first few weeks of the bite and may be accompanied by fatigue and a low-grade fever.

If left untreated, the infection may progress to early disseminated disease, which occurs weeks to months after the initial bite. This second stage of Lyme disease manifests with multiple erythema migrans lesions on additional parts of the body, indicating spirochete dissemination through the bloodstream and lymphatic system. Early disseminated disease may also include borrelial lymphocytoma, Lyme neuroborreliosis, and cardiac conduction abnormalities such as AV block.

The third stage of Lyme disease, late Lyme disease, occurs months to years after an initial infection that has gone untreated. The key feature of this stage is arthritis, which tends to affect the knees and may be migratory in nature. Neurological symptoms such as encephalopathy and polyneuropathies may also develop. A minority of patients with late Lyme disease may develop acrodermatitis chronica atrophicans, a rash that typically occurs on the dorsal hands and feet as blue-red plaques that turn the affected skin atrophic.¹

This patient was treated with a 3-week course of oral doxycycline 100 mg twice daily and was referred to an infectious disease specialist for further work-up of systemic symptoms, given the risk for cardiac pathology in disseminated Lyme disease.

‌

Photo courtesy of Le Wen Chiu, MD. Text courtesy of Le Wen Chiu, MD, Department of Dermatology, University of New Mexico School of Medicine, Albuquerque, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

The patient’s multiple pink, subtly annular patches after recent travel to Lyme-endemic areas of the United States demonstrated a classic manifestation of disseminated Lyme disease. An enzyme-linked immunosorbent assay was positive for Borrelia burgdorferi IgM and IgG antibodies, confirming an acute infection.

While not usually necessary, skin biopsy shows a nonspecific perivascular cellular infiltrate that may be comprised of histiocytes, lymphocytes, and plasma cells. Spirochetes are not typically seen, but they may be identified with antibody-labeled or silver stains.

Lyme disease initially manifests as localized disease with erythema migrans, a targetoid lesion on the skin that appears at the site of the tick bite. This initial stage develops within the first few weeks of the bite and may be accompanied by fatigue and a low-grade fever.

If left untreated, the infection may progress to early disseminated disease, which occurs weeks to months after the initial bite. This second stage of Lyme disease manifests with multiple erythema migrans lesions on additional parts of the body, indicating spirochete dissemination through the bloodstream and lymphatic system. Early disseminated disease may also include borrelial lymphocytoma, Lyme neuroborreliosis, and cardiac conduction abnormalities such as AV block.

The third stage of Lyme disease, late Lyme disease, occurs months to years after an initial infection that has gone untreated. The key feature of this stage is arthritis, which tends to affect the knees and may be migratory in nature. Neurological symptoms such as encephalopathy and polyneuropathies may also develop. A minority of patients with late Lyme disease may develop acrodermatitis chronica atrophicans, a rash that typically occurs on the dorsal hands and feet as blue-red plaques that turn the affected skin atrophic.¹

This patient was treated with a 3-week course of oral doxycycline 100 mg twice daily and was referred to an infectious disease specialist for further work-up of systemic symptoms, given the risk for cardiac pathology in disseminated Lyme disease.

‌

Photo courtesy of Le Wen Chiu, MD. Text courtesy of Le Wen Chiu, MD, Department of Dermatology, University of New Mexico School of Medicine, Albuquerque, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

The patient’s multiple pink, subtly annular patches after recent travel to Lyme-endemic areas of the United States demonstrated a classic manifestation of disseminated Lyme disease. An enzyme-linked immunosorbent assay was positive for Borrelia burgdorferi IgM and IgG antibodies, confirming an acute infection.

While not usually necessary, skin biopsy shows a nonspecific perivascular cellular infiltrate that may be comprised of histiocytes, lymphocytes, and plasma cells. Spirochetes are not typically seen, but they may be identified with antibody-labeled or silver stains.

Lyme disease initially manifests as localized disease with erythema migrans, a targetoid lesion on the skin that appears at the site of the tick bite. This initial stage develops within the first few weeks of the bite and may be accompanied by fatigue and a low-grade fever.

If left untreated, the infection may progress to early disseminated disease, which occurs weeks to months after the initial bite. This second stage of Lyme disease manifests with multiple erythema migrans lesions on additional parts of the body, indicating spirochete dissemination through the bloodstream and lymphatic system. Early disseminated disease may also include borrelial lymphocytoma, Lyme neuroborreliosis, and cardiac conduction abnormalities such as AV block.

The third stage of Lyme disease, late Lyme disease, occurs months to years after an initial infection that has gone untreated. The key feature of this stage is arthritis, which tends to affect the knees and may be migratory in nature. Neurological symptoms such as encephalopathy and polyneuropathies may also develop. A minority of patients with late Lyme disease may develop acrodermatitis chronica atrophicans, a rash that typically occurs on the dorsal hands and feet as blue-red plaques that turn the affected skin atrophic.¹

This patient was treated with a 3-week course of oral doxycycline 100 mg twice daily and was referred to an infectious disease specialist for further work-up of systemic symptoms, given the risk for cardiac pathology in disseminated Lyme disease.

‌

Photo courtesy of Le Wen Chiu, MD. Text courtesy of Le Wen Chiu, MD, Department of Dermatology, University of New Mexico School of Medicine, Albuquerque, and Daniel Stulberg, MD, FAAFP, Professor and Chair, Department of Family and Community Medicine, Western Michigan University Homer Stryker, MD School of Medicine, Kalamazoo.

This patient had a posttraumatic tache noir (also known as talon noir on the volar aspect of the feet); it is a subcorneal hematoma. The diagnosis is made clinically. Dermoscopic evaluation of tache/talon noir will reveal “pebbles on a ridge” or “satellite globules.” Confirmation of tache/talon noir can be made by paring the corneum with a #15 blade, which will reveal blood in the shavings and punctate lesions.¹

This patient noted that the knob of his baseball bat rubbed the hypothenar eminence of his nondominant hand when he took a swing. The sheer force of the knob led to the subcorneal hematoma. Tache noir was high on the differential due to his physician’s clinical experience with similar cases. Tache noir occurs predominantly in people ages 12 to 24 years, without regard to gender.² The condition is commonly found in athletes who participate in baseball, cricket, racquet sports, weightlifting, and rock climbing.^2-4

Talon noir occurs most commonly in athletes who are frequently jumping, turning, and pivoting, as in football, basketball, tennis, and lacrosse.

Tache noir can be differentiated from other conditions by the presence of preserved architecture of the skin surface and punctate capillaries beneath the stratum corneum. The differential diagnosis includes verruca vulgaris, acral melanoma, and a traumatic tattoo.

Talon/tache noir are benign conditions that do not require treatment and do not affect sports performance. The lesion will usually self-resolve within a matter of weeks from onset or can even be gently scraped with a sterile needle or blade.

This patient was advised that the lesion would resolve on its own. His knee pain was determined to be a simple case of patellofemoral syndrome or “runner’s knee” and he opted to complete a home exercise program to obtain relief.

‌

This case was adapted from: Warden D. Hyperpigmented lesion on left palm. J Fam Pract. 2021;70:459-460. Photos courtesy of Daniel Warden, MD

This patient had a posttraumatic tache noir (also known as talon noir on the volar aspect of the feet); it is a subcorneal hematoma. The diagnosis is made clinically. Dermoscopic evaluation of tache/talon noir will reveal “pebbles on a ridge” or “satellite globules.” Confirmation of tache/talon noir can be made by paring the corneum with a #15 blade, which will reveal blood in the shavings and punctate lesions.¹

This patient noted that the knob of his baseball bat rubbed the hypothenar eminence of his nondominant hand when he took a swing. The sheer force of the knob led to the subcorneal hematoma. Tache noir was high on the differential due to his physician’s clinical experience with similar cases. Tache noir occurs predominantly in people ages 12 to 24 years, without regard to gender.² The condition is commonly found in athletes who participate in baseball, cricket, racquet sports, weightlifting, and rock climbing.^2-4

Talon noir occurs most commonly in athletes who are frequently jumping, turning, and pivoting, as in football, basketball, tennis, and lacrosse.

Tache noir can be differentiated from other conditions by the presence of preserved architecture of the skin surface and punctate capillaries beneath the stratum corneum. The differential diagnosis includes verruca vulgaris, acral melanoma, and a traumatic tattoo.

Talon/tache noir are benign conditions that do not require treatment and do not affect sports performance. The lesion will usually self-resolve within a matter of weeks from onset or can even be gently scraped with a sterile needle or blade.

This patient was advised that the lesion would resolve on its own. His knee pain was determined to be a simple case of patellofemoral syndrome or “runner’s knee” and he opted to complete a home exercise program to obtain relief.

