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COVID-19: Cutaneous manifestations and issues related to dermatologic care

COVID-19: Cutaneous manifestations and issues related to dermatologic care
Authors:
Steven R Feldman, MD, PhD
Esther E Freeman, MD, PhD
Section Editors:
Jeffrey Callen, MD, FACP, FAAD
Kristina Callis Duffin, MD
Deputy Editors:
Abena O Ofori, MD
Rosamaria Corona, MD, DSc
Literature review current through: Nov 2022. | This topic last updated: Jul 07, 2022.

INTRODUCTION — Coronavirus disease 2019 (COVID-19), caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), raises many critical issues in dermatology and dermatologic care. Addressing these issues is necessary, yet also challenging, because there are few direct data on which to base recommendations [1].

This topic will discuss issues related to dermatologic care during the COVID-19 pandemic. Other relevant aspects of SARS-CoV-2 infection and patient management are discussed in detail separately.

(See "COVID-19: Epidemiology, virology, and prevention".)

(See "COVID-19: Clinical features".)

(See "COVID-19: Diagnosis".)

(See "COVID-19: Infection prevention for persons with SARS-CoV-2 infection".)

(See "COVID-19: Evaluation of adults with acute illness in the outpatient setting" and "COVID-19: Management of adults with acute illness in the outpatient setting".)

(See "COVID-19: Hypercoagulability".)

(See "COVID-19: Multisystem inflammatory syndrome in children (MIS-C) clinical features, evaluation, and diagnosis".)

(See "COVID-19: Management in hospitalized adults".)

(See "COVID-19: Questions and answers".)

(See "COVID-19: Considerations in patients with cancer".)

(See "COVID-19: Care of adult patients with systemic rheumatic disease".)

CUTANEOUS MANIFESTATIONS OF COVID-19 — Case series from around the world have identified a range of potential dermatologic manifestations of coronavirus disease 2019 (COVID-19) [2-8]. The frequency (ranging from 0.2 to 20.4 percent of cases) and timing of cutaneous manifestations of COVID-19 are difficult to ascertain [9-11]. Also unclear is the association of certain skin manifestations with the illness severity [12]. Moreover, it cannot be excluded that in some patients the observed skin findings may represent cutaneous reactions to the numerous treatments used for COVID-19 [12,13].

The American Academy of Dermatology's COVID-19 Registry, a collaboration between the American Academy of Dermatology and the International League of Dermatologic Societies, is attempting to collate cases and better define the cutaneous manifestations of COVID-19 [14] (see 'Registries' below). Among 171 laboratory-confirmed COVID-19 patients with cutaneous manifestations from the registry, the most commonly reported were morbilliform rash (22 percent), pernio-like acral lesions (18 percent), urticaria (16 percent), macular erythema (13 percent), vesicular eruption (11 percent), papulosquamous eruption (9.9 percent), and retiform purpura (6.4 percent) [15]. Fever and cough were reported in approximately 60 percent of cases:

Exanthematous (morbilliform) rash – In several case series, a morbilliform rash predominantly involving the trunk has been reported as the most common cutaneous manifestation of COVID-19 [2,3,10,15-17]. The rash has been noted either at the disease onset or, more frequently, after hospital discharge or recovery [10].

Pernio (chilblain)-like acral lesions – Pernio (chilblain)-like lesions of acral surfaces ("COVID toes") present as erythematous-violaceous or purpuric macules on fingers, elbows, toes, and the lateral aspect of the feet, with or without accompanying edema and pruritus (picture 1A-B) (see "Pernio (chilblains)"):

Incidence – Pernio-like lesions have been increasingly reported across the age spectrum during the COVID-19 pandemic, with most cases occurring among adolescents and young adults. In a northern California study, the incidence of chilblains increased during the pandemic (April 2020 to December 2020) compared with the prepandemic period (April 2016 to December 2019), from 5.2 per 100,000 person-years (95% CI 4.8-5.6) to 28.6 per 100,000 person-years (95% CI 26.8-30.4) [18].

Association with SARS-CoV-2 infection – During the pandemic, pernio-like lesions have been reported with increased frequency in patients with or without confirmed COVID-19 or history of contact with patients with confirmed COVID-19 and in the absence of documented cold exposure or underlying conditions associated with pernio [2-4,15,18-26]. However, the association between chilblains and COVID-19 remains controversial.

In patients with pernio-like lesions who underwent testing for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), polymerase chain reaction (PCR) was negative in the majority of cases, with rates of PCR positivity ranging from 4 to 7 percent in large series:

-In a French series of 311 patients (median age 26 years) with acral manifestations seen between March 2020 and May 2020, 150 patients (49 patients with symptoms suspicious for COVID-19) underwent nasopharyngeal swab reverse transcription (RT)-PCR and/or serology for SARS-CoV-2 [27]. Five of 75 patients were positive for SARS-CoV-2 serology, and 7 of 121 patients were positive for SARS-CoV-2 RT-PCR. Overall, 10 of 170 patients (7 percent) had confirmed COVID-19.

-In the American Academy of Dermatology/International League of Dermatologic Societies registry study, of 318 cases from eight countries, 14 of these cases were PCR positive (4.4 percent) [4].

-In a large, retrospective, cohort study conducted within a health care system in northern California that included 780 patients diagnosed with chilblains between April 2020 and December 2020, of 456 patients who underwent PCR testing for SARS-CoV-2, 17 patients (3.7 percent) were positive [18].

Serology for SARS-CoV-2 (mainly immunoglobulin G [IgG] and immunoglobulin M [IgM]) was performed in a limited number of patients with pernio-like lesions and negative PCR for SARS-CoV-2, in most cases only at one point in time, with positivity rates of 1 to 17 percent [4,18,28,29]. Of note, in some series of patients, specific immunoglobulin A (IgA) antibodies were detected more frequently than IgG [29,30]:

-In a subset of 97 patients from a series of 780 patients with chilblains reported during the pandemic, single time point IgG positivity rate was 1 percent [18]. IgM and IgA were not tested [18].

-In a French series of 40 consecutive patients with chilblain-like lesions, COVID-19 serology was positive in 12 patients, of whom 7 (17.5 percent) had only IgA and 5 (12.5 percent) had IgG [30].

-In an Italian series of 30 children with pernio-like lesions, of whom 17 were retested at a five- to seven-week interval, the overall positivity rate was 17 percent for IgG and 53 percent for IgA [29].

-In a United States small cohort of 21 patients with chilblains diagnosed during the first wave of the pandemic, only two cases (9 percent) had PCR test-confirmed SARS-CoV-2 infection; positive serology for IgG, IgA, and IgM antibodies against S, receptor binding domain, and nucleocapsid antigens; and evidence of antigen-specific T cell responses to SARS-CoV-2 [31]. Serology and T cell response were negative in the other 19 patients with chilblains.

-In a study of 50 patients with chilblain-like lesions seen during the first wave of the pandemic, PCR testing for SARS-CoV-2 as well as serology for IgG and IgA were negative in all patients [32]. Compared with patients with seasonal chilblains seen before the pandemic, chilblain-like lesions had similar histopathologic and immunohistochemical features, as well as immune transcriptomic signature, with upregulation of type I and II interferon pathways, T helper 1 (Th1) cell polarization, cytotoxicity markers, and natural killer signaling.

Clinical presentation and course – The majority of patients with pernio-like lesions and confirmed or suspected SARS-CoV-2 infection were asymptomatic or had mild symptoms compatible with COVID-19, with very rare reports of severe COVID-19 in patients with pernio-like lesions [2,4,30,33,34]. In the American Academy of Dermatology/International League of Dermatologic Societies registry study, 55 percent of patients overall were otherwise asymptomatic, and 98 percent of patients in the study were treated in the outpatient setting alone [4]. This finding held true when restricted to laboratory-confirmed cases only, with 78 percent remaining in the outpatient setting.

In patients with confirmed or suspected SARS-CoV-2 infection, pernio lesions started one to four weeks after the onset of COVID-19 symptoms, suggesting a postviral or delayed-onset process. In the American Academy of Dermatology/International League of Dermatologic Societies registry, 80 of 318 cases with pernio-like lesions developed lesions after the onset of other COVID-19 symptoms [4]. In some cases, lesions appeared while patients were still PCR positive for the virus [4,26].

Resolution usually occurred in two to eight weeks. A prolonged course of more than 60 days has been reported in some patients ("long haulers") [35]. Additionally, some patients have developed recurrence of pernio, likely triggered by cold, during the following fall-winter season [36,37].

Potential pathogenetic mechanisms – Proposed mechanisms for the development of pernio-like lesions during the pandemic include a reaction to the immune response to the virus and pandemic-related lifestyle changes that may increase the risk for pernio. As an example, in a large, cohort study that included 780 patients with pernio seen during the pandemic, 94 percent reported not wearing shoes at home [18].

Examination of biopsied pernio-like lesions demonstrates a primarily inflammatory process, with histopathologic and direct immunofluorescence findings similar to those seen in idiopathic and autoimmune-related pernio [3,22,24,38-41]. (See "Pernio (chilblains)", section on 'Skin biopsy'.)

These inflammatory changes have been hypothesized to be associated with enhanced interferon-alpha responses to the virus and are, at times, associated with an IgA antibody response to the virus [30,35,42].

A French study demonstrated increased in vitro production of interferon-alpha from stimulated peripheral blood T cells in patients with pernio compared with patients with PCR-positive, moderate to severe COVID-19 without pernio, suggesting that a robust, innate immune response may lead to rapid control of the virus in these patients and could, at least in part, explain the relatively mild disease course and low level of antibody production [42].

Management – There are no treatment guidelines for COVID-19-associated, pernio-like lesions of the feet or hands. However, clinical experience suggests that high-potency topical corticosteroids may be helpful if the lesions are causing discomfort.

Although PCR positivity has been found infrequently in patients with pernio during the COVID-19 pandemic and not all cases are necessarily related to COVID-19, it may be prudent that patients presenting with new-onset, pernio-like lesions that have no other clear cause be tested for SARS-CoV-2 PCR within seven days of the onset of pernio lesions [43-46]. For patients who have had these lesions for >4 weeks, IgM and IgG antibody testing can be considered, following local guidelines and depending on the quality of available tests, acknowledging that many of these patients may only make transient antibody responses or IgA responses that are not currently being tested in commercial laboratories. A positive serology could rule out other causes of pernio that might need additional work-up. Work-up of other causes of pernio is discussed in greater detail separately [2,4,30]. (See "Pernio (chilblains)".)

Livedo reticularis-like – Livedo reticularis-like vascular lesions have been reported in a few patients with COVID-19 [15,20,47-51]. In a series of 171 laboratory-confirmed cases, these vascular lesions were noted in 5.3 and 2.3 percent of patients, respectively [15].

Fixed livedo racemosa/retiform purpura/necrotic vascular lesions – Retiform purpura and necrotic vascular lesions seem to be associated with severe COVID-19 (picture 2A-B) [15,20,52,53]. In a series of 11 patients with retiform purpura and laboratory confirmed COVID-19, all were hospitalized and nine had acute respiratory distress syndrome [15]. In three patients with SARS-CoV-2 infection and severe respiratory failure who had retiform purpura or livedo racemosa, histologic and immunohistochemistry studies of skin biopsies revealed a pattern of complement-mediated microvascular injury in both involved and normally appearing skin [52]. Histopathologic findings of thrombotic vasculopathy and/or laboratory coagulation alterations have also been demonstrated in patients with severe COVID-19 and acral ischemic lesions [38,53]. (See "Approach to the patient with retiform (angulated) purpura" and "Livedoid vasculopathy" and "COVID-19: Hypercoagulability".)

Urticaria – Acute urticaria with or without concomitant fever has been reported as a presenting sign of COVID-19 infection [2,3,10,15,20,54].

Vesicular (varicella-like) eruptions – There are several reports describing a vesicular-pustular, varicella-like eruption associated with COVID-19 [2,20,55,56]. In a series of 24 patients, an eruption of small papules, vesicles, and pustules appeared 4 to 30 days after the onset of COVID symptoms and resolved in a median of 10 days [57]. A real-time PCR for SARS-CoV-2 from vesicle content performed in four patients yielded negative results. Seventeen of 24 patients were not taking any medications, ruling out a drug reaction.

Multisystem inflammatory syndrome in children (MIS-C) – An erythematous, polymorphic rash, erythema and/or firm induration of hands and feet, oral mucositis, and conjunctivitis, along with systemic, laboratory, and imaging findings of atypical, severe Kawasaki disease, were initially described in a cohort of 10 Italian children during the COVID-19 pandemic [58]. Similar cases have been reported in the United Kingdom [59], the United States [60], and other countries. Case definitions for MIS-C have been proposed by the World Health Organization and the United States Centers for Disease Control and Prevention. (See "COVID-19: Multisystem inflammatory syndrome in children (MIS-C) clinical features, evaluation, and diagnosis".)

Less frequently reported dermatologic manifestations include papulosquamous eruptions [61], erythema multiforme-like lesions [62-64], dengue-like rashes [65,66], petechiae [67], and gangrene [68].

Some infants born to mothers with COVID-19 at birth have had transient rash. In a review of nine small case series from China that included a total of 65 pregnant women who were infected with SARS-CoV-2 during pregnancy and 67 newborns, two newborns presented with a rash [69]. The rash has been described in one infant as a diffuse, maculopapular eruption that resolved in one day with desquamation and in another as a diffuse, red, miliaria-like eruption that disappeared in 10 days without treatment [70].

DERMATOLOGIC CONDITIONS RELATED TO COVID-19 PANDEMIC — Skin injury, mechanical/friction dermatitis, and irritant contact dermatitis due to personal protective equipment (PPE) and hand hygiene measures have been reported in the majority of health care workers involved in the direct care of patients with coronavirus disease 2019 (COVID-19) [71].

Personal protective equipment-induced skin injury — Health care workers caring for COVID-19 patients or patients potentially infected with severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) may spend long hours wearing PPE. The American Academy of Dermatology has released recommendations on preventing and treating occupationally induced dermatologic conditions during the COVID-19 pandemic:

Mechanical injury/friction dermatitis – PPE-induced skin injury is common, occurring in up to over 90 percent of health care workers [71-74]. Long durations of PPE use (>6 hours per day) increase rates of skin damage [71,72,75]. Masks, goggles, face shields, and gloves apply pressure, create abrasion, and retain moisture and can injure the nasal bridge, cheek, forehead, and hands [71-73]. PPE-induced injuries include desquamation, erythema, maceration, fissuring, papules, and erosions, leading to itching and pain [72].

Irritant and allergic contact dermatitis – Multiple case series have reported allergic contact dermatitis due to rubber, adhesives, and formaldehyde, as well as irritant contact dermatitis due to pressure and friction, in health care workers wearing N95 or equivalent masks for >6 hours daily [76,77].

Facial dermatoses ("maskne") – New-onset or exacerbation of facial dermatoses, including acne ("maskne"), rosacea ("mask rosacea"), seborrheic dermatitis, periorificial dermatitis, and folliculitis, likely due to friction and occlusion, have been reported in persons wearing masks for >6 hours per day [76,78,79]. Mask-related Koebner phenomenon (trauma-induced development of lesions clinically similar to the underlying skin disease in previously uninvolved areas) has also been described in patients with a variety of skin disorders, including psoriasis, vitiligo, acne, and rosacea [80].

Prevention of PPE-related injuries has the potential to reduce PPE protocol breaches due to inadvertent adjustment and touching [81]. The use of barrier films or dressings at pressure points before donning PPE may reduce these types of injuries [82-86]. However, the effects of these preventive measures on PPE ability to prevent viral spread are not well characterized, and caution is warranted [81,84].

Hand hygiene-related dermatitis — Hand hygiene is considered a key tool against COVID-19. Hand eczema was already an issue among health care workers and is likely to be an even greater problem with higher rates of hand washing and glove use during the pandemic [87].

The frequency of irritant contact dermatitis of the hands may be reduced by frequent usage of emollients, washing with lukewarm water instead of hot water, and usage of alcohol-based cleansers when hands are not visibly dirty [82,85,88,89]. Overzealous hand hygiene may cause hand eczema in the general population as well [90].

The American Academy of Dermatology has released recommendations on preventing and treating occupationally induced dermatologic conditions during the COVID-19 pandemic. (See "Irritant contact dermatitis in adults" and "Chronic hand eczema".)

THERAPEUTIC CONSIDERATIONS DURING THE PANDEMIC — The coronavirus disease 2019 (COVID-19) pandemic has led to necessary adjustments to the therapeutic approach for some dermatologic diseases. Considerations for immunosuppressive therapy, phototherapy, and skin cancer treatment are reviewed here. Various professional organizations have also released guidelines for clinical care during the pandemic. (See 'Society guideline links' below and "COVID-19: Care of adult patients with systemic rheumatic disease".)

Use of biologic and other immunosuppressive therapies — Biologic and immunosuppressive therapies play important roles in the management of a wide variety of dermatologic diseases, such as psoriasis, atopic dermatitis, and other inflammatory or autoimmune conditions. The risks of these immunomodulatory therapies in relation to COVID-19 remain unclear. Although it is generally accepted that most patients without COVID-19 who are already taking immunosuppressive drugs for dermatologic disease can continue therapy, a more cautious approach is typically taken for patients who have suspected or confirmed COVID-19 and patients who are considering starting a new immunosuppressive therapy. (See 'Patients without COVID-19' below and 'Patients with presumed or confirmed COVID-19' below.)

Recommendations for COVID-19 vaccination in immunocompromised patients are reviewed separately. (See "COVID-19: Vaccines", section on 'Immunocompromised individuals'.)

Assessment of risk — The uncertainty regarding the impact of biologic and other immunosuppressive therapies on severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection risk and COVID-19 severity makes risk assessment challenging [91-93]. Specific challenges for risk assessment include the paucity of data, the various mechanisms of action of immunosuppressive drugs, and the need to consider patient-specific and disease-specific morbidity and comorbidities. Some authors have proposed that the broad immunosuppression induced by small molecule immunosuppressants (eg, cyclosporine, mycophenolate, azathioprine) may be of greater concern than the targeted immunosuppression induced by biologic drugs; however, the relative safety of individual immunosuppressants remains unclear [94].

Consideration of the potential risks of immunosuppressive therapy must also be balanced with consideration of the detrimental effects on skin disease and associated conditions that may result from cessation of effective therapies [95]. Cutaneous disease may flare, and occasional patients may not achieve the same level of response upon the reintroduction of a previously effective biologic therapy [92,93]. Of note, the long half-lives of some biologic agents mean that immunosuppressive effects of concern may still persist for some time following the decision to stop therapy.

Studies evaluating use of immunomodulatory therapies in relation to COVID-19 in patients with dermatologic disease are limited and insufficient for drawing conclusions on risk in this population [96-99]. It is unclear whether data from clinical trials that have assessed risk for upper respiratory infections during biologic therapy for dermatologic disease are applicable to SARS-CoV-2 infection [93,100-102].

In support of the theory that risks of continuing biologic therapy for skin disease may be low, one retrospective study of 5206 patients in northern Italy treated with biologic agents for plaque psoriasis between February 20 and April 1, 2020, found no COVID-19-related deaths and only four COVID-19-related hospitalizations [96]. In addition, a case control study performed in the Lombardy region of Italy that involved assessment of 1193 patients with psoriasis treated with biologic or small molecule therapy and approximately 10 million controls between February 21 and April 9, 2020, found higher risks for testing positive for COVID-19, being self-quarantined at home due to COVID-19, or being hospitalized due to COVID-19 among psoriasis patients receiving biologic therapy compared with controls but did not find statistically significant increases in risk for intensive care unit admission or dying in this population [97]. A cohort study that compared outcomes of COVID-19 in 214 patients treated with tumor necrosis factor (TNF) inhibitors or methotrexate within one year of contracting COVID-19 with over 31,000 patients who did not receive these drugs found no difference in the likelihood of hospitalization or mortality [103].

Although the potential for a beneficial effect of biologic inhibitors TNF-alpha or interleukin (IL) 17 in COVID-19 has been proposed based upon the theory that some immunosuppressive drugs might have inhibitory effects on damaging immune response that is thought to contribute to organ damage in COVID-19, this has not been proven [104-107]. Data on IL-6 pathway inhibitors is reviewed separately. Dexamethasone has been used in the treatment of select patients with severe COVID-19. (See "COVID-19: Clinical features", section on 'Acute course and complications' and "COVID-19: Management in hospitalized adults", section on 'Dexamethasone and other glucocorticoids' and "COVID-19: Management in hospitalized adults", section on 'IL-6 pathway inhibitors (eg, tocilizumab)'.)

Patients without COVID-19 — Decisions on the use of immunosuppressive therapies in patients without signs or symptoms of COVID-19 during the global pandemic should be made on a case-by-case basis and in conjunction with the patient. This may involve review of the patient's comorbidities, severity of the disease originally being treated, limited available data, expert opinion, local recommendations, and patient preference.

Continuation of immunosuppressive therapies — Based upon an absence of evidence that suggests benefit of discontinuing immunosuppressive therapies in patients without COVID-19 and the potential detrimental effects of discontinuing effective therapies, the continuation of biologic and small molecule immunosuppressants for dermatologic disease is generally considered a safe and appropriate option for patients who do not have suspected or documented COVID-19. Examples of societies that support this approach include the American Academy of Dermatology [108], National Psoriasis Foundation [109], International Psoriasis Council [110], British Academy of Dermatology [111], and International League of Dermatological Societies [112].

Initiation of immunosuppressive therapies — Routine avoidance of initiating a new immunosuppressive therapy for dermatologic disease in patients without COVID-19 is not considered necessary. However, given that some uncertainty remains regarding the effects of immunosuppressive therapies on COVID-19, the decision to start a new immunosuppressive drug for dermatologic disease should be taken carefully, involving a case-specific review of the potential risks and benefits of therapy. In particular, for patients perceived to be at increased risk for severe COVID-19, it may be prudent to consider deferring immunosuppressive treatments in favor of other therapies [108]. (See "COVID-19: Clinical features", section on 'Risk factors for severe illness'.)

Some authors have proposed testing for SARS-CoV-2 infection or immunity prior to initiation of immunosuppressive therapies [113]. However, the value of this approach is unclear.

Patients with presumed or confirmed COVID-19 — Active infection is an accepted indication for discontinuation and avoidance of initiation of immunosuppressive therapies. Some professional societies, including the American Academy of Dermatology, have issued statements that recommend discontinuation of immunosuppressive drugs in patients who develop COVID-19, although this remains an area of debate [114]. This approach may be the appropriate default for most patients with confirmed COVID-19. Immunosuppressive therapy may be resumed, if needed, following complete recovery from COVID-19.

However, given the uncertainty about the effects of various immunosuppressants on the course of COVID-19, the decision to discontinue treatment in a patient with COVID-19 should be made on a case-by-case basis. Other factors that may influence the decision to cease treatment may include the severity of COVID-19, the potential that biologic treatment may reduce risk of cytokine storm, and the potential negative ramifications of treatment cessation on flaring immunologic activity, including both dermatologic disease and comorbidities.

Phototherapy — In-office phototherapy typically involves frequent clinic visits, potentially increasing exposure of patients and clinical staff to SARS-CoV-2. Thus, the risks and benefits of office-based phototherapy should be weighed carefully for individual patients.

Home phototherapy is an alternative that may be the preferred method of phototherapy during the pandemic but may not be feasible for all patients. If in-office phototherapy is necessary, careful precautions, including screening for symptoms, limiting visitors, personal protective equipment (PPE) use, and equipment disinfection, should be taken to reduce the risk of transmission of infection [115,116]. Alternatives to phototherapy should also be considered. (See "COVID-19: Infection prevention for persons with SARS-CoV-2 infection", section on 'Infection prevention in the health care setting'.)

Skin cancer — Many full body skin examinations, biopsies, and skin cancer excisions have been postponed due to the COVID-19 pandemic, which may lead to delays in diagnosis and treatment. Triage and management strategies during the COVID-19 pandemic for melanoma, advanced squamous cell carcinoma, and advanced basal cell carcinoma have been developed by several groups, including the National Comprehensive Cancer Network, the European Society for Medical Oncology, and the American College of Mohs Surgery, with deferment of surgery or prompt surgery dependent upon the type of lesion and reason for the visit [117-119]. The United States Cutaneous Lymphoma Consortium has published recommendations for the treatment of cutaneous lymphomas during the COVID-19 pandemic [120].

For patients with advanced melanoma and nonmelanoma skin cancers who are under treatment, there are no recommendations to cease skin cancer-related systemic therapies [121,122]. However, the decision regarding the continuation or initiation of systemic targeted therapies or immunotherapies must be made on a case-by-case basis, after careful evaluation of benefits versus risks.

General and specific issues related to the care of cancer patients during the pandemic are discussed elsewhere. (See "COVID-19: Considerations in patients with cancer".)

CONSIDERATIONS FOR VACCINATION TO PREVENT SARS-COV-2 INFECTION — The development of vaccines to prevent severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection is occurring at an unprecedented rate. Vaccines to prevent SARS-CoV-2 infection are reviewed in detail separately. (See "COVID-19: Vaccines".)

Cutaneous adverse events — Examples of cutaneous reactions following receipt of coronavirus disease 2019 (COVID-19) vaccines have included delayed, large, local reactions (also known as "COVID arm"); injection site reactions; urticaria; morbilliform eruptions ("maculopapular rash"); pityriasis rosea-like reactions; pernio/chilblains; bullous pemphigoid-like reactions; lichen planus-like reactions; purpuric reactions; and other findings [123-128]. (See "COVID-19: Allergic reactions to SARS-CoV-2 vaccines", section on 'Reactions to specific vaccines'.)

The term "vaccine-related eruption of papules and plaques" (V-REPP) has been proposed for the group of cutaneous COVID-19 vaccination reactions characterized by the histologic finding of spongiotic dermatitis and clinical findings of papulovesicular, pityriasis rosea-like, and papulosquamous skin lesions [128].

Cutaneous and other adverse events following COVID-19 vaccines should be reported. (See 'Registries' below.)

Delayed local reactions — A delayed local reaction secondary to COVID-19 vaccination (also known as "COVID arm") is an immune-mediated reaction characterized by the development of a well-demarcated, inflamed plaque near the site of mRNA vaccination (picture 3). In contrast to typical injection site reactions, which appear within one to two days after vaccination, the usual time of onset is seven to eight days after vaccination. Delayed local reactions have been most frequently reported following initial vaccination and appear to be more common in females than males [129,130]. Clinically, delayed local reactions may be mistaken for cellulitis. Reactions generally spontaneously resolve within several days, though longer durations have been reported [129]. Antibiotic therapy is not indicated. (See "COVID-19: Allergic reactions to SARS-CoV-2 vaccines", section on 'Late local reactions'.)

Soft tissue fillers — Reports of facial swelling following receipt of the mRNA 1273 (Moderna) COVID-19 vaccine in patients with a history of facial soft tissue filler injections suggest a relationship between prior cosmetic soft tissue filler injections and postvaccination swelling, although such reports are rare, and additional data are necessary to confirm an association. A US Food and Drug Administration (FDA) briefing document on the mRNA 1273 vaccine released in December 2020 included three reports of facial swelling following receipt of the mRNA 1273 vaccine [131]. Symptoms generally occur within two weeks after vaccination. A local, inflammatory reaction related to an interaction between the postvaccination immune response and dermal filler is a proposed mechanism for this occurrence [131].

Guidance for soft tissue filler use in relation to COVID-19 vaccination is evolving given the limited available data. Early guidance from the American Society for Dermatologic Surgery advised not discouraging or precluding vaccination for patients previously treated with soft tissue fillers and not precluding previously vaccinated patients from receipt of soft tissue fillers in the future [132]. Other authors have suggested a four- to eight-week interval between filler injection and vaccination [123].

Pending additional data to confirm or negate an association, it is reasonable to include a discussion of reports of facial swelling following receipt of the mRNA 1273 vaccine in pretreatment counseling for patients seeking cosmetic soft tissue filler injections [123].

Given the apparent rarity of this adverse event and the expectation for complete resolution of associated facial swelling, decisions to proceed with soft tissue filler injections in close proximity to receipt of the vaccine may involve consideration of patient and provider tolerance for risk for facial swelling as well as consideration of the risks of delaying COVID-19 vaccination. (See "Injectable soft tissue fillers: Overview of clinical use".)

Immunocompromised patients — Limited data suggest vaccination against SARS-CoV-2 is safe in dermatologic patients receiving immunomodulatory therapies [133]. Efficacy of vaccination in this population may vary based upon the type of immunomodulatory therapy and vaccine [133]. Guidance regarding administration of COVID-19 vaccines in immunocompromised patients is provided separately. (See "COVID-19: Vaccines", section on 'Immunocompromised individuals' and "COVID-19: Care of adult patients with systemic rheumatic disease", section on 'COVID-19 vaccination while on immunosuppressive therapy'.)

DELIVERY OF CARE DURING THE PANDEMIC — Local guidelines on the performance of routine, nonurgent medical care during the pandemic differ and continue to evolve. In many settings, the pandemic has led to increased use of telemedicine for dermatologic care (ie, teledermatology). In scenarios in which in-person care remains necessary or appropriate, precautions to limit risk for transmission of infection are indicated. (See 'Telemedicine' below and 'In-person care' below and 'Society guideline links' below.)

Telemedicine — Telemedicine provides an opportunity to provide care while reducing risk for exposure of clinicians, staff, and patients to individuals with coronavirus disease 2019 (COVID-19) [134,135]. Both synchronous (eg, simultaneous, two-way communication between the patient and clinician via telephone or videoconferencing) and asynchronous (eg, store-and-forward transmission of images for later assessment by the clinician) modalities have been utilized for teledermatology care [136]. A structured triage process may be helpful for identifying patients who require in-person, rather than a telemedicine, visit [137,138].

Telemedicine may also be an appropriate option for inpatient dermatologic care in some scenarios. The Society of Dermatology Hospitalists has produced an algorithm to guide triaging of consultations and the performance of safe inpatient dermatologic care [139].

Concerns have been raised over privacy and security of telemedicine [140,141]. The platform selected should be compliant with local privacy regulations. Due to the COVID-19 pandemic, some regulatory bodies have relaxed or waived rules to allow more flexibility in telemedicine [142].

Photography tips for patients seeking telemedicine evaluation for skin conditions are provided in a table (table 1).

In-person care — In-person visits should be performed with appropriate infection control precautions. This typically includes at least patient screening and use of appropriate personal protective equipment (PPE) [143-145]. Best practices for infection control in the clinical setting are reviewed separately. (See "COVID-19: Infection prevention for persons with SARS-CoV-2 infection", section on 'Infection prevention in the health care setting'.)

Although the risk of transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) through procedures such as dermoscopy remains unclear, clinicians should be cognizant about the potential for transmission through equipment that may come into contact with multiple patients. In regard to dermoscopy, noncontact dermoscopy is the preferred form of dermoscopy during the pandemic. Examples of additional suggestions for reducing risk for disease transmission through dermoscopy have included disinfection of the dermatoscope with alcohol for at least one minute prior to and following examination, use of polyvinyl chloride food wrap or glass slide between the lens and lesion, use of alcohol gel as an interface medium, and use of disposable dermoscopic lens covers [146-148].

REGISTRIES

COVID-19 — Multiple registries have been developed, with the goal of increasing knowledge of the dermatologic manifestations and impact of coronavirus disease 2019 (COVID-19) in patients with dermatologic disease. Examples include:

General dermatologic manifestations of COVID-19 or patients with COVID-19 and any pre-existing dermatologic condition:

American Academy of Dermatology/International League of Dermatological Societies COVID-19 Registry

Psoriasis:

Psoriasis Registry for Outcomes, Therapy, and Epidemiology of COVID-19 Infection (PsoPROTECT)

Surveillance Epidemiology of Coronavirus (COVID-19) Under Research Exclusion Registry (SECURE-Psoriasis Registry)

Atopic dermatitis:

Surveillance Epidemiology of Coronavirus (COVID-19) Under Research Exclusion Registry (SECURE-AD Registry)

Alopecia:

Surveillance Epidemiology of Coronavirus (COVID-19) Under Research Exclusion Registry (SECURE-Alopecia Registry)

Hidradenitis suppurativa:

Global Hidradenitis Suppurativa COVID-19 Registry

Acral changes in the pediatric population:

COVID Acral Ischemia/Perniosis in Children Registry

Disease registries for rheumatologic diseases are reviewed separately. (See "COVID-19: Care of adult patients with systemic rheumatic disease", section on 'Disease registries'.)

COVID-19 vaccine reactions — Reactions to COVID-19 vaccines should be reported. Resources for reporting adverse events include:

All adverse events:

Vaccine Adverse Event Reporting System (The United States Centers for Disease Control and Prevention)

Cutaneous adverse events:

COVID-19 Dermatology Registry (American Academy of Dermatology and International League of Dermatologic Societies)

SOCIETY GUIDELINE LINKS — Links to society and government-sponsored guidelines from selected countries and regions around the world are provided separately. (See "Society guideline links: COVID-19 – Index of guideline topics" and "Society guideline links: COVID-19 – Dermatology care".)

INFORMATION FOR PATIENTS — UpToDate offers two types of patient education materials, "The Basics" and "Beyond the Basics." The Basics patient education pieces are written in plain language, at the 5th to 6th grade reading level, and they answer the four or five key questions a patient might have about a given condition. These articles are best for patients who want a general overview and who prefer short, easy-to-read materials. Beyond the Basics patient education pieces are longer, more sophisticated, and more detailed. These articles are written at the 10th to 12th grade reading level and are best for patients who want in-depth information and are comfortable with some medical jargon.

Here are the patient education articles that are relevant to this topic. We encourage you to print or e-mail these topics to your patients. (You can also locate patient education articles on a variety of subjects by searching on "patient info" and the keyword(s) of interest.)

Basics topics (see "Patient education: COVID-19 overview (The Basics)" and "Patient education: COVID-19 vaccines (The Basics)" and "Patient education: COVID-19 and children (The Basics)" and "Patient education: COVID-19 and pregnancy (The Basics)")

SUMMARY AND RECOMMENDATIONS

Cutaneous manifestations of COVID-19 – Multiple skin manifestations have been described in patients with confirmed or suspected severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infection. These include a morbilliform rash; urticaria; pernio-like, acral lesions; livedo-like, vascular lesions; and vesicular, varicella-like eruptions. A severe multisystem inflammatory syndrome with mucocutaneous, systemic, laboratory, and imaging findings of atypical, severe Kawasaki disease has also been reported in children and adolescents with coronavirus disease 2019 (COVID-19). (See 'Cutaneous manifestations of COVID-19' above and "COVID-19: Multisystem inflammatory syndrome in children (MIS-C) clinical features, evaluation, and diagnosis".)

Personal protective equipment and hand hygiene-related dermatoses – Skin injury, mechanical/friction dermatitis, and hand irritant contact dermatitis due to personal protective equipment (PPE) and hand hygiene measures have been reported in the majority of health care workers involved in the care of patients with COVID-19. Use of barrier films or dressings at pressure points of PPE and frequent use of emollients after hand washing may help reduce skin damage and irritation. (See 'Dermatologic conditions related to COVID-19 pandemic' above.)

Impact of the pandemic on dermatologic care – The COVID-19 pandemic has contributed to the need to adjust aspects of dermatologic care. Examples include adjustments in the approach to immunosuppressive treatment, phototherapy, skin cancer treatment, and routine clinical care (see 'Therapeutic considerations during the pandemic' above and 'Delivery of care during the pandemic' above):

Immunosuppressive therapy – The impact of immunosuppressive therapies for dermatologic disease on risk for SARS-CoV-2 infection and risk for complications of COVID-19 is unclear. The decision to continue or start immunosuppressive therapy for dermatologic disease during the pandemic should be made on a case-by-case basis. Examples of important factors to consider include the patient's infection status, the immunosuppressant under consideration, and the impact of treatment cessation on the dermatologic disease and comorbidities (see 'Therapeutic considerations during the pandemic' above):

-Patients without COVID-19 – Given the absence of evidence indicating benefit of discontinuing immunosuppressive therapies in patients without COVID-19, continuation of immunosuppressive therapy for dermatologic disease is considered a safe and appropriate option for this population. The decision to start a new immunosuppressive drug should include careful consideration of potential risks and benefits of therapy. For patients with risk for severe COVID-19, it may be appropriate to defer immunosuppressive treatments in favor of other therapies. (See 'Patients without COVID-19' above.)

-Patients with COVID-19 – Active infection is an accepted indication for discontinuation and avoidance of initiation of immunosuppressive therapies, and some professional organizations, including the American Academy of Dermatology, have issued statements recommending discontinuation of immunosuppressive drugs for cutaneous disease in patients who develop COVID-19. Given the paucity of evidence on risks and benefits of discontinuation, the decision to continue or discontinue immunosuppressive treatment in patients with presumed or confirmed COVID-19 may be made on a case-by-case basis. If discontinued, immunosuppressive therapies may be resumed upon complete recovery from COVID-19. (See 'Patients with presumed or confirmed COVID-19' above.)

Delivery of care – The COVID-19 pandemic has contributed to increased use of telemedicine for routine clinical care. When in-person visits are performed, appropriate infection control precautions should be implemented. (See 'Delivery of care during the pandemic' above.)

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  117. Tagliaferri L, Di Stefani A, Schinzari G, et al. Skin cancer triage and management during COVID-19 pandemic. J Eur Acad Dermatol Venereol 2020; 34:1136.
  118. Der Sarkissian SA, Kim L, Veness M, et al. Recommendations on dermatologic surgery during the COVID-19 pandemic. J Am Acad Dermatol 2020; 83:e29.
  119. Geskin LJ, Trager MH, Aasi SZ, et al. Perspectives on the recommendations for skin cancer management during the COVID-19 pandemic. J Am Acad Dermatol 2020; 83:295.
  120. Zic JA, Ai W, Akilov OE, et al. United States Cutaneous Lymphoma Consortium recommendations for treatment of cutaneous lymphomas during the COVID-19 pandemic. J Am Acad Dermatol 2020; 83:703.
  121. Conforti C, Giuffrida R, Di Meo N, Zalaudek I. Management of advanced melanoma in the COVID-19 era. Dermatol Ther 2020; 33:e13444.
  122. Villani A, Fabbrocini G, Costa C, Scalvenzi M. Patients with advanced basal cell carcinomas in treatment with sonic hedgehog inhibitors during the coronavirus disease 2019 (COVID-19) period: Management and adherence to treatment. J Am Acad Dermatol 2020; 82:e205.
  123. Rice SM, Ferree SD, Mesinkovska NA, Kourosh AS. The art of prevention: COVID-19 vaccine preparedness for the dermatologist. Int J Womens Dermatol 2021; 7:209.
  124. Blumenthal KG, Freeman EE, Saff RR, et al. Delayed Large Local Reactions to mRNA-1273 Vaccine against SARS-CoV-2. N Engl J Med 2021; 384:1273.
  125. McMahon DE, Amerson E, Rosenbach M, et al. Cutaneous reactions reported after Moderna and Pfizer COVID-19 vaccination: A registry-based study of 414 cases. J Am Acad Dermatol 2021; 85:46.
  126. Català A, Muñoz-Santos C, Galván-Casas C, et al. Cutaneous reactions after SARS-CoV-2 vaccination: a cross-sectional Spanish nationwide study of 405 cases. Br J Dermatol 2022; 186:142.
  127. Meara AS, Silkowski M, Quin K, Jarjour W. A Case of Chilblains-like Lesions Post SARS-CoV-2 Vaccine? J Rheumatol 2021; 48:1754.
  128. McMahon DE, Kovarik CL, Damsky W, et al. Clinical and pathologic correlation of cutaneous COVID-19 vaccine reactions including V-REPP: A registry-based study. J Am Acad Dermatol 2022; 86:113.
  129. Johnston MS, Galan A, Watsky KL, Little AJ. Delayed Localized Hypersensitivity Reactions to the Moderna COVID-19 Vaccine: A Case Series. JAMA Dermatol 2021; 157:716.
  130. Fernandez-Nieto D, Hammerle J, Fernandez-Escribano M, et al. Skin manifestations of the BNT162b2 mRNA COVID-19 vaccine in healthcare workers. 'COVID-arm': a clinical and histological characterization. J Eur Acad Dermatol Venereol 2021; 35:e425.
  131. Vaccines and Related Biological Products Advisory Committee Meeting. December 17, 2020. FDA Briefing Document. Moderna COVID-19 Vaccine. https://www.fda.gov/media/144434/download (Accessed on January 23, 2021).
  132. https://www.asds.net/Portals/0/PDF/secure/ASDS-SARS-CoV-2-Vaccine-Guidance.pdf (Accessed on January 28, 2021).
  133. Gresham LM, Marzario B, Dutz J, Kirchhof MG. An evidence-based guide to SARS-CoV-2 vaccination of patients on immunotherapies in dermatology. J Am Acad Dermatol 2021; 84:1652.
  134. Villani A, Scalvenzi M, Fabbrocini G. Teledermatology: a useful tool to fight COVID-19. J Dermatolog Treat 2020; 31:325.
  135. Gupta R, Ibraheim MK, Doan HQ. Teledermatology in the wake of COVID-19: Advantages and challenges to continued care in a time of disarray. J Am Acad Dermatol 2020; 83:168.
  136. Armstrong AW, Chambers CJ, Maverakis E, et al. Effectiveness of Online vs In-Person Care for Adults With Psoriasis: A Randomized Clinical Trial. JAMA Netw Open 2018; 1:e183062.
  137. Price KN, Thiede R, Shi VY, Curiel-Lewandrowski C. Strategic dermatology clinical operations during the coronavirus disease 2019 (COVID-19) pandemic. J Am Acad Dermatol 2020; 82:e207.
  138. Gisondi P, Piaserico S, Conti A, Naldi L. Dermatologists and SARS-CoV-2: the impact of the pandemic on daily practice. J Eur Acad Dermatol Venereol 2020; 34:1196.
  139. Trinidad J, Kroshinsky D, Kaffenberger BH, Rojek NW. Telemedicine for inpatient dermatology consultations in response to the COVID-19 pandemic. J Am Acad Dermatol 2020; 83:e69.
  140. Jakhar D, Kaul S, Kaur I. WhatsApp messenger as a teledermatology tool during coronavirus disease (COVID-19): from bedside to phone-side. Clin Exp Dermatol 2020; 45:739.
  141. Black SM, Ali FR. Secure communication conduits during COVID-19 lockdown. Clin Exp Dermatol 2020; 45:748.
  142. Lee I, Kovarik C, Tejasvi T, et al. Telehealth: Helping your patients and practice survive and thrive during the COVID-19 crisis with rapid quality implementation. J Am Acad Dermatol 2020; 82:1213.
  143. Chen Y, Pradhan S, Xue S. What are we doing in the dermatology outpatient department amidst the raging of the 2019 novel coronavirus? J Am Acad Dermatol 2020; 82:1034.
  144. Elston DM. The coronavirus (COVID-19) epidemic and patient safety. J Am Acad Dermatol 2020; 82:819.
  145. Tao J, Song Z, Yang L, et al. Emergency management for preventing and controlling nosocomial infection of the 2019 novel coronavirus: implications for the dermatology department. Br J Dermatol 2020; 182:1477.
  146. Goldust M, Zalaudek I, Gupta A, et al. Performing dermoscopy in the COVID-19 pandemic. Dermatol Ther 2020; 33:e13506.
  147. Jakhar D, Kaur I, Kaul S. Art of performing dermoscopy during the times of coronavirus disease (COVID-19): simple change in approach can save the day! J Eur Acad Dermatol Venereol 2020; 34:e242.
  148. Mun JH, Park SM, Ko HC, et al. Prevention of possible cross-infection among patients by dermoscopy: a brief review of the literature and our suggestion. Dermatol Pract Concept 2013; 3:33.
Topic 127978 Version 17.0

References

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11 : How Dermatologists Can Learn and Contribute at the Leading Edge of the COVID-19 Global Pandemic.

12 : Cutaneous manifestations in COVID-19: Lessons learned from current evidence.

13 : Cutaneous sıde-effects of the potential COVID-19 drugs.

14 : The American Academy of Dermatology COVID-19 registry: Crowdsourcing dermatology in the age of COVID-19.

15 : The spectrum of COVID-19-associated dermatologic manifestations: An international registry of 716 patients from 31 countries.

16 : Morbilliform exanthem associated with COVID-19.

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19 : Characterization of acute acral skin lesions in nonhospitalized patients: A case series of 132 patients during the COVID-19 outbreak.

20 : Vascular skin symptoms in COVID-19: a French observational study.

21 : Two cases of COVID-19 presenting with a clinical picture resembling chilblains: first report from the Middle East.

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26 : Diversity of clinical appearance of cutaneous manifestations in the course of COVID-19.

27 : Most chilblains observed during the COVID-19 outbreak occur in patients who are negative for COVID-19 on polymerase chain reaction and serology testing.

28 : Do we have serological evidences that chilblain-like lesions are related to SARS-CoV-2? A review of the literature.

29 : Are SARS-CoV-2 IgA antibodies in paediatric patients with chilblain-like lesions indicative of COVID-19 asymptomatic or paucisymptomatic infection?

30 : Negative SARS-CoV-2 PCR in patients with chilblain-like lesions.

31 : Lack of association between pandemic chilblains and SARS-CoV-2 infection.

32 : Type I interferon response and vascular alteration in chilblain-like lesions during the COVID-19 outbreak.

33 : Cutaneous manifestations of COVID-19: a systematic review and analysis of individual patient-level data.

34 : Eruptions and related clinical course among 296 hospitalized adults with confirmed COVID-19.

35 : Long COVID in the skin: a registry analysis of COVID-19 dermatological duration.

36 : Bilateral Chilblain-like Lesions of the Toes Characterized by Microvascular Remodeling in Adolescents During the COVID-19 Pandemic.

37 : Cold and COVID: recurrent pernio during the COVID-19 pandemic.

38 : [Clinical and coagulation characteristics of 7 patients with critical COVID-2019 pneumonia and acro-ischemia].

39 : Histopathological Study of a Broad Spectrum of Skin Dermatoses in Patients Affected or Highly Suspected of Infection by COVID-19 in the Northern Part of Italy: Analysis of the Many Faces of the Viral-Induced Skin Diseases in Previous and New Reported Cases.

40 : Chilblain-like acral lesions during the COVID-19 pandemic ("COVID toes"): Histologic, immunofluorescence, and immunohistochemical study of 17 cases.

41 : SARS-CoV-2 endothelial infection causes COVID-19 chilblains: histopathological, immunohistochemical and ultrastructural study of seven paediatric cases.

42 : Clinical, Laboratory, and Interferon-Alpha Response Characteristics of Patients With Chilblain-like Lesions During the COVID-19 Pandemic.

43 : Are chilblain-like acral skin lesions really indicative of COVID-19? A prospective study and literature review.

44 : Evaluation of Chilblains as a Manifestation of the COVID-19 Pandemic.

45 : Assessment of Acute Acral Lesions in a Case Series of Children and Adolescents During the COVID-19 Pandemic.

46 : Timing of PCR and antibody testing in patients with COVID-19-associated dermatologic manifestations.

47 : Reply to: "A dermatologic manifestation of COVID-19: Transient livedo reticularis".

48 : A dermatologic manifestation of COVID-19: Transient livedo reticularis.

49 : Relapsing symmetric livedo reticularis in a patient with COVID-19 infection.

50 : Cutaneous manifestations in patients with COVID-19: a preliminary review of an emerging issue.

51 : Cutaneous manifestations in SARS-CoV-2 infection (COVID-19): a French experience and a systematic review of the literature.

52 : Complement associated microvascular injury and thrombosis in the pathogenesis of severe COVID-19 infection: A report of five cases.

53 : Thrombotic occlusive vasculopathy in a skin biopsy from a livedoid lesion of a patient with COVID-19.

54 : Urticarial exanthem as early diagnostic clue for COVID-19 infection.

55 : Varicella-like exanthem as a specific COVID-19-associated skin manifestation: Multicenter case series of 22 patients.

56 : Reply to "Varicella-like exanthem as a specific COVID-19-associated skin manifestation: multicenter case series of 22 patients": Discussing specificity.

57 : Clinical and histological characterization of vesicular COVID-19 rashes: a prospective study in a tertiary care hospital.

58 : An outbreak of severe Kawasaki-like disease at the Italian epicentre of the SARS-CoV-2 epidemic: an observational cohort study.

59 : Hyperinflammatory shock in children during COVID-19 pandemic.

60 : Mucocutaneous Manifestations of Multisystem Inflammatory Syndrome in Children During the COVID-19 Pandemic.

61 : Digitate Papulosquamous Eruption Associated With Severe Acute Respiratory Syndrome Coronavirus 2 Infection.

62 : Erythema multiforme-like eruption in patients with COVID-19 infection: clinical and histological findings.

63 : Atypical erythema multiforme palmar plaques lesions due to Sars-Cov-2.

64 : Erythema multiforme-like lesions in children and COVID-19.

65 : COVID-19 can present with a rash and be mistaken for dengue.

66 : Reply to "COVID-19 can present with a rash and be mistaken for dengue": Petechial rash in a patient with COVID-19 infection.

67 : Petechial Skin Rash Associated With Severe Acute Respiratory Syndrome Coronavirus 2 Infection.

68 : Potential effect of blood purification therapy in reducing cytokine storm as a late complication of critically ill COVID-19.

69 : COVID-19 in Children, Pregnancy and Neonates: A Review of Epidemiologic and Clinical Features.

70 : Infants Born to Mothers With a New Coronavirus (COVID-19).

71 : Adverse skin reactions among healthcare workers during the coronavirus disease 2019 outbreak: a survey in Wuhan and its surrounding regions.

72 : Skin damage among health care workers managing coronavirus disease-2019.

73 : The Prevalence, Characteristics, and Prevention Status of Skin Injury Caused by Personal Protective Equipment Among Medical Staff in Fighting COVID-19: A Multicenter, Cross-Sectional Study.

74 : Evaluation of skin problems and dermatology life quality index in health care workers who use personal protection measures during COVID-19 pandemic.

75 : Personal Protective Equipment (PPE) in COVID 19 Pandemic: Related Symptoms and Adverse Reactions in Healthcare Workers and General Population.

76 : Occupational dermatitis to facial personal protective equipment in health care workers: A systematic review.

77 : The Effects of the Face Mask on the Skin Underneath: A Prospective Survey During the COVID-19 Pandemic.

78 : Mask related acne ("maskne") and other facial dermatoses.

79 : COVID-19 related masks increase severity of both acne (maskne) and rosacea (mask rosacea): Multi-center, real-life, telemedical, and observational prospective study.

80 : Mask-induced Koebner phenomenon and its clinical phenotypes: A multicenter, real-life study focusing on 873 dermatological consultations during COVID-19 pandemics.

81 : Behavioral considerations and impact on personal protective equipment use: Early lessons from the coronavirus (COVID-19) pandemic.

82 : Consensus of Chinese experts on protection of skin and mucous membrane barrier for health-care workers fighting against coronavirus disease 2019.

83 : Occupational skin disease among health care workers during the coronavirus (COVID-19) epidemic.

84 : Reply to: "Skin damage among health care workers managing coronavirus disease-2019".

85 : European Task Force on Contact Dermatitis statement on coronavirus disease-19 (COVID-19) outbreak and the risk of adverse cutaneous reactions.

86 : COVID-19 and personal protective equipment: Treatment and prevention of skin conditions related to the occupational use of personal protective equipment.

87 : The role of occupational dermatology in the COVID-19 outbreak.

88 : Frequent handwashing amidst the COVID-19 outbreak: prevention of hand irritant contact dermatitis and other considerations.

89 : Rational hand hygiene during the coronavirus 2019 (COVID-19) pandemic.

90 : Overzealous hand hygiene during the COVID 19 pandemic causing an increased incidence of hand eczema among general population.

91 : COVID-19 and psoriasis: Is it time to limit treatment with immunosuppressants? A call for action.

92 : Should patients stop their biologic treatment during the COVID-19 pandemic.

93 : Should biologics for psoriasis be interrupted in the era of COVID-19?

94 : COVID-19 and immunomodulator/immunosuppressant use in dermatology.

95 : Psoriasis and psoriatic arthritis: How to manage immunosuppressants in COVID-19 days.

96 : The impact of the COVID-19 pandemic on patients with chronic plaque psoriasis being treated with biological therapy: the Northern Italy experience.

97 : Biologics increase the risk of SARS-CoV-2 infection and hospitalization, but not ICU admission and death: Real-life data from a large cohort during red-zone declaration.

98 : No evidence of increased risk for Coronavirus Disease 2019 (COVID-19) in patients treated with Dupilumab for atopic dermatitis in a high-epidemic area - Bergamo, Lombardy, Italy.

99 : Risk of COVID-19 in dermatologic patients receiving long-term immunomodulatory therapy.

100 : Novel Coronavirus Disease (COVID-19) and Biologic Therapy in Psoriasis: Infection Risk and Patient Counseling in Uncertain Times.

101 : Adalimumab for treatment of hidradenitis suppurativa during the COVID-19 pandemic: Safety considerations.

102 : The risk of respiratory tract infections and symptoms in psoriasis patients treated with interleukin 17 pathway-inhibiting biologics: A meta-estimate of pivotal trials relevant to decision making during the COVID-19 pandemic.

103 : Clinical outcomes of COVID-19 in patients taking tumor necrosis factor inhibitors or methotrexate: A multicenter research network study.

104 : TNF-alpha inhibition for potential therapeutic modulation of SARS coronavirus infection.

105 : Inhibition of tumor necrosis factor reduces the severity of virus-specific lung immunopathology.

106 : Reducing mortality from 2019-nCoV: host-directed therapies should be an option.

107 : COVID-19: a case for inhibiting IL-17?

108 : COVID-19: a case for inhibiting IL-17?

109 : COVID-19: a case for inhibiting IL-17?

110 : COVID-19: a case for inhibiting IL-17?

111 : COVID-19: a case for inhibiting IL-17?

112 : COVID-19: a case for inhibiting IL-17?

113 : Immunomodulators and immunosuppressants in the era of SARS-CoV-2 - could laboratory tests be the missing link?

114 : Immunomodulators and immunosuppressants in the era of SARS-CoV-2 - could laboratory tests be the missing link?

115 : Recommendations for phototherapy during the COVID-19 pandemic.

116 : Phototherapeutic approach to dermatology patients during the 2019 coronavirus pandemic: real-life data from the Italian red zone.

117 : Skin cancer triage and management during COVID-19 pandemic.

118 : Recommendations on dermatologic surgery during the COVID-19 pandemic.

119 : Perspectives on the recommendations for skin cancer management during the COVID-19 pandemic.

120 : United States Cutaneous Lymphoma Consortium recommendations for treatment of cutaneous lymphomas during the COVID-19 pandemic.

121 : Management of advanced melanoma in the COVID-19 era.

122 : Patients with advanced basal cell carcinomas in treatment with sonic hedgehog inhibitors during the coronavirus disease 2019 (COVID-19) period: Management and adherence to treatment.

123 : The art of prevention: COVID-19 vaccine preparedness for the dermatologist.

124 : Delayed Large Local Reactions to mRNA-1273 Vaccine against SARS-CoV-2.

125 : Cutaneous reactions reported after Moderna and Pfizer COVID-19 vaccination: A registry-based study of 414 cases.

126 : Cutaneous reactions after SARS-CoV-2 vaccination: a cross-sectional Spanish nationwide study of 405 cases.

127 : A Case of Chilblains-like Lesions Post SARS-CoV-2 Vaccine?

128 : Clinical and pathologic correlation of cutaneous COVID-19 vaccine reactions including V-REPP: A registry-based study.

129 : Delayed Localized Hypersensitivity Reactions to the Moderna COVID-19 Vaccine: A Case Series.

130 : Skin manifestations of the BNT162b2 mRNA COVID-19 vaccine in healthcare workers. 'COVID-arm': a clinical and histological characterization.

131 : Skin manifestations of the BNT162b2 mRNA COVID-19 vaccine in healthcare workers. 'COVID-arm': a clinical and histological characterization.

132 : Skin manifestations of the BNT162b2 mRNA COVID-19 vaccine in healthcare workers. 'COVID-arm': a clinical and histological characterization.

133 : An evidence-based guide to SARS-CoV-2 vaccination of patients on immunotherapies in dermatology.

134 : Teledermatology: a useful tool to fight COVID-19.

135 : Teledermatology in the wake of COVID-19: Advantages and challenges to continued care in a time of disarray.

136 : Effectiveness of Online vs In-Person Care for Adults With Psoriasis: A Randomized Clinical Trial.

137 : Strategic dermatology clinical operations during the coronavirus disease 2019 (COVID-19) pandemic.

138 : Dermatologists and SARS-CoV-2: the impact of the pandemic on daily practice.

139 : Telemedicine for inpatient dermatology consultations in response to the COVID-19 pandemic.

140 : WhatsApp messenger as a teledermatology tool during coronavirus disease (COVID-19): from bedside to phone-side.

141 : Secure communication conduits during COVID-19 lockdown.

142 : Telehealth: Helping your patients and practice survive and thrive during the COVID-19 crisis with rapid quality implementation.

143 : What are we doing in the dermatology outpatient department amidst the raging of the 2019 novel coronavirus?

144 : The coronavirus (COVID-19) epidemic and patient safety.

145 : Emergency management for preventing and controlling nosocomial infection of the 2019 novel coronavirus: implications for the dermatology department.

146 : Performing dermoscopy in the COVID-19 pandemic.

147 : Art of performing dermoscopy during the times of coronavirus disease (COVID-19): simple change in approach can save the day!

148 : Prevention of possible cross-infection among patients by dermoscopy: a brief review of the literature and our suggestion.