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Transgender and Gender Diverse Health Care in the US Military: What Dermatologists Need to Know

Article Type
Article
Changed
Mon, 07/08/2024 - 12:57
Display Headline
Transgender and Gender Diverse Health Care in the US Military: What Dermatologists Need to Know
Author(s)
Frank B. Higgins, MD
Heidi L. Dearborn, DO
Joshua M. Smalley, DO

People whose gender identity differs from the sex assigned at birth are referred to as transgender. For some, gender identity may not fit into the binary constructs of male and female but rather falls between, within, or outside this construct. These people often consider themselves nonbinary or gender diverse. As the terminology continues to evolve, current recommendations include referring to this patient population as transgender and gender diverse (TGD) to ensure the broadest inclusivity.1 In this article, the following terms are used as defined below:

  • The terms transgender woman and trans feminine describe persons who were assigned male gender at birth but their affirmed gender is female or nonmasculine.
  • The terms transgender man and trans masculine describe persons who were assigned female gender at birth but their affirmed gender is male or nonfeminine.

The US Military’s policies on the service of TGD persons have evolved considerably over the past decade. Initial military policies barred TGD service members (TSMs) from service all together, leading to challenges in accessing necessary health care. The first official memorandum explicitly allowing military service by TGD persons was released on June 30, 2016.2 The intention of this memorandum was 2-fold: (1) to allow TGD persons to serve in the military so long as they meet “the rigorous standards for military service and readiness” by fulfilling the same standards and procedures as other military service members, including medical fitness for duty, physical fitness, uniform and grooming, deployability, and retention, and (2) to direct the establishment of new or updated policies to specific departments and prescribe procedures for retention standards, separation from service, in-service transition, and medical coverage.2 Several other official policies were released following this initial memorandum that provided more specific guidance on how to implement these policies at the level of the force, unit, and individual service member.

Modifications to the original 2016 policies had varying impacts on transgender health care provision and access.3 At the time of publication of this article, the current policy—the Department of Defense Instruction 1300.284—among others, establishes standards and procedures for the process by which active and reserve TSMs may medically, socially, and legally transition genders within the military. The current policy applies to all military branches and serves as the framework by which each branch currently organizes their gender-affirmation processes (GAP).4

There currently are several different GAP models among the military branches.5 Each branch has a different model or approach to implementing the current policy, with varying service-specific processes in place for TSMs to access gender-affirming care; however, this may be changing. The Defense Health Agency is in the process of consolidating and streamlining the GAP across the Department of Defense branches in an effort to optimize costs and ensure uniformity of care. Per the Defense Health Agency Procedural Instruction Number 6025.21 published in May 2023, the proposed consolidated model likely will entail a single central transgender health center that provides oversight and guidance for several regional joint-service gender-affirming medical hubs. Patients would either be managed at the level of the hub or be referred to the central site.5

Herein, we discuss the importance of gender-affirming care and how military and civilian dermatologists can contribute. We also review disparities in health care and identify areas of improvement.

 

 

Benefits of Gender-Affirming Care

Gender-affirming procedures are critical for aligning physical appearance with gender identity. Physical appearance is essential for psychological well-being, operational readiness, and the safety of TSMs.6 It is well documented that TGD persons experience suicidal ideation, depression, stigma, discrimination and violence at higher rates than their cisgender peers.7,8 It is important to recognize that transgender identity is not a mental illness, and these elevated rates have been linked to complex trauma, societal stigma, violence, and discrimination.1 Other studies have suggested that increased access to gender-affirming interventions may ameliorate these mental health concerns.1,7-9

The major components of gender-affirming care include hormone therapy, gender confirmation surgery, and mental health care, if needed. These are covered by TRICARE, the health care program for military service members; however, at the time of publication, many of the dermatologic gender-affirming procedures are not covered by TRICARE because they are considered “cosmetic procedures,” which is a term used by insurance companies but does not accurately indicate whether a procedure is medically necessary or not. Newer literature has demonstrated that gender-affirming care positively affects the lives of TGD patients, strengthening the argument that gender-affirming care is a medical necessity and not just cosmetic.1

Aesthetic Procedures in Gender-Affirming Care

Surgeons, including those within the specialties of oto-laryngology, oral and maxillofacial surgery, urology, gynecology, and plastic surgery, provide major gender-affirming interventions; however, dermatologists may offer less invasive solutions that can serve as a temporary experience prior to undergoing more permanent procedures.Hormonally driven disorders including acne, hair loss, and melasma also are managed by dermatologists, along with scar treatment following surgeries.

Because human variation is expansive and subjective, what is considered feminine or masculine may vary by person, group, culture, and country; therefore, it is imperative to ask patients about their individual aesthetic goals and tailor their treatment accordingly. Feminine and masculine are terms that will be used to describe prototypical appearances and are not meant to define a patient’s current state or ultimate goals. The following procedures and medical interventions are where dermatologists can play an important role in TGD persons’ GAPs.

Botulinum Toxin Injections—Botulinum toxin injection is the most common nonsurgical aesthetic procedure performed around the world.10 The selective paralysis afforded by botulinum toxin has several uses for people undergoing transition. Aesthetically, the feminine eyebrow tends to be positioned above the orbital rim and is arched with its apex between the lateral limbus and lateral canthus,11 while the masculine eyebrow tends to be flatter and fuller and runs over the orbital rim without a peak. For people seeking a more feminine appearance, an eyebrow lift with botulinum toxin can help reshape the typical flatter masculine eyebrow to give it lateral lift that often is considered more feminine. The targeted muscle is the superolateral orbicularis oculi, which serves as a depressor on the eyebrow. This can be combined with purposefully avoiding total lateral frontalis paralysis, which leads to a “Spock” brow for extra lift. Conversely, a naturally arched and higher eyebrow can be flattened and lowered by selectively targeting areas of the frontalis muscle.

Broad square jawlines typically are considered a masculine feature and are another area where botulinum toxin can be used to feminize a patient’s facial features. Targeting the masseter muscle induces muscle weakness, which ultimately may result in atrophy after one or more treatment sessions. This atrophy may lead to narrowing of the lower face and thus may lead to a fuller-appearing midface or overall more heart-shaped face. Every individual’s aesthetic goals are unique and therefore should be discussed prior to any treatment.

Dermal Fillers—Dermal fillers are gel-like substances injected under the skin for subtle contouring of the face. Fillers also can be used to help promote a more masculine or feminine appearance. Filler can be placed in the lips to create a fuller, more projected, feminine-appearing lip. Malar cheek and central lower chin filler can be used to help define a heart-shaped face by accentuating the upper portion of the face and creating a more pointed chin, respectively. Alternatively, filler can be used to masculinize the chin by placing it where it can increase jawline squareness and increase anterior jaw projection. Additionally, filler at the angle of the jaw can help accentuate a square facial shape and a more defined jawline. Although not as widely practiced, lateral brow filler can create a heavier-appearing and broader forehead for a more masculine appearance. These procedures can be combined with the previously mentioned botulinum toxin procedures for a synergistic effect.

Deoxycholic Acid—Deoxycholic acid is an injectable product used to selectively remove unwanted fat. It currently is approved by the US Food and Drug Administration for submental fat, but some providers are experimenting with off-label uses. Buccal fat pad removal—or in this case reduction by dissolution—tends to give a thinner, more feminine facial appearance.12 Reducing fat around the axillae also can help promote a more masculine upper torso.13 The safety of deoxycholic acid in these areas has not been adequately tested; thus, caution should be used when discussing these off-label uses with patients.

Hair and Tattoo Removal—Hair removal may be desired by TGD persons for a variety of reasons. Because cisgender females tend to have less body hair overall, transgender people in pursuit of a more feminine appearance often desire removal of facial, neck, and body hair. Although shaving and other modalities such as waxing and chemical depilatories are readily available at-home options, they are not permanent and may lead to folliculitis or pseudofolliculitis barbae. Laser hair removal (LHR) and electrolysis are modalities provided by dermatologists that tend to be more permanent and lead to better outcomes, including less irritation and better aesthetic appearance. It is important to keep in mind that not every person and not every body site can be safely treated with LHR. Patients with lighter skin types and darker hair tend to have the most effective response with a higher margin of safety, as these features allow the laser energy to be selectively absorbed by the melanin in the hair bulb and not by the background skin pigmentation.14,15 Inappropriate patient selection or improper settings for wavelength, pulse width, or fluences can lead to burns and permanent scarring.14,15 Electrolysis is an alternative to hair removal within tattoos and is more effective for those individuals with blonde, red, or white hair.16

Another novel treatment for unwanted hair is eflor­nithine hydrochloride cream, which works by blocking ornithine decarboxylase, the enzyme that stimulates hair growth. It currently is approved to reduce unwanted hair on the face and adjacent areas under the chin; however the effects of this medication are modest and the medication can be expensive.17

Cosmetic hair and tattoo removal are not currently covered by TRICARE, except in cases of surgical and donor-site preparation for some GAPs. Individuals may desire removal of tattoos at surgery sites to obtain more natural-appearing skin. Currently, GAPs such as vaginoplasty, phalloplasty, and metoidioplasty—often referred to by patients as “bottom surgeries”—include insurance coverage for tattoo removal, LHR, and/or electrolysis.

 

 

Management of Hormonal Adverse Effects

Acne—Individuals on testosterone supplementation tend to develop acne for the first several years of treatment, but it may improve with time.18 Acne is treated in individuals receiving testosterone the same way as it is treated in cisgender men, with numerous options for topical and oral medications. In trans masculine persons, spironolactone therapy typically is avoided because it may interfere with the actions of exogenous testosterone administered as part of gender-affirming medical treatment and may lead to other undesired adverse effects such as impotence and gynecomastia.1

Although acne typically improves after starting estrogen therapy, patients receiving estrogens may still develop acne. Most trans feminine patients will already be on an estrogen and an antiandrogen, often spironolactone.1 Spironolactone often is used as monotherapy for acne control in cisgender women. Additionally, an important factor to consider with spironolactone is the possible adverse effect of increased micturition. Currently, the military rarely has gender-inclusive restroom options, which can create a challenge for TSMs who find themselves needing to use the restroom more frequently in the workplace.

If planning therapy with isotretinoin, dermatologists should discuss several important factors with all patients, including TGD patients. One consideration is the patient’s planned future surgeries. Although new literature shows that isotretinoin does not adversely affect wound healing,19 some surgeons still adhere to an isotretinoin washout period of 6 to 12 months prior to performing any elective procedures due to concerns about wound healing.20,21 Second, be sure to properly assess and document pregnancy potential in TGD persons. Providers should not assume that a patient is not pregnant or is not trying to become pregnant just because they are trans masculine. It also is important to note that testosterone is not a reliable birth control method.1 If a patient still has ovaries, fallopian tubes, and a uterus, they are considered medically capable of pregnancy, and providers should keep this in mind regarding all procedures in the TGD population.

Another newer acne treatment modality is the 1762-nm laser, which targets sebaceous glands.22 This device allows for targeted treatment of acne-prone areas without systemic therapy such as retinoids or antiandrogens. The 1762-nm laser is not widely available but may become a regular treatment option once its benefits are proven over time.

Alopecia and Hyperpigmentation—Androgens, whether endogenously or exogenously derived, can lead to androgenetic alopecia (AGA) in genetically susceptible individuals. Trans masculine persons and others receiving androgen therapy are at higher risk for AGA, which often is undesirable and may be considered gender affirming by some TGD persons. Standard AGA treatments for cisgender men also can be used in trans masculine persons. Some of the most common anti-AGA medications are topical minoxidil, oral finasteride, and oral minoxidil. Although Coleman et al1 recently reported that finasteride may be an appropriate treatment option in trans masculine persons experiencing alopecia, treatment with 5α-reductase inhibitors may impair clitoral growth and the development of facial and body hair. Further studies are needed to assess the efficacy and safety of 5α-reductase inhibitors in transgender populations.1 Dutasteride may be used off-label and comes with a similar potential adverse-event profile as finasteride, which includes depression, decreased libido, erectile dysfunction, ejaculation disorders, and gynecomastia.

Conversely, AGA tends to improve in trans feminine persons and others receiving estrogen and antiandrogen therapy. Natural testosterone production is suppressed by estrogens and spironolactone as well as in patients who undergo orchiectomy.1 Although spironolactone is not approved for acne, AGA, or hirsutism, it is a standard treatment of AGA in cisgender women because it functions to block the effects of androgens, including at the hair follicle. Finasteride may be used for AGA in cisgender women but it is not recommended for trans feminine persons.1

There are many other modalities available for the treatment of AGA that are less commonly used—some may be cost prohibitive or do not have robust supporting evidence, or both. One example is hair transplantation. Although this procedure gives dramatic results, it typically is performed by a specialized dermatologist, is not covered by insurance, and can cost up to tens of thousands of dollars out-of-pocket. Patients typically require continuous medical management of AGA even after the procedure. Examples of treatment modalities with uncertain supporting evidence are platelet-rich plasma injections, laser combs or hats, and microneedling. Additionally, clascoterone is a topical antiandrogen currently approved for acne, but it is under investigation for the treatment of AGA and may become an additional nonsystemic medication available for AGA in the future.23

Melasma is a hyperpigmentation disorder related to estrogens, UV light exposure, and sometimes medication use (eg, hormonal birth control, spironolactone).24 The mainstay of treatment is prevention, including sun avoidance as well as use of sun-protective clothing and broad-spectrum sunscreens. Dermatologists tend to recommend physical sunscreens containing zinc oxide, titanium dioxide, and/or iron oxide, as they cover a wider UV spectrum and also provide some protection from visible light. Once melasma is present, dermatologists still have several treatment options. Topical hydroquinone is a proven treatment; however, it must be used with caution to avoid ochronosis. With careful patient selection, chemical peels also are effective treatment options for dyspigmentation and hyperpigmentation. Energy devices such as intense pulsed light and tattoo removal lasers—Q-switched lasers and picosecond pulse widths—also can be used to treat hyperpigmentation. Oral, intralesional, and topical tranexamic acid are newer treatment options for melasma that still are being studied and have shown promising results. Further studies are needed to determine long-term safety and optimal treatment regimens.24,25

Many insurance carriers, including TRICARE, do not routinely cover medical management of AGA or melasma. Patients should be advised that they likely will have to pay for any medications prescribed and procedures undertaken for these purposes; however, some medication costs can be offset by ordering larger prescription quantities, such as a 90-day supply vs a 30-day supply, as well as utilizing pharmacy discount programs.

 

 

Scar Management Following Surgery

In TSMs who undergo gender-affirming surgeries, dermatologists play an important role when scar symptoms develop, including pruritus, tenderness, and/or paresthesia. In the military, some common treatment modalities for symptomatic scars include intralesional steroids with or without 5-fluouroruacil and the fractionated CO2 laser. There also are numerous experimental treatment options for scars, including intralesional or perilesional botulinum toxin, the pulsed dye laser, or nonablative fractionated lasers. These modalities also may be used on hypertrophic scars or keloids. Another option for keloids is scar excision followed by superficial radiation therapy.26

Mental Health Considerations

Providers must take psychological adverse effects into consideration when considering medical therapies for dermatologic conditions in TGD patients. In particular, it is important to consider the risks for increased rates of depression and suicidal ideation formerly associated with the use of isotretinoin and finasteride, though much of the evidence regarding these risks has been called into question in recent years.27,28 Nonetheless, it remains prominent in lay media and may be a more important consideration in patients at higher baseline risk.27 Although there are no known studies that have expressly assessed rates of depression or suicidal ideation in TGD patients taking isotretinoin or finasteride, it is well established that TGD persons are at higher baseline risk for depression and suicidality.1,7,8 All patients should be carefully assessed for depression and suicidal ideation as well as counseled regarding these risks prior to initiating these therapies. If concerns for untreated mental health issues arise during screening and counseling, patients should be referred for assessment by a behavioral health specialist prior to starting therapy.

Future Directions

The future of TGD health care in the military could see an expansion of covered benefits and the development of new dermatologic procedures or medications. Research and policy evolution are necessary to bridge the current gaps in care; however, it is unlikely that all procedures currently considered to be cosmetic will become covered benefits.

Facial LHR is a promising candidate for future coverage for trans feminine persons. When cisgender men develop adverse effects from mandatory daily shaving, LHR is already a covered benefit. Two arguments in support of adding LHR for TGD patients revolve around achieving and maintaining an appearance congruent with their gender along with avoiding unwanted adverse effects related to daily shaving. Visual conformity with one’s affirmed gender has been associated with improvements in well-being, quality of life, and some mental health conditions.29

Scar prevention, treatment, and reduction are additional areas under active research in which dermatologists likely will play a crucial role.30,31 As more dermatologic procedures are performed on TGD persons, the published data and collective knowledge regarding best practices in this population will continue to grow, which will lead to improved cosmetic and safety outcomes.

Final Thoughts

Although dermatologists do not directly perform gender-affirming surgeries or hormone management, they do play an important role in enhancing a TGD person’s desired appearance and managing possible adverse effects resulting from gender-affirming interventions. There have been considerable advancements in TGD health care over the past decade, but there likely are more changes on the way. As policies and understanding of TGD health care needs evolve, it is crucial that the military health care system adapts to provide comprehensive, accessible, and equitable care, which includes expanding the range of covered dermatologic treatments to fully support the health and readiness of TSMs.

Acknowledgment—We would like to extend our sincere appreciation to the invaluable contributions and editorial support provided by Allison Higgins, JD (San Antonio, Texas), throughout the writing of this article.

References
  1. Coleman E, Radix AE, Bouman WP, et al. Standards of care for the health of transgender and gender diverse people, version 8. Int J Transgend Health. 2022;23(suppl 1):S1-S260. doi:10.1080/26895269.2022.2100644
  2. Secretary of Defense. DTM 16-005—military service of transgender service members. June 30, 2016. Accessed June 17, 2024. https://dod.defense.gov/Portals/1/features/2016/0616_policy/DTM-16-005.pdf
  3. Office of the Deputy Secretary of Defense. DTM 19-004—military service by transgender persons and persons with gender dysphoria. March 17, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/03/17/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  4. Office of the Under Secretary of Defense for Personnel and Readiness. Department of Defense Instruction (DODI) 1300.28. in-service transition for transgender service members. September 4, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/09/04/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  5. Defense Health Agency Procedural Instruction Number 6025.21, Guidance for Gender-Affirming Health Care of Transgender and Gender-Diverse Active and Reserve Component Service Members, May 12, 2023. https://www.health.mil/Reference-Center/DHA-Publications/2023/05/12/DHA-PI-6015-21
  6. Elders MJ, Brown GR, Coleman E, et al. Medical aspects of transgender military service. Armed Forces Soc. 2015;41:199-220. doi:10.1177/0095327X14545625.
  7. Almazan AN, Keuroghlian AS. Association between gender-affirming surgeries and mental health outcomes. JAMA Surg. 2021;156:611-618.
  8. Tordoff DM, Wanta JW, Collin A, et al. Mental health outcomes in transgender and nonbinary youths receiving gender-affirming care. JAMA Netw Open. 2022;5:E220978. doi:10.1001/jamanetworkopen.2022.0978
  9. Olson-Kennedy J, Warus J, Okonta V, et al. Chest reconstruction and chest dysphoria in transmasculine minors and young adults: comparisons of nonsurgical and postsurgical cohorts. JAMA Pediatr. 2018;172:431-436. doi:10.1001/jamapediatrics.2017.5440
  10. Top non-invasive cosmetic procedures worldwide 2022. Statista website. February 8, 2024. Accessed June 13, 2024. https://www.statista.com/statistics/293449/leading-nonsurgical-cosmetic-procedures/
  11. Kashkouli MB, Abdolalizadeh P, Abolfathzadeh N, et al. Periorbital facial rejuvenation; applied anatomy and pre-operative assessment. J Curr Ophthalmol. 2017;29:154-168. doi:10.1016/j.joco.2017.04.001
  12. Thomas MK, D’Silva JA, Borole AJ. Injection lipolysis: a systematic review of literature and our experience with a combination of phosphatidylcholine and deoxycholate over a period of 14 years in 1269 patients of Indian and South East Asian origin. J Cutan Aesthet Surg. 2018;11:222-228. doi:10.4103/JCAS.JCAS_117_18
  13. Jegasothy SM. Deoxycholic acid injections for bra-line lipolysis. Dermatol Surg. 2018;44:757-760. doi:10.1097/DSS.0000000000001311
  14. Dierickx CC. Hair removal by lasers and intense pulsed light sources. Dermatol Clin. 2002;20:135-146. doi:10.1016/s0733-8635(03)00052-4
  15. Lepselter J, Elman M. Biological and clinical aspects in laser hair removal. J Dermatolog Treat. 2004;15:72-83. doi:10.1080/09546630310023152
  16. Yuan N, Feldman AT, Chin P, et al. Comparison of permanent hair removal procedures before gender-affirming vaginoplasty: why we should consider laser hair removal as a first-line treatment for patients who meet criteria. Sex Med. 2022;10:100545. doi:10.1016/j.esxm.2022.100545
  17. Kumar A, Naguib YW, Shi YC, et al. A method to improve the efficacy of topical eflornithine hydrochloride cream. Drug Deliv. 2016;23:1495-1501. doi:10.3109/10717544.2014.951746
  18. Hembree WC, Cohen-Kettenis PT, Gooren L, et al. Endocrine treatment of gender-dysphoric/gender-incongruent persons: an endocrine society clinical practice guideline. J Clin Endocrinol Metabol. 2017;102:3869-3903.
  19. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  20. Rubenstein R, Roenigk HH Jr, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15(2 pt 1):280-285.
  21. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706.
  22. Goldberg D, Kothare A, Doucette M, et al. Selective photothermolysis with a novel 1726 nm laser beam: a safe and effective solution for acne vulgaris. J Cosmet Dermatol. 2023;22:486-496. doi:10.1111/jocd.15602
  23. Sun HY, Sebaratnam DF. Clascoterone as a novel treatment for androgenetic alopecia. Clin Exp Dermatol. 2020;45:913-914. doi:10.1111/ced.14292
  24. Bolognia JL, Schaffer JV, Cerroni L. Dermatology: 2-Volume Set. Elsevier; 2024:1130.
  25. Konisky H, Balazic E, Jaller JA, et al. Tranexamic acid in melasma: a focused review on drug administration routes. J Cosmet Dermatol. 2023;22:1197-1206. doi:10.1111/jocd.15589
  26. Walsh LA, Wu E, Pontes D, et al. Keloid treatments: an evidence-based systematic review of recent advances. Syst Rev. 2023;12:42. doi:10.1186/s13643-023-02192-7
  27. Kridin K, Ludwig RJ. Isotretinoin and the risk of psychiatric disturbances: a global study shedding new light on a debatable story. J Am Acad Dermatol. 2023;88:388-394. doi:10.1016/j.jaad.2022.10.031
  28. Dyson TE, Cantrell MA, Lund BC. Lack of association between 5α-reductase inhibitors and depression. J Urol. 2020;204:793-798. doi:10.1097/JU.0000000000001079
  29. To M, Zhang Q, Bradlyn A, et al. Visual conformity with affirmed gender or “passing”: its distribution and association with depression and anxiety in a cohort of transgender people. J Sex Med. 2020;17:2084-2092. doi:10.1016/j.jsxm.2020.07.019
  30. Fernandes MG, da Silva LP, Cerqueira MT, et al. Mechanomodulatory biomaterials prospects in scar prevention and treatment. Acta Biomater. 2022;150:22-33. doi:10.1016/j.actbio.2022.07.042
  31. Kolli H, Moy RL. Prevention of scarring with intraoperative erbium:YAG laser treatment. J Drugs Dermatol. 2020;19:1040-1043. doi:10.36849/JDD.2020.5244
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From the San Antonio Uniformed Services Health Education Consortium, Joint Base San Antonio, Texas.

The authors report no conflict of interest.

The views expressed are those of the authors and do not reflect the official views or policy of the Department of Defense or its components.

Correspondence: Frank B. Higgins, MD, 1100 Wilford Hall Loop, Lackland AFB, TX 78236 ([email protected]).

Cutis. 2024 July;114(1):5-9. doi:10.12788/cutis.1048

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Military Dermatology
Author(s)
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Heidi L. Dearborn, DO
Joshua M. Smalley, DO
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Heidi L. Dearborn, DO
Joshua M. Smalley, DO
Author and Disclosure Information

 

From the San Antonio Uniformed Services Health Education Consortium, Joint Base San Antonio, Texas.

The authors report no conflict of interest.

The views expressed are those of the authors and do not reflect the official views or policy of the Department of Defense or its components.

Correspondence: Frank B. Higgins, MD, 1100 Wilford Hall Loop, Lackland AFB, TX 78236 ([email protected]).

Cutis. 2024 July;114(1):5-9. doi:10.12788/cutis.1048

Author and Disclosure Information

 

From the San Antonio Uniformed Services Health Education Consortium, Joint Base San Antonio, Texas.

The authors report no conflict of interest.

The views expressed are those of the authors and do not reflect the official views or policy of the Department of Defense or its components.

Correspondence: Frank B. Higgins, MD, 1100 Wilford Hall Loop, Lackland AFB, TX 78236 ([email protected]).

Cutis. 2024 July;114(1):5-9. doi:10.12788/cutis.1048

Article PDF
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People whose gender identity differs from the sex assigned at birth are referred to as transgender. For some, gender identity may not fit into the binary constructs of male and female but rather falls between, within, or outside this construct. These people often consider themselves nonbinary or gender diverse. As the terminology continues to evolve, current recommendations include referring to this patient population as transgender and gender diverse (TGD) to ensure the broadest inclusivity.1 In this article, the following terms are used as defined below:

  • The terms transgender woman and trans feminine describe persons who were assigned male gender at birth but their affirmed gender is female or nonmasculine.
  • The terms transgender man and trans masculine describe persons who were assigned female gender at birth but their affirmed gender is male or nonfeminine.

The US Military’s policies on the service of TGD persons have evolved considerably over the past decade. Initial military policies barred TGD service members (TSMs) from service all together, leading to challenges in accessing necessary health care. The first official memorandum explicitly allowing military service by TGD persons was released on June 30, 2016.2 The intention of this memorandum was 2-fold: (1) to allow TGD persons to serve in the military so long as they meet “the rigorous standards for military service and readiness” by fulfilling the same standards and procedures as other military service members, including medical fitness for duty, physical fitness, uniform and grooming, deployability, and retention, and (2) to direct the establishment of new or updated policies to specific departments and prescribe procedures for retention standards, separation from service, in-service transition, and medical coverage.2 Several other official policies were released following this initial memorandum that provided more specific guidance on how to implement these policies at the level of the force, unit, and individual service member.

Modifications to the original 2016 policies had varying impacts on transgender health care provision and access.3 At the time of publication of this article, the current policy—the Department of Defense Instruction 1300.284—among others, establishes standards and procedures for the process by which active and reserve TSMs may medically, socially, and legally transition genders within the military. The current policy applies to all military branches and serves as the framework by which each branch currently organizes their gender-affirmation processes (GAP).4

There currently are several different GAP models among the military branches.5 Each branch has a different model or approach to implementing the current policy, with varying service-specific processes in place for TSMs to access gender-affirming care; however, this may be changing. The Defense Health Agency is in the process of consolidating and streamlining the GAP across the Department of Defense branches in an effort to optimize costs and ensure uniformity of care. Per the Defense Health Agency Procedural Instruction Number 6025.21 published in May 2023, the proposed consolidated model likely will entail a single central transgender health center that provides oversight and guidance for several regional joint-service gender-affirming medical hubs. Patients would either be managed at the level of the hub or be referred to the central site.5

Herein, we discuss the importance of gender-affirming care and how military and civilian dermatologists can contribute. We also review disparities in health care and identify areas of improvement.

 

 

Benefits of Gender-Affirming Care

Gender-affirming procedures are critical for aligning physical appearance with gender identity. Physical appearance is essential for psychological well-being, operational readiness, and the safety of TSMs.6 It is well documented that TGD persons experience suicidal ideation, depression, stigma, discrimination and violence at higher rates than their cisgender peers.7,8 It is important to recognize that transgender identity is not a mental illness, and these elevated rates have been linked to complex trauma, societal stigma, violence, and discrimination.1 Other studies have suggested that increased access to gender-affirming interventions may ameliorate these mental health concerns.1,7-9

The major components of gender-affirming care include hormone therapy, gender confirmation surgery, and mental health care, if needed. These are covered by TRICARE, the health care program for military service members; however, at the time of publication, many of the dermatologic gender-affirming procedures are not covered by TRICARE because they are considered “cosmetic procedures,” which is a term used by insurance companies but does not accurately indicate whether a procedure is medically necessary or not. Newer literature has demonstrated that gender-affirming care positively affects the lives of TGD patients, strengthening the argument that gender-affirming care is a medical necessity and not just cosmetic.1

Aesthetic Procedures in Gender-Affirming Care

Surgeons, including those within the specialties of oto-laryngology, oral and maxillofacial surgery, urology, gynecology, and plastic surgery, provide major gender-affirming interventions; however, dermatologists may offer less invasive solutions that can serve as a temporary experience prior to undergoing more permanent procedures.Hormonally driven disorders including acne, hair loss, and melasma also are managed by dermatologists, along with scar treatment following surgeries.

Because human variation is expansive and subjective, what is considered feminine or masculine may vary by person, group, culture, and country; therefore, it is imperative to ask patients about their individual aesthetic goals and tailor their treatment accordingly. Feminine and masculine are terms that will be used to describe prototypical appearances and are not meant to define a patient’s current state or ultimate goals. The following procedures and medical interventions are where dermatologists can play an important role in TGD persons’ GAPs.

Botulinum Toxin Injections—Botulinum toxin injection is the most common nonsurgical aesthetic procedure performed around the world.10 The selective paralysis afforded by botulinum toxin has several uses for people undergoing transition. Aesthetically, the feminine eyebrow tends to be positioned above the orbital rim and is arched with its apex between the lateral limbus and lateral canthus,11 while the masculine eyebrow tends to be flatter and fuller and runs over the orbital rim without a peak. For people seeking a more feminine appearance, an eyebrow lift with botulinum toxin can help reshape the typical flatter masculine eyebrow to give it lateral lift that often is considered more feminine. The targeted muscle is the superolateral orbicularis oculi, which serves as a depressor on the eyebrow. This can be combined with purposefully avoiding total lateral frontalis paralysis, which leads to a “Spock” brow for extra lift. Conversely, a naturally arched and higher eyebrow can be flattened and lowered by selectively targeting areas of the frontalis muscle.

Broad square jawlines typically are considered a masculine feature and are another area where botulinum toxin can be used to feminize a patient’s facial features. Targeting the masseter muscle induces muscle weakness, which ultimately may result in atrophy after one or more treatment sessions. This atrophy may lead to narrowing of the lower face and thus may lead to a fuller-appearing midface or overall more heart-shaped face. Every individual’s aesthetic goals are unique and therefore should be discussed prior to any treatment.

Dermal Fillers—Dermal fillers are gel-like substances injected under the skin for subtle contouring of the face. Fillers also can be used to help promote a more masculine or feminine appearance. Filler can be placed in the lips to create a fuller, more projected, feminine-appearing lip. Malar cheek and central lower chin filler can be used to help define a heart-shaped face by accentuating the upper portion of the face and creating a more pointed chin, respectively. Alternatively, filler can be used to masculinize the chin by placing it where it can increase jawline squareness and increase anterior jaw projection. Additionally, filler at the angle of the jaw can help accentuate a square facial shape and a more defined jawline. Although not as widely practiced, lateral brow filler can create a heavier-appearing and broader forehead for a more masculine appearance. These procedures can be combined with the previously mentioned botulinum toxin procedures for a synergistic effect.

Deoxycholic Acid—Deoxycholic acid is an injectable product used to selectively remove unwanted fat. It currently is approved by the US Food and Drug Administration for submental fat, but some providers are experimenting with off-label uses. Buccal fat pad removal—or in this case reduction by dissolution—tends to give a thinner, more feminine facial appearance.12 Reducing fat around the axillae also can help promote a more masculine upper torso.13 The safety of deoxycholic acid in these areas has not been adequately tested; thus, caution should be used when discussing these off-label uses with patients.

Hair and Tattoo Removal—Hair removal may be desired by TGD persons for a variety of reasons. Because cisgender females tend to have less body hair overall, transgender people in pursuit of a more feminine appearance often desire removal of facial, neck, and body hair. Although shaving and other modalities such as waxing and chemical depilatories are readily available at-home options, they are not permanent and may lead to folliculitis or pseudofolliculitis barbae. Laser hair removal (LHR) and electrolysis are modalities provided by dermatologists that tend to be more permanent and lead to better outcomes, including less irritation and better aesthetic appearance. It is important to keep in mind that not every person and not every body site can be safely treated with LHR. Patients with lighter skin types and darker hair tend to have the most effective response with a higher margin of safety, as these features allow the laser energy to be selectively absorbed by the melanin in the hair bulb and not by the background skin pigmentation.14,15 Inappropriate patient selection or improper settings for wavelength, pulse width, or fluences can lead to burns and permanent scarring.14,15 Electrolysis is an alternative to hair removal within tattoos and is more effective for those individuals with blonde, red, or white hair.16

Another novel treatment for unwanted hair is eflor­nithine hydrochloride cream, which works by blocking ornithine decarboxylase, the enzyme that stimulates hair growth. It currently is approved to reduce unwanted hair on the face and adjacent areas under the chin; however the effects of this medication are modest and the medication can be expensive.17

Cosmetic hair and tattoo removal are not currently covered by TRICARE, except in cases of surgical and donor-site preparation for some GAPs. Individuals may desire removal of tattoos at surgery sites to obtain more natural-appearing skin. Currently, GAPs such as vaginoplasty, phalloplasty, and metoidioplasty—often referred to by patients as “bottom surgeries”—include insurance coverage for tattoo removal, LHR, and/or electrolysis.

 

 

Management of Hormonal Adverse Effects

Acne—Individuals on testosterone supplementation tend to develop acne for the first several years of treatment, but it may improve with time.18 Acne is treated in individuals receiving testosterone the same way as it is treated in cisgender men, with numerous options for topical and oral medications. In trans masculine persons, spironolactone therapy typically is avoided because it may interfere with the actions of exogenous testosterone administered as part of gender-affirming medical treatment and may lead to other undesired adverse effects such as impotence and gynecomastia.1

Although acne typically improves after starting estrogen therapy, patients receiving estrogens may still develop acne. Most trans feminine patients will already be on an estrogen and an antiandrogen, often spironolactone.1 Spironolactone often is used as monotherapy for acne control in cisgender women. Additionally, an important factor to consider with spironolactone is the possible adverse effect of increased micturition. Currently, the military rarely has gender-inclusive restroom options, which can create a challenge for TSMs who find themselves needing to use the restroom more frequently in the workplace.

If planning therapy with isotretinoin, dermatologists should discuss several important factors with all patients, including TGD patients. One consideration is the patient’s planned future surgeries. Although new literature shows that isotretinoin does not adversely affect wound healing,19 some surgeons still adhere to an isotretinoin washout period of 6 to 12 months prior to performing any elective procedures due to concerns about wound healing.20,21 Second, be sure to properly assess and document pregnancy potential in TGD persons. Providers should not assume that a patient is not pregnant or is not trying to become pregnant just because they are trans masculine. It also is important to note that testosterone is not a reliable birth control method.1 If a patient still has ovaries, fallopian tubes, and a uterus, they are considered medically capable of pregnancy, and providers should keep this in mind regarding all procedures in the TGD population.

Another newer acne treatment modality is the 1762-nm laser, which targets sebaceous glands.22 This device allows for targeted treatment of acne-prone areas without systemic therapy such as retinoids or antiandrogens. The 1762-nm laser is not widely available but may become a regular treatment option once its benefits are proven over time.

Alopecia and Hyperpigmentation—Androgens, whether endogenously or exogenously derived, can lead to androgenetic alopecia (AGA) in genetically susceptible individuals. Trans masculine persons and others receiving androgen therapy are at higher risk for AGA, which often is undesirable and may be considered gender affirming by some TGD persons. Standard AGA treatments for cisgender men also can be used in trans masculine persons. Some of the most common anti-AGA medications are topical minoxidil, oral finasteride, and oral minoxidil. Although Coleman et al1 recently reported that finasteride may be an appropriate treatment option in trans masculine persons experiencing alopecia, treatment with 5α-reductase inhibitors may impair clitoral growth and the development of facial and body hair. Further studies are needed to assess the efficacy and safety of 5α-reductase inhibitors in transgender populations.1 Dutasteride may be used off-label and comes with a similar potential adverse-event profile as finasteride, which includes depression, decreased libido, erectile dysfunction, ejaculation disorders, and gynecomastia.

Conversely, AGA tends to improve in trans feminine persons and others receiving estrogen and antiandrogen therapy. Natural testosterone production is suppressed by estrogens and spironolactone as well as in patients who undergo orchiectomy.1 Although spironolactone is not approved for acne, AGA, or hirsutism, it is a standard treatment of AGA in cisgender women because it functions to block the effects of androgens, including at the hair follicle. Finasteride may be used for AGA in cisgender women but it is not recommended for trans feminine persons.1

There are many other modalities available for the treatment of AGA that are less commonly used—some may be cost prohibitive or do not have robust supporting evidence, or both. One example is hair transplantation. Although this procedure gives dramatic results, it typically is performed by a specialized dermatologist, is not covered by insurance, and can cost up to tens of thousands of dollars out-of-pocket. Patients typically require continuous medical management of AGA even after the procedure. Examples of treatment modalities with uncertain supporting evidence are platelet-rich plasma injections, laser combs or hats, and microneedling. Additionally, clascoterone is a topical antiandrogen currently approved for acne, but it is under investigation for the treatment of AGA and may become an additional nonsystemic medication available for AGA in the future.23

Melasma is a hyperpigmentation disorder related to estrogens, UV light exposure, and sometimes medication use (eg, hormonal birth control, spironolactone).24 The mainstay of treatment is prevention, including sun avoidance as well as use of sun-protective clothing and broad-spectrum sunscreens. Dermatologists tend to recommend physical sunscreens containing zinc oxide, titanium dioxide, and/or iron oxide, as they cover a wider UV spectrum and also provide some protection from visible light. Once melasma is present, dermatologists still have several treatment options. Topical hydroquinone is a proven treatment; however, it must be used with caution to avoid ochronosis. With careful patient selection, chemical peels also are effective treatment options for dyspigmentation and hyperpigmentation. Energy devices such as intense pulsed light and tattoo removal lasers—Q-switched lasers and picosecond pulse widths—also can be used to treat hyperpigmentation. Oral, intralesional, and topical tranexamic acid are newer treatment options for melasma that still are being studied and have shown promising results. Further studies are needed to determine long-term safety and optimal treatment regimens.24,25

Many insurance carriers, including TRICARE, do not routinely cover medical management of AGA or melasma. Patients should be advised that they likely will have to pay for any medications prescribed and procedures undertaken for these purposes; however, some medication costs can be offset by ordering larger prescription quantities, such as a 90-day supply vs a 30-day supply, as well as utilizing pharmacy discount programs.

 

 

Scar Management Following Surgery

In TSMs who undergo gender-affirming surgeries, dermatologists play an important role when scar symptoms develop, including pruritus, tenderness, and/or paresthesia. In the military, some common treatment modalities for symptomatic scars include intralesional steroids with or without 5-fluouroruacil and the fractionated CO2 laser. There also are numerous experimental treatment options for scars, including intralesional or perilesional botulinum toxin, the pulsed dye laser, or nonablative fractionated lasers. These modalities also may be used on hypertrophic scars or keloids. Another option for keloids is scar excision followed by superficial radiation therapy.26

Mental Health Considerations

Providers must take psychological adverse effects into consideration when considering medical therapies for dermatologic conditions in TGD patients. In particular, it is important to consider the risks for increased rates of depression and suicidal ideation formerly associated with the use of isotretinoin and finasteride, though much of the evidence regarding these risks has been called into question in recent years.27,28 Nonetheless, it remains prominent in lay media and may be a more important consideration in patients at higher baseline risk.27 Although there are no known studies that have expressly assessed rates of depression or suicidal ideation in TGD patients taking isotretinoin or finasteride, it is well established that TGD persons are at higher baseline risk for depression and suicidality.1,7,8 All patients should be carefully assessed for depression and suicidal ideation as well as counseled regarding these risks prior to initiating these therapies. If concerns for untreated mental health issues arise during screening and counseling, patients should be referred for assessment by a behavioral health specialist prior to starting therapy.

Future Directions

The future of TGD health care in the military could see an expansion of covered benefits and the development of new dermatologic procedures or medications. Research and policy evolution are necessary to bridge the current gaps in care; however, it is unlikely that all procedures currently considered to be cosmetic will become covered benefits.

Facial LHR is a promising candidate for future coverage for trans feminine persons. When cisgender men develop adverse effects from mandatory daily shaving, LHR is already a covered benefit. Two arguments in support of adding LHR for TGD patients revolve around achieving and maintaining an appearance congruent with their gender along with avoiding unwanted adverse effects related to daily shaving. Visual conformity with one’s affirmed gender has been associated with improvements in well-being, quality of life, and some mental health conditions.29

Scar prevention, treatment, and reduction are additional areas under active research in which dermatologists likely will play a crucial role.30,31 As more dermatologic procedures are performed on TGD persons, the published data and collective knowledge regarding best practices in this population will continue to grow, which will lead to improved cosmetic and safety outcomes.

Final Thoughts

Although dermatologists do not directly perform gender-affirming surgeries or hormone management, they do play an important role in enhancing a TGD person’s desired appearance and managing possible adverse effects resulting from gender-affirming interventions. There have been considerable advancements in TGD health care over the past decade, but there likely are more changes on the way. As policies and understanding of TGD health care needs evolve, it is crucial that the military health care system adapts to provide comprehensive, accessible, and equitable care, which includes expanding the range of covered dermatologic treatments to fully support the health and readiness of TSMs.

Acknowledgment—We would like to extend our sincere appreciation to the invaluable contributions and editorial support provided by Allison Higgins, JD (San Antonio, Texas), throughout the writing of this article.

People whose gender identity differs from the sex assigned at birth are referred to as transgender. For some, gender identity may not fit into the binary constructs of male and female but rather falls between, within, or outside this construct. These people often consider themselves nonbinary or gender diverse. As the terminology continues to evolve, current recommendations include referring to this patient population as transgender and gender diverse (TGD) to ensure the broadest inclusivity.1 In this article, the following terms are used as defined below:

  • The terms transgender woman and trans feminine describe persons who were assigned male gender at birth but their affirmed gender is female or nonmasculine.
  • The terms transgender man and trans masculine describe persons who were assigned female gender at birth but their affirmed gender is male or nonfeminine.

The US Military’s policies on the service of TGD persons have evolved considerably over the past decade. Initial military policies barred TGD service members (TSMs) from service all together, leading to challenges in accessing necessary health care. The first official memorandum explicitly allowing military service by TGD persons was released on June 30, 2016.2 The intention of this memorandum was 2-fold: (1) to allow TGD persons to serve in the military so long as they meet “the rigorous standards for military service and readiness” by fulfilling the same standards and procedures as other military service members, including medical fitness for duty, physical fitness, uniform and grooming, deployability, and retention, and (2) to direct the establishment of new or updated policies to specific departments and prescribe procedures for retention standards, separation from service, in-service transition, and medical coverage.2 Several other official policies were released following this initial memorandum that provided more specific guidance on how to implement these policies at the level of the force, unit, and individual service member.

Modifications to the original 2016 policies had varying impacts on transgender health care provision and access.3 At the time of publication of this article, the current policy—the Department of Defense Instruction 1300.284—among others, establishes standards and procedures for the process by which active and reserve TSMs may medically, socially, and legally transition genders within the military. The current policy applies to all military branches and serves as the framework by which each branch currently organizes their gender-affirmation processes (GAP).4

There currently are several different GAP models among the military branches.5 Each branch has a different model or approach to implementing the current policy, with varying service-specific processes in place for TSMs to access gender-affirming care; however, this may be changing. The Defense Health Agency is in the process of consolidating and streamlining the GAP across the Department of Defense branches in an effort to optimize costs and ensure uniformity of care. Per the Defense Health Agency Procedural Instruction Number 6025.21 published in May 2023, the proposed consolidated model likely will entail a single central transgender health center that provides oversight and guidance for several regional joint-service gender-affirming medical hubs. Patients would either be managed at the level of the hub or be referred to the central site.5

Herein, we discuss the importance of gender-affirming care and how military and civilian dermatologists can contribute. We also review disparities in health care and identify areas of improvement.

 

 

Benefits of Gender-Affirming Care

Gender-affirming procedures are critical for aligning physical appearance with gender identity. Physical appearance is essential for psychological well-being, operational readiness, and the safety of TSMs.6 It is well documented that TGD persons experience suicidal ideation, depression, stigma, discrimination and violence at higher rates than their cisgender peers.7,8 It is important to recognize that transgender identity is not a mental illness, and these elevated rates have been linked to complex trauma, societal stigma, violence, and discrimination.1 Other studies have suggested that increased access to gender-affirming interventions may ameliorate these mental health concerns.1,7-9

The major components of gender-affirming care include hormone therapy, gender confirmation surgery, and mental health care, if needed. These are covered by TRICARE, the health care program for military service members; however, at the time of publication, many of the dermatologic gender-affirming procedures are not covered by TRICARE because they are considered “cosmetic procedures,” which is a term used by insurance companies but does not accurately indicate whether a procedure is medically necessary or not. Newer literature has demonstrated that gender-affirming care positively affects the lives of TGD patients, strengthening the argument that gender-affirming care is a medical necessity and not just cosmetic.1

Aesthetic Procedures in Gender-Affirming Care

Surgeons, including those within the specialties of oto-laryngology, oral and maxillofacial surgery, urology, gynecology, and plastic surgery, provide major gender-affirming interventions; however, dermatologists may offer less invasive solutions that can serve as a temporary experience prior to undergoing more permanent procedures.Hormonally driven disorders including acne, hair loss, and melasma also are managed by dermatologists, along with scar treatment following surgeries.

Because human variation is expansive and subjective, what is considered feminine or masculine may vary by person, group, culture, and country; therefore, it is imperative to ask patients about their individual aesthetic goals and tailor their treatment accordingly. Feminine and masculine are terms that will be used to describe prototypical appearances and are not meant to define a patient’s current state or ultimate goals. The following procedures and medical interventions are where dermatologists can play an important role in TGD persons’ GAPs.

Botulinum Toxin Injections—Botulinum toxin injection is the most common nonsurgical aesthetic procedure performed around the world.10 The selective paralysis afforded by botulinum toxin has several uses for people undergoing transition. Aesthetically, the feminine eyebrow tends to be positioned above the orbital rim and is arched with its apex between the lateral limbus and lateral canthus,11 while the masculine eyebrow tends to be flatter and fuller and runs over the orbital rim without a peak. For people seeking a more feminine appearance, an eyebrow lift with botulinum toxin can help reshape the typical flatter masculine eyebrow to give it lateral lift that often is considered more feminine. The targeted muscle is the superolateral orbicularis oculi, which serves as a depressor on the eyebrow. This can be combined with purposefully avoiding total lateral frontalis paralysis, which leads to a “Spock” brow for extra lift. Conversely, a naturally arched and higher eyebrow can be flattened and lowered by selectively targeting areas of the frontalis muscle.

Broad square jawlines typically are considered a masculine feature and are another area where botulinum toxin can be used to feminize a patient’s facial features. Targeting the masseter muscle induces muscle weakness, which ultimately may result in atrophy after one or more treatment sessions. This atrophy may lead to narrowing of the lower face and thus may lead to a fuller-appearing midface or overall more heart-shaped face. Every individual’s aesthetic goals are unique and therefore should be discussed prior to any treatment.

Dermal Fillers—Dermal fillers are gel-like substances injected under the skin for subtle contouring of the face. Fillers also can be used to help promote a more masculine or feminine appearance. Filler can be placed in the lips to create a fuller, more projected, feminine-appearing lip. Malar cheek and central lower chin filler can be used to help define a heart-shaped face by accentuating the upper portion of the face and creating a more pointed chin, respectively. Alternatively, filler can be used to masculinize the chin by placing it where it can increase jawline squareness and increase anterior jaw projection. Additionally, filler at the angle of the jaw can help accentuate a square facial shape and a more defined jawline. Although not as widely practiced, lateral brow filler can create a heavier-appearing and broader forehead for a more masculine appearance. These procedures can be combined with the previously mentioned botulinum toxin procedures for a synergistic effect.

Deoxycholic Acid—Deoxycholic acid is an injectable product used to selectively remove unwanted fat. It currently is approved by the US Food and Drug Administration for submental fat, but some providers are experimenting with off-label uses. Buccal fat pad removal—or in this case reduction by dissolution—tends to give a thinner, more feminine facial appearance.12 Reducing fat around the axillae also can help promote a more masculine upper torso.13 The safety of deoxycholic acid in these areas has not been adequately tested; thus, caution should be used when discussing these off-label uses with patients.

Hair and Tattoo Removal—Hair removal may be desired by TGD persons for a variety of reasons. Because cisgender females tend to have less body hair overall, transgender people in pursuit of a more feminine appearance often desire removal of facial, neck, and body hair. Although shaving and other modalities such as waxing and chemical depilatories are readily available at-home options, they are not permanent and may lead to folliculitis or pseudofolliculitis barbae. Laser hair removal (LHR) and electrolysis are modalities provided by dermatologists that tend to be more permanent and lead to better outcomes, including less irritation and better aesthetic appearance. It is important to keep in mind that not every person and not every body site can be safely treated with LHR. Patients with lighter skin types and darker hair tend to have the most effective response with a higher margin of safety, as these features allow the laser energy to be selectively absorbed by the melanin in the hair bulb and not by the background skin pigmentation.14,15 Inappropriate patient selection or improper settings for wavelength, pulse width, or fluences can lead to burns and permanent scarring.14,15 Electrolysis is an alternative to hair removal within tattoos and is more effective for those individuals with blonde, red, or white hair.16

Another novel treatment for unwanted hair is eflor­nithine hydrochloride cream, which works by blocking ornithine decarboxylase, the enzyme that stimulates hair growth. It currently is approved to reduce unwanted hair on the face and adjacent areas under the chin; however the effects of this medication are modest and the medication can be expensive.17

Cosmetic hair and tattoo removal are not currently covered by TRICARE, except in cases of surgical and donor-site preparation for some GAPs. Individuals may desire removal of tattoos at surgery sites to obtain more natural-appearing skin. Currently, GAPs such as vaginoplasty, phalloplasty, and metoidioplasty—often referred to by patients as “bottom surgeries”—include insurance coverage for tattoo removal, LHR, and/or electrolysis.

 

 

Management of Hormonal Adverse Effects

Acne—Individuals on testosterone supplementation tend to develop acne for the first several years of treatment, but it may improve with time.18 Acne is treated in individuals receiving testosterone the same way as it is treated in cisgender men, with numerous options for topical and oral medications. In trans masculine persons, spironolactone therapy typically is avoided because it may interfere with the actions of exogenous testosterone administered as part of gender-affirming medical treatment and may lead to other undesired adverse effects such as impotence and gynecomastia.1

Although acne typically improves after starting estrogen therapy, patients receiving estrogens may still develop acne. Most trans feminine patients will already be on an estrogen and an antiandrogen, often spironolactone.1 Spironolactone often is used as monotherapy for acne control in cisgender women. Additionally, an important factor to consider with spironolactone is the possible adverse effect of increased micturition. Currently, the military rarely has gender-inclusive restroom options, which can create a challenge for TSMs who find themselves needing to use the restroom more frequently in the workplace.

If planning therapy with isotretinoin, dermatologists should discuss several important factors with all patients, including TGD patients. One consideration is the patient’s planned future surgeries. Although new literature shows that isotretinoin does not adversely affect wound healing,19 some surgeons still adhere to an isotretinoin washout period of 6 to 12 months prior to performing any elective procedures due to concerns about wound healing.20,21 Second, be sure to properly assess and document pregnancy potential in TGD persons. Providers should not assume that a patient is not pregnant or is not trying to become pregnant just because they are trans masculine. It also is important to note that testosterone is not a reliable birth control method.1 If a patient still has ovaries, fallopian tubes, and a uterus, they are considered medically capable of pregnancy, and providers should keep this in mind regarding all procedures in the TGD population.