‌

This case was adapted from: Warden D. Hyperpigmented lesion on left palm. J Fam Pract. 2021;70:459-460. Photos courtesy of Daniel Warden, MD

This patient had a posttraumatic tache noir (also known as talon noir on the volar aspect of the feet); it is a subcorneal hematoma. The diagnosis is made clinically. Dermoscopic evaluation of tache/talon noir will reveal “pebbles on a ridge” or “satellite globules.” Confirmation of tache/talon noir can be made by paring the corneum with a #15 blade, which will reveal blood in the shavings and punctate lesions.¹

This patient noted that the knob of his baseball bat rubbed the hypothenar eminence of his nondominant hand when he took a swing. The sheer force of the knob led to the subcorneal hematoma. Tache noir was high on the differential due to his physician’s clinical experience with similar cases. Tache noir occurs predominantly in people ages 12 to 24 years, without regard to gender.² The condition is commonly found in athletes who participate in baseball, cricket, racquet sports, weightlifting, and rock climbing.^2-4

Talon noir occurs most commonly in athletes who are frequently jumping, turning, and pivoting, as in football, basketball, tennis, and lacrosse.

Tache noir can be differentiated from other conditions by the presence of preserved architecture of the skin surface and punctate capillaries beneath the stratum corneum. The differential diagnosis includes verruca vulgaris, acral melanoma, and a traumatic tattoo.

Talon/tache noir are benign conditions that do not require treatment and do not affect sports performance. The lesion will usually self-resolve within a matter of weeks from onset or can even be gently scraped with a sterile needle or blade.

This patient was advised that the lesion would resolve on its own. His knee pain was determined to be a simple case of patellofemoral syndrome or “runner’s knee” and he opted to complete a home exercise program to obtain relief.

‌

This case was adapted from: Warden D. Hyperpigmented lesion on left palm. J Fam Pract. 2021;70:459-460. Photos courtesy of Daniel Warden, MD

Two shave biopsies were taken, 1 in the center of a previous SCC site with hyperkeratosis, the other in a site not previously affected by SCC but with the physical features of a pustule. Biopsy results from both sites were consistent with erosive pustular dermatosis, an unusual inflammatory disorder that mimics SCC.

Erosive pustular dermatosis of the scalp is an uncommon dermatitis that usually affects older women but may appear in men and women of all ages. It can mimic many other conditions that can affect the scalp, including seborrheic dermatitis, psoriasis, actinic keratosis, and SCC.

The exact causative mechanism is not understood, and cases may develop spontaneously. Rough papules, pustules, crusts, and ulcers develop and (apart from the pustules) share many features of actinic keratoses, SCCs, and field cancerization. The presence of pustules helps point to the diagnosis.

Triggers include previous surgery or physical trauma, burns, skin or hair grafts, and treatment of actinic keratoses with imiquimod, 5-fluourouracil, or photodynamic therapy. Some autoimmune diseases (including Hashimoto thyroiditis, autoimmune hepatitis, and rheumatoid arthritis) have been linked to disease occurrence and severity.¹

Treatment includes potent or super-potent topical steroids such as clobetasol 0.05% ointment. Topical tacrolimus 0.1% ointment and calcipotriene 0.005% cream have been reported as steroid alternatives. Paradoxically, photodynamic therapy, while associated with triggering disease, has also been used therapeutically. Systemic immunomodulators such as cyclosporine 3 mg/kg/d or prednisone 0.5 to 1 mg/kg/d may be needed in severe cases. Antibiotics including topical dapsone 5% gel, systemic dapsone from 50 mg bid to tid, and doxycycline have been helpful due, in part, to their immunomodulatory effects.^1,2

This patient was told to apply topical triamcinolone 0.1% ointment around and over ulcers and pustules and to take doxycycline 100 mg twice daily. The patient cleared well after 6 weeks. He continued to apply topical triamcinolone every few days as maintenance therapy.

He had some mild recurrence after discontinuing all topical and oral therapy, so he currently is being maintained on topical clobetasol 0.05% ointment every other day. He comes in for follow-up appointments every 3 months to monitor for control of the erosive pustular dermatosis of the scalp and for skin cancer surveillance.

‌

Photos and text for Photo Rounds Friday courtesy of Jonathan Karnes, MD (copyright retained). Dr. Karnes is the medical director of MDFMR Dermatology Services, Augusta, ME

Two shave biopsies were taken, 1 in the center of a previous SCC site with hyperkeratosis, the other in a site not previously affected by SCC but with the physical features of a pustule. Biopsy results from both sites were consistent with erosive pustular dermatosis, an unusual inflammatory disorder that mimics SCC.

