Dermatology: Practical and Conceptual


Original Article | Dermatol Pract Concept. 2022;12(2):e2022091 1

Dermatology Practical & Conceptual

Association of Flame-Retardant Clothing With 
Mycosis Fungoides: A Retrospective Analysis

Katherine E. Park1, Vignesh Ramachandran2, Jessica Tran3, Tejas P. Joshi4, Naveen Garg5, 
Madeleine Duvic3

1 Department of Dermatology, University of New Mexico School of Medicine, Albuquerque, New Mexico, USA

2 Department of Dermatology, New York University Grossman School of Medicine, New York, New York, USA

3 Department of Dermatology, University of Texas, MD Anderson Cancer Center, Houston, Texas, USA

4 School of Medicine, Baylor College of Medicine, Houston, Texas, USA

5 Department of Radiology, University of Texas, MD Anderson Cancer Center, Houston, Texas, USