Home Mask-related skin changes among healthcare workers in a community-based hospital
Article Open Access

Mask-related skin changes among healthcare workers in a community-based hospital

  • Brittany Valk EMAIL logo , Nedyalko N. Ivanov , Amanda Nahhas , Katie Corwin , Katrina Hansen , Jeff Globerson , Annette LaCasse , William Corser and Lynn Sikorski
Published/Copyright: August 29, 2022
Download Article (PDF)
Journal of Osteopathic Medicine
From the journal Journal of Osteopathic Medicine Volume 122 Issue 12

Abstract

Context

During the COVID-19 pandemic, dermatologists within the Beaumont Farmington Hills’ Dermatology program noticed an increase in conditions associated with mask wearing, such as “maskne” (acne in a mask distribution, thought to be caused by mask wearing), as well as worsening of previously diagnosed dermatologic conditions.

Objectives

The goal of our study was to explore various factors that impacted mask-related skin changes and how these skin changes affected quality of life.

Methods

A cross-sectional study was performed. The primary 10-item survey instrument administered was the Dermatology Life Quality Index (DLQI). Respondents were asked a series of 10 additional questions concerning the degree to which abnormal mask-related skin conditions affect their skin symptoms, possible embarrassment/self-consciousness, and perceived impact of mask-related skin changes. A series of descriptive statistics, cross-tabulation charts, and graphical examinations of data was utilized to evaluate sample subgroup and outcome distributional patterns. Pearson r bivariate correlation coefficients between possible collinear predictive measures on the primary study outcome were calculated. A series of simple inferential chi-squared (Χ2) tests of independence were also conducted.

Results

A total of 370 out of 430 (86.0%) Beaumont Health employees noticed some degree of skin changes since the work-hours face mask requirement was instituted, while 378 out of 430 (87.9%) felt that their skin was better when not wearing a mask. The majority of respondents, 283 (65.8%), reported having at least a little symptomatic skin (i.e., itchy, painful, sore, stinging) during the prior week. Furthermore, 72.3% reported that they were at least a little embarrassed or self-conscious of their skin. Chi-squared analysis of composite DLQI score categories by the number of types of masks utilized (Pearson X2=19.0, df=8, p=0.015), and some degree of symptomatic skin (Pearson X2=156.4, df=4, p<0.001) were found to be statistically significant.

Conclusions

A large number of healthcare workers are affected by mask-related skin changes. Further research should be directed at better understanding how skin changes associated with mask wearing impact one’s quality of life and mental health.

The COVID-19 pandemic is one of the most devastating and unprecedented global health crises of the 21st century [1]. Healthcare workers are at the highest risk of contracting the virus and must take appropriate precautions to protect themselves [2]. Because the virus is thought to spread through respiratory droplets, masks are undoubtedly the most essential piece of personal protective equipment (PPE) [1].

Mask wearing is associated with dermatologic conditions including acne and contact dermatitis [3]. In a cross-sectional study of 20 healthcare workers by Han et al. [1], greater levels of sebum were identified in areas covered by PPE, which could not be explained by circadian changes in sebum levels. The authors also reported increased skin hydration, transepidermal water loss, erythema, and pH [1]. Excessive sebum may contribute to the development of “maskne,” [1] which is acne in a mask distribution, thought to be caused by mask wearing. Increased skin pH leads to changes in the skin microflora, including compromised antimicrobial defenses that promote infection and irritation [1]. In a study of 21 healthy participants, Park et al. [4] similarly reported an increase in skin temperature, redness, hydration, and sebum production after both 1 h and 6 h of mask wearing. Skin redness and increased temperature may be markers for increased skin permeability and inflammation [1]. Changes in the aforementioned skin characteristics promote mask-related skin conditions.

Increased skin hydration increases chemical absorption and enhances susceptibility to allergens and irritants, leading to the development of allergic and irritant contact dermatitis [1]. The perioral area is most commonly affected due to its close approximation to the mouth [4]. Irritants such as friction and mechanical pressure [5] are exacerbated by humidity, leading to a breach in epidermal integrity [6]. Surgical masks and N95s contain formaldehyde and other preservatives that are known culprits of allergic contact dermatitis [2]. Other potential allergens include thiuram in elastic ear straps and dibromodicyanobutane in mask adhesive [5]. Unfortunately, potential allergens are difficult to identify, because chemicals utilized in mask manufacturing are often not disclosed [7].