Erosive pustular dermatosis of the scalp is an uncommon dermatitis that usually affects older women but may appear in men and women of all ages. It can mimic many other conditions that can affect the scalp, including seborrheic dermatitis, psoriasis, actinic keratosis, and SCC.

The exact causative mechanism is not understood, and cases may develop spontaneously. Rough papules, pustules, crusts, and ulcers develop and (apart from the pustules) share many features of actinic keratoses, SCCs, and field cancerization. The presence of pustules helps point to the diagnosis.

Triggers include previous surgery or physical trauma, burns, skin or hair grafts, and treatment of actinic keratoses with imiquimod, 5-fluourouracil, or photodynamic therapy. Some autoimmune diseases (including Hashimoto thyroiditis, autoimmune hepatitis, and rheumatoid arthritis) have been linked to disease occurrence and severity.¹

Treatment includes potent or super-potent topical steroids such as clobetasol 0.05% ointment. Topical tacrolimus 0.1% ointment and calcipotriene 0.005% cream have been reported as steroid alternatives. Paradoxically, photodynamic therapy, while associated with triggering disease, has also been used therapeutically. Systemic immunomodulators such as cyclosporine 3 mg/kg/d or prednisone 0.5 to 1 mg/kg/d may be needed in severe cases. Antibiotics including topical dapsone 5% gel, systemic dapsone from 50 mg bid to tid, and doxycycline have been helpful due, in part, to their immunomodulatory effects.^1,2

This patient was told to apply topical triamcinolone 0.1% ointment around and over ulcers and pustules and to take doxycycline 100 mg twice daily. The patient cleared well after 6 weeks. He continued to apply topical triamcinolone every few days as maintenance therapy.

He had some mild recurrence after discontinuing all topical and oral therapy, so he currently is being maintained on topical clobetasol 0.05% ointment every other day. He comes in for follow-up appointments every 3 months to monitor for control of the erosive pustular dermatosis of the scalp and for skin cancer surveillance.

‌

Photos and text for Photo Rounds Friday courtesy of Jonathan Karnes, MD (copyright retained). Dr. Karnes is the medical director of MDFMR Dermatology Services, Augusta, ME

Two shave biopsies were taken, 1 in the center of a previous SCC site with hyperkeratosis, the other in a site not previously affected by SCC but with the physical features of a pustule. Biopsy results from both sites were consistent with erosive pustular dermatosis, an unusual inflammatory disorder that mimics SCC.

Erosive pustular dermatosis of the scalp is an uncommon dermatitis that usually affects older women but may appear in men and women of all ages. It can mimic many other conditions that can affect the scalp, including seborrheic dermatitis, psoriasis, actinic keratosis, and SCC.

The exact causative mechanism is not understood, and cases may develop spontaneously. Rough papules, pustules, crusts, and ulcers develop and (apart from the pustules) share many features of actinic keratoses, SCCs, and field cancerization. The presence of pustules helps point to the diagnosis.

Triggers include previous surgery or physical trauma, burns, skin or hair grafts, and treatment of actinic keratoses with imiquimod, 5-fluourouracil, or photodynamic therapy. Some autoimmune diseases (including Hashimoto thyroiditis, autoimmune hepatitis, and rheumatoid arthritis) have been linked to disease occurrence and severity.¹

Treatment includes potent or super-potent topical steroids such as clobetasol 0.05% ointment. Topical tacrolimus 0.1% ointment and calcipotriene 0.005% cream have been reported as steroid alternatives. Paradoxically, photodynamic therapy, while associated with triggering disease, has also been used therapeutically. Systemic immunomodulators such as cyclosporine 3 mg/kg/d or prednisone 0.5 to 1 mg/kg/d may be needed in severe cases. Antibiotics including topical dapsone 5% gel, systemic dapsone from 50 mg bid to tid, and doxycycline have been helpful due, in part, to their immunomodulatory effects.^1,2

This patient was told to apply topical triamcinolone 0.1% ointment around and over ulcers and pustules and to take doxycycline 100 mg twice daily. The patient cleared well after 6 weeks. He continued to apply topical triamcinolone every few days as maintenance therapy.

He had some mild recurrence after discontinuing all topical and oral therapy, so he currently is being maintained on topical clobetasol 0.05% ointment every other day. He comes in for follow-up appointments every 3 months to monitor for control of the erosive pustular dermatosis of the scalp and for skin cancer surveillance.

‌

Photos and text for Photo Rounds Friday courtesy of Jonathan Karnes, MD (copyright retained). Dr. Karnes is the medical director of MDFMR Dermatology Services, Augusta, ME