Another newer acne treatment modality is the 1762-nm laser, which targets sebaceous glands.22 This device allows for targeted treatment of acne-prone areas without systemic therapy such as retinoids or antiandrogens. The 1762-nm laser is not widely available but may become a regular treatment option once its benefits are proven over time.

Alopecia and Hyperpigmentation—Androgens, whether endogenously or exogenously derived, can lead to androgenetic alopecia (AGA) in genetically susceptible individuals. Trans masculine persons and others receiving androgen therapy are at higher risk for AGA, which often is undesirable and may be considered gender affirming by some TGD persons. Standard AGA treatments for cisgender men also can be used in trans masculine persons. Some of the most common anti-AGA medications are topical minoxidil, oral finasteride, and oral minoxidil. Although Coleman et al1 recently reported that finasteride may be an appropriate treatment option in trans masculine persons experiencing alopecia, treatment with 5α-reductase inhibitors may impair clitoral growth and the development of facial and body hair. Further studies are needed to assess the efficacy and safety of 5α-reductase inhibitors in transgender populations.1 Dutasteride may be used off-label and comes with a similar potential adverse-event profile as finasteride, which includes depression, decreased libido, erectile dysfunction, ejaculation disorders, and gynecomastia.

Conversely, AGA tends to improve in trans feminine persons and others receiving estrogen and antiandrogen therapy. Natural testosterone production is suppressed by estrogens and spironolactone as well as in patients who undergo orchiectomy.1 Although spironolactone is not approved for acne, AGA, or hirsutism, it is a standard treatment of AGA in cisgender women because it functions to block the effects of androgens, including at the hair follicle. Finasteride may be used for AGA in cisgender women but it is not recommended for trans feminine persons.1

There are many other modalities available for the treatment of AGA that are less commonly used—some may be cost prohibitive or do not have robust supporting evidence, or both. One example is hair transplantation. Although this procedure gives dramatic results, it typically is performed by a specialized dermatologist, is not covered by insurance, and can cost up to tens of thousands of dollars out-of-pocket. Patients typically require continuous medical management of AGA even after the procedure. Examples of treatment modalities with uncertain supporting evidence are platelet-rich plasma injections, laser combs or hats, and microneedling. Additionally, clascoterone is a topical antiandrogen currently approved for acne, but it is under investigation for the treatment of AGA and may become an additional nonsystemic medication available for AGA in the future.23

Melasma is a hyperpigmentation disorder related to estrogens, UV light exposure, and sometimes medication use (eg, hormonal birth control, spironolactone).24 The mainstay of treatment is prevention, including sun avoidance as well as use of sun-protective clothing and broad-spectrum sunscreens. Dermatologists tend to recommend physical sunscreens containing zinc oxide, titanium dioxide, and/or iron oxide, as they cover a wider UV spectrum and also provide some protection from visible light. Once melasma is present, dermatologists still have several treatment options. Topical hydroquinone is a proven treatment; however, it must be used with caution to avoid ochronosis. With careful patient selection, chemical peels also are effective treatment options for dyspigmentation and hyperpigmentation. Energy devices such as intense pulsed light and tattoo removal lasers—Q-switched lasers and picosecond pulse widths—also can be used to treat hyperpigmentation. Oral, intralesional, and topical tranexamic acid are newer treatment options for melasma that still are being studied and have shown promising results. Further studies are needed to determine long-term safety and optimal treatment regimens.24,25

Many insurance carriers, including TRICARE, do not routinely cover medical management of AGA or melasma. Patients should be advised that they likely will have to pay for any medications prescribed and procedures undertaken for these purposes; however, some medication costs can be offset by ordering larger prescription quantities, such as a 90-day supply vs a 30-day supply, as well as utilizing pharmacy discount programs.

 

 

Scar Management Following Surgery

In TSMs who undergo gender-affirming surgeries, dermatologists play an important role when scar symptoms develop, including pruritus, tenderness, and/or paresthesia. In the military, some common treatment modalities for symptomatic scars include intralesional steroids with or without 5-fluouroruacil and the fractionated CO2 laser. There also are numerous experimental treatment options for scars, including intralesional or perilesional botulinum toxin, the pulsed dye laser, or nonablative fractionated lasers. These modalities also may be used on hypertrophic scars or keloids. Another option for keloids is scar excision followed by superficial radiation therapy.26

Mental Health Considerations

Providers must take psychological adverse effects into consideration when considering medical therapies for dermatologic conditions in TGD patients. In particular, it is important to consider the risks for increased rates of depression and suicidal ideation formerly associated with the use of isotretinoin and finasteride, though much of the evidence regarding these risks has been called into question in recent years.27,28 Nonetheless, it remains prominent in lay media and may be a more important consideration in patients at higher baseline risk.27 Although there are no known studies that have expressly assessed rates of depression or suicidal ideation in TGD patients taking isotretinoin or finasteride, it is well established that TGD persons are at higher baseline risk for depression and suicidality.1,7,8 All patients should be carefully assessed for depression and suicidal ideation as well as counseled regarding these risks prior to initiating these therapies. If concerns for untreated mental health issues arise during screening and counseling, patients should be referred for assessment by a behavioral health specialist prior to starting therapy.

Future Directions

The future of TGD health care in the military could see an expansion of covered benefits and the development of new dermatologic procedures or medications. Research and policy evolution are necessary to bridge the current gaps in care; however, it is unlikely that all procedures currently considered to be cosmetic will become covered benefits.

Facial LHR is a promising candidate for future coverage for trans feminine persons. When cisgender men develop adverse effects from mandatory daily shaving, LHR is already a covered benefit. Two arguments in support of adding LHR for TGD patients revolve around achieving and maintaining an appearance congruent with their gender along with avoiding unwanted adverse effects related to daily shaving. Visual conformity with one’s affirmed gender has been associated with improvements in well-being, quality of life, and some mental health conditions.29

Scar prevention, treatment, and reduction are additional areas under active research in which dermatologists likely will play a crucial role.30,31 As more dermatologic procedures are performed on TGD persons, the published data and collective knowledge regarding best practices in this population will continue to grow, which will lead to improved cosmetic and safety outcomes.

Final Thoughts

Although dermatologists do not directly perform gender-affirming surgeries or hormone management, they do play an important role in enhancing a TGD person’s desired appearance and managing possible adverse effects resulting from gender-affirming interventions. There have been considerable advancements in TGD health care over the past decade, but there likely are more changes on the way. As policies and understanding of TGD health care needs evolve, it is crucial that the military health care system adapts to provide comprehensive, accessible, and equitable care, which includes expanding the range of covered dermatologic treatments to fully support the health and readiness of TSMs.

Acknowledgment—We would like to extend our sincere appreciation to the invaluable contributions and editorial support provided by Allison Higgins, JD (San Antonio, Texas), throughout the writing of this article.

References
  1. Coleman E, Radix AE, Bouman WP, et al. Standards of care for the health of transgender and gender diverse people, version 8. Int J Transgend Health. 2022;23(suppl 1):S1-S260. doi:10.1080/26895269.2022.2100644
  2. Secretary of Defense. DTM 16-005—military service of transgender service members. June 30, 2016. Accessed June 17, 2024. https://dod.defense.gov/Portals/1/features/2016/0616_policy/DTM-16-005.pdf
  3. Office of the Deputy Secretary of Defense. DTM 19-004—military service by transgender persons and persons with gender dysphoria. March 17, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/03/17/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  4. Office of the Under Secretary of Defense for Personnel and Readiness. Department of Defense Instruction (DODI) 1300.28. in-service transition for transgender service members. September 4, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/09/04/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  5. Defense Health Agency Procedural Instruction Number 6025.21, Guidance for Gender-Affirming Health Care of Transgender and Gender-Diverse Active and Reserve Component Service Members, May 12, 2023. https://www.health.mil/Reference-Center/DHA-Publications/2023/05/12/DHA-PI-6015-21
  6. Elders MJ, Brown GR, Coleman E, et al. Medical aspects of transgender military service. Armed Forces Soc. 2015;41:199-220. doi:10.1177/0095327X14545625.
  7. Almazan AN, Keuroghlian AS. Association between gender-affirming surgeries and mental health outcomes. JAMA Surg. 2021;156:611-618.
  8. Tordoff DM, Wanta JW, Collin A, et al. Mental health outcomes in transgender and nonbinary youths receiving gender-affirming care. JAMA Netw Open. 2022;5:E220978. doi:10.1001/jamanetworkopen.2022.0978
  9. Olson-Kennedy J, Warus J, Okonta V, et al. Chest reconstruction and chest dysphoria in transmasculine minors and young adults: comparisons of nonsurgical and postsurgical cohorts. JAMA Pediatr. 2018;172:431-436. doi:10.1001/jamapediatrics.2017.5440
  10. Top non-invasive cosmetic procedures worldwide 2022. Statista website. February 8, 2024. Accessed June 13, 2024. https://www.statista.com/statistics/293449/leading-nonsurgical-cosmetic-procedures/
  11. Kashkouli MB, Abdolalizadeh P, Abolfathzadeh N, et al. Periorbital facial rejuvenation; applied anatomy and pre-operative assessment. J Curr Ophthalmol. 2017;29:154-168. doi:10.1016/j.joco.2017.04.001
  12. Thomas MK, D’Silva JA, Borole AJ. Injection lipolysis: a systematic review of literature and our experience with a combination of phosphatidylcholine and deoxycholate over a period of 14 years in 1269 patients of Indian and South East Asian origin. J Cutan Aesthet Surg. 2018;11:222-228. doi:10.4103/JCAS.JCAS_117_18
  13. Jegasothy SM. Deoxycholic acid injections for bra-line lipolysis. Dermatol Surg. 2018;44:757-760. doi:10.1097/DSS.0000000000001311
  14. Dierickx CC. Hair removal by lasers and intense pulsed light sources. Dermatol Clin. 2002;20:135-146. doi:10.1016/s0733-8635(03)00052-4
  15. Lepselter J, Elman M. Biological and clinical aspects in laser hair removal. J Dermatolog Treat. 2004;15:72-83. doi:10.1080/09546630310023152
  16. Yuan N, Feldman AT, Chin P, et al. Comparison of permanent hair removal procedures before gender-affirming vaginoplasty: why we should consider laser hair removal as a first-line treatment for patients who meet criteria. Sex Med. 2022;10:100545. doi:10.1016/j.esxm.2022.100545
  17. Kumar A, Naguib YW, Shi YC, et al. A method to improve the efficacy of topical eflornithine hydrochloride cream. Drug Deliv. 2016;23:1495-1501. doi:10.3109/10717544.2014.951746
  18. Hembree WC, Cohen-Kettenis PT, Gooren L, et al. Endocrine treatment of gender-dysphoric/gender-incongruent persons: an endocrine society clinical practice guideline. J Clin Endocrinol Metabol. 2017;102:3869-3903.
  19. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  20. Rubenstein R, Roenigk HH Jr, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15(2 pt 1):280-285.
  21. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706.
  22. Goldberg D, Kothare A, Doucette M, et al. Selective photothermolysis with a novel 1726 nm laser beam: a safe and effective solution for acne vulgaris. J Cosmet Dermatol. 2023;22:486-496. doi:10.1111/jocd.15602
  23. Sun HY, Sebaratnam DF. Clascoterone as a novel treatment for androgenetic alopecia. Clin Exp Dermatol. 2020;45:913-914. doi:10.1111/ced.14292
  24. Bolognia JL, Schaffer JV, Cerroni L. Dermatology: 2-Volume Set. Elsevier; 2024:1130.
  25. Konisky H, Balazic E, Jaller JA, et al. Tranexamic acid in melasma: a focused review on drug administration routes. J Cosmet Dermatol. 2023;22:1197-1206. doi:10.1111/jocd.15589
  26. Walsh LA, Wu E, Pontes D, et al. Keloid treatments: an evidence-based systematic review of recent advances. Syst Rev. 2023;12:42. doi:10.1186/s13643-023-02192-7
  27. Kridin K, Ludwig RJ. Isotretinoin and the risk of psychiatric disturbances: a global study shedding new light on a debatable story. J Am Acad Dermatol. 2023;88:388-394. doi:10.1016/j.jaad.2022.10.031
  28. Dyson TE, Cantrell MA, Lund BC. Lack of association between 5α-reductase inhibitors and depression. J Urol. 2020;204:793-798. doi:10.1097/JU.0000000000001079
  29. To M, Zhang Q, Bradlyn A, et al. Visual conformity with affirmed gender or “passing”: its distribution and association with depression and anxiety in a cohort of transgender people. J Sex Med. 2020;17:2084-2092. doi:10.1016/j.jsxm.2020.07.019
  30. Fernandes MG, da Silva LP, Cerqueira MT, et al. Mechanomodulatory biomaterials prospects in scar prevention and treatment. Acta Biomater. 2022;150:22-33. doi:10.1016/j.actbio.2022.07.042
  31. Kolli H, Moy RL. Prevention of scarring with intraoperative erbium:YAG laser treatment. J Drugs Dermatol. 2020;19:1040-1043. doi:10.36849/JDD.2020.5244
References
  1. Coleman E, Radix AE, Bouman WP, et al. Standards of care for the health of transgender and gender diverse people, version 8. Int J Transgend Health. 2022;23(suppl 1):S1-S260. doi:10.1080/26895269.2022.2100644
  2. Secretary of Defense. DTM 16-005—military service of transgender service members. June 30, 2016. Accessed June 17, 2024. https://dod.defense.gov/Portals/1/features/2016/0616_policy/DTM-16-005.pdf
  3. Office of the Deputy Secretary of Defense. DTM 19-004—military service by transgender persons and persons with gender dysphoria. March 17, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/03/17/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  4. Office of the Under Secretary of Defense for Personnel and Readiness. Department of Defense Instruction (DODI) 1300.28. in-service transition for transgender service members. September 4, 2020. Accessed June 17, 2024. https://health.mil/Reference-Center/Policies/2020/09/04/Military-Service-by-Transgender-Persons-and-Persons-with-Gender-Dysphoria
  5. Defense Health Agency Procedural Instruction Number 6025.21, Guidance for Gender-Affirming Health Care of Transgender and Gender-Diverse Active and Reserve Component Service Members, May 12, 2023. https://www.health.mil/Reference-Center/DHA-Publications/2023/05/12/DHA-PI-6015-21
  6. Elders MJ, Brown GR, Coleman E, et al. Medical aspects of transgender military service. Armed Forces Soc. 2015;41:199-220. doi:10.1177/0095327X14545625.
  7. Almazan AN, Keuroghlian AS. Association between gender-affirming surgeries and mental health outcomes. JAMA Surg. 2021;156:611-618.
  8. Tordoff DM, Wanta JW, Collin A, et al. Mental health outcomes in transgender and nonbinary youths receiving gender-affirming care. JAMA Netw Open. 2022;5:E220978. doi:10.1001/jamanetworkopen.2022.0978
  9. Olson-Kennedy J, Warus J, Okonta V, et al. Chest reconstruction and chest dysphoria in transmasculine minors and young adults: comparisons of nonsurgical and postsurgical cohorts. JAMA Pediatr. 2018;172:431-436. doi:10.1001/jamapediatrics.2017.5440
  10. Top non-invasive cosmetic procedures worldwide 2022. Statista website. February 8, 2024. Accessed June 13, 2024. https://www.statista.com/statistics/293449/leading-nonsurgical-cosmetic-procedures/
  11. Kashkouli MB, Abdolalizadeh P, Abolfathzadeh N, et al. Periorbital facial rejuvenation; applied anatomy and pre-operative assessment. J Curr Ophthalmol. 2017;29:154-168. doi:10.1016/j.joco.2017.04.001
  12. Thomas MK, D’Silva JA, Borole AJ. Injection lipolysis: a systematic review of literature and our experience with a combination of phosphatidylcholine and deoxycholate over a period of 14 years in 1269 patients of Indian and South East Asian origin. J Cutan Aesthet Surg. 2018;11:222-228. doi:10.4103/JCAS.JCAS_117_18
  13. Jegasothy SM. Deoxycholic acid injections for bra-line lipolysis. Dermatol Surg. 2018;44:757-760. doi:10.1097/DSS.0000000000001311
  14. Dierickx CC. Hair removal by lasers and intense pulsed light sources. Dermatol Clin. 2002;20:135-146. doi:10.1016/s0733-8635(03)00052-4
  15. Lepselter J, Elman M. Biological and clinical aspects in laser hair removal. J Dermatolog Treat. 2004;15:72-83. doi:10.1080/09546630310023152
  16. Yuan N, Feldman AT, Chin P, et al. Comparison of permanent hair removal procedures before gender-affirming vaginoplasty: why we should consider laser hair removal as a first-line treatment for patients who meet criteria. Sex Med. 2022;10:100545. doi:10.1016/j.esxm.2022.100545
  17. Kumar A, Naguib YW, Shi YC, et al. A method to improve the efficacy of topical eflornithine hydrochloride cream. Drug Deliv. 2016;23:1495-1501. doi:10.3109/10717544.2014.951746
  18. Hembree WC, Cohen-Kettenis PT, Gooren L, et al. Endocrine treatment of gender-dysphoric/gender-incongruent persons: an endocrine society clinical practice guideline. J Clin Endocrinol Metabol. 2017;102:3869-3903.
  19. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  20. Rubenstein R, Roenigk HH Jr, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15(2 pt 1):280-285.
  21. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706.
  22. Goldberg D, Kothare A, Doucette M, et al. Selective photothermolysis with a novel 1726 nm laser beam: a safe and effective solution for acne vulgaris. J Cosmet Dermatol. 2023;22:486-496. doi:10.1111/jocd.15602
  23. Sun HY, Sebaratnam DF. Clascoterone as a novel treatment for androgenetic alopecia. Clin Exp Dermatol. 2020;45:913-914. doi:10.1111/ced.14292
  24. Bolognia JL, Schaffer JV, Cerroni L. Dermatology: 2-Volume Set. Elsevier; 2024:1130.
  25. Konisky H, Balazic E, Jaller JA, et al. Tranexamic acid in melasma: a focused review on drug administration routes. J Cosmet Dermatol. 2023;22:1197-1206. doi:10.1111/jocd.15589
  26. Walsh LA, Wu E, Pontes D, et al. Keloid treatments: an evidence-based systematic review of recent advances. Syst Rev. 2023;12:42. doi:10.1186/s13643-023-02192-7
  27. Kridin K, Ludwig RJ. Isotretinoin and the risk of psychiatric disturbances: a global study shedding new light on a debatable story. J Am Acad Dermatol. 2023;88:388-394. doi:10.1016/j.jaad.2022.10.031
  28. Dyson TE, Cantrell MA, Lund BC. Lack of association between 5α-reductase inhibitors and depression. J Urol. 2020;204:793-798. doi:10.1097/JU.0000000000001079
  29. To M, Zhang Q, Bradlyn A, et al. Visual conformity with affirmed gender or “passing”: its distribution and association with depression and anxiety in a cohort of transgender people. J Sex Med. 2020;17:2084-2092. doi:10.1016/j.jsxm.2020.07.019
  30. Fernandes MG, da Silva LP, Cerqueira MT, et al. Mechanomodulatory biomaterials prospects in scar prevention and treatment. Acta Biomater. 2022;150:22-33. doi:10.1016/j.actbio.2022.07.042
  31. Kolli H, Moy RL. Prevention of scarring with intraoperative erbium:YAG laser treatment. J Drugs Dermatol. 2020;19:1040-1043. doi:10.36849/JDD.2020.5244
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Transgender and Gender Diverse Health Care in the US Military: What Dermatologists Need to Know
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Practice Points

  • Transgender and gender diverse (TGD) health care is multidisciplinary, and both military and civilian dermatologists can serve an important role.
  • Although dermatologists do not directly perform gender-affirming surgeries or hormone management, there are a number of dermatologic procedures and medical interventions that can enhance a TGD person’s desired appearance.
  • Dermatologists also can help manage possible adverse effects from gender-affirming interventions.
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Benzoyl Peroxide, Benzene, and Lots of Unanswered Questions: Where Are We Now?

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Benzoyl Peroxide, Benzene, and Lots of Unanswered Questions: Where Are We Now?
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James Q. Del Rosso, DO

March 2024 proved to be a busy month for benzoyl peroxide in the media! We are now at almost 4 months since Valisure, an independent analytical laboratory located in Connecticut, filed a Citizen Petition on benzene in benzoyl peroxide drug products with the US Food and Drug Administration (FDA) on March 5, 2024.1 This petition was filed shortly before the annual meeting of the American Academy of Dermatology was held in San Diego, California, creating quite a stir of concern in the dermatology world. Further information on the degradation of benzoyl peroxide with production of benzene was published in the medical literature in March 2024.2 As benzene is recognized as a human carcinogen, manufacturing regulations exist to assure that it does not appear in topical products either through contamination or degradation over the course of a product’s shelf-life.3

As anticipated, several opinions and commentaries appeared quickly, both on video and in various articles. The American Acne & Rosacea Society (AARS) released a statement on this issue on March 20, 2024.4 The safety of the public is the overarching primary concern. This AARS statement does include some general suggestions related to benzoyl peroxide use based on the best assessment to date while awaiting further guidance from the FDA on this issue. Benzoyl peroxide is approved for use by the FDA as an over-the-counter (OTC) topical product for acne and also is in several FDA-approved prescription topical products.5,6

The following reflects my personal viewpoint as both a dermatologist and a grandfather who has grandchildren who use acne products. My views are not necessarily those of AARS. Since early March 2024, I have read several documents and spoken to several dermatologists, scientists, and formulators with knowledge in this area, including contacts at Valisure. I was hoping to get to some reasonable definitive answer but have not been able to achieve this to my full satisfaction. There are many opinions and concerns, and each one makes sense based on the vantage point of the presenter. However, several unanswered questions remain related to what testing and data are currently required of companies to gain FDA approval of a benzoyl peroxide product, including:

  • assessment of stability and degradation products (including benzene),
  • validation of testing methods,
  • the issue of benzoyl peroxide stability in commercial products, and
  • the relevant magnitude of resultant benzene exposures, especially as we are all exposed to benzene from several sources each day.

I am certain that companies with benzoyl peroxide products will evaluate their already-approved products and also do further testing. However, in this situation, which impacts millions of people on so many levels, I feel there needs to be an organized approach to evaluate and resolve the issue, otherwise the likelihood of continued confusion and uncertainty is high. As the FDA is the approval body, I am hoping it will provide definitive guidance within a reasonable timeline so that clinicians, patients, and manufacturers of benzoyl peroxide can proceed with full confidence. Right now, we all remain in a state of limbo. It is time for less talk and more definitive action to sort out this issue.

References
  1. Valisure Citizen Petition on Benzene in Benzoyl Peroxide Products. March 5, 2024. Accessed June 5, 2024. https://assets-global.website-files.com/6215052733f8bb8fea016220/65e8560962ed23f744902a7b_Valisure%20Citizen%20Petition%20on%20Benzene%20in%20Benzoyl%20Peroxide%20Drug%20Products.pdf
  2. Kucera K, Zenzola N, Hudspeth A, et al. Benzoyl peroxide drug products form benzene. Environ Health Perspect. 2024;132:37702. doi:10.1289/EHP13984
  3. US Food and Drug Administration. Reformulating drug products that contain carbomers manufactured with benzene. December 2023. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/reformulating-drug-products-contain-carbomers-manufactured-benzene
  4. American Acne & Rosacea Society. Response Statement from the AARS to the Valisure Citizen Petition on Benzene in Benzoyl Peroxide Drug Products. March 20, 2024. Accessed June 12, 2024. https://www.einpresswire.com/article/697481595/response-statement-from-the-aars-to-the-valisure-citizen-petition-on-benzene-in-benzoyl-peroxide-drug-products
  5. Department of Health and Human Services. Classification of benzoyl peroxide as safe and effective and revision of labeling to drug facts format; topical acne drug products for over-the-counter human use; Final Rule. Fed Registr. 2010;75:9767-9777.
  6. US Food and Drug Administration. Topical acne drug products for over-the-counter human use—revision of labeling and classification of benzoyl peroxide as safe and effective. June 2011. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/topical-acne-drug-products-over-counter-human-use-revision-labeling-and-classification-benzoyl
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From JDR Dermatology Research, Las Vegas, Nevada; Advanced Dermatology & Cosmetic Surgery, Maitland, Florida; and Touro University Nevada, Henderson.

Dr. Del Rosso is a consultant, investigator, researcher, and/or speaker for AbbVie; Aclaris; Almirall; Amgen; Anaptys Bio; Arcutis Biotherapeutics; Aslan; Athenex; Bausch Health (Ortho Dermatologics); Biofrontera; BiopharmX; Biorasi; Blue Creek; Botanix; Brickell; Bristol-Myers-Squibb; Cara Therapeutics; Cassiopea; Dermata; Dermavant Sciences, Inc; Eli Lilly and Company; Encore; EPI Health; Evommune; Ferndale; Galderma; Genentech; Incyte; Janssen; JEM Health; La Roche Posay Laboratoire Pharmaceutique; LEO Pharma; MC2 Therapeutics; Novan; Pfizer Inc; Ralexar; Regeneron; Sanofi; Sente; Solgel; Sonoma; Sun Pharmaceuticals; UCB; Verrica Pharmaceuticals; and Vyne. He also is the President of the American Acne & Rosacea Society.

Correspondence: James Q. Del Rosso, DO ([email protected]).

Cutis. 2024 July;114(1):3-4. doi:10.12788/cutis.1043

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From JDR Dermatology Research, Las Vegas, Nevada; Advanced Dermatology & Cosmetic Surgery, Maitland, Florida; and Touro University Nevada, Henderson.

Dr. Del Rosso is a consultant, investigator, researcher, and/or speaker for AbbVie; Aclaris; Almirall; Amgen; Anaptys Bio; Arcutis Biotherapeutics; Aslan; Athenex; Bausch Health (Ortho Dermatologics); Biofrontera; BiopharmX; Biorasi; Blue Creek; Botanix; Brickell; Bristol-Myers-Squibb; Cara Therapeutics; Cassiopea; Dermata; Dermavant Sciences, Inc; Eli Lilly and Company; Encore; EPI Health; Evommune; Ferndale; Galderma; Genentech; Incyte; Janssen; JEM Health; La Roche Posay Laboratoire Pharmaceutique; LEO Pharma; MC2 Therapeutics; Novan; Pfizer Inc; Ralexar; Regeneron; Sanofi; Sente; Solgel; Sonoma; Sun Pharmaceuticals; UCB; Verrica Pharmaceuticals; and Vyne. He also is the President of the American Acne & Rosacea Society.

Correspondence: James Q. Del Rosso, DO ([email protected]).

Cutis. 2024 July;114(1):3-4. doi:10.12788/cutis.1043

Author and Disclosure Information

 

From JDR Dermatology Research, Las Vegas, Nevada; Advanced Dermatology & Cosmetic Surgery, Maitland, Florida; and Touro University Nevada, Henderson.

Dr. Del Rosso is a consultant, investigator, researcher, and/or speaker for AbbVie; Aclaris; Almirall; Amgen; Anaptys Bio; Arcutis Biotherapeutics; Aslan; Athenex; Bausch Health (Ortho Dermatologics); Biofrontera; BiopharmX; Biorasi; Blue Creek; Botanix; Brickell; Bristol-Myers-Squibb; Cara Therapeutics; Cassiopea; Dermata; Dermavant Sciences, Inc; Eli Lilly and Company; Encore; EPI Health; Evommune; Ferndale; Galderma; Genentech; Incyte; Janssen; JEM Health; La Roche Posay Laboratoire Pharmaceutique; LEO Pharma; MC2 Therapeutics; Novan; Pfizer Inc; Ralexar; Regeneron; Sanofi; Sente; Solgel; Sonoma; Sun Pharmaceuticals; UCB; Verrica Pharmaceuticals; and Vyne. He also is the President of the American Acne & Rosacea Society.

Correspondence: James Q. Del Rosso, DO ([email protected]).

Cutis. 2024 July;114(1):3-4. doi:10.12788/cutis.1043

Article PDF
CT114001003.pdf
Article PDF
CT114001003.pdf

March 2024 proved to be a busy month for benzoyl peroxide in the media! We are now at almost 4 months since Valisure, an independent analytical laboratory located in Connecticut, filed a Citizen Petition on benzene in benzoyl peroxide drug products with the US Food and Drug Administration (FDA) on March 5, 2024.1 This petition was filed shortly before the annual meeting of the American Academy of Dermatology was held in San Diego, California, creating quite a stir of concern in the dermatology world. Further information on the degradation of benzoyl peroxide with production of benzene was published in the medical literature in March 2024.2 As benzene is recognized as a human carcinogen, manufacturing regulations exist to assure that it does not appear in topical products either through contamination or degradation over the course of a product’s shelf-life.3

As anticipated, several opinions and commentaries appeared quickly, both on video and in various articles. The American Acne & Rosacea Society (AARS) released a statement on this issue on March 20, 2024.4 The safety of the public is the overarching primary concern. This AARS statement does include some general suggestions related to benzoyl peroxide use based on the best assessment to date while awaiting further guidance from the FDA on this issue. Benzoyl peroxide is approved for use by the FDA as an over-the-counter (OTC) topical product for acne and also is in several FDA-approved prescription topical products.5,6

The following reflects my personal viewpoint as both a dermatologist and a grandfather who has grandchildren who use acne products. My views are not necessarily those of AARS. Since early March 2024, I have read several documents and spoken to several dermatologists, scientists, and formulators with knowledge in this area, including contacts at Valisure. I was hoping to get to some reasonable definitive answer but have not been able to achieve this to my full satisfaction. There are many opinions and concerns, and each one makes sense based on the vantage point of the presenter. However, several unanswered questions remain related to what testing and data are currently required of companies to gain FDA approval of a benzoyl peroxide product, including:

  • assessment of stability and degradation products (including benzene),
  • validation of testing methods,
  • the issue of benzoyl peroxide stability in commercial products, and
  • the relevant magnitude of resultant benzene exposures, especially as we are all exposed to benzene from several sources each day.

I am certain that companies with benzoyl peroxide products will evaluate their already-approved products and also do further testing. However, in this situation, which impacts millions of people on so many levels, I feel there needs to be an organized approach to evaluate and resolve the issue, otherwise the likelihood of continued confusion and uncertainty is high. As the FDA is the approval body, I am hoping it will provide definitive guidance within a reasonable timeline so that clinicians, patients, and manufacturers of benzoyl peroxide can proceed with full confidence. Right now, we all remain in a state of limbo. It is time for less talk and more definitive action to sort out this issue.

March 2024 proved to be a busy month for benzoyl peroxide in the media! We are now at almost 4 months since Valisure, an independent analytical laboratory located in Connecticut, filed a Citizen Petition on benzene in benzoyl peroxide drug products with the US Food and Drug Administration (FDA) on March 5, 2024.1 This petition was filed shortly before the annual meeting of the American Academy of Dermatology was held in San Diego, California, creating quite a stir of concern in the dermatology world. Further information on the degradation of benzoyl peroxide with production of benzene was published in the medical literature in March 2024.2 As benzene is recognized as a human carcinogen, manufacturing regulations exist to assure that it does not appear in topical products either through contamination or degradation over the course of a product’s shelf-life.3

As anticipated, several opinions and commentaries appeared quickly, both on video and in various articles. The American Acne & Rosacea Society (AARS) released a statement on this issue on March 20, 2024.4 The safety of the public is the overarching primary concern. This AARS statement does include some general suggestions related to benzoyl peroxide use based on the best assessment to date while awaiting further guidance from the FDA on this issue. Benzoyl peroxide is approved for use by the FDA as an over-the-counter (OTC) topical product for acne and also is in several FDA-approved prescription topical products.5,6

The following reflects my personal viewpoint as both a dermatologist and a grandfather who has grandchildren who use acne products. My views are not necessarily those of AARS. Since early March 2024, I have read several documents and spoken to several dermatologists, scientists, and formulators with knowledge in this area, including contacts at Valisure. I was hoping to get to some reasonable definitive answer but have not been able to achieve this to my full satisfaction. There are many opinions and concerns, and each one makes sense based on the vantage point of the presenter. However, several unanswered questions remain related to what testing and data are currently required of companies to gain FDA approval of a benzoyl peroxide product, including:

  • assessment of stability and degradation products (including benzene),
  • validation of testing methods,
  • the issue of benzoyl peroxide stability in commercial products, and
  • the relevant magnitude of resultant benzene exposures, especially as we are all exposed to benzene from several sources each day.

I am certain that companies with benzoyl peroxide products will evaluate their already-approved products and also do further testing. However, in this situation, which impacts millions of people on so many levels, I feel there needs to be an organized approach to evaluate and resolve the issue, otherwise the likelihood of continued confusion and uncertainty is high. As the FDA is the approval body, I am hoping it will provide definitive guidance within a reasonable timeline so that clinicians, patients, and manufacturers of benzoyl peroxide can proceed with full confidence. Right now, we all remain in a state of limbo. It is time for less talk and more definitive action to sort out this issue.

References
  1. Valisure Citizen Petition on Benzene in Benzoyl Peroxide Products. March 5, 2024. Accessed June 5, 2024. https://assets-global.website-files.com/6215052733f8bb8fea016220/65e8560962ed23f744902a7b_Valisure%20Citizen%20Petition%20on%20Benzene%20in%20Benzoyl%20Peroxide%20Drug%20Products.pdf
  2. Kucera K, Zenzola N, Hudspeth A, et al. Benzoyl peroxide drug products form benzene. Environ Health Perspect. 2024;132:37702. doi:10.1289/EHP13984
  3. US Food and Drug Administration. Reformulating drug products that contain carbomers manufactured with benzene. December 2023. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/reformulating-drug-products-contain-carbomers-manufactured-benzene
  4. American Acne & Rosacea Society. Response Statement from the AARS to the Valisure Citizen Petition on Benzene in Benzoyl Peroxide Drug Products. March 20, 2024. Accessed June 12, 2024. https://www.einpresswire.com/article/697481595/response-statement-from-the-aars-to-the-valisure-citizen-petition-on-benzene-in-benzoyl-peroxide-drug-products
  5. Department of Health and Human Services. Classification of benzoyl peroxide as safe and effective and revision of labeling to drug facts format; topical acne drug products for over-the-counter human use; Final Rule. Fed Registr. 2010;75:9767-9777.
  6. US Food and Drug Administration. Topical acne drug products for over-the-counter human use—revision of labeling and classification of benzoyl peroxide as safe and effective. June 2011. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/topical-acne-drug-products-over-counter-human-use-revision-labeling-and-classification-benzoyl
References
  1. Valisure Citizen Petition on Benzene in Benzoyl Peroxide Products. March 5, 2024. Accessed June 5, 2024. https://assets-global.website-files.com/6215052733f8bb8fea016220/65e8560962ed23f744902a7b_Valisure%20Citizen%20Petition%20on%20Benzene%20in%20Benzoyl%20Peroxide%20Drug%20Products.pdf
  2. Kucera K, Zenzola N, Hudspeth A, et al. Benzoyl peroxide drug products form benzene. Environ Health Perspect. 2024;132:37702. doi:10.1289/EHP13984
  3. US Food and Drug Administration. Reformulating drug products that contain carbomers manufactured with benzene. December 2023. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/reformulating-drug-products-contain-carbomers-manufactured-benzene
  4. American Acne & Rosacea Society. Response Statement from the AARS to the Valisure Citizen Petition on Benzene in Benzoyl Peroxide Drug Products. March 20, 2024. Accessed June 12, 2024. https://www.einpresswire.com/article/697481595/response-statement-from-the-aars-to-the-valisure-citizen-petition-on-benzene-in-benzoyl-peroxide-drug-products
  5. Department of Health and Human Services. Classification of benzoyl peroxide as safe and effective and revision of labeling to drug facts format; topical acne drug products for over-the-counter human use; Final Rule. Fed Registr. 2010;75:9767-9777.
  6. US Food and Drug Administration. Topical acne drug products for over-the-counter human use—revision of labeling and classification of benzoyl peroxide as safe and effective. June 2011. Accessed June 12, 2024. https://www.fda.gov/regulatory-information/search-fda-guidance-documents/topical-acne-drug-products-over-counter-human-use-revision-labeling-and-classification-benzoyl
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Evolving Treatment of Severe Alopecia

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Ali Jabbari, MD

The classification of severe alopecia areata (AA) and its treatment are evolving. Dr Ali Jabbari, from the University of Iowa, discusses factors that characterize severe AA and traces the expanded treatment options provided by the advent of Janus kinase (JAK) inhibitors.

Dr Jabbari reports on a modified AA severity scale, published in the Journal of American Academy of Dermatology, in which the presence of certain factors upgrade the level of severity. Factors include eyebrow/eyelash involvement and psychosocial comorbidities such as depression, anxiety, and social phobias. Traditional treatments for severe AA have relied largely on corticosteroids. Dr Jabbari explains how this treatment can be helpful for patients with limited disease, but may be burdensome for those with severe disease, in terms of injection pain and side effects of long-term use. Another option for patients with severe AA is the use of systemic immunosuppressants, but these are not as effective as newer treatments.

Dr Jabbari looks at two FDA-approved options for JAK inhibitors: baricitinib for patients aged 18 years or older and ritlecitinib for patients aged 12 years or older. He notes some of the potential side effects of these medications but concludes that JAK inhibitors are a safe option for treating patients with severe AA.

--

Ali Jabbari, MD, PhD, Chair, DEO, Roger I. Ceilley Associate Professor, Department of Dermatology, University of Iowa Roy J. and Lucille A. Carver College of Medicine, Iowa City, Iowa

Ali Jabbari, MD, PhD, has disclosed the following relevant financial relationships:

 

Serve(d) as a consultant for: Pfizer; Inc.; Cage Bio

Received research grant from: National Institutes of Health; Department of Veterans Affairs; Pfizer; Inc

Scientific Advisory Board for: BiologicsMD

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Ali Jabbari, MD

The classification of severe alopecia areata (AA) and its treatment are evolving. Dr Ali Jabbari, from the University of Iowa, discusses factors that characterize severe AA and traces the expanded treatment options provided by the advent of Janus kinase (JAK) inhibitors.

Dr Jabbari reports on a modified AA severity scale, published in the Journal of American Academy of Dermatology, in which the presence of certain factors upgrade the level of severity. Factors include eyebrow/eyelash involvement and psychosocial comorbidities such as depression, anxiety, and social phobias. Traditional treatments for severe AA have relied largely on corticosteroids. Dr Jabbari explains how this treatment can be helpful for patients with limited disease, but may be burdensome for those with severe disease, in terms of injection pain and side effects of long-term use. Another option for patients with severe AA is the use of systemic immunosuppressants, but these are not as effective as newer treatments.

Dr Jabbari looks at two FDA-approved options for JAK inhibitors: baricitinib for patients aged 18 years or older and ritlecitinib for patients aged 12 years or older. He notes some of the potential side effects of these medications but concludes that JAK inhibitors are a safe option for treating patients with severe AA.

--

Ali Jabbari, MD, PhD, Chair, DEO, Roger I. Ceilley Associate Professor, Department of Dermatology, University of Iowa Roy J. and Lucille A. Carver College of Medicine, Iowa City, Iowa

Ali Jabbari, MD, PhD, has disclosed the following relevant financial relationships:

 

Serve(d) as a consultant for: Pfizer; Inc.; Cage Bio

Received research grant from: National Institutes of Health; Department of Veterans Affairs; Pfizer; Inc

Scientific Advisory Board for: BiologicsMD

The classification of severe alopecia areata (AA) and its treatment are evolving. Dr Ali Jabbari, from the University of Iowa, discusses factors that characterize severe AA and traces the expanded treatment options provided by the advent of Janus kinase (JAK) inhibitors.

Dr Jabbari reports on a modified AA severity scale, published in the Journal of American Academy of Dermatology, in which the presence of certain factors upgrade the level of severity. Factors include eyebrow/eyelash involvement and psychosocial comorbidities such as depression, anxiety, and social phobias. Traditional treatments for severe AA have relied largely on corticosteroids. Dr Jabbari explains how this treatment can be helpful for patients with limited disease, but may be burdensome for those with severe disease, in terms of injection pain and side effects of long-term use. Another option for patients with severe AA is the use of systemic immunosuppressants, but these are not as effective as newer treatments.

Dr Jabbari looks at two FDA-approved options for JAK inhibitors: baricitinib for patients aged 18 years or older and ritlecitinib for patients aged 12 years or older. He notes some of the potential side effects of these medications but concludes that JAK inhibitors are a safe option for treating patients with severe AA.

--

Ali Jabbari, MD, PhD, Chair, DEO, Roger I. Ceilley Associate Professor, Department of Dermatology, University of Iowa Roy J. and Lucille A. Carver College of Medicine, Iowa City, Iowa

Ali Jabbari, MD, PhD, has disclosed the following relevant financial relationships:

 

Serve(d) as a consultant for: Pfizer; Inc.; Cage Bio

Received research grant from: National Institutes of Health; Department of Veterans Affairs; Pfizer; Inc

Scientific Advisory Board for: BiologicsMD

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Isotretinoin-Induced Skin Fragility in an Aerialist

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Isotretinoin-Induced Skin Fragility in an Aerialist
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Helana Ghali, BS
Sharon E. Albers, MD

Isotretinoin was introduced more than 3 decades ago and marked a major advancement in the treatment of severe refractory cystic acne. The most common adverse effects linked to isotretinoin usage are mucocutaneous in nature, manifesting as xerosis and cheilitis.1 Skin fragility and poor wound healing also have been reported.2-6 Current recommendations for avoiding these adverse effects include refraining from waxing, laser procedures, and other elective cutaneous procedures for at least 6 months.7 We present a case of isotretinoin-induced cutaneous fragility resulting in blistering and erosions on the palms of a competitive aerial trapeze artist.

Case Report

A 25-year-old woman presented for follow-up during week 12 of isotretinoin therapy (40 mg twice daily) prescribed for acne. She reported peeling of the skin on the palms following intense aerial acrobatic workouts. She had been a performing aerialist for many years and had never sustained a similar injury. The wounds were painful and led to decreased activity. She had no notable medical history. Physical examination of the palms revealed erosions in a distribution that corresponded to horizontal bar contact and friction (Figure). The patient was advised on proper wound care, application of emollients, and minimizing friction. She completed the course of isotretinoin and has continued aerialist activity without recurrence of skin fragility.

Comment

Skin fragility is a well-known adverse effect of isotretinoin therapy.8 Pavlis and Lieblich9 reported skin fragility in a young wrestler who experienced similar skin erosions due to isotretinoin therapy. The proposed mechanism of isotretinoin-induced skin fragility is multifactorial. It involves an apoptotic effect on sebocytes,5 which results in reduced stratum corneum hydration and an associated increase in transepidermal water loss.6,10,11 Retinoids also are known to cause thinning of the skin, likely due to the disadhesion of both the epidermis and the stratum corneum, which was demonstrated by the easy removal of cornified cells through tape stripping in hairless mice treated with isotretinoin.12 In further investigations, human patients and hairless mice treated with isotretinoin readily developed friction blisters through pencil eraser abrasion.13 Examination of the friction blisters using light and electron microscopy revealed fraying or loss of the stratum corneum and viable epidermis as well as loss of desmosomes and tonofilaments. Additionally, intracellular and intercellular deposits of an unidentified amorphous material were noted.13

A and B, Erosions on the palms due to isotretinoin induced skin fragility.

Overall, the origin of skin fragility induced by isotretinoin is supported by its effect on sebocytes, increased transepidermal water loss, and profound disruption of the integrity of the epidermis, resulting in an elevated risk for inadvertent skin damage. Patients were encouraged to avoid cosmetic procedures in prior case reports,14-16 and because our case demonstrates the risk for cutaneous injury in athletes due to isotretinoin-induced skin fragility, we propose an extension of these warnings to encompass athletes receiving isotretinoin treatment. Offering early guidance on wound prevention is of paramount importance in maintaining athletic performance and minimizing painful injuries.

References
  1. Rajput I, Anjankar VP. Side effects of treating acne vulgaris with isotretinoin: a systematic review. Cureus. 2024;16:E55946. doi:10.7759/cureus.55946
  2. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  3. McDonald KA, Shelley AJ, Alavi A. A systematic review on oral isotretinoin therapy and clinically observable wound healing in acne patients. J Cutan Med Surg. 2017;21:325-333. doi:10.1177/1203475417701419
  4. Layton A. The use of isotretinoin in acne. Dermatoendocrinol. 2009;1:162-169. doi:10.4161/derm.1.3.9364
  5. Zouboulis CC. Isotretinoin revisited: pluripotent effects on human sebaceous gland cells. J Invest Dermatol. 2006;126:2154-2156. doi:10.1038/sj.jid.5700418
  6. Kmiec´ ML, Pajor A, Broniarczyk-Dyła G. Evaluation of biophysical skin parameters and assessment of hair growth in patients with acne treated with isotretinoin. Postepy Dermatol Alergol. 2013;30:343-349. doi:10.5114/pdia.2013.39432
  7. Waldman A, Bolotin D, Arndt KA, et al. ASDS Guidelines Task Force: Consensus recommendations regarding the safety of lasers, dermabrasion, chemical peels, energy devices, and skin surgery during and after isotretinoin use. Dermatolog Surg. 2017;43:1249-1262. doi:10.1097/DSS.0000000000001166
  8. Aksoy H, Aksoy B, Calikoglu E. Systemic retinoids and scar dehiscence. Indian J Dermatol. 2019;64:68. doi:10.4103/ijd.IJD_148_18
  9. Pavlis MB, Lieblich L. Isotretinoin-induced skin fragility in a teenaged athlete: a case report. Cutis. 2013;92:33-34.
  10. Herane MI, Fuenzalida H, Zegpi E, et al. Specific gel-cream as adjuvant to oral isotretinoin improved hydration and prevented TEWL increase—a double-blind, randomized, placebo-controlled study. J Cosmet Dermatol. 2009;8:181-185. doi:10.1111/j.1473-2165.2009.00455.x
  11. Park KY, Ko EJ, Kim IS, et al. The effect of evening primrose oil for the prevention of xerotic cheilitis in acne patients being treated with isotretinoin: a pilot study. Ann Dermatol. 2014;26:706-712. doi:10.5021/ad.2014.26.6.706
  12. Elias PM, Fritsch PO, Lampe M, et al. Retinoid effects on epidermal structure, differentiation, and permeability. Lab Invest. 1981;44:531-540.
  13. Williams ML, Elias PM. Nature of skin fragility in patients receiving retinoids for systemic effect. Arch Dermatol. 1981;117:611-619.
  14. Rubenstein R, Roenigk HH, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15:280-285. doi:10.1016/S0190-9622(86)70167-9
  15. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706. doi:10.1111/j.1365-2133.1988.tb02574.x
  16. Katz BE, Mac Farlane DF. Atypical facial scarring after isotretinoin therapy in a patient with previous dermabrasion. J Am Acad Dermatol. 1994;30:852-853. doi:10.1016/S0190-9622(94)70096-6
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From the University of South Florida, Tampa. Helana Ghali is from the Morsani College of Medicine, and Dr. Albers is from the Department of Dermatology and Cutaneous Surgery.

The authors report no conflict of interest.

Correspondence: Helana Ghali, BS, 560 Channelside Dr, Tampa, FL 33602 ([email protected]).

Cutis. 2024 July;114(1):32-33. doi:10.12788/cutis.1042

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From the University of South Florida, Tampa. Helana Ghali is from the Morsani College of Medicine, and Dr. Albers is from the Department of Dermatology and Cutaneous Surgery.

The authors report no conflict of interest.

Correspondence: Helana Ghali, BS, 560 Channelside Dr, Tampa, FL 33602 ([email protected]).

Cutis. 2024 July;114(1):32-33. doi:10.12788/cutis.1042

Author and Disclosure Information

 

From the University of South Florida, Tampa. Helana Ghali is from the Morsani College of Medicine, and Dr. Albers is from the Department of Dermatology and Cutaneous Surgery.

The authors report no conflict of interest.

Correspondence: Helana Ghali, BS, 560 Channelside Dr, Tampa, FL 33602 ([email protected]).

Cutis. 2024 July;114(1):32-33. doi:10.12788/cutis.1042

Article PDF
CT114001032.pdf
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CT114001032.pdf

Isotretinoin was introduced more than 3 decades ago and marked a major advancement in the treatment of severe refractory cystic acne. The most common adverse effects linked to isotretinoin usage are mucocutaneous in nature, manifesting as xerosis and cheilitis.1 Skin fragility and poor wound healing also have been reported.2-6 Current recommendations for avoiding these adverse effects include refraining from waxing, laser procedures, and other elective cutaneous procedures for at least 6 months.7 We present a case of isotretinoin-induced cutaneous fragility resulting in blistering and erosions on the palms of a competitive aerial trapeze artist.

Case Report

A 25-year-old woman presented for follow-up during week 12 of isotretinoin therapy (40 mg twice daily) prescribed for acne. She reported peeling of the skin on the palms following intense aerial acrobatic workouts. She had been a performing aerialist for many years and had never sustained a similar injury. The wounds were painful and led to decreased activity. She had no notable medical history. Physical examination of the palms revealed erosions in a distribution that corresponded to horizontal bar contact and friction (Figure). The patient was advised on proper wound care, application of emollients, and minimizing friction. She completed the course of isotretinoin and has continued aerialist activity without recurrence of skin fragility.

Comment

Skin fragility is a well-known adverse effect of isotretinoin therapy.8 Pavlis and Lieblich9 reported skin fragility in a young wrestler who experienced similar skin erosions due to isotretinoin therapy. The proposed mechanism of isotretinoin-induced skin fragility is multifactorial. It involves an apoptotic effect on sebocytes,5 which results in reduced stratum corneum hydration and an associated increase in transepidermal water loss.6,10,11 Retinoids also are known to cause thinning of the skin, likely due to the disadhesion of both the epidermis and the stratum corneum, which was demonstrated by the easy removal of cornified cells through tape stripping in hairless mice treated with isotretinoin.12 In further investigations, human patients and hairless mice treated with isotretinoin readily developed friction blisters through pencil eraser abrasion.13 Examination of the friction blisters using light and electron microscopy revealed fraying or loss of the stratum corneum and viable epidermis as well as loss of desmosomes and tonofilaments. Additionally, intracellular and intercellular deposits of an unidentified amorphous material were noted.13

A and B, Erosions on the palms due to isotretinoin induced skin fragility.

Overall, the origin of skin fragility induced by isotretinoin is supported by its effect on sebocytes, increased transepidermal water loss, and profound disruption of the integrity of the epidermis, resulting in an elevated risk for inadvertent skin damage. Patients were encouraged to avoid cosmetic procedures in prior case reports,14-16 and because our case demonstrates the risk for cutaneous injury in athletes due to isotretinoin-induced skin fragility, we propose an extension of these warnings to encompass athletes receiving isotretinoin treatment. Offering early guidance on wound prevention is of paramount importance in maintaining athletic performance and minimizing painful injuries.

Isotretinoin was introduced more than 3 decades ago and marked a major advancement in the treatment of severe refractory cystic acne. The most common adverse effects linked to isotretinoin usage are mucocutaneous in nature, manifesting as xerosis and cheilitis.1 Skin fragility and poor wound healing also have been reported.2-6 Current recommendations for avoiding these adverse effects include refraining from waxing, laser procedures, and other elective cutaneous procedures for at least 6 months.7 We present a case of isotretinoin-induced cutaneous fragility resulting in blistering and erosions on the palms of a competitive aerial trapeze artist.

Case Report

A 25-year-old woman presented for follow-up during week 12 of isotretinoin therapy (40 mg twice daily) prescribed for acne. She reported peeling of the skin on the palms following intense aerial acrobatic workouts. She had been a performing aerialist for many years and had never sustained a similar injury. The wounds were painful and led to decreased activity. She had no notable medical history. Physical examination of the palms revealed erosions in a distribution that corresponded to horizontal bar contact and friction (Figure). The patient was advised on proper wound care, application of emollients, and minimizing friction. She completed the course of isotretinoin and has continued aerialist activity without recurrence of skin fragility.

Comment

Skin fragility is a well-known adverse effect of isotretinoin therapy.8 Pavlis and Lieblich9 reported skin fragility in a young wrestler who experienced similar skin erosions due to isotretinoin therapy. The proposed mechanism of isotretinoin-induced skin fragility is multifactorial. It involves an apoptotic effect on sebocytes,5 which results in reduced stratum corneum hydration and an associated increase in transepidermal water loss.6,10,11 Retinoids also are known to cause thinning of the skin, likely due to the disadhesion of both the epidermis and the stratum corneum, which was demonstrated by the easy removal of cornified cells through tape stripping in hairless mice treated with isotretinoin.12 In further investigations, human patients and hairless mice treated with isotretinoin readily developed friction blisters through pencil eraser abrasion.13 Examination of the friction blisters using light and electron microscopy revealed fraying or loss of the stratum corneum and viable epidermis as well as loss of desmosomes and tonofilaments. Additionally, intracellular and intercellular deposits of an unidentified amorphous material were noted.13

A and B, Erosions on the palms due to isotretinoin induced skin fragility.

Overall, the origin of skin fragility induced by isotretinoin is supported by its effect on sebocytes, increased transepidermal water loss, and profound disruption of the integrity of the epidermis, resulting in an elevated risk for inadvertent skin damage. Patients were encouraged to avoid cosmetic procedures in prior case reports,14-16 and because our case demonstrates the risk for cutaneous injury in athletes due to isotretinoin-induced skin fragility, we propose an extension of these warnings to encompass athletes receiving isotretinoin treatment. Offering early guidance on wound prevention is of paramount importance in maintaining athletic performance and minimizing painful injuries.

References
  1. Rajput I, Anjankar VP. Side effects of treating acne vulgaris with isotretinoin: a systematic review. Cureus. 2024;16:E55946. doi:10.7759/cureus.55946
  2. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  3. McDonald KA, Shelley AJ, Alavi A. A systematic review on oral isotretinoin therapy and clinically observable wound healing in acne patients. J Cutan Med Surg. 2017;21:325-333. doi:10.1177/1203475417701419
  4. Layton A. The use of isotretinoin in acne. Dermatoendocrinol. 2009;1:162-169. doi:10.4161/derm.1.3.9364
  5. Zouboulis CC. Isotretinoin revisited: pluripotent effects on human sebaceous gland cells. J Invest Dermatol. 2006;126:2154-2156. doi:10.1038/sj.jid.5700418
  6. Kmiec´ ML, Pajor A, Broniarczyk-Dyła G. Evaluation of biophysical skin parameters and assessment of hair growth in patients with acne treated with isotretinoin. Postepy Dermatol Alergol. 2013;30:343-349. doi:10.5114/pdia.2013.39432
  7. Waldman A, Bolotin D, Arndt KA, et al. ASDS Guidelines Task Force: Consensus recommendations regarding the safety of lasers, dermabrasion, chemical peels, energy devices, and skin surgery during and after isotretinoin use. Dermatolog Surg. 2017;43:1249-1262. doi:10.1097/DSS.0000000000001166
  8. Aksoy H, Aksoy B, Calikoglu E. Systemic retinoids and scar dehiscence. Indian J Dermatol. 2019;64:68. doi:10.4103/ijd.IJD_148_18
  9. Pavlis MB, Lieblich L. Isotretinoin-induced skin fragility in a teenaged athlete: a case report. Cutis. 2013;92:33-34.
  10. Herane MI, Fuenzalida H, Zegpi E, et al. Specific gel-cream as adjuvant to oral isotretinoin improved hydration and prevented TEWL increase—a double-blind, randomized, placebo-controlled study. J Cosmet Dermatol. 2009;8:181-185. doi:10.1111/j.1473-2165.2009.00455.x
  11. Park KY, Ko EJ, Kim IS, et al. The effect of evening primrose oil for the prevention of xerotic cheilitis in acne patients being treated with isotretinoin: a pilot study. Ann Dermatol. 2014;26:706-712. doi:10.5021/ad.2014.26.6.706
  12. Elias PM, Fritsch PO, Lampe M, et al. Retinoid effects on epidermal structure, differentiation, and permeability. Lab Invest. 1981;44:531-540.
  13. Williams ML, Elias PM. Nature of skin fragility in patients receiving retinoids for systemic effect. Arch Dermatol. 1981;117:611-619.
  14. Rubenstein R, Roenigk HH, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15:280-285. doi:10.1016/S0190-9622(86)70167-9
  15. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706. doi:10.1111/j.1365-2133.1988.tb02574.x
  16. Katz BE, Mac Farlane DF. Atypical facial scarring after isotretinoin therapy in a patient with previous dermabrasion. J Am Acad Dermatol. 1994;30:852-853. doi:10.1016/S0190-9622(94)70096-6
References
  1. Rajput I, Anjankar VP. Side effects of treating acne vulgaris with isotretinoin: a systematic review. Cureus. 2024;16:E55946. doi:10.7759/cureus.55946
  2. Hatami P, Balighi K, Asl HN, et al. Isotretinoin and timing of procedural interventions: clinical implications and practical points. J Cosmet Dermatol. 2023;22:2146-2149. doi:10.1111/jocd.15874
  3. McDonald KA, Shelley AJ, Alavi A. A systematic review on oral isotretinoin therapy and clinically observable wound healing in acne patients. J Cutan Med Surg. 2017;21:325-333. doi:10.1177/1203475417701419
  4. Layton A. The use of isotretinoin in acne. Dermatoendocrinol. 2009;1:162-169. doi:10.4161/derm.1.3.9364
  5. Zouboulis CC. Isotretinoin revisited: pluripotent effects on human sebaceous gland cells. J Invest Dermatol. 2006;126:2154-2156. doi:10.1038/sj.jid.5700418
  6. Kmiec´ ML, Pajor A, Broniarczyk-Dyła G. Evaluation of biophysical skin parameters and assessment of hair growth in patients with acne treated with isotretinoin. Postepy Dermatol Alergol. 2013;30:343-349. doi:10.5114/pdia.2013.39432
  7. Waldman A, Bolotin D, Arndt KA, et al. ASDS Guidelines Task Force: Consensus recommendations regarding the safety of lasers, dermabrasion, chemical peels, energy devices, and skin surgery during and after isotretinoin use. Dermatolog Surg. 2017;43:1249-1262. doi:10.1097/DSS.0000000000001166
  8. Aksoy H, Aksoy B, Calikoglu E. Systemic retinoids and scar dehiscence. Indian J Dermatol. 2019;64:68. doi:10.4103/ijd.IJD_148_18
  9. Pavlis MB, Lieblich L. Isotretinoin-induced skin fragility in a teenaged athlete: a case report. Cutis. 2013;92:33-34.
  10. Herane MI, Fuenzalida H, Zegpi E, et al. Specific gel-cream as adjuvant to oral isotretinoin improved hydration and prevented TEWL increase—a double-blind, randomized, placebo-controlled study. J Cosmet Dermatol. 2009;8:181-185. doi:10.1111/j.1473-2165.2009.00455.x
  11. Park KY, Ko EJ, Kim IS, et al. The effect of evening primrose oil for the prevention of xerotic cheilitis in acne patients being treated with isotretinoin: a pilot study. Ann Dermatol. 2014;26:706-712. doi:10.5021/ad.2014.26.6.706
  12. Elias PM, Fritsch PO, Lampe M, et al. Retinoid effects on epidermal structure, differentiation, and permeability. Lab Invest. 1981;44:531-540.
  13. Williams ML, Elias PM. Nature of skin fragility in patients receiving retinoids for systemic effect. Arch Dermatol. 1981;117:611-619.
  14. Rubenstein R, Roenigk HH, Stegman SJ, et al. Atypical keloids after dermabrasion of patients taking isotretinoin. J Am Acad Dermatol. 1986;15:280-285. doi:10.1016/S0190-9622(86)70167-9
  15. Zachariae H. Delayed wound healing and keloid formation following argon laser treatment or dermabrasion during isotretinoin treatment. Br J Dermatol. 1988;118:703-706. doi:10.1111/j.1365-2133.1988.tb02574.x
  16. Katz BE, Mac Farlane DF. Atypical facial scarring after isotretinoin therapy in a patient with previous dermabrasion. J Am Acad Dermatol. 1994;30:852-853. doi:10.1016/S0190-9622(94)70096-6
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Practice Points

  • Isotretinoin is used to treat severe nodulocystic acne but can cause adverse effects such as skin fragility, xerosis, and poor wound healing.
  • Dermatologists should inform athletes of heightened skin vulnerability while undergoing isotretinoin treatment.
  • Isotretinoin-induced skin fragility involves the effects of isotretinoin on sebocytes, transepidermal water loss, and disruption of the integrity of the epidermis.
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Two Techniques to Avoid Cyst Spray During Excision

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Bita Tristani-Firouzi, BA
Elliott D. Herron, BS
Christopher M. Hull, MD
Mark D. Herron, MD

Practice Gap

Epidermoid cysts are asymptomatic, well-circumscribed, mobile, subcutaneous masses that elevate the skin. Also known as epidermal, keratin, or infundibular cysts, epidermoid cysts are caused by proliferation of surface epidermoid cells within the dermis and can arise anywhere on the body, most commonly on the face, neck, and trunk.1 Cutaneous cysts often contain fluid or semifluid contents and can be aesthetically displeasing or cause mild pain, prompting patients to seek removal. Definitive treatment of epidermoid cysts is complete surgical removal,2 which can be performed in office in a sterile or clean manner by either dermatologists or primary care providers.

Prior to incision, a local anesthetic—commonly lidocaine with epinephrine—is injected in the region surrounding the cyst sac so as not to rupture the cyst wall. Maintaining the cyst wall throughout the procedure ensures total cyst removal and minimizes the risk for recurrence. However, it often is difficult to approximate the cyst border because it cannot be visualized prior to incision.

Throughout the duration of the procedure, cyst contents may suddenly spray out of the area and pose a risk to providers and their staff (Figure, A). Even with careful application around the periphery, either puncture or ­pericystic anesthesia between the cyst wall and the dermis can lead to splatter. Larger and wider peripheral anesthesia may not be possible given a shortage of ­lidocaine and a desire to minimize injection. Even with meticulous use of personal protective equipment in cutaneous surgery, infectious organisms found in ruptured cysts and abscesses may spray the surgical field.3 Therefore, it is in our best interest to minimize the trajectory of cyst spray contents.

The Tools

We have employed 2 simple techniques using equipment normally found on a standard surgical tray for easy safe injection of cysts. Supplies needed include 4×4-inch gauze pads, alcohol and chlorhexidine, a marker, all instruments necessary for cyst excision, and a small clear biohazard bag.

The Technique

Prior to covering the cyst, care is taken to locate the cyst opening. At times, a comedo or punctum can be seen overlying the cyst bulge. We mark the lumen and cyst opening with a surgical marker. If the pore is not easily identified, we draw an 8-mm circle around the mound of the cyst. 

One option is to apply a gauze pad over the cyst to allow for stabilization of the surgical field and blanket the area from splatter (Figure, B). Then we cover the cyst using antiseptic-soaked gauze as a protective barrier to avoid potentially contaminated spray. This tool can be constructed from a 4×4-inch gauze pad with the addition of alcohol and chlorhexidine. When the cyst is covered, the surgeon can inject the lesion and surrounding tissue without biohazard splatter.

A, During surgical excision of an epidermoid cyst, contents may spray out and pose a risk to clinicians and staff. B, Application of an antisepticsoaked gauze pad over the cyst allows for stabilization of the surgical field and blankets the area from splatter. C, Alternatively, the cyst can be covered with a small clear biohazard bag to catch any spraying contents while allowing visualization of the surgical field.

Another method is to cover the cyst with a small clear biohazard bag (Figure, C). When injecting anesthetic through the bag, the spray is captured by the bag and does not reach the surgeon or staff. This method is potentially more effective given that the cyst can still be visualized fully for more accurate injection.

Practice Implications

Outpatient surgical excision is a common effective procedure for epidermoid cysts. However, it is not uncommon for cyst contents to spray during the injection of anesthetic, posing a nuisance to the surgeon, health care staff, and patient. The technique of covering the lesion with antiseptic-soaked gauze or a small clear biohazard bag prevents cyst contents from spraying and reduces risk for contamination. In addition to these protective benefits, the use of readily available items replaces the need to order a splatter control shield.

Limitations—Although we seldom see spray using our technique, covering the cyst with gauze may disguise the region of interest and interfere with accurate incision. Marking the lesion prior to anesthesia administration or using a clear biohazard bag minimizes difficulty visualizing the cyst opening.

References
  1. Zito PM, Scharf R. Epidermoid cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June 13, 2024. https://www.ncbi.nlm.nih.gov/books/NBK499974
  2. Weir CB, St. Hilaire NJ. Epidermal inclusion cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June3, 2024. https://www.ncbi.nlm.nih.gov/books/NBK532310/
  3. Kuniyuki S, Yoshida Y, Maekawa N, et al. Bacteriological study of epidermal cysts. Acta Derm Venereol. 2018;88:23-25. doi:10.2340/00015555-0348
Article PDF
CT114001011.pdf
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Bita Tristani-Firouzi is from Pomona College, Claremont, California. Elliott D. Herron is from the University of Alabama Birmingham. Dr. Hull is from the Department of Dermatology, University of Utah, Salt Lake City. Dr. Herron is from Herron Dermatology and Laser, Montgomery, Alabama.

The authors report no conflict of interest.

Correspondence: Mark D. Herron, MD, Herron Dermatology and Laser, 7260 Halcyon Summit Dr, Montgomery, AL 36117 ([email protected]).

Cutis. 2024 July;114(1):11, 26. doi:10.12788/cutis.1047

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Mark D. Herron, MD
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Elliott D. Herron, BS
Christopher M. Hull, MD
Mark D. Herron, MD
Author and Disclosure Information

 

Bita Tristani-Firouzi is from Pomona College, Claremont, California. Elliott D. Herron is from the University of Alabama Birmingham. Dr. Hull is from the Department of Dermatology, University of Utah, Salt Lake City. Dr. Herron is from Herron Dermatology and Laser, Montgomery, Alabama.

The authors report no conflict of interest.

Correspondence: Mark D. Herron, MD, Herron Dermatology and Laser, 7260 Halcyon Summit Dr, Montgomery, AL 36117 ([email protected]).

Cutis. 2024 July;114(1):11, 26. doi:10.12788/cutis.1047

Author and Disclosure Information

 

Bita Tristani-Firouzi is from Pomona College, Claremont, California. Elliott D. Herron is from the University of Alabama Birmingham. Dr. Hull is from the Department of Dermatology, University of Utah, Salt Lake City. Dr. Herron is from Herron Dermatology and Laser, Montgomery, Alabama.

The authors report no conflict of interest.

Correspondence: Mark D. Herron, MD, Herron Dermatology and Laser, 7260 Halcyon Summit Dr, Montgomery, AL 36117 ([email protected]).

Cutis. 2024 July;114(1):11, 26. doi:10.12788/cutis.1047

Article PDF
CT114001011.pdf
Article PDF
CT114001011.pdf

Practice Gap

Epidermoid cysts are asymptomatic, well-circumscribed, mobile, subcutaneous masses that elevate the skin. Also known as epidermal, keratin, or infundibular cysts, epidermoid cysts are caused by proliferation of surface epidermoid cells within the dermis and can arise anywhere on the body, most commonly on the face, neck, and trunk.1 Cutaneous cysts often contain fluid or semifluid contents and can be aesthetically displeasing or cause mild pain, prompting patients to seek removal. Definitive treatment of epidermoid cysts is complete surgical removal,2 which can be performed in office in a sterile or clean manner by either dermatologists or primary care providers.

Prior to incision, a local anesthetic—commonly lidocaine with epinephrine—is injected in the region surrounding the cyst sac so as not to rupture the cyst wall. Maintaining the cyst wall throughout the procedure ensures total cyst removal and minimizes the risk for recurrence. However, it often is difficult to approximate the cyst border because it cannot be visualized prior to incision.

Throughout the duration of the procedure, cyst contents may suddenly spray out of the area and pose a risk to providers and their staff (Figure, A). Even with careful application around the periphery, either puncture or ­pericystic anesthesia between the cyst wall and the dermis can lead to splatter. Larger and wider peripheral anesthesia may not be possible given a shortage of ­lidocaine and a desire to minimize injection. Even with meticulous use of personal protective equipment in cutaneous surgery, infectious organisms found in ruptured cysts and abscesses may spray the surgical field.3 Therefore, it is in our best interest to minimize the trajectory of cyst spray contents.

The Tools

We have employed 2 simple techniques using equipment normally found on a standard surgical tray for easy safe injection of cysts. Supplies needed include 4×4-inch gauze pads, alcohol and chlorhexidine, a marker, all instruments necessary for cyst excision, and a small clear biohazard bag.

The Technique

Prior to covering the cyst, care is taken to locate the cyst opening. At times, a comedo or punctum can be seen overlying the cyst bulge. We mark the lumen and cyst opening with a surgical marker. If the pore is not easily identified, we draw an 8-mm circle around the mound of the cyst. 

One option is to apply a gauze pad over the cyst to allow for stabilization of the surgical field and blanket the area from splatter (Figure, B). Then we cover the cyst using antiseptic-soaked gauze as a protective barrier to avoid potentially contaminated spray. This tool can be constructed from a 4×4-inch gauze pad with the addition of alcohol and chlorhexidine. When the cyst is covered, the surgeon can inject the lesion and surrounding tissue without biohazard splatter.

A, During surgical excision of an epidermoid cyst, contents may spray out and pose a risk to clinicians and staff. B, Application of an antisepticsoaked gauze pad over the cyst allows for stabilization of the surgical field and blankets the area from splatter. C, Alternatively, the cyst can be covered with a small clear biohazard bag to catch any spraying contents while allowing visualization of the surgical field.

Another method is to cover the cyst with a small clear biohazard bag (Figure, C). When injecting anesthetic through the bag, the spray is captured by the bag and does not reach the surgeon or staff. This method is potentially more effective given that the cyst can still be visualized fully for more accurate injection.

Practice Implications

Outpatient surgical excision is a common effective procedure for epidermoid cysts. However, it is not uncommon for cyst contents to spray during the injection of anesthetic, posing a nuisance to the surgeon, health care staff, and patient. The technique of covering the lesion with antiseptic-soaked gauze or a small clear biohazard bag prevents cyst contents from spraying and reduces risk for contamination. In addition to these protective benefits, the use of readily available items replaces the need to order a splatter control shield.

Limitations—Although we seldom see spray using our technique, covering the cyst with gauze may disguise the region of interest and interfere with accurate incision. Marking the lesion prior to anesthesia administration or using a clear biohazard bag minimizes difficulty visualizing the cyst opening.

Practice Gap

Epidermoid cysts are asymptomatic, well-circumscribed, mobile, subcutaneous masses that elevate the skin. Also known as epidermal, keratin, or infundibular cysts, epidermoid cysts are caused by proliferation of surface epidermoid cells within the dermis and can arise anywhere on the body, most commonly on the face, neck, and trunk.1 Cutaneous cysts often contain fluid or semifluid contents and can be aesthetically displeasing or cause mild pain, prompting patients to seek removal. Definitive treatment of epidermoid cysts is complete surgical removal,2 which can be performed in office in a sterile or clean manner by either dermatologists or primary care providers.

Prior to incision, a local anesthetic—commonly lidocaine with epinephrine—is injected in the region surrounding the cyst sac so as not to rupture the cyst wall. Maintaining the cyst wall throughout the procedure ensures total cyst removal and minimizes the risk for recurrence. However, it often is difficult to approximate the cyst border because it cannot be visualized prior to incision.

Throughout the duration of the procedure, cyst contents may suddenly spray out of the area and pose a risk to providers and their staff (Figure, A). Even with careful application around the periphery, either puncture or ­pericystic anesthesia between the cyst wall and the dermis can lead to splatter. Larger and wider peripheral anesthesia may not be possible given a shortage of ­lidocaine and a desire to minimize injection. Even with meticulous use of personal protective equipment in cutaneous surgery, infectious organisms found in ruptured cysts and abscesses may spray the surgical field.3 Therefore, it is in our best interest to minimize the trajectory of cyst spray contents.

The Tools

We have employed 2 simple techniques using equipment normally found on a standard surgical tray for easy safe injection of cysts. Supplies needed include 4×4-inch gauze pads, alcohol and chlorhexidine, a marker, all instruments necessary for cyst excision, and a small clear biohazard bag.

The Technique

Prior to covering the cyst, care is taken to locate the cyst opening. At times, a comedo or punctum can be seen overlying the cyst bulge. We mark the lumen and cyst opening with a surgical marker. If the pore is not easily identified, we draw an 8-mm circle around the mound of the cyst. 

One option is to apply a gauze pad over the cyst to allow for stabilization of the surgical field and blanket the area from splatter (Figure, B). Then we cover the cyst using antiseptic-soaked gauze as a protective barrier to avoid potentially contaminated spray. This tool can be constructed from a 4×4-inch gauze pad with the addition of alcohol and chlorhexidine. When the cyst is covered, the surgeon can inject the lesion and surrounding tissue without biohazard splatter.

A, During surgical excision of an epidermoid cyst, contents may spray out and pose a risk to clinicians and staff. B, Application of an antisepticsoaked gauze pad over the cyst allows for stabilization of the surgical field and blankets the area from splatter. C, Alternatively, the cyst can be covered with a small clear biohazard bag to catch any spraying contents while allowing visualization of the surgical field.

Another method is to cover the cyst with a small clear biohazard bag (Figure, C). When injecting anesthetic through the bag, the spray is captured by the bag and does not reach the surgeon or staff. This method is potentially more effective given that the cyst can still be visualized fully for more accurate injection.

Practice Implications

Outpatient surgical excision is a common effective procedure for epidermoid cysts. However, it is not uncommon for cyst contents to spray during the injection of anesthetic, posing a nuisance to the surgeon, health care staff, and patient. The technique of covering the lesion with antiseptic-soaked gauze or a small clear biohazard bag prevents cyst contents from spraying and reduces risk for contamination. In addition to these protective benefits, the use of readily available items replaces the need to order a splatter control shield.

Limitations—Although we seldom see spray using our technique, covering the cyst with gauze may disguise the region of interest and interfere with accurate incision. Marking the lesion prior to anesthesia administration or using a clear biohazard bag minimizes difficulty visualizing the cyst opening.

References
  1. Zito PM, Scharf R. Epidermoid cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June 13, 2024. https://www.ncbi.nlm.nih.gov/books/NBK499974
  2. Weir CB, St. Hilaire NJ. Epidermal inclusion cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June3, 2024. https://www.ncbi.nlm.nih.gov/books/NBK532310/
  3. Kuniyuki S, Yoshida Y, Maekawa N, et al. Bacteriological study of epidermal cysts. Acta Derm Venereol. 2018;88:23-25. doi:10.2340/00015555-0348
References
  1. Zito PM, Scharf R. Epidermoid cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June 13, 2024. https://www.ncbi.nlm.nih.gov/books/NBK499974
  2. Weir CB, St. Hilaire NJ. Epidermal inclusion cyst. StatPearls [Internet]. Updated August 8, 2023. Accessed June3, 2024. https://www.ncbi.nlm.nih.gov/books/NBK532310/
  3. Kuniyuki S, Yoshida Y, Maekawa N, et al. Bacteriological study of epidermal cysts. Acta Derm Venereol. 2018;88:23-25. doi:10.2340/00015555-0348
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Vascular Mass on the Posterior Neck in a Newborn

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Vascular Mass on the Posterior Neck in a Newborn
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Roksana Hesari, DO
Mandy Alhajj, DO
Howard D. Wang, MD
Sonal D. Shah, MD

The Diagnosis: Congenital Hemangioma

Surgical resection of the mass was performed at 4 months of age without complication (Figure 1). Histopathology revealed a lobular endothelial cell proliferation within a densely fibrotic stroma, multiple thin-walled vessels, and negative immunoreactivity to glucose transporter type 1 (GLUT-1)(Figures 2 and 3). Combined with the patient’s clinical history and findings on imaging (Figure 4), the most accurate diagnosis was a congenital hemangioma (CH). The mass was determined to be a noninvoluting congenital hemangioma (NICH).

A variety of vascular anomalies manifest in newborns and can be differentiated by the patient’s clinical history—particularly whether the lesion is present at birth or develops after birth. Imaging and histopathology of the lesion(s) may be utilized when clinical examination alone is not sufficient to make a diagnosis. Histopathology and immunohistochemistry further aid in differentiating the type of vascular lesion.

FIGURE 1. A congenital hemangioma in a newborn was surgically resected without complication.

FIGURE 2. Histopathology of a congenital hemangioma revealed a lobular endothelial cell proliferation within a densely fibrotic stroma as well as multiple thin-walled vessels (H&E, original magnification ×200).

Overall, vascular anomalies are classified broadly into 2 categories based on their pathogenesis: tumors and malformations. Vascular tumors are composed of proliferating endothelial cells that have the potential to resolve spontaneously over time. Examples include CH, infantile hemangioma (IH), kaposiform hemangioendothelioma (KHE), and tufted angioma (TA). In contrast, vascular malformations (ie, arteriovenous malformations) are composed of dysplastic vessels with normal endothelial cell turnover and do not resolve without intervention.1

Congenital hemangiomas are rare vascular tumors that are fully developed at birth. These tumors proliferate in utero, enabling prenatal detection via ultrasonography as early as 12 weeks’ gestation for large heterogeneous vascular masses.2-4 Congenital hemangiomas are described as solitary, well-circumscribed, raised, violaceous lesions most commonly located in the head and neck region.4-6 Histopathologically, they are characterized by lobules of proliferating capillaries surrounded by fibrous stroma and dysplastic vascular channels.6,7

Congenital hemangiomas are categorized based on their postnatal involution patterns.2 Fetally involuting CH both develops and begins regression in utero and often is completely regressed at birth.8 Rapidly involuting CH begins regression in the first few weeks of life and usually is completely involuted by 14 months of age.6,9-11 Conversely, NICH does not regress, often requiring surgical excision due to functional and cosmetic issues.12,13 Partially involuting CH is intermediary, beginning as rapidly involuting but not involuting completely and persisting as lesions that resemble NICH.14-16 Although generally benign and asymptomatic, these tumors can cause transient thrombocytopenia and coagulopathy at birth, as seen in our patient.17,18

FIGURE 3. Immunohistochemistry of a congenital hemangioma demonstrated negative immunoreactivity to glucose transporter type 1 (GLUT-1).

FIGURE 4. Magnetic resonance imaging of a congenital hemangioma demonstrated a well-circumscribed mass with avid arterial phase enhancement.

Infantile hemangioma is the most common vascular tumor of infancy.19-21 Although a precursor lesion may be present at birth, generally this tumor becomes apparent after the first few weeks of life as a solitary vascular plaque or nodule with a predilection for the head and neck.22-25 Once it arises, IH quickly enters a period of rapid growth, followed by a period of slower continued growth, with most reaching maximum size by 3 months.22 Thereafter, IH enters a slow period of involution (range, 3–9 years)26; more recent data suggest near resolution by 5 years of age.27 Infantile hemangioma is categorized based on its depth in the skin and subcutaneous tissues and can be classified as superficial, mixed, or deep.22,24,28,29 Superficial IH appears as a red plaque and may exhibit lobulation, while deep IH can be identified as flesh-colored or blue subcutaneous masses. Mixed IH may manifest with both superficial and deep features depending on the extent of its involvement in the dermal and subcutaneous layers. The pattern of involvement may be focal, segmental, or indeterminate.24 In contrast, CH typically is a solitary vascular mass with prominent telangiectases, nodules, and radiating veins.6 Histologically, IH is composed of proliferative plump endothelial cells that form capillaries, and the lesion stains positively for GLUT-1, whereas CH does not.30

Kaposiform hemangioendothelioma is classified as a locally aggressive vascular tumor that manifests either prenatally or in early infancy.31 It is described as a solitary, ill-defined, firm, purple plaque most commonly located on the extremities and retroperitoneum.32-34 Histopathologically, these lesions are characterized by dilated lymphatic channels and irregular sheets or lobules of spindle-shaped endothelial cells infiltrating the dermis and subcutaneous fat.33,35 In contrast to CH, KHE lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein.36,37 Notably, 70% of these tumors are complicated by the presence of Kasabach-Merritt phenomenon, a potentially life-threatening emergency that occurs when platelets are trapped within a vascular tumor, leading to the consumption of clotting factors, intralesional bleeding, and rapid enlargement of the tumor.32 The Kasabach-Merritt phenomenon manifests clinically as microangiopathic hemolytic anemia, severe thrombocytopenia, and disseminated intravascular coagulation. 38 Although CH lesions also can be associated with thrombocytopenia and coagulopathy, they generally are mild and self-limited.18

Tufted angioma is a vascular tumor that arises within the first 5 years of life as firm violaceous papules or plaques, often with associated hyperhidrosis or hypertrichosis.39,40 Although TA grows slowly for a period of time, it eventually stabilizes and persists, rarely regressing completely.41 These tumors share many similarities with KHE, and it has been suggested that they may be part of the same spectrum. 42 As with KHE, TA lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein, which are negative in CH.36,37 Although TA also can be complicated by Kasabach-Merritt phenomenon, the incidence is much lower (up to 38%).43,44 As such, TAs tend to be recognized as more superficial benign lesions. However, they still can cause notable cosmetic and functional impairment and should be monitored closely, especially in the presence of associated symptoms or complications.

Arteriovenous malformation is a vascular lesion that results from errors during the embryonic development of vascular channels.45 Although present at birth, it may not become clinically apparent until later in life. Arteriovenous malformations enlarge postnatally, and their growth is proportional to the developmental growth of the affected individual rather than the result of endothelial proliferation.46 In infants, AVM may manifest as a faint vascular stain that can evolve over time into a pink patch associated with a palpable thrill during adolescence. 4 On Doppler flow imaging, AVMs are identified as fast-flow anomalies arising from an abnormal communication between high-pressure arterial systems and low-pressure venous systems without the presence of a capillary bed.47 One of the differentiating factors between AVM and CH is that AVMs do not regress spontaneously and tend to have high recurrence rates, even with intervention. 48 In contrast, CH can be categorized based on its postnatal involution pattern. Another distinguishing factor is that AVMs tend to be larger and more invasive than CHs.46 Therefore, early diagnosis and intervention are crucial to prevent complications such as bleeding, seizures, or neurologic deficits associated with AVMs.1

References
  1. Enjolras O, Wassef M, Chapot R. Introduction: ISSVA Classification. In: Enjolras O, Wassef M, Chapot R, eds. Color Atlas of Vascular Tumors and Vascular Malformations. Cambridge University Press; 2007:3-11.
  2. Fadell MF, Jones BV, Adams DM. Prenatal diagnosis and postnatal follow-up of rapidly involuting congenital hemangioma (RICH). Pediatr Radiol. 2011;41:1057-1060.
  3. Feygin T, Khalek N, Moldenhauer JS. Fetal brain, head, and neck tumors: prenatal imaging and management. Prenat Diagn. 2020;40:1203-1219.
  4. Foley LS, Kulungowski AM. Vascular anomalies in pediatrics. Adv Pediatr. 2015;62:227-255.
  5. Bruder E, Alaggio R, Kozakewich HPW, et al. Vascular and perivascular lesions of skin and soft tissues in children and adolescents. Pediatr Dev Pathol. 2012;15:26-61.
  6. Berenguer B, Mulliken JB, Enjolras O, et al. Rapidly involuting congenital hemangioma: clinical and histopathologic features. Pediatr Dev Pathol. 2003;6:495-510.
  7. North PE, Waner M, James CA, et al. Congenital nonprogressive hemangioma: a distinct clinicopathologic entity unlike infantile hemangioma. Arch Dermatol. 2001;137:1607-1620.
  8. Maguiness S, Uihlein LC, Liang MG, et al. Rapidly involuting congenital hemangioma with fetal involution. Pediatr Dermatol. 2015;32:321-326.
  9. Keating LJ, Soares GM, Muratore CS. Rapidly involuting congenital hemangioma. Med Health R I. 2012;95:149-152.
  10. Schafer F, Tapia M, Pinto C. Rapidly involuting congenital haemangioma. Arch Dis Child Fetal Neonatal Ed. 2014;99:F422.
  11. Boon LM, Enjolras O, Mulliken JB. Congenital hemangioma: evidence of accelerated involution. J Pediatr. 1996;128:329-335.
  12. Liang MG, Frieden IJ. Infantile and congenital hemangiomas. Semin Pediatr Surg. 2014;23:162-167.
  13. Enjolras O, Mulliken JB, Boon LM, et al. Noninvoluting congenital hemangioma: a rare cutaneous vascular anomaly. Plast Reconstr Surg. 2001;107:1647-1654.
  14. Nasseri E, Piram M, McCuaig CC, et al. Partially involuting congenital hemangiomas: a report of 8 cases and review of the literature. J Am Acad Dermatol. 2014;70:75-79.
  15. Wassef M, Blei F, Adams D, et al. Vascular anomalies classification: recommendations from the International Society for the Study of Vascular Anomalies. Pediatrics. 2015;136:E203-E214.
  16. Boull C, Maguiness SM. Congenital hemangiomas. Semin Cutan Med Surg. 2016;35:124-127.
  17. Drolet BA, Frommelt PC, Chamlin SL, et al. Initiation and use of propranolol for infantile hemangioma: report of a consensus conference. Pediatrics. 2013;131:128-140.
  18. Baselga E, Cordisco MR, Garzon M, et al. Rapidly involuting congenital haemangioma associated with transient thrombocytopenia and coagulopathy: a case series. Br J Dermatol. 2008;158:1363-1370.
  19. Kanada KN, Merin MR, Munden A, et al. A prospective study of cutaneous findings in newborns in the United States: correlation with race, ethnicity, and gestational status using updated classification and nomenclature. J Pediatr. 2012;161:240-245.
  20. Munden A, Butschek R, Tom WL, et al. Prospective study of infantile haemangiomas: incidence, clinical characteristics and association with placental anomalies. Br J Dermatol. 2014;170:907-913.
  21. Léauté-Labrèze C, Harper JI, Hoeger PH. Infantile haemangioma. Lancet. 2017;390:85-94.
  22. Chang LC, Haggstrom AN, Drolet BA, et al. Growth characteristics of infantile hemangiomas: implications for management. Pediatrics. 2008;122:360-367.
  23. Hidano A, Nakajima S. Earliest features of the strawberry mark in the newborn. Br J Dermatol. 1972;87:138-144.
  24. Martinez-Perez D, Fein NA, Boon LM, et al. Not all hemangiomas look like strawberries: uncommon presentations of the most common tumor of infancy. Pediatr Dermatol. 1995;12:1-6.
  25. Payne MM, Moyer F, Marcks KM, et al. The precursor to the hemangioma. Plast Reconstr Surg. 1966;38:64-67.
  26. Bowers RE, Graham EA, Tomlinson KM. The natural history of the strawberry nevus. Arch Dermatol. 1960;82:667-680.
  27. Couto RA, Maclellan RA, Zurakowski D, et al. Infantile hemangioma: clinical assessment of the involuting phase and implications for management. Plast Reconstr Surg. 2012;130:619-624.
  28. Drolet BA, Esterly NB, Frieden IJ. Hemangiomas in children. N Engl J Med. 1999;341:173-181.
  29. Chiller KG, Passaro D, Frieden IJ. Hemangiomas of infancy: clinical characteristics, morphologic subtypes, and their relationship to race, ethnicity, and sex. Arch Dermatol. 2002;138:1567-1576.
  30. North PE, Waner M, Mizeracki A, et al. GLUT1: a newly discovered immunohistochemical marker for juvenile hemangiomas. Hum Pathol. 2000;31:11-22.
  31. Gruman A, Liang MG, Mulliken JB, et al. Kaposiform hemangioendothelioma without Kasabach-Merritt phenomenon. J Am Acad Dermatol. 2005;52:616-622.
  32. Croteau SE, Liang MG, Kozakewich HP, et al. Kaposiform hemangioendothelioma: atypical features and risks of Kasabach- Merritt phenomenon in 107 referrals. J Pediatr. 2013;162:142-147.
  33. Zukerberg LR, Nickoloff BJ, Weiss SW. Kaposiform hemangioendothelioma of infancy and childhood. an aggressive neoplasm associated with Kasabach-Merritt syndrome and lymphangiomatosis. Am J Surg Pathol. 1993;17:321-328.
  34. Mac-Moune Lai F, To KF, Choi PC, et al. Kaposiform hemangioendothelioma: five patients with cutaneous lesion and long follow-up. Mod Pathol. 2001;14:1087-1092.
  35. O’Rafferty C, O’Regan GM, Irvine AD, et al. Recent advances in the pathobiology and management of Kasabach-Merritt phenomenon. Br J Haematol. 2015;171:38-51.
  36. Le Huu AR, Jokinen CH, Rubin BP, et al. Expression of prox1, lymphatic endothelial nuclear transcription factor, in kaposiform hemangioendothelioma and tufted angioma. Am J Surg Pathol. 2010;34:1563-1573.
  37. Debelenko LV, Perez-Atayde AR, Mulliken JB, et al. D2-40 immuno-histochemical analysis of pediatric vascular tumors reveals positivity in kaposiform hemangioendothelioma. Mod Pathol. 2005;18:1454-1460.
  38. Haisley-Royster C, Enjolras O, Frieden IJ, et al. Kasabach-Merritt phenomenon: a retrospective study of treatment with vincristine. J Pediatr Hematol Oncol. 2002;24:459-462.
  39. Wilmer A, Kaatz M, Bocker T, et al. Tufted angioma. Eur J Dermatol. 1999;9:51-53.
  40. Herron MD, Coffin CM, Vanderhooft SL. Tufted angiomas: variability of the clinical morphology. Pediatr Dermatol. 2002;19:394-401.
  41. North PE. Pediatric vascular tumors and malformations. Surg Pathol Clin. 2010,3:455-494.
  42. Chu CY, Hsiao CH, Chiu HC. Transformation between kaposiform hemangioendothelioma and tufted angioma. Dermatology. 2003;206:334-337.
  43. Osio A, Fraitag S, Hadj-Rabia S, et al. Clinical spectrum of tufted angiomas in childhood: a report of 13 cases and a review of the literature. Arch Dermatol. 2010;146:758-763.
  44. Johnson EF, Davis DM, Tollefson MM, et al. Vascular tumors in infants: case report and review of clinical, histopathologic, and immunohistochemical characteristics of infantile hemangioma, pyogenic granuloma, noninvoluting congenital hemangioma, tufted angioma, and kaposiform hemangioendothelioma. Am J Dermatopathol. 2018;40:231-239.
  45. Christison-Lagay ER, Fishman SJ. Vascular anomalies. Surg Clin North Am. 2006;86:393-425.
  46. Liu AS, Mulliken JB, Zurakowski D, et al. Extracranial arteriovenous malformations: natural progression and recurrence after treatment. Plast Reconstr Surg. 2010;125:1185-1194.
  47. Young AE, Mulliken JB. Arteriovenous malformations. In: Mulliken JB, Young AE, eds. Vascular Birthmarks: Haemangiomas and Malformations. WB Saunders; 1988:228-245.
  48. Duggan EM, Fishman SJ. Vascular anomalies. In: Holcomb GW III, Murphy JP, St Peter SD, eds. Holcomb and Ashcraft’s Pediatric Surgery. 7th edition. Elsevier; 2019:1147-1170.
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Dr. Hesari is from the Lake Erie College of Osteopathic Medicine, Bradenton, Florida. Dr. Alhajj is from the Department of Dermatology, University Hospitals Cleveland Medical Center, Ohio. Drs. Wang and Shah are from Rainbow Babies & Children’s Hospital, University Hospitals Cleveland Medical Center. Dr. Wang is from the Department of Pediatric Plastic Surgery and Dr. Shah is from the Department of Pediatric Dermatology.

Drs. Hesari, Alhajj, and Wang report no conflicts of interest. Dr. Shah has received royalties income from UpToDate.

Correspondence: Mandy Alhajj, DO, University Hospitals Cleveland Medical Center, Department of Dermatology, 11100 Euclid Ave, Cleveland, OH 44106 ([email protected]).

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Author(s)
Roksana Hesari, DO
Mandy Alhajj, DO
Howard D. Wang, MD
Sonal D. Shah, MD
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Mandy Alhajj, DO
Howard D. Wang, MD
Sonal D. Shah, MD
Author and Disclosure Information

Dr. Hesari is from the Lake Erie College of Osteopathic Medicine, Bradenton, Florida. Dr. Alhajj is from the Department of Dermatology, University Hospitals Cleveland Medical Center, Ohio. Drs. Wang and Shah are from Rainbow Babies & Children’s Hospital, University Hospitals Cleveland Medical Center. Dr. Wang is from the Department of Pediatric Plastic Surgery and Dr. Shah is from the Department of Pediatric Dermatology.

Drs. Hesari, Alhajj, and Wang report no conflicts of interest. Dr. Shah has received royalties income from UpToDate.

Correspondence: Mandy Alhajj, DO, University Hospitals Cleveland Medical Center, Department of Dermatology, 11100 Euclid Ave, Cleveland, OH 44106 ([email protected]).

Author and Disclosure Information

Dr. Hesari is from the Lake Erie College of Osteopathic Medicine, Bradenton, Florida. Dr. Alhajj is from the Department of Dermatology, University Hospitals Cleveland Medical Center, Ohio. Drs. Wang and Shah are from Rainbow Babies & Children’s Hospital, University Hospitals Cleveland Medical Center. Dr. Wang is from the Department of Pediatric Plastic Surgery and Dr. Shah is from the Department of Pediatric Dermatology.

Drs. Hesari, Alhajj, and Wang report no conflicts of interest. Dr. Shah has received royalties income from UpToDate.

Correspondence: Mandy Alhajj, DO, University Hospitals Cleveland Medical Center, Department of Dermatology, 11100 Euclid Ave, Cleveland, OH 44106 ([email protected]).

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CT114001015.pdf
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The Diagnosis: Congenital Hemangioma

Surgical resection of the mass was performed at 4 months of age without complication (Figure 1). Histopathology revealed a lobular endothelial cell proliferation within a densely fibrotic stroma, multiple thin-walled vessels, and negative immunoreactivity to glucose transporter type 1 (GLUT-1)(Figures 2 and 3). Combined with the patient’s clinical history and findings on imaging (Figure 4), the most accurate diagnosis was a congenital hemangioma (CH). The mass was determined to be a noninvoluting congenital hemangioma (NICH).

A variety of vascular anomalies manifest in newborns and can be differentiated by the patient’s clinical history—particularly whether the lesion is present at birth or develops after birth. Imaging and histopathology of the lesion(s) may be utilized when clinical examination alone is not sufficient to make a diagnosis. Histopathology and immunohistochemistry further aid in differentiating the type of vascular lesion.

FIGURE 1. A congenital hemangioma in a newborn was surgically resected without complication.

FIGURE 2. Histopathology of a congenital hemangioma revealed a lobular endothelial cell proliferation within a densely fibrotic stroma as well as multiple thin-walled vessels (H&E, original magnification ×200).

Overall, vascular anomalies are classified broadly into 2 categories based on their pathogenesis: tumors and malformations. Vascular tumors are composed of proliferating endothelial cells that have the potential to resolve spontaneously over time. Examples include CH, infantile hemangioma (IH), kaposiform hemangioendothelioma (KHE), and tufted angioma (TA). In contrast, vascular malformations (ie, arteriovenous malformations) are composed of dysplastic vessels with normal endothelial cell turnover and do not resolve without intervention.1

Congenital hemangiomas are rare vascular tumors that are fully developed at birth. These tumors proliferate in utero, enabling prenatal detection via ultrasonography as early as 12 weeks’ gestation for large heterogeneous vascular masses.2-4 Congenital hemangiomas are described as solitary, well-circumscribed, raised, violaceous lesions most commonly located in the head and neck region.4-6 Histopathologically, they are characterized by lobules of proliferating capillaries surrounded by fibrous stroma and dysplastic vascular channels.6,7

Congenital hemangiomas are categorized based on their postnatal involution patterns.2 Fetally involuting CH both develops and begins regression in utero and often is completely regressed at birth.8 Rapidly involuting CH begins regression in the first few weeks of life and usually is completely involuted by 14 months of age.6,9-11 Conversely, NICH does not regress, often requiring surgical excision due to functional and cosmetic issues.12,13 Partially involuting CH is intermediary, beginning as rapidly involuting but not involuting completely and persisting as lesions that resemble NICH.14-16 Although generally benign and asymptomatic, these tumors can cause transient thrombocytopenia and coagulopathy at birth, as seen in our patient.17,18

FIGURE 3. Immunohistochemistry of a congenital hemangioma demonstrated negative immunoreactivity to glucose transporter type 1 (GLUT-1).

FIGURE 4. Magnetic resonance imaging of a congenital hemangioma demonstrated a well-circumscribed mass with avid arterial phase enhancement.

Infantile hemangioma is the most common vascular tumor of infancy.19-21 Although a precursor lesion may be present at birth, generally this tumor becomes apparent after the first few weeks of life as a solitary vascular plaque or nodule with a predilection for the head and neck.22-25 Once it arises, IH quickly enters a period of rapid growth, followed by a period of slower continued growth, with most reaching maximum size by 3 months.22 Thereafter, IH enters a slow period of involution (range, 3–9 years)26; more recent data suggest near resolution by 5 years of age.27 Infantile hemangioma is categorized based on its depth in the skin and subcutaneous tissues and can be classified as superficial, mixed, or deep.22,24,28,29 Superficial IH appears as a red plaque and may exhibit lobulation, while deep IH can be identified as flesh-colored or blue subcutaneous masses. Mixed IH may manifest with both superficial and deep features depending on the extent of its involvement in the dermal and subcutaneous layers. The pattern of involvement may be focal, segmental, or indeterminate.24 In contrast, CH typically is a solitary vascular mass with prominent telangiectases, nodules, and radiating veins.6 Histologically, IH is composed of proliferative plump endothelial cells that form capillaries, and the lesion stains positively for GLUT-1, whereas CH does not.30

Kaposiform hemangioendothelioma is classified as a locally aggressive vascular tumor that manifests either prenatally or in early infancy.31 It is described as a solitary, ill-defined, firm, purple plaque most commonly located on the extremities and retroperitoneum.32-34 Histopathologically, these lesions are characterized by dilated lymphatic channels and irregular sheets or lobules of spindle-shaped endothelial cells infiltrating the dermis and subcutaneous fat.33,35 In contrast to CH, KHE lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein.36,37 Notably, 70% of these tumors are complicated by the presence of Kasabach-Merritt phenomenon, a potentially life-threatening emergency that occurs when platelets are trapped within a vascular tumor, leading to the consumption of clotting factors, intralesional bleeding, and rapid enlargement of the tumor.32 The Kasabach-Merritt phenomenon manifests clinically as microangiopathic hemolytic anemia, severe thrombocytopenia, and disseminated intravascular coagulation. 38 Although CH lesions also can be associated with thrombocytopenia and coagulopathy, they generally are mild and self-limited.18

Tufted angioma is a vascular tumor that arises within the first 5 years of life as firm violaceous papules or plaques, often with associated hyperhidrosis or hypertrichosis.39,40 Although TA grows slowly for a period of time, it eventually stabilizes and persists, rarely regressing completely.41 These tumors share many similarities with KHE, and it has been suggested that they may be part of the same spectrum. 42 As with KHE, TA lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein, which are negative in CH.36,37 Although TA also can be complicated by Kasabach-Merritt phenomenon, the incidence is much lower (up to 38%).43,44 As such, TAs tend to be recognized as more superficial benign lesions. However, they still can cause notable cosmetic and functional impairment and should be monitored closely, especially in the presence of associated symptoms or complications.

Arteriovenous malformation is a vascular lesion that results from errors during the embryonic development of vascular channels.45 Although present at birth, it may not become clinically apparent until later in life. Arteriovenous malformations enlarge postnatally, and their growth is proportional to the developmental growth of the affected individual rather than the result of endothelial proliferation.46 In infants, AVM may manifest as a faint vascular stain that can evolve over time into a pink patch associated with a palpable thrill during adolescence. 4 On Doppler flow imaging, AVMs are identified as fast-flow anomalies arising from an abnormal communication between high-pressure arterial systems and low-pressure venous systems without the presence of a capillary bed.47 One of the differentiating factors between AVM and CH is that AVMs do not regress spontaneously and tend to have high recurrence rates, even with intervention. 48 In contrast, CH can be categorized based on its postnatal involution pattern. Another distinguishing factor is that AVMs tend to be larger and more invasive than CHs.46 Therefore, early diagnosis and intervention are crucial to prevent complications such as bleeding, seizures, or neurologic deficits associated with AVMs.1

The Diagnosis: Congenital Hemangioma

Surgical resection of the mass was performed at 4 months of age without complication (Figure 1). Histopathology revealed a lobular endothelial cell proliferation within a densely fibrotic stroma, multiple thin-walled vessels, and negative immunoreactivity to glucose transporter type 1 (GLUT-1)(Figures 2 and 3). Combined with the patient’s clinical history and findings on imaging (Figure 4), the most accurate diagnosis was a congenital hemangioma (CH). The mass was determined to be a noninvoluting congenital hemangioma (NICH).

A variety of vascular anomalies manifest in newborns and can be differentiated by the patient’s clinical history—particularly whether the lesion is present at birth or develops after birth. Imaging and histopathology of the lesion(s) may be utilized when clinical examination alone is not sufficient to make a diagnosis. Histopathology and immunohistochemistry further aid in differentiating the type of vascular lesion.

FIGURE 1. A congenital hemangioma in a newborn was surgically resected without complication.

FIGURE 2. Histopathology of a congenital hemangioma revealed a lobular endothelial cell proliferation within a densely fibrotic stroma as well as multiple thin-walled vessels (H&E, original magnification ×200).

Overall, vascular anomalies are classified broadly into 2 categories based on their pathogenesis: tumors and malformations. Vascular tumors are composed of proliferating endothelial cells that have the potential to resolve spontaneously over time. Examples include CH, infantile hemangioma (IH), kaposiform hemangioendothelioma (KHE), and tufted angioma (TA). In contrast, vascular malformations (ie, arteriovenous malformations) are composed of dysplastic vessels with normal endothelial cell turnover and do not resolve without intervention.1

Congenital hemangiomas are rare vascular tumors that are fully developed at birth. These tumors proliferate in utero, enabling prenatal detection via ultrasonography as early as 12 weeks’ gestation for large heterogeneous vascular masses.2-4 Congenital hemangiomas are described as solitary, well-circumscribed, raised, violaceous lesions most commonly located in the head and neck region.4-6 Histopathologically, they are characterized by lobules of proliferating capillaries surrounded by fibrous stroma and dysplastic vascular channels.6,7

Congenital hemangiomas are categorized based on their postnatal involution patterns.2 Fetally involuting CH both develops and begins regression in utero and often is completely regressed at birth.8 Rapidly involuting CH begins regression in the first few weeks of life and usually is completely involuted by 14 months of age.6,9-11 Conversely, NICH does not regress, often requiring surgical excision due to functional and cosmetic issues.12,13 Partially involuting CH is intermediary, beginning as rapidly involuting but not involuting completely and persisting as lesions that resemble NICH.14-16 Although generally benign and asymptomatic, these tumors can cause transient thrombocytopenia and coagulopathy at birth, as seen in our patient.17,18

FIGURE 3. Immunohistochemistry of a congenital hemangioma demonstrated negative immunoreactivity to glucose transporter type 1 (GLUT-1).

FIGURE 4. Magnetic resonance imaging of a congenital hemangioma demonstrated a well-circumscribed mass with avid arterial phase enhancement.

Infantile hemangioma is the most common vascular tumor of infancy.19-21 Although a precursor lesion may be present at birth, generally this tumor becomes apparent after the first few weeks of life as a solitary vascular plaque or nodule with a predilection for the head and neck.22-25 Once it arises, IH quickly enters a period of rapid growth, followed by a period of slower continued growth, with most reaching maximum size by 3 months.22 Thereafter, IH enters a slow period of involution (range, 3–9 years)26; more recent data suggest near resolution by 5 years of age.27 Infantile hemangioma is categorized based on its depth in the skin and subcutaneous tissues and can be classified as superficial, mixed, or deep.22,24,28,29 Superficial IH appears as a red plaque and may exhibit lobulation, while deep IH can be identified as flesh-colored or blue subcutaneous masses. Mixed IH may manifest with both superficial and deep features depending on the extent of its involvement in the dermal and subcutaneous layers. The pattern of involvement may be focal, segmental, or indeterminate.24 In contrast, CH typically is a solitary vascular mass with prominent telangiectases, nodules, and radiating veins.6 Histologically, IH is composed of proliferative plump endothelial cells that form capillaries, and the lesion stains positively for GLUT-1, whereas CH does not.30

Kaposiform hemangioendothelioma is classified as a locally aggressive vascular tumor that manifests either prenatally or in early infancy.31 It is described as a solitary, ill-defined, firm, purple plaque most commonly located on the extremities and retroperitoneum.32-34 Histopathologically, these lesions are characterized by dilated lymphatic channels and irregular sheets or lobules of spindle-shaped endothelial cells infiltrating the dermis and subcutaneous fat.33,35 In contrast to CH, KHE lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein.36,37 Notably, 70% of these tumors are complicated by the presence of Kasabach-Merritt phenomenon, a potentially life-threatening emergency that occurs when platelets are trapped within a vascular tumor, leading to the consumption of clotting factors, intralesional bleeding, and rapid enlargement of the tumor.32 The Kasabach-Merritt phenomenon manifests clinically as microangiopathic hemolytic anemia, severe thrombocytopenia, and disseminated intravascular coagulation. 38 Although CH lesions also can be associated with thrombocytopenia and coagulopathy, they generally are mild and self-limited.18

Tufted angioma is a vascular tumor that arises within the first 5 years of life as firm violaceous papules or plaques, often with associated hyperhidrosis or hypertrichosis.39,40 Although TA grows slowly for a period of time, it eventually stabilizes and persists, rarely regressing completely.41 These tumors share many similarities with KHE, and it has been suggested that they may be part of the same spectrum. 42 As with KHE, TA lesions show immunoreactivity to the markers podoplanin, lymphatic vessel endothelial receptor 1, and prospero homeobox 1 protein, which are negative in CH.36,37 Although TA also can be complicated by Kasabach-Merritt phenomenon, the incidence is much lower (up to 38%).43,44 As such, TAs tend to be recognized as more superficial benign lesions. However, they still can cause notable cosmetic and functional impairment and should be monitored closely, especially in the presence of associated symptoms or complications.

Arteriovenous malformation is a vascular lesion that results from errors during the embryonic development of vascular channels.45 Although present at birth, it may not become clinically apparent until later in life. Arteriovenous malformations enlarge postnatally, and their growth is proportional to the developmental growth of the affected individual rather than the result of endothelial proliferation.46 In infants, AVM may manifest as a faint vascular stain that can evolve over time into a pink patch associated with a palpable thrill during adolescence. 4 On Doppler flow imaging, AVMs are identified as fast-flow anomalies arising from an abnormal communication between high-pressure arterial systems and low-pressure venous systems without the presence of a capillary bed.47 One of the differentiating factors between AVM and CH is that AVMs do not regress spontaneously and tend to have high recurrence rates, even with intervention. 48 In contrast, CH can be categorized based on its postnatal involution pattern. Another distinguishing factor is that AVMs tend to be larger and more invasive than CHs.46 Therefore, early diagnosis and intervention are crucial to prevent complications such as bleeding, seizures, or neurologic deficits associated with AVMs.1

References
  1. Enjolras O, Wassef M, Chapot R. Introduction: ISSVA Classification. In: Enjolras O, Wassef M, Chapot R, eds. Color Atlas of Vascular Tumors and Vascular Malformations. Cambridge University Press; 2007:3-11.
  2. Fadell MF, Jones BV, Adams DM. Prenatal diagnosis and postnatal follow-up of rapidly involuting congenital hemangioma (RICH). Pediatr Radiol. 2011;41:1057-1060.
  3. Feygin T, Khalek N, Moldenhauer JS. Fetal brain, head, and neck tumors: prenatal imaging and management. Prenat Diagn. 2020;40:1203-1219.
  4. Foley LS, Kulungowski AM. Vascular anomalies in pediatrics. Adv Pediatr. 2015;62:227-255.
  5. Bruder E, Alaggio R, Kozakewich HPW, et al. Vascular and perivascular lesions of skin and soft tissues in children and adolescents. Pediatr Dev Pathol. 2012;15:26-61.
  6. Berenguer B, Mulliken JB, Enjolras O, et al. Rapidly involuting congenital hemangioma: clinical and histopathologic features. Pediatr Dev Pathol. 2003;6:495-510.
  7. North PE, Waner M, James CA, et al. Congenital nonprogressive hemangioma: a distinct clinicopathologic entity unlike infantile hemangioma. Arch Dermatol. 2001;137:1607-1620.
  8. Maguiness S, Uihlein LC, Liang MG, et al. Rapidly involuting congenital hemangioma with fetal involution. Pediatr Dermatol. 2015;32:321-326.
  9. Keating LJ, Soares GM, Muratore CS. Rapidly involuting congenital hemangioma. Med Health R I. 2012;95:149-152.
  10. Schafer F, Tapia M, Pinto C. Rapidly involuting congenital haemangioma. Arch Dis Child Fetal Neonatal Ed. 2014;99:F422.
  11. Boon LM, Enjolras O, Mulliken JB. Congenital hemangioma: evidence of accelerated involution. J Pediatr. 1996;128:329-335.
  12. Liang MG, Frieden IJ. Infantile and congenital hemangiomas. Semin Pediatr Surg. 2014;23:162-167.
  13. Enjolras O, Mulliken JB, Boon LM, et al. Noninvoluting congenital hemangioma: a rare cutaneous vascular anomaly. Plast Reconstr Surg. 2001;107:1647-1654.
  14. Nasseri E, Piram M, McCuaig CC, et al. Partially involuting congenital hemangiomas: a report of 8 cases and review of the literature. J Am Acad Dermatol. 2014;70:75-79.
  15. Wassef M, Blei F, Adams D, et al. Vascular anomalies classification: recommendations from the International Society for the Study of Vascular Anomalies. Pediatrics. 2015;136:E203-E214.
  16. Boull C, Maguiness SM. Congenital hemangiomas. Semin Cutan Med Surg. 2016;35:124-127.
  17. Drolet BA, Frommelt PC, Chamlin SL, et al. Initiation and use of propranolol for infantile hemangioma: report of a consensus conference. Pediatrics. 2013;131:128-140.
  18. Baselga E, Cordisco MR, Garzon M, et al. Rapidly involuting congenital haemangioma associated with transient thrombocytopenia and coagulopathy: a case series. Br J Dermatol. 2008;158:1363-1370.
  19. Kanada KN, Merin MR, Munden A, et al. A prospective study of cutaneous findings in newborns in the United States: correlation with race, ethnicity, and gestational status using updated classification and nomenclature. J Pediatr. 2012;161:240-245.
  20. Munden A, Butschek R, Tom WL, et al. Prospective study of infantile haemangiomas: incidence, clinical characteristics and association with placental anomalies. Br J Dermatol. 2014;170:907-913.
  21. Léauté-Labrèze C, Harper JI, Hoeger PH. Infantile haemangioma. Lancet. 2017;390:85-94.
  22. Chang LC, Haggstrom AN, Drolet BA, et al. Growth characteristics of infantile hemangiomas: implications for management. Pediatrics. 2008;122:360-367.
  23. Hidano A, Nakajima S. Earliest features of the strawberry mark in the newborn. Br J Dermatol. 1972;87:138-144.
  24. Martinez-Perez D, Fein NA, Boon LM, et al. Not all hemangiomas look like strawberries: uncommon presentations of the most common tumor of infancy. Pediatr Dermatol. 1995;12:1-6.
  25. Payne MM, Moyer F, Marcks KM, et al. The precursor to the hemangioma. Plast Reconstr Surg. 1966;38:64-67.
  26. Bowers RE, Graham EA, Tomlinson KM. The natural history of the strawberry nevus. Arch Dermatol. 1960;82:667-680.
  27. Couto RA, Maclellan RA, Zurakowski D, et al. Infantile hemangioma: clinical assessment of the involuting phase and implications for management. Plast Reconstr Surg. 2012;130:619-624.
  28. Drolet BA, Esterly NB, Frieden IJ. Hemangiomas in children. N Engl J Med. 1999;341:173-181.
  29. Chiller KG, Passaro D, Frieden IJ. Hemangiomas of infancy: clinical characteristics, morphologic subtypes, and their relationship to race, ethnicity, and sex. Arch Dermatol. 2002;138:1567-1576.
  30. North PE, Waner M, Mizeracki A, et al. GLUT1: a newly discovered immunohistochemical marker for juvenile hemangiomas. Hum Pathol. 2000;31:11-22.
  31. Gruman A, Liang MG, Mulliken JB, et al. Kaposiform hemangioendothelioma without Kasabach-Merritt phenomenon. J Am Acad Dermatol. 2005;52:616-622.
  32. Croteau SE, Liang MG, Kozakewich HP, et al. Kaposiform hemangioendothelioma: atypical features and risks of Kasabach- Merritt phenomenon in 107 referrals. J Pediatr. 2013;162:142-147.
  33. Zukerberg LR, Nickoloff BJ, Weiss SW. Kaposiform hemangioendothelioma of infancy and childhood. an aggressive neoplasm associated with Kasabach-Merritt syndrome and lymphangiomatosis. Am J Surg Pathol. 1993;17:321-328.
  34. Mac-Moune Lai F, To KF, Choi PC, et al. Kaposiform hemangioendothelioma: five patients with cutaneous lesion and long follow-up. Mod Pathol. 2001;14:1087-1092.
  35. O’Rafferty C, O’Regan GM, Irvine AD, et al. Recent advances in the pathobiology and management of Kasabach-Merritt phenomenon. Br J Haematol. 2015;171:38-51.
  36. Le Huu AR, Jokinen CH, Rubin BP, et al. Expression of prox1, lymphatic endothelial nuclear transcription factor, in kaposiform hemangioendothelioma and tufted angioma. Am J Surg Pathol. 2010;34:1563-1573.
  37. Debelenko LV, Perez-Atayde AR, Mulliken JB, et al. D2-40 immuno-histochemical analysis of pediatric vascular tumors reveals positivity in kaposiform hemangioendothelioma. Mod Pathol. 2005;18:1454-1460.
  38. Haisley-Royster C, Enjolras O, Frieden IJ, et al. Kasabach-Merritt phenomenon: a retrospective study of treatment with vincristine. J Pediatr Hematol Oncol. 2002;24:459-462.
  39. Wilmer A, Kaatz M, Bocker T, et al. Tufted angioma. Eur J Dermatol. 1999;9:51-53.
  40. Herron MD, Coffin CM, Vanderhooft SL. Tufted angiomas: variability of the clinical morphology. Pediatr Dermatol. 2002;19:394-401.
  41. North PE. Pediatric vascular tumors and malformations. Surg Pathol Clin. 2010,3:455-494.
  42. Chu CY, Hsiao CH, Chiu HC. Transformation between kaposiform hemangioendothelioma and tufted angioma. Dermatology. 2003;206:334-337.
  43. Osio A, Fraitag S, Hadj-Rabia S, et al. Clinical spectrum of tufted angiomas in childhood: a report of 13 cases and a review of the literature. Arch Dermatol. 2010;146:758-763.
  44. Johnson EF, Davis DM, Tollefson MM, et al. Vascular tumors in infants: case report and review of clinical, histopathologic, and immunohistochemical characteristics of infantile hemangioma, pyogenic granuloma, noninvoluting congenital hemangioma, tufted angioma, and kaposiform hemangioendothelioma. Am J Dermatopathol. 2018;40:231-239.
  45. Christison-Lagay ER, Fishman SJ. Vascular anomalies. Surg Clin North Am. 2006;86:393-425.
  46. Liu AS, Mulliken JB, Zurakowski D, et al. Extracranial arteriovenous malformations: natural progression and recurrence after treatment. Plast Reconstr Surg. 2010;125:1185-1194.
  47. Young AE, Mulliken JB. Arteriovenous malformations. In: Mulliken JB, Young AE, eds. Vascular Birthmarks: Haemangiomas and Malformations. WB Saunders; 1988:228-245.
  48. Duggan EM, Fishman SJ. Vascular anomalies. In: Holcomb GW III, Murphy JP, St Peter SD, eds. Holcomb and Ashcraft’s Pediatric Surgery. 7th edition. Elsevier; 2019:1147-1170.
References
  1. Enjolras O, Wassef M, Chapot R. Introduction: ISSVA Classification. In: Enjolras O, Wassef M, Chapot R, eds. Color Atlas of Vascular Tumors and Vascular Malformations. Cambridge University Press; 2007:3-11.
  2. Fadell MF, Jones BV, Adams DM. Prenatal diagnosis and postnatal follow-up of rapidly involuting congenital hemangioma (RICH). Pediatr Radiol. 2011;41:1057-1060.
  3. Feygin T, Khalek N, Moldenhauer JS. Fetal brain, head, and neck tumors: prenatal imaging and management. Prenat Diagn. 2020;40:1203-1219.
  4. Foley LS, Kulungowski AM. Vascular anomalies in pediatrics. Adv Pediatr. 2015;62:227-255.
  5. Bruder E, Alaggio R, Kozakewich HPW, et al. Vascular and perivascular lesions of skin and soft tissues in children and adolescents. Pediatr Dev Pathol. 2012;15:26-61.
  6. Berenguer B, Mulliken JB, Enjolras O, et al. Rapidly involuting congenital hemangioma: clinical and histopathologic features. Pediatr Dev Pathol. 2003;6:495-510.
  7. North PE, Waner M, James CA, et al. Congenital nonprogressive hemangioma: a distinct clinicopathologic entity unlike infantile hemangioma. Arch Dermatol. 2001;137:1607-1620.
  8. Maguiness S, Uihlein LC, Liang MG, et al. Rapidly involuting congenital hemangioma with fetal involution. Pediatr Dermatol. 2015;32:321-326.
  9. Keating LJ, Soares GM, Muratore CS. Rapidly involuting congenital hemangioma. Med Health R I. 2012;95:149-152.
  10. Schafer F, Tapia M, Pinto C. Rapidly involuting congenital haemangioma. Arch Dis Child Fetal Neonatal Ed. 2014;99:F422.
  11. Boon LM, Enjolras O, Mulliken JB. Congenital hemangioma: evidence of accelerated involution. J Pediatr. 1996;128:329-335.
  12. Liang MG, Frieden IJ. Infantile and congenital hemangiomas. Semin Pediatr Surg. 2014;23:162-167.
  13. Enjolras O, Mulliken JB, Boon LM, et al. Noninvoluting congenital hemangioma: a rare cutaneous vascular anomaly. Plast Reconstr Surg. 2001;107:1647-1654.
  14. Nasseri E, Piram M, McCuaig CC, et al. Partially involuting congenital hemangiomas: a report of 8 cases and review of the literature. J Am Acad Dermatol. 2014;70:75-79.
  15. Wassef M, Blei F, Adams D, et al. Vascular anomalies classification: recommendations from the International Society for the Study of Vascular Anomalies. Pediatrics. 2015;136:E203-E214.
  16. Boull C, Maguiness SM. Congenital hemangiomas. Semin Cutan Med Surg. 2016;35:124-127.
  17. Drolet BA, Frommelt PC, Chamlin SL, et al. Initiation and use of propranolol for infantile hemangioma: report of a consensus conference. Pediatrics. 2013;131:128-140.
  18. Baselga E, Cordisco MR, Garzon M, et al. Rapidly involuting congenital haemangioma associated with transient thrombocytopenia and coagulopathy: a case series. Br J Dermatol. 2008;158:1363-1370.
  19. Kanada KN, Merin MR, Munden A, et al. A prospective study of cutaneous findings in newborns in the United States: correlation with race, ethnicity, and gestational status using updated classification and nomenclature. J Pediatr. 2012;161:240-245.
  20. Munden A, Butschek R, Tom WL, et al. Prospective study of infantile haemangiomas: incidence, clinical characteristics and association with placental anomalies. Br J Dermatol. 2014;170:907-913.
  21. Léauté-Labrèze C, Harper JI, Hoeger PH. Infantile haemangioma. Lancet. 2017;390:85-94.
  22. Chang LC, Haggstrom AN, Drolet BA, et al. Growth characteristics of infantile hemangiomas: implications for management. Pediatrics. 2008;122:360-367.
  23. Hidano A, Nakajima S. Earliest features of the strawberry mark in the newborn. Br J Dermatol. 1972;87:138-144.
  24. Martinez-Perez D, Fein NA, Boon LM, et al. Not all hemangiomas look like strawberries: uncommon presentations of the most common tumor of infancy. Pediatr Dermatol. 1995;12:1-6.
  25. Payne MM, Moyer F, Marcks KM, et al. The precursor to the hemangioma. Plast Reconstr Surg. 1966;38:64-67.
  26. Bowers RE, Graham EA, Tomlinson KM. The natural history of the strawberry nevus. Arch Dermatol. 1960;82:667-680.
  27. Couto RA, Maclellan RA, Zurakowski D, et al. Infantile hemangioma: clinical assessment of the involuting phase and implications for management. Plast Reconstr Surg. 2012;130:619-624.
  28. Drolet BA, Esterly NB, Frieden IJ. Hemangiomas in children. N Engl J Med. 1999;341:173-181.
  29. Chiller KG, Passaro D, Frieden IJ. Hemangiomas of infancy: clinical characteristics, morphologic subtypes, and their relationship to race, ethnicity, and sex. Arch Dermatol. 2002;138:1567-1576.
  30. North PE, Waner M, Mizeracki A, et al. GLUT1: a newly discovered immunohistochemical marker for juvenile hemangiomas. Hum Pathol. 2000;31:11-22.
  31. Gruman A, Liang MG, Mulliken JB, et al. Kaposiform hemangioendothelioma without Kasabach-Merritt phenomenon. J Am Acad Dermatol. 2005;52:616-622.
  32. Croteau SE, Liang MG, Kozakewich HP, et al. Kaposiform hemangioendothelioma: atypical features and risks of Kasabach- Merritt phenomenon in 107 referrals. J Pediatr. 2013;162:142-147.
  33. Zukerberg LR, Nickoloff BJ, Weiss SW. Kaposiform hemangioendothelioma of infancy and childhood. an aggressive neoplasm associated with Kasabach-Merritt syndrome and lymphangiomatosis. Am J Surg Pathol. 1993;17:321-328.
  34. Mac-Moune Lai F, To KF, Choi PC, et al. Kaposiform hemangioendothelioma: five patients with cutaneous lesion and long follow-up. Mod Pathol. 2001;14:1087-1092.
  35. O’Rafferty C, O’Regan GM, Irvine AD, et al. Recent advances in the pathobiology and management of Kasabach-Merritt phenomenon. Br J Haematol. 2015;171:38-51.
  36. Le Huu AR, Jokinen CH, Rubin BP, et al. Expression of prox1, lymphatic endothelial nuclear transcription factor, in kaposiform hemangioendothelioma and tufted angioma. Am J Surg Pathol. 2010;34:1563-1573.
  37. Debelenko LV, Perez-Atayde AR, Mulliken JB, et al. D2-40 immuno-histochemical analysis of pediatric vascular tumors reveals positivity in kaposiform hemangioendothelioma. Mod Pathol. 2005;18:1454-1460.
  38. Haisley-Royster C, Enjolras O, Frieden IJ, et al. Kasabach-Merritt phenomenon: a retrospective study of treatment with vincristine. J Pediatr Hematol Oncol. 2002;24:459-462.
  39. Wilmer A, Kaatz M, Bocker T, et al. Tufted angioma. Eur J Dermatol. 1999;9:51-53.
  40. Herron MD, Coffin CM, Vanderhooft SL. Tufted angiomas: variability of the clinical morphology. Pediatr Dermatol. 2002;19:394-401.
  41. North PE. Pediatric vascular tumors and malformations. Surg Pathol Clin. 2010,3:455-494.
  42. Chu CY, Hsiao CH, Chiu HC. Transformation between kaposiform hemangioendothelioma and tufted angioma. Dermatology. 2003;206:334-337.
  43. Osio A, Fraitag S, Hadj-Rabia S, et al. Clinical spectrum of tufted angiomas in childhood: a report of 13 cases and a review of the literature. Arch Dermatol. 2010;146:758-763.
  44. Johnson EF, Davis DM, Tollefson MM, et al. Vascular tumors in infants: case report and review of clinical, histopathologic, and immunohistochemical characteristics of infantile hemangioma, pyogenic granuloma, noninvoluting congenital hemangioma, tufted angioma, and kaposiform hemangioendothelioma. Am J Dermatopathol. 2018;40:231-239.
  45. Christison-Lagay ER, Fishman SJ. Vascular anomalies. Surg Clin North Am. 2006;86:393-425.
  46. Liu AS, Mulliken JB, Zurakowski D, et al. Extracranial arteriovenous malformations: natural progression and recurrence after treatment. Plast Reconstr Surg. 2010;125:1185-1194.
  47. Young AE, Mulliken JB. Arteriovenous malformations. In: Mulliken JB, Young AE, eds. Vascular Birthmarks: Haemangiomas and Malformations. WB Saunders; 1988:228-245.
  48. Duggan EM, Fishman SJ. Vascular anomalies. In: Holcomb GW III, Murphy JP, St Peter SD, eds. Holcomb and Ashcraft’s Pediatric Surgery. 7th edition. Elsevier; 2019:1147-1170.
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Vascular Mass on the Posterior Neck in a Newborn
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A newborn male was delivered via cesarean section at 38 weeks 5 days’ gestation with a large vascular mass on the posterior neck. The mass previously had been identified on a 23-week prenatal ultrasound. Physical examination by dermatology at birth revealed a well-defined violaceous mass measuring 6×5 cm with prominent radiating veins, coarse telangiectases, and a pale rim. Magnetic resonance imaging demonstrated a well-circumscribed mass with avid arterial phase enhancement. The patient experienced transient thrombocytopenia that resolved following administration of methylprednisolone. No evidence of rapid involution was noted after 3 months of observation.

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Diagnostic yield reporting of bronchoscopic peripheral pulmonary nodule biopsies: A call for standardization

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Irene Riestra Guiance, MD, Fellow-in-Training
Samira Shojaee, MD, MPH, FCCP, Section Chair

THORACIC ONCOLOGY AND CHEST PROCEDURES NETWORK

Interventional Procedures Section

More than 1.5 million Americans are diagnosed with an incidental CT scan-detected lung nodule annually. Advanced bronchoscopy, as a diagnostic tool for evaluation of these nodules, has evolved rapidly, incorporating a range of techniques and tools beyond CT scan-guided biopsies to assess peripheral lesions. The primary goal is to provide patients with accurate benign or malignant diagnoses. However, accurately determining the effectiveness of innovative technologies in providing a diagnosis remains challenging, in part due to limitations in study design and outcome reporting, along with the scarcity of comparative and randomized controlled studies.1,2 Current literature shows significant variability in diagnostic yield definition, lacking generalizability.

CHEST
Dr. Irene Riestra Guiance

To address this issue, an official research statement by the American Thoracic Society and CHEST defines the diagnostic yield as “the proportion of all individuals undergoing the diagnostic procedure under evaluation in whom a specific malignant or benign diagnosis is established.”3 To achieve this measure, the numerator includes all patients with lung nodules in whom the result of a diagnostic procedure establishes a specific benign or malignant diagnosis that is readily sufficient to inform patient care without additional diagnostic workup, and the denominator should include all patients in whom the procedure was attempted or performed. This standardized definition is crucial for ensuring consistency across studies, allowing for comparison or pooling of results, enhancing the reliability of diagnostic yield data, and informing clinical decisions.

CHEST
Dr. Samira Shojaee


The adoption of standardized outcome definitions is essential to critically evaluate modern, minimally invasive procedures for peripheral lung nodules diagnosis and to guide patient-centered care while minimizing the downstream effects of nondiagnostic biopsies. Clear, transparent, and consistent reporting will enable physicians to choose the most appropriate diagnostic tools, improve patient outcomes by reducing unnecessary procedures, and expedite accurate diagnoses. This initiative is a crucial first step toward creating high-quality studies that can inform technology implementation decisions and promote equitable health care.


References

1. Tanner NT, Yarmus L, Chen A, et al. Standard bronchoscopy with fluoroscopy vs thin bronchoscopy and radial endobronchial ultrasound for biopsy of pulmonary lesions: a multicenter, prospective, randomized trial. Chest. 2018;154(5):1035-1043.

2. Ost DE, Ernst A, Lei X, et al. Diagnostic yield and complications of bronchoscopy for peripheral lung lesions. Results of the AQuIRE Registry. Am J Resp Crit Care Med. 2016;193(1):68-77.

3. Gonzalez AV, Silvestri GA, Korevaar DA, et al. Assessment of advanced diagnostic bronchoscopy outcomes for peripheral lung lesions: a Delphi consensus definition of diagnostic yield and recommendations for patient-centered study designs. An official American Thoracic Society/American College of Chest Physicians research statement. Am J Respir Crit Care Med. 2024;209(6):634-646.

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Irene Riestra Guiance, MD, Fellow-in-Training
Samira Shojaee, MD, MPH, FCCP, Section Chair
Author(s)
Irene Riestra Guiance, MD, Fellow-in-Training
Samira Shojaee, MD, MPH, FCCP, Section Chair

THORACIC ONCOLOGY AND CHEST PROCEDURES NETWORK

Interventional Procedures Section

More than 1.5 million Americans are diagnosed with an incidental CT scan-detected lung nodule annually. Advanced bronchoscopy, as a diagnostic tool for evaluation of these nodules, has evolved rapidly, incorporating a range of techniques and tools beyond CT scan-guided biopsies to assess peripheral lesions. The primary goal is to provide patients with accurate benign or malignant diagnoses. However, accurately determining the effectiveness of innovative technologies in providing a diagnosis remains challenging, in part due to limitations in study design and outcome reporting, along with the scarcity of comparative and randomized controlled studies.1,2 Current literature shows significant variability in diagnostic yield definition, lacking generalizability.

CHEST
Dr. Irene Riestra Guiance

To address this issue, an official research statement by the American Thoracic Society and CHEST defines the diagnostic yield as “the proportion of all individuals undergoing the diagnostic procedure under evaluation in whom a specific malignant or benign diagnosis is established.”3 To achieve this measure, the numerator includes all patients with lung nodules in whom the result of a diagnostic procedure establishes a specific benign or malignant diagnosis that is readily sufficient to inform patient care without additional diagnostic workup, and the denominator should include all patients in whom the procedure was attempted or performed. This standardized definition is crucial for ensuring consistency across studies, allowing for comparison or pooling of results, enhancing the reliability of diagnostic yield data, and informing clinical decisions.

CHEST
Dr. Samira Shojaee


The adoption of standardized outcome definitions is essential to critically evaluate modern, minimally invasive procedures for peripheral lung nodules diagnosis and to guide patient-centered care while minimizing the downstream effects of nondiagnostic biopsies. Clear, transparent, and consistent reporting will enable physicians to choose the most appropriate diagnostic tools, improve patient outcomes by reducing unnecessary procedures, and expedite accurate diagnoses. This initiative is a crucial first step toward creating high-quality studies that can inform technology implementation decisions and promote equitable health care.


References

1. Tanner NT, Yarmus L, Chen A, et al. Standard bronchoscopy with fluoroscopy vs thin bronchoscopy and radial endobronchial ultrasound for biopsy of pulmonary lesions: a multicenter, prospective, randomized trial. Chest. 2018;154(5):1035-1043.

2. Ost DE, Ernst A, Lei X, et al. Diagnostic yield and complications of bronchoscopy for peripheral lung lesions. Results of the AQuIRE Registry. Am J Resp Crit Care Med. 2016;193(1):68-77.

3. Gonzalez AV, Silvestri GA, Korevaar DA, et al. Assessment of advanced diagnostic bronchoscopy outcomes for peripheral lung lesions: a Delphi consensus definition of diagnostic yield and recommendations for patient-centered study designs. An official American Thoracic Society/American College of Chest Physicians research statement. Am J Respir Crit Care Med. 2024;209(6):634-646.

THORACIC ONCOLOGY AND CHEST PROCEDURES NETWORK

Interventional Procedures Section

More than 1.5 million Americans are diagnosed with an incidental CT scan-detected lung nodule annually. Advanced bronchoscopy, as a diagnostic tool for evaluation of these nodules, has evolved rapidly, incorporating a range of techniques and tools beyond CT scan-guided biopsies to assess peripheral lesions. The primary goal is to provide patients with accurate benign or malignant diagnoses. However, accurately determining the effectiveness of innovative technologies in providing a diagnosis remains challenging, in part due to limitations in study design and outcome reporting, along with the scarcity of comparative and randomized controlled studies.1,2 Current literature shows significant variability in diagnostic yield definition, lacking generalizability.

CHEST
Dr. Irene Riestra Guiance

To address this issue, an official research statement by the American Thoracic Society and CHEST defines the diagnostic yield as “the proportion of all individuals undergoing the diagnostic procedure under evaluation in whom a specific malignant or benign diagnosis is established.”3 To achieve this measure, the numerator includes all patients with lung nodules in whom the result of a diagnostic procedure establishes a specific benign or malignant diagnosis that is readily sufficient to inform patient care without additional diagnostic workup, and the denominator should include all patients in whom the procedure was attempted or performed. This standardized definition is crucial for ensuring consistency across studies, allowing for comparison or pooling of results, enhancing the reliability of diagnostic yield data, and informing clinical decisions.

CHEST
Dr. Samira Shojaee


The adoption of standardized outcome definitions is essential to critically evaluate modern, minimally invasive procedures for peripheral lung nodules diagnosis and to guide patient-centered care while minimizing the downstream effects of nondiagnostic biopsies. Clear, transparent, and consistent reporting will enable physicians to choose the most appropriate diagnostic tools, improve patient outcomes by reducing unnecessary procedures, and expedite accurate diagnoses. This initiative is a crucial first step toward creating high-quality studies that can inform technology implementation decisions and promote equitable health care.


References

1. Tanner NT, Yarmus L, Chen A, et al. Standard bronchoscopy with fluoroscopy vs thin bronchoscopy and radial endobronchial ultrasound for biopsy of pulmonary lesions: a multicenter, prospective, randomized trial. Chest. 2018;154(5):1035-1043.

2. Ost DE, Ernst A, Lei X, et al. Diagnostic yield and complications of bronchoscopy for peripheral lung lesions. Results of the AQuIRE Registry. Am J Resp Crit Care Med. 2016;193(1):68-77.

3. Gonzalez AV, Silvestri GA, Korevaar DA, et al. Assessment of advanced diagnostic bronchoscopy outcomes for peripheral lung lesions: a Delphi consensus definition of diagnostic yield and recommendations for patient-centered study designs. An official American Thoracic Society/American College of Chest Physicians research statement. Am J Respir Crit Care Med. 2024;209(6):634-646.

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Post–intensive care syndrome and insomnia

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Changed
Tue, 07/02/2024 - 15:22
Author(s)
Leela Krishna Teja Boppana, MD, Fellow-in-Training
Lisa Wolfe, MD, FCCP, Member-at-Large
Mariam Louis, MD, FCCP, Section Chair

SLEEP MEDICINE NETWORK

Nonrespiratory Sleep Section

There has been a recent interest in post–intensive care syndrome (PICS), as an increasing number of patients are surviving critical illness. PICS is defined as “new onset or worsening of impairments in physical, cognitive, and/or mental health that arises after an ICU stay and persists beyond hospital discharge.1 We know that poor sleep is a common occurrence in the ICU, which can contribute to cognitive impairment and could be due to various risk factors, including age, individual comorbidities, reason for admission, and ICU interventions.2 Sleep impairment after hospital discharge is highly prevalent for up to 1 year after hospitalization.

CHEST
Dr. Leela Krishna Teja Boppana

The most common sleep impairment described after hospital discharge from the ICU is insomnia, which coexists with anxiety, depression, and posttraumatic stress disorder.3 When patients are seen in a post-ICU clinic, a multimodal strategy is needed for the treatment of insomnia, which includes practicing good sleep hygiene, cognitive behavioral therapy for insomnia (CBT-I), and pharmacotherapy if indicated.

CHEST
Dr. Mariam Louis


Since the American Academy of Sleep Medicine (AASM) 2021 clinical practice guideline on behavioral and psychological treatments for chronic insomnia, which made a strong recommendation for CBT-I, we continue to face barriers to incorporating CBT-I into our own clinical practice.4 This is due to limited access to CBT-I psychotherapists and patients’ lack of knowledge or treatment beliefs, among other reasons. However, there are numerous digital CBT-I platforms that patients can freely access from their mobile phone and are listed in the AASM article, “Digital cognitive behavioral therapy for insomnia: Platforms and characteristics,” which can help with treatment of insomnia.

For patients who are seen in post-ICU clinics, the first step in treating insomnia is discussing good sleep hygiene, providing resources for CBT-I (digital or in person), and treating coexistent psychiatric conditions.

References

1. Rawal G, Yadav S, Kumar R. Post-intensive care syndrome: an overview. J Transl Int Med. 2017;5(2):90-92.

2. Zampieri FG, et al. Ann Am Thorac Soc. 2023;20(11):1558-1560.

3. Altman MT, Knauert MP, Pisani MA. Sleep disturbance after hospitalization and critical illness: a systematic review. Ann Am Thorac Soc. 2017;14(9):1457-1468.

4. Edinger JD, Arnedt JT, Bertisch SM, et al. Behavioral and psychological treatments for chronic insomnia disorder in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2021;17(2):255-262.

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CHEST Physician
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Sleep Medicine
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Sleep Strategies
Author(s)
Leela Krishna Teja Boppana, MD, Fellow-in-Training
Lisa Wolfe, MD, FCCP, Member-at-Large
Mariam Louis, MD, FCCP, Section Chair
Author(s)
Leela Krishna Teja Boppana, MD, Fellow-in-Training
Lisa Wolfe, MD, FCCP, Member-at-Large
Mariam Louis, MD, FCCP, Section Chair

SLEEP MEDICINE NETWORK

Nonrespiratory Sleep Section

There has been a recent interest in post–intensive care syndrome (PICS), as an increasing number of patients are surviving critical illness. PICS is defined as “new onset or worsening of impairments in physical, cognitive, and/or mental health that arises after an ICU stay and persists beyond hospital discharge.1 We know that poor sleep is a common occurrence in the ICU, which can contribute to cognitive impairment and could be due to various risk factors, including age, individual comorbidities, reason for admission, and ICU interventions.2 Sleep impairment after hospital discharge is highly prevalent for up to 1 year after hospitalization.

CHEST
Dr. Leela Krishna Teja Boppana

The most common sleep impairment described after hospital discharge from the ICU is insomnia, which coexists with anxiety, depression, and posttraumatic stress disorder.3 When patients are seen in a post-ICU clinic, a multimodal strategy is needed for the treatment of insomnia, which includes practicing good sleep hygiene, cognitive behavioral therapy for insomnia (CBT-I), and pharmacotherapy if indicated.

CHEST
Dr. Mariam Louis


Since the American Academy of Sleep Medicine (AASM) 2021 clinical practice guideline on behavioral and psychological treatments for chronic insomnia, which made a strong recommendation for CBT-I, we continue to face barriers to incorporating CBT-I into our own clinical practice.4 This is due to limited access to CBT-I psychotherapists and patients’ lack of knowledge or treatment beliefs, among other reasons. However, there are numerous digital CBT-I platforms that patients can freely access from their mobile phone and are listed in the AASM article, “Digital cognitive behavioral therapy for insomnia: Platforms and characteristics,” which can help with treatment of insomnia.

For patients who are seen in post-ICU clinics, the first step in treating insomnia is discussing good sleep hygiene, providing resources for CBT-I (digital or in person), and treating coexistent psychiatric conditions.

References

1. Rawal G, Yadav S, Kumar R. Post-intensive care syndrome: an overview. J Transl Int Med. 2017;5(2):90-92.

2. Zampieri FG, et al. Ann Am Thorac Soc. 2023;20(11):1558-1560.

3. Altman MT, Knauert MP, Pisani MA. Sleep disturbance after hospitalization and critical illness: a systematic review. Ann Am Thorac Soc. 2017;14(9):1457-1468.

4. Edinger JD, Arnedt JT, Bertisch SM, et al. Behavioral and psychological treatments for chronic insomnia disorder in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2021;17(2):255-262.

SLEEP MEDICINE NETWORK

Nonrespiratory Sleep Section

There has been a recent interest in post–intensive care syndrome (PICS), as an increasing number of patients are surviving critical illness. PICS is defined as “new onset or worsening of impairments in physical, cognitive, and/or mental health that arises after an ICU stay and persists beyond hospital discharge.1 We know that poor sleep is a common occurrence in the ICU, which can contribute to cognitive impairment and could be due to various risk factors, including age, individual comorbidities, reason for admission, and ICU interventions.2 Sleep impairment after hospital discharge is highly prevalent for up to 1 year after hospitalization.

CHEST
Dr. Leela Krishna Teja Boppana

The most common sleep impairment described after hospital discharge from the ICU is insomnia, which coexists with anxiety, depression, and posttraumatic stress disorder.3 When patients are seen in a post-ICU clinic, a multimodal strategy is needed for the treatment of insomnia, which includes practicing good sleep hygiene, cognitive behavioral therapy for insomnia (CBT-I), and pharmacotherapy if indicated.

CHEST
Dr. Mariam Louis


Since the American Academy of Sleep Medicine (AASM) 2021 clinical practice guideline on behavioral and psychological treatments for chronic insomnia, which made a strong recommendation for CBT-I, we continue to face barriers to incorporating CBT-I into our own clinical practice.4 This is due to limited access to CBT-I psychotherapists and patients’ lack of knowledge or treatment beliefs, among other reasons. However, there are numerous digital CBT-I platforms that patients can freely access from their mobile phone and are listed in the AASM article, “Digital cognitive behavioral therapy for insomnia: Platforms and characteristics,” which can help with treatment of insomnia.

For patients who are seen in post-ICU clinics, the first step in treating insomnia is discussing good sleep hygiene, providing resources for CBT-I (digital or in person), and treating coexistent psychiatric conditions.

References

1. Rawal G, Yadav S, Kumar R. Post-intensive care syndrome: an overview. J Transl Int Med. 2017;5(2):90-92.

2. Zampieri FG, et al. Ann Am Thorac Soc. 2023;20(11):1558-1560.

3. Altman MT, Knauert MP, Pisani MA. Sleep disturbance after hospitalization and critical illness: a systematic review. Ann Am Thorac Soc. 2017;14(9):1457-1468.

4. Edinger JD, Arnedt JT, Bertisch SM, et al. Behavioral and psychological treatments for chronic insomnia disorder in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2021;17(2):255-262.

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Short telomere length and immunosuppression: Updates in nonidiopathic pulmonary fibrosis, interstitial lung disease

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Changed
Tue, 07/02/2024 - 15:25
Author(s)
Mamta Chhabria, MD, Fellow-in-Training
Ryan D. Boente, MD, Member-at-Large

DIFFUSE LUNG DISEASE AND LUNG TRANSPLANT NETWORK

Interstitial Lung Disease Section

Interstitial lung diseases (ILDs) are a diverse group of relentlessly progressive fibroinflammatory disorders. Pharmacotherapy includes antifibrotics and immunosuppressants as foundational strategies to mitigate loss of lung function. There has been a growing interest in telomere length and its response to immunosuppression in the ILD community.

CHEST
Dr. Mamta Chhabria

Telomeres are repetitive nucleotide sequences that “cap” chromosomes and protect against chromosomal shortening during cell replication. Genetic and environmental factors can lead to premature shortening of telomeres. Once a critical length is reached, the cell enters senescence. Short telomere length has been linked to rapid progression, worse outcomes, and poor response to immunosuppressants in idiopathic pulmonary fibrosis (IPF).

CHEST
Dr. Ryan D. Boente


Data in patients with non-IPF ILD (which is arguably more difficult to diagnose and manage) were lacking until a recent retrospective cohort study of patients from five centers across the US demonstrated that immunosuppressant exposure in patients with age-adjusted telomere length <10th percentile was associated with a reduced 2-year transplant-free survival in fibrotic hypersensitivity pneumonitis and unclassifiable ILD subgroups.1 This study was underpowered to detect associations in the connective tissue disease-ILD group. Interestingly, authors noted that immunosuppressant exposure was not associated with lung function decline in the short telomere group, suggesting that worse outcomes may be attributable to unmasking extrapulmonary manifestations of short telomeres, such as bone marrow failure and impaired adaptive immunity. Studies like these are essential to guide decision-making in the age of personalized medicine and underscore the necessity for prospective studies to validate these findings.

References

1. Zhang D, Adegunsoye A, Oldham JM, et al. Telomere length and immunosuppression in non-idiopathic pulmonary fibrosis interstitial lung disease. Eur Respir J. 2023;62(5):2300441.

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Mamta Chhabria, MD, Fellow-in-Training
Ryan D. Boente, MD, Member-at-Large
Author(s)
Mamta Chhabria, MD, Fellow-in-Training
Ryan D. Boente, MD, Member-at-Large

DIFFUSE LUNG DISEASE AND LUNG TRANSPLANT NETWORK

Interstitial Lung Disease Section

Interstitial lung diseases (ILDs) are a diverse group of relentlessly progressive fibroinflammatory disorders. Pharmacotherapy includes antifibrotics and immunosuppressants as foundational strategies to mitigate loss of lung function. There has been a growing interest in telomere length and its response to immunosuppression in the ILD community.

CHEST
Dr. Mamta Chhabria

Telomeres are repetitive nucleotide sequences that “cap” chromosomes and protect against chromosomal shortening during cell replication. Genetic and environmental factors can lead to premature shortening of telomeres. Once a critical length is reached, the cell enters senescence. Short telomere length has been linked to rapid progression, worse outcomes, and poor response to immunosuppressants in idiopathic pulmonary fibrosis (IPF).

CHEST
Dr. Ryan D. Boente


Data in patients with non-IPF ILD (which is arguably more difficult to diagnose and manage) were lacking until a recent retrospective cohort study of patients from five centers across the US demonstrated that immunosuppressant exposure in patients with age-adjusted telomere length <10th percentile was associated with a reduced 2-year transplant-free survival in fibrotic hypersensitivity pneumonitis and unclassifiable ILD subgroups.1 This study was underpowered to detect associations in the connective tissue disease-ILD group. Interestingly, authors noted that immunosuppressant exposure was not associated with lung function decline in the short telomere group, suggesting that worse outcomes may be attributable to unmasking extrapulmonary manifestations of short telomeres, such as bone marrow failure and impaired adaptive immunity. Studies like these are essential to guide decision-making in the age of personalized medicine and underscore the necessity for prospective studies to validate these findings.

References

1. Zhang D, Adegunsoye A, Oldham JM, et al. Telomere length and immunosuppression in non-idiopathic pulmonary fibrosis interstitial lung disease. Eur Respir J. 2023;62(5):2300441.

DIFFUSE LUNG DISEASE AND LUNG TRANSPLANT NETWORK

Interstitial Lung Disease Section

Interstitial lung diseases (ILDs) are a diverse group of relentlessly progressive fibroinflammatory disorders. Pharmacotherapy includes antifibrotics and immunosuppressants as foundational strategies to mitigate loss of lung function. There has been a growing interest in telomere length and its response to immunosuppression in the ILD community.

CHEST
Dr. Mamta Chhabria

Telomeres are repetitive nucleotide sequences that “cap” chromosomes and protect against chromosomal shortening during cell replication. Genetic and environmental factors can lead to premature shortening of telomeres. Once a critical length is reached, the cell enters senescence. Short telomere length has been linked to rapid progression, worse outcomes, and poor response to immunosuppressants in idiopathic pulmonary fibrosis (IPF).

CHEST
Dr. Ryan D. Boente


Data in patients with non-IPF ILD (which is arguably more difficult to diagnose and manage) were lacking until a recent retrospective cohort study of patients from five centers across the US demonstrated that immunosuppressant exposure in patients with age-adjusted telomere length <10th percentile was associated with a reduced 2-year transplant-free survival in fibrotic hypersensitivity pneumonitis and unclassifiable ILD subgroups.1 This study was underpowered to detect associations in the connective tissue disease-ILD group. Interestingly, authors noted that immunosuppressant exposure was not associated with lung function decline in the short telomere group, suggesting that worse outcomes may be attributable to unmasking extrapulmonary manifestations of short telomeres, such as bone marrow failure and impaired adaptive immunity. Studies like these are essential to guide decision-making in the age of personalized medicine and underscore the necessity for prospective studies to validate these findings.

References

1. Zhang D, Adegunsoye A, Oldham JM, et al. Telomere length and immunosuppression in non-idiopathic pulmonary fibrosis interstitial lung disease. Eur Respir J. 2023;62(5):2300441.

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Expanding recommendations for RSV vaccination

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Changed
Tue, 07/02/2024 - 15:23
Author(s)
Melanie Krongold, MD, Fellow-in-Training
Megan Conroy, MD, Member-at-Large

AIRWAYS DISORDERS NETWORK

Asthma and COPD Section

Respiratory syncytial virus (RSV) has been increasingly recognized as a prevalent cause of lower respiratory tract infection (LRTI) among adults in the United States. The risk of hospitalization and mortality from RSV-associated respiratory failure is higher in those with chronic lung disease. In adults aged 65 years or older, RSV has shown to cause up to 160,000 hospitalizations and 10,000 deaths annually.

CHEST
Dr. Melanie Krongold

In 2023, the US Food and Drug Administration approved the adjuvanted RSVPreF3 vaccine (Arexvy, GSK) and the bivalent RSVPreF vaccine (Abrysvo, Pfizer). Both vaccines have been shown to significantly reduce the risk of developing RSV LRTI and are currently recommended for single-dose administration in adults 60 years or older—irrespective of comorbidities.

RSV has been well established as a major cause of LRTI and morbidity among infants. Maternal vaccination with RSVPreF in patients who are pregnant is suggested between 32 0/7 and 36 6/7 weeks of gestation if the date of delivery falls during RSV season to prevent severe illness in young infants in their first months of life. At present, there are no data supporting vaccine administration to patients who are pregnant delivering outside of the RSV season.

CHEST
Dr. Megan Conroy


What about the rest of the patients? A phase 3b clinical trial to assess the safety and immunogenicity of the RSVPreF3 vaccine in individuals 18 to 49 years of age at increased risk for RSV LRTI, including those with chronic respiratory diseases, is currently underway with projected completion in April 2025 (clinical trials.gov; ID NCT06389487). Additional studies examining safety and immunogenicity combining RSV vaccines with PCV20, influenza, COVID, or Tdap vaccines are also underway. These outcomes will be significant for future recommendations to further lower the risk of developing LRTI, hospitalization, and death among patients less than the age of 60 with chronic lung diseases.


Resources

1. Melgar M, Britton A, Roper LE, et al. Use of respiratory syncytial virus vaccines in older adults: recommendations of the Advisory Committee on Immunization Practices - United States, 2023. MMWR Morb Mortal Wkly Rep. 2023;72(29):793-801.

2. Healthcare Providers: RSV Vaccination for Adults 60 Years of Age and Over. Centers for Disease Control and Prevention. Updated March 1, 2024. https://www.cdc.gov/vaccines/vpd/rsv/hcp/older-adults.html

3. Ault KA, Hughes BL, Riley LE. Maternal Respiratory Syncytial Virus Vaccination. The American College of Obstetricians and Gynecologists. Updated December 11, 2023. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2023/09/maternal-respiratory-syncytial-virus-vaccination

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Author(s)
Melanie Krongold, MD, Fellow-in-Training
Megan Conroy, MD, Member-at-Large
Author(s)
Melanie Krongold, MD, Fellow-in-Training
Megan Conroy, MD, Member-at-Large

AIRWAYS DISORDERS NETWORK

Asthma and COPD Section

Respiratory syncytial virus (RSV) has been increasingly recognized as a prevalent cause of lower respiratory tract infection (LRTI) among adults in the United States. The risk of hospitalization and mortality from RSV-associated respiratory failure is higher in those with chronic lung disease. In adults aged 65 years or older, RSV has shown to cause up to 160,000 hospitalizations and 10,000 deaths annually.

CHEST
Dr. Melanie Krongold

In 2023, the US Food and Drug Administration approved the adjuvanted RSVPreF3 vaccine (Arexvy, GSK) and the bivalent RSVPreF vaccine (Abrysvo, Pfizer). Both vaccines have been shown to significantly reduce the risk of developing RSV LRTI and are currently recommended for single-dose administration in adults 60 years or older—irrespective of comorbidities.

RSV has been well established as a major cause of LRTI and morbidity among infants. Maternal vaccination with RSVPreF in patients who are pregnant is suggested between 32 0/7 and 36 6/7 weeks of gestation if the date of delivery falls during RSV season to prevent severe illness in young infants in their first months of life. At present, there are no data supporting vaccine administration to patients who are pregnant delivering outside of the RSV season.

CHEST
Dr. Megan Conroy


What about the rest of the patients? A phase 3b clinical trial to assess the safety and immunogenicity of the RSVPreF3 vaccine in individuals 18 to 49 years of age at increased risk for RSV LRTI, including those with chronic respiratory diseases, is currently underway with projected completion in April 2025 (clinical trials.gov; ID NCT06389487). Additional studies examining safety and immunogenicity combining RSV vaccines with PCV20, influenza, COVID, or Tdap vaccines are also underway. These outcomes will be significant for future recommendations to further lower the risk of developing LRTI, hospitalization, and death among patients less than the age of 60 with chronic lung diseases.


Resources

1. Melgar M, Britton A, Roper LE, et al. Use of respiratory syncytial virus vaccines in older adults: recommendations of the Advisory Committee on Immunization Practices - United States, 2023. MMWR Morb Mortal Wkly Rep. 2023;72(29):793-801.

2. Healthcare Providers: RSV Vaccination for Adults 60 Years of Age and Over. Centers for Disease Control and Prevention. Updated March 1, 2024. https://www.cdc.gov/vaccines/vpd/rsv/hcp/older-adults.html

3. Ault KA, Hughes BL, Riley LE. Maternal Respiratory Syncytial Virus Vaccination. The American College of Obstetricians and Gynecologists. Updated December 11, 2023. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2023/09/maternal-respiratory-syncytial-virus-vaccination

AIRWAYS DISORDERS NETWORK

Asthma and COPD Section

Respiratory syncytial virus (RSV) has been increasingly recognized as a prevalent cause of lower respiratory tract infection (LRTI) among adults in the United States. The risk of hospitalization and mortality from RSV-associated respiratory failure is higher in those with chronic lung disease. In adults aged 65 years or older, RSV has shown to cause up to 160,000 hospitalizations and 10,000 deaths annually.

CHEST
Dr. Melanie Krongold

In 2023, the US Food and Drug Administration approved the adjuvanted RSVPreF3 vaccine (Arexvy, GSK) and the bivalent RSVPreF vaccine (Abrysvo, Pfizer). Both vaccines have been shown to significantly reduce the risk of developing RSV LRTI and are currently recommended for single-dose administration in adults 60 years or older—irrespective of comorbidities.

RSV has been well established as a major cause of LRTI and morbidity among infants. Maternal vaccination with RSVPreF in patients who are pregnant is suggested between 32 0/7 and 36 6/7 weeks of gestation if the date of delivery falls during RSV season to prevent severe illness in young infants in their first months of life. At present, there are no data supporting vaccine administration to patients who are pregnant delivering outside of the RSV season.

CHEST
Dr. Megan Conroy


What about the rest of the patients? A phase 3b clinical trial to assess the safety and immunogenicity of the RSVPreF3 vaccine in individuals 18 to 49 years of age at increased risk for RSV LRTI, including those with chronic respiratory diseases, is currently underway with projected completion in April 2025 (clinical trials.gov; ID NCT06389487). Additional studies examining safety and immunogenicity combining RSV vaccines with PCV20, influenza, COVID, or Tdap vaccines are also underway. These outcomes will be significant for future recommendations to further lower the risk of developing LRTI, hospitalization, and death among patients less than the age of 60 with chronic lung diseases.


Resources

1. Melgar M, Britton A, Roper LE, et al. Use of respiratory syncytial virus vaccines in older adults: recommendations of the Advisory Committee on Immunization Practices - United States, 2023. MMWR Morb Mortal Wkly Rep. 2023;72(29):793-801.

2. Healthcare Providers: RSV Vaccination for Adults 60 Years of Age and Over. Centers for Disease Control and Prevention. Updated March 1, 2024. https://www.cdc.gov/vaccines/vpd/rsv/hcp/older-adults.html

3. Ault KA, Hughes BL, Riley LE. Maternal Respiratory Syncytial Virus Vaccination. The American College of Obstetricians and Gynecologists. Updated December 11, 2023. https://www.acog.org/clinical/clinical-guidance/practice-advisory/articles/2023/09/maternal-respiratory-syncytial-virus-vaccination

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