During the COVID-19 pandemic, dermatologists at Beaumont Farmington Hills noticed an increase in conditions associated with mask wearing, such as maskne, as well as worsening of previously diagnosed dermatologic conditions. The goal of our study was to explore various factors that impacted mask-related skin changes and how these skin changes affected quality of life. We hypothesized that a majority of healthcare workers would report mask-related skin changes that negatively impacted their quality of life.

Methods

Data collection

After IRB approval from the Beaumont Health IRB (IRB#2021-011), the study team observed an “opt in” recruitment method in which only those eligible Beaumont Farmington Hills healthcare workers who actively clicked on the SurveyMonkey [8] link provided to them through the health system’s email system were allowed to enter any study survey responses. The SurveyMonkey [8] software was programmed with both secure socket layers (SSL) and internet protocol security (IPsec) encryption to systematically conceal the identities of all respondents to members of the study team. Each respondent was advised in initial survey instructions that they are asked to avoid providing any identifying information in all survey fields. The study date range was from April 21, 2021 to July 1, 2021.

A cross-sectional survey study was performed. The primary 10-item survey instrument that was administered is the Dermatology Life Quality Index (DLQI) [9], a well-validated Likert-scale survey tool utilized by the team analyst (WC) to generate a composite score of between 0 and 30 points [10]. The composite DLQI score can be utilized to categorize patients into one of five overall categories, ranging from “no effect at all on my life” (0–1 point) through “extremely large effect on my life” (21–30 points) [11]. Respondents were asked a series of 10 additional questions concerning the degree to which abnormal mask-related skin conditions affect their skin symptoms, possible embarrassment/self-consciousness, and perceived impact of mask-related skin changes (Figure 1).

Figure 1: Survey questions. Participants were asked 10 questions regarding mask usage and their associated skin changes.
Figure 1:

Survey questions. Participants were asked 10 questions regarding mask usage and their associated skin changes.

The following eligibility criteria were observed: adults 21 years of age and older; Beaumont Health employees; and regular mask usage during work hours. Children less than 18 years of age and cognitively impaired individuals were excluded.

Minimal sample size calculations

Before data collection was begun for this IRB-approved project, the team analyst utilized G*Power 3.1.94 software [12] to generate a priori minimal sample size calculations for the hypothesized main effect influence of the predominant type of protective mask utilized (i.e., P100/N95/Kn95 vs. surgical/cloth mask) on variations in continuous DLQI composite scores. These calculations indicated that a minimal total sample size of at least 70 discrete respondents (i.e., at least 35 P100/N95/KN95 mask users vs. 35 surgical/cloth mask users) would afford the study team a 0.8005384 1 minus β level of statistical power to detect statistically significant variations between sample subgroups observing a two-tailed coefficient alpha of 0.05 to indicate statistical significance. This sample size was also based on a critical Z estimate for the hypothesized two-tailed influence of mask use subgroup on “moderate effect or higher” composite DLQI scores, as reported by Lan et al. [13] in 2020 (Critical Z=1.9599640).

Data analyses

After IRB approval, author WC conducted all analytic procedures. After cleaning the de-identified SurveyMonkey [8] data from string to numerical form, he created a “working” data set. For analytic procedures, the analyst examined the validity of the study teams’ hypothesized relationships utilizing SPSS Version 27 analytic software [14].

First, a series of descriptive statistics, cross-tabulation charts, and graphical examinations of data were utilized to evaluate sample subgroup and outcome distributional patterns. For most analyses, continuous study measures (e.g., continuous DLQI scores, etc.) were conservatively categorized into sample subgroups as prescribed by the original DLQI designers. Next, a series of Pearson r bivariate correlation coefficients between possible collinear predictive measures on the primary study outcome (i.e., mask-related DLQI score variations of 6 or greater) were utilized [15]. A series of simple inferential chi-squared tests of independence were also conducted [15].

Finally, the predictive significance of each selected measure on the selected dichotomous and categorical outcomes of interest were modeled out during a series of nonparametric (i.e., not based on any normal distribution assumptions) two-tailed forward “stepwise” (i.e., one model term entered at a time, retained if initial p values are less than 0.10) “main effects” multinomial regression procedures [16]. For all analytic procedures, the analyst observed a two-tailed coefficient alpha p value of less than 0.05 to indicate statistical significance.

Results

Mask-related skin changes

A total of 430 Beaumont Health employees completed the questionnaire and DLQI, out of which 62, or 12.6%, were excluded due to incomplete responses. A total of 370 out of 430 (86.0%) noticed skin changes since the work-hours face mask requirement was instituted at Beaumont, while 378 out of 430 (87.9%) felt that their skin was better when not wearing a mask. Among the participants, 167 (38.8%) reported worsening of a pre-existing skin condition in the area covered by the mask, 163 (37.9%) reported starting a new medication (over-the-counter or prescription), while 98 (22.8%) needed a prescription to manage a new or worsening mask-associated skin disorder. Further, 201 (46.7%) researched potential treatment options for mask-related skin changes. The majority, 267 (62.1%), of the respondents wore masks for greater than 31 h per week, with N95 (32.1%), cloth (30.0%), and surgical masks (23.5%) comprising the most reported mask types. The use of two or more total mask types was reported in 249 (57.9%). Many of the respondents, 272 (63.3%), wore the same mask for 1 day or less, whereas 83 (19.3%) wore the same mask for 2–3 days, and 63 (14.7%) wore the same mask for greater than 4 or more days. Responses to the questionnaire regarding mask-related skin changes are summarized in Table 1.

Table 1:

Ten-item survey of mask-related skin changes among beaumont health employees.

Participants (N=430), No. (%)
1. How many hours a day do you wear a mask during the work week? <20 81 (18.8)
20–30 69 (16.0)
31–40 136 (31.6)
>40 131 (30.5)
Missing data 13 (3.0)
2(a). What types of mask(s) do you wear? P100 13 (3.0)
N95 138 (32.1)
KN95 33 (7.7)
Surgical mask 101 (23.5)
Cloth mask 129 (30.0)
Face shield or other/nothing 16 (3.7)
2(b). What is the total number of reported mask types utilized? One 169 (39.3)
Two 134 (31.2)
Three/four 115 (26.7)
Missing data 12 (2.8)
3. How many consecutive days do you wear the same mask? <1 day 98 (22.8)
1 day 174 (40.5)
2 or 3 days 83 (19.3)
4 or more days 63 (14.7)
Missing data 12(2.8)
4. Have you noticed changes in your skin since the work-hours face mask requirement was instituted? Yes 370 (86.0)
No 48 (11.2)
Missing data 12 (2.8)
5. Have you needed a prescription to manage a new or worsening mask-associated skin disorder? Yes 98 (22.8)
No 319 (74.2)
Missing data 13 (3.0)
6. If you had a pre-existing skin condition in the area the mask covers, has this condition worsened? Yes 167 (38.8)
No 241 (56.0)
Missing data 22 (5.1)
7. Have you noticed any bony-cartilage deformation of any skin covered by your mask? Yes 32 (7.4)
No 375 (87.2)
Missing data 23 (5.3)
8. Have you researched or searched for treatment options for mask-related skin changes? Yes 201 (46.7)
No 214 (49.8)
Missing data 15 (3.5)
9. Have you started any new medications (over-the-counter or prescription) to treat a new mask-related skin change? Yes 163 (37.9)
No 254 (59.1)
Missing data 13 (3.0)
10. Do you feel that your skin is better when you are not wearing a mask? Yes 378 (87.9)
No 39 (9.1)
Missing data 13 (3.0)

Dermatology life quality index (DLQI)

The majority of respondents, 283 (65.8%), reported having at least a little symptomatic skin (i.e., itchy, painful, sore, stinging) during the prior week. Furthermore, 311 (72.3%) reported that they were at least a little embarrassed or self-conscious of their skin. Problems caused by the treatment of their skin (i.e., taking up time) were reported in 178 (41.4%) of participants. Sample respondents’ mean DLQI composite scores were 4.5 (SD 4.3), ranging from 0 to 24 on a possible scale from 0 to 30. A DLQI score of 4.5 is interpreted as a small effect on a patient’s life. Due to the extremely nonparametric spread of composite scores with a lower mean DLQI score, our author group observed the DLQI designer’s five categories. Responses to the DLQI are summarized in Table 2.

Table 2:

Dermatology life quality index (DLQI) questionnaire.

Participants (N=430), No. (%)
1. Over the last week, how itchy, sore, painful, or stinging has your skin been? Very much 29 (6.7)
A lot 57 (13.3)
A little 197 (45.8)
Not at all or not relevant 146 (34.0)
Missing data 1 (0.2)
2. Over the last week, how embarrassed or self-conscious have you been because of your skin? Very much 57 (13.3)
A lot 78 (18.1)
A little 176 (40.9)
Not at all or not relevant 119 (27.7)
3. Over the last week, how much has your skin interfered with you going shopping or looking after your home or garden? Very much 6 (1.4)
A lot 14 (3.3)
A little 43 (10.0)
Not at all or not relevant 367 (85.3)
4. Over the last week, how much has your skin influenced the clothes you wear? Very much 7 (1.6)
A lot 20 (4.7)
A little 64 (14.9)
Not at all or not relevant 338 (78.6)
Missing data 1 (0.2)
5. Over the last week, how much has your skin affected any social or leisure activities? Very much 11 (2.6)
A lot 25 (5.8)
A little 112 (26.0)
Not at all or not relevant 282 (65.6)
6. Over the last week, how much has your skin made it difficult for you to do any sport? Very much 4 (0.9)
A lot 4 (0.9)
A little 22 (5.1)
Not at all or not relevant 399 (92.8)
Missing data 1 (0.2)
7. Over the last week, has your skin prevented you from working or studying? A lot 24 (5.6)
A little 154 (35.8)
Not relevant or not relevant 252 (58.6)
8. Over the last week, how much has your skin created problems with your partner or any of your close friends or relatives? Very much 9 (2.1)
A lot 5 (1.2)
A little 70 (16.3)
Not at all or not relevant 346 (80.5)
9. Over the last week, how much has your skin caused any sexual difficulties? Very much 5 (1.2)
A lot 4 (0.9)
A little 36 (8.4)
Not at all or not relevant 383 (89.1)
Missing data 2 (0.5)
10. Over the last week, how much of a problem has the treatment for your skin been, for example, by making your home messy, or by taking up time? Very much 7 (1.6)
A lot 32 (7.4)
A little 139 (32.3)
Not at all or not relevant 252 (58.6)

Chi-squared analysis

Chi-squared (X2) analysis of composite DLQI tertile score (Table 3) by the number of different mask types utilized (Pearson X2=19.0, df=8, p=0.015), and some degree of symptomatic skin (Pearson X2=156.4, df 4, p<0.001), were found to be statistically significant. The number of mask types utilized and experiencing some degree of symptomatic skin were associated with a higher impact on the respondent’s quality of life.

Table 3:

Composite DLQI impact score categories.

Participants (N=430), No. (%)
“No effect at all on patient’s life” (score 0–1) 121 (28.1)
“Small effect on patient’s life” (score 2–5) 171 (39.8)
“Moderate effect on patient’s life” (score 6–10) 90 (20.9)
“Very large effect on patient’s life” (score 11–20) 41 (9.5)
“Extremely large effect on patient’s life” (score 21–30) 3 (0.7)
Missing data 4 (0.9)

Multinomial regression predictive modeling

A multivariate controlled two-tailed multinomial regression predictive modeling procedure was completed to examine for the significance of each respondent mask use characteristic on this categorical DLQI composite score outcome observing the DLQI designer parameters when controlling for respondent characteristics. The number of days the same mask was worn (Wald=22.3, df=12, p=0.035), and some degree of symptomatic skin (Wald=217.1, df=8, p<0.001), reached statistical significance on composite DLQI scores (Table 3). Thus, wearing a mask for a greater number of days and reporting some degree of symptomatic skin was associated with a higher impact on the respondent’s quality of life.

Discussion

Healthcare workers are at an increased risk of developing mask-related dermatoses compared to the general population [17]. A cross-sectional study of 833 participants by Techasatian et al. [17] found longer duration of mask wearing in healthcare workers, more frequent use of surgical masks compared to other types of masks, and increased practice of not changing masks daily compared to non-healthcare workers to be associated with an increased risk of developing mask-related dermatoses. The prevalence of mask-related cutaneous reactions in this study was 454 (54.5%) [17].

In the present study, 86% of participants self-reported changes in their skin since the work-hours face mask requirement was instituted. These findings are similar to the high number of affected respondents reported in previous studies. Lan et al. [13] reported a 97% prevalence of skin damage in a study of 542 first-line healthcare workers. In a study of 322 healthcare workers by Foo et al. [18], 35.5% of medical staff utilizing masks reported adverse reactions. In a study of 43 healthcare workers by Singh et al. [6], 21% of respondents reported work absenteeism secondary to PPE-related dermatoses. These findings implicate that the significance of PPE-induced dermatoses on healthcare workers and healthcare systems cannot be ignored.

A majority of respondents (65.8%) reported at least a little symptomatic skin (i.e., itchy, painful, sore, stinging), and 87.9% of respondents felt that their skin was better when they were not wearing a mask. In the previously mentioned study by Singh et al. [6], pruritus was the most common symptom reported by healthcare worker respondents (67.4%) [6]. Sensitive skin and atopy are significantly associated with increased risk of itch [19]. The risk of mask-induced itch is also related to the presence of pre-existing dermatologic conditions such as atopic dermatitis, seborrheic dermatitis, and acne [19]. Gomolin et al. [20] recommend placing two to three pieces of gauze inside the mask to alleviate mask-induced pruritus. The importance of treating itch cannot be overstated because pruritus negatively impacts psychosocial status [19].

In the present study, 86.0% of our respondents reported skin changes, and almost half (46.7%) of the respondents explored treatment options for these skin changes. Over a third (37.9%) started a new medication to address a facial skin concern, and 22.8% needed a prescription for their maskne. The large proportion of respondents who required treatment highlights the severity of their mask-induced skin changes. In a cross-sectional study of 4,306 healthcare workers by Jiang et al. [21], only 17.7% of respondents utilized preventative measures to protect their skin. Of those who developed skin injuries in the study (42.8% of respondents), 45% utilized hydrocolloid dressing, oil, or cream for treatment [21]. This emphasizes the deficiency in prevention and treatment, and further supports the need for additional education and resources.

Despite the number of publications exploring the factors that contribute to mask-related skin changes, there is a paucity of research investigating how these skin changes impact healthcare workers’ quality of life. As osteopathic-trained dermatologists, we recognize the impact that dermatologic conditions can have on patients’ mental and emotional well-being. It is important that one treats the whole patient when addressing dermatologic complaints, such as acne and atopic dermatitis. Even mild acne can have a negative impact on patients’ quality of life [22].

Sample respondents’ mean DLQI composite score was 4.5 (SD 4.3), reflecting an overall “small effect” ranging from 0 to 24 on a possible scale from 0 through 30. However, the majority of the respondents in our study (72.3%) reported that they were at least a little embarrassed or self-conscious of their skin. In a controlled predictive regression model, the total number of reported mask types was the only statistically significant mask use characteristic on the DLQI. The number of mask types utilized and experiencing some degree of symptomatic skin were associated with a higher impact on the respondent’s quality of life.

We suspect that the total number of mask types is reflective of a respondent’s proximity to combating the COVID-19 virus. A respondent wearing multiple masks may be working long shifts in an environment that is not conducive to removing the mask while at work. Those who wear a mask for greater than 6 h are at the highest risk of developing mask-related skin changes [7]. N95 masks are also associated with more discomfort and mask-induced skin changes compared to surgical masks [2]. Thus, those who wear multiple masks may be at a higher risk of developing mask-related skin changes that impact quality of life. However, this is only inferred, and further research should be directed at this possible association.

Limitations

This study is not without limitations. The data was only collected from one healthcare organization. The cross-sectional design of the study is also a limitation. The lack of demographic data introduces potential confounding factors, including age, gender, and healthcare roles. We recognize that the question “How many hours a day do you wear your mask during the work week?” with options “Less than 20, 20–30, 31–40, and over 40” is poorly worded because there are only 24 h in a day. Our results likely underestimate the effect that mask wearing has on skin conditions among healthcare workers because the survey was distributed to both frontline healthcare workers and those who work in a corporate office setting.

The lack of significant associations between some of the selected study measures on selected study outcomes could be partially attributed to (A) the lack of a sufficient-sized sample to detect meaningful sample subgroup differences; (B) an inadequately heterogeneous sample (e.g., more variation needed among selected measures or outcomes); (C) missing data patterns; and/or (D) perhaps the lack of any possible association to detect in the first place. The study team acknowledges that their results may have been skewed by “preferred response” or self-selection respondent biases. We also recognize that dermatologic conditions and symptoms were self-diagnosed and self-perceived.

Conclusions

In conclusion, our study demonstrated that a large number of healthcare workers at Beaumont Health were affected by mask-related skin changes at the onset of the COVID-19 pandemic. Further research should be directed at better understanding how skin changes associated with mask wearing impact one’s quality of life and mental health. As new variants of the COVID-19 virus emerge, healthcare workers will likely be wearing masks for the foreseeable future. Education is also needed regarding the best practices and prevention strategies of mask wearing to prevent mask-related dermatoses.

Corresponding author: Brittany Valk, DO, Beaumont Health Systems – Department of Dermatology, Farmington Hills Campus, 28050 Grand River Avenue, Farmington Hills, MI 48336, USA, E-mail:

Acknowledgements

The authors would like to thank Evie Russell and Kirsten Gage for their assistance with the IRB process and SharePoint data collection. We would also like to thank Donna McIntyre for her assistance with RedCap.

  1. Research funding: None reported.

  2. Author contributions: All authors provided substantial contributions to conception and design, acquisition of data, or analysis and interpretation of data; B.V., N.I., L.S., W.C., and A.L. drafted the article or revised it critically for important intellectual content; all authors gave final approval for the version of the article to be published; and all authors agree to be accountable for all aspects of the work in ensuring that questions related to the accuracy or integrity of any part of the work are appropriately investigated and resolved.

  3. Competing interests: None reported.

  4. Informed consent: All study participants provided written informed consent prior to participation.

  5. Ethical approval: This study was reviewed and approved by the Beaumont Health IRB (IRB number: 2021-011).

References

1. Han, HS, Shin, SH, Park, JW, Li, K, Kim, BJ, Yoo, KH. Changes in skin characteristics after using respiratory protective equipment (medical masks and respirators) in the COVID-19 pandemic among healthcare workers. Contact Dermatitis 2021;85:225–32. https://doi.org/10.1111/cod.13855.Search in Google Scholar PubMed PubMed Central

2. Hua, W, Zuo, Y, Wan, R, Xiong, L, Tang, J, Zou, L, et al.. Short-term skin reactions following use of N95 respirators and medical masks. Contact Dermatitis 2020;83:115–21. https://doi.org/10.1111/cod.13601.Search in Google Scholar PubMed PubMed Central

3. Kim, J, Yoo, S, Kwon, OS, Jeong, ET, Lim, JM, Park, SG. Influence of quarantine mask use on skin characteristics: one of the changes in our life caused by the COVID-19 pandemic. Skin Res Technol 2021;27:599–606. https://doi.org/10.1111/srt.12992.Search in Google Scholar PubMed PubMed Central

4. Park, SR, Han, J, Yeon, YM, Kang, NY, Kim, E. Effect of face mask on skin characteristics changes during the COVID-19 pandemic. Skin Res Technol 2021;27:554–9. https://doi.org/10.1111/srt.12983.Search in Google Scholar PubMed PubMed Central

5. Bhatia, R, Sindhuja, T, Bhatia, S, Dev, T, Gupta, A, Bajpai, M, et al.. Iatrogenic dermatitis in times of COVID-19: a pandemic within a pandemic. J Eur Acad Dermatol Venereol 2020;34:e563–6. https://doi.org/10.1111/jdv.16710.Search in Google Scholar PubMed PubMed Central

6. Singh, M, Pawar, M, Bothra, A, Maheshwari, A, Dubey, V, Tiwari, A, et al.. Personal protective equipment induced facial dermatoses in healthcare workers managing Coronavirus disease 2019. J Eur Acad Dermatol Venereol 2020;34:e378–80. https://doi.org/10.1111/jdv.16628.Search in Google Scholar PubMed PubMed Central

7. Yu, J, Chen, JK, Mowad, CM, Reeder, M, Hylwa, S, Chisolm, S, et al.. Occupational dermatitis to facial personal protective equipment in health care workers: a systematic review. J Am Acad Dermatol 2021;84:486–94. https://doi.org/10.1016/j.jaad.2020.09.074.Search in Google Scholar PubMed PubMed Central

8. Momentive Inc. SurveyMonkey. San Mateo, CA: Inc (Survey Software); 2020. Available from: www.surveymonkey.com.Search in Google Scholar

9. Finlay, AY, Khan, GK. Dermatology life quality index (DLQI)-a simple practical measure for routine clinical use. Clin Exp Dermatol 1994;19:210–6. https://doi.org/10.1111/j.1365-2230.1994.tb01167.x.Search in Google Scholar PubMed

10. Basra, MK, Fenech, R, Gatt, RM, Salek, MS, Finlay, AY. The dermatology life quality index 1994–2007: a comprehensive review of validation data and clinical results. Br J Dermatol 2008;159:997–1035.10.1111/j.1365-2133.2008.08832.xSearch in Google Scholar PubMed

11. Hongbo, Y, Thomas, CL, Harrison, MA, Salek, MS, Finlay, AY. Translating the science of quality of life into practice: what do dermatology life quality index scores mean? J Invest Dermatol 2005;125:659–64. https://doi.org/10.1111/j.0022-202x.2005.23621.x.Search in Google Scholar

12. Faul, F, Erdfelder, E, Buchner, A, Lang, AG. Statistical power analyses using G*Power 3.1: tests for correlation and regression analyses. Behav Res Methods 2009;41:1149–60. https://doi.org/10.3758/brm.41.4.1149.Search in Google Scholar PubMed

13. Lan, J, Song, Z, Miao, X, Li, H, Li, Y, Dong, L, et al.. Skin damage among health care workers managing coronavirus disease-2019. J Am Acad Dermatol 2020;82:1215–6. https://doi.org/10.1016/j.jaad.2020.03.014.Search in Google Scholar PubMed PubMed Central

14. IBM, Corp Released 20120. IBM SPSS statistics for windows, version 27.0. Armonk, NY: IBM Corp; 2020.Search in Google Scholar

15. Moore, DS, McCabe, GP, Craig, BA. Introduction to the practice of statistics, 9th ed. New York: W H Freeman; 2017.Search in Google Scholar

16. Vittinghoff, E, Shiboski, SC, Glidden, DV, McCulloch, CE. Regression methods in biostatistics: linear, logistic, survival, and repeated measures models. New York: Brooks/Cole, Springer Science+Business Media, Inc; 2012.10.1007/978-1-4614-1353-0Search in Google Scholar

17. Techasatian, L, Lebsing, S, Uppala, R, Thaowandee, W, Chaiyarit, J, Supakunpinyo, C, et al.. The effects of the face mask on the skin underneath: a prospective survey during the COVID-19 pandemic. J Prim Care Community Health 2020;11:2150132720966167. https://doi.org/10.1177/2150132720966167.Search in Google Scholar PubMed PubMed Central

18. Foo, CC, Goon, AT, Leow, YH, Goh, CL. Adverse skin reactions to personal protective equipment against severe acute respiratory syndrome-a descriptive study in Singapore. Contact Dermatitis 2006;55:291–4. https://doi.org/10.1111/j.1600-0536.2006.00953.x.Search in Google Scholar PubMed PubMed Central

19. Szepietowski, JC, Matusiak, L, Szepietowska, M, Krajewski, PK, Bialynicki-Birula, R. Face mask-induced itch: a self-questionnaire study of 2,315 responders during the COVID-19 pandemic. Acta Derm Venereol 2020;100:adv00152. https://doi.org/10.2340/00015555-3536.Search in Google Scholar PubMed PubMed Central

20. Gomolin, TA, Cline, A, Russo, M. Maskne: exacerbation or eruption of acne during the COVID-19 pandemic. J Cutan Med Surg 2020;4:438–9. https://doi.org/10.25251/skin.4.5.7.Search in Google Scholar

21. Jiang, Q, Song, S, Zhou, J, Liu, Y, Chen, A, Bai, Y, et al.. 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. Adv Wound Care 2020;9:357–64. https://doi.org/10.1089/wound.2020.1212.Search in Google Scholar PubMed PubMed Central

22. Rocha, MA, Begatin, E. Adult-onset acne: prevalence, impact, and management challenges. Clin Cosmet Invest Dermatol 2018;11:59–69. https://doi.org/10.2147/ccid.s137794.Search in Google Scholar
Received: 2022-05-10
Accepted: 2022-08-04
Published Online: 2022-08-29

© 2022 the author(s), published by De Gruyter, Berlin/Boston

This work is licensed under the Creative Commons Attribution 4.0 International License.

Articles in the same Issue

  1. Frontmatter
  2. Cardiopulmonary Medicine
  3. Case Report
  4. Safe endovascular retrieval of a vena cava filter after duodenal perforation
  5. General
  6. Original Article
  7. Mask-related skin changes among healthcare workers in a community-based hospital
  8. Medical Education
  9. Original Article
  10. The effect of the COVID-19 pandemic on osteopathic education in ACGME-OR residencies from February 2020 to February 2021
  11. Musculoskeletal Medicine and Pain
  12. Original Article
  13. Pain and functional recovery from chronic low back pain over 12 months: implications for osteopathic medicine
  14. Case Report
  15. Chronic exertional compartment syndrome in a patient with restrictive cardiomyopathy and portal hypertension
  16. Public Health and Primary Care
  17. Original Article
  18. Casirivimab/imdevimab treatment for outpatient COVID-19 during a SARS-CoV-2 B1.617.2 (Delta) surge at a community hospital
  19. Clinical Images
  20. The groove sign
  21. Acute pericarditis confirmed by coronary computed tomography angiogram
  22. Subcutaneous Sweet’s syndrome: a rare subtype of acute febrile neutrophilic dermatosis
  23. Abstracts
  24. 2022 AOA Research Abstracts and Poster Competition
https://doi.org/10.1515/jom-2022-0097
Creative Commons
BY 4.0

Articles in the same Issue

  1. Frontmatter
  2. Cardiopulmonary Medicine
  3. Case Report
  4. Safe endovascular retrieval of a vena cava filter after duodenal perforation
  5. General
  6. Original Article
  7. Mask-related skin changes among healthcare workers in a community-based hospital
  8. Medical Education
  9. Original Article
  10. The effect of the COVID-19 pandemic on osteopathic education in ACGME-OR residencies from February 2020 to February 2021
  11. Musculoskeletal Medicine and Pain
  12. Original Article
  13. Pain and functional recovery from chronic low back pain over 12 months: implications for osteopathic medicine
  14. Case Report
  15. Chronic exertional compartment syndrome in a patient with restrictive cardiomyopathy and portal hypertension
  16. Public Health and Primary Care
  17. Original Article
  18. Casirivimab/imdevimab treatment for outpatient COVID-19 during a SARS-CoV-2 B1.617.2 (Delta) surge at a community hospital
  19. Clinical Images
  20. The groove sign
  21. Acute pericarditis confirmed by coronary computed tomography angiogram
  22. Subcutaneous Sweet’s syndrome: a rare subtype of acute febrile neutrophilic dermatosis
  23. Abstracts
  24. 2022 AOA Research Abstracts and Poster Competition
Sign up now to receive a 20% welcome discount
Institutional Access
How does access work?
Have an idea on how to improve our website?
Please write us.
© 2025 De Gruyter Brill
Downloaded on 26.9.2025 from https://www.degruyterbrill.com/document/doi/10.1515/jom-2022-0097/html
Scroll to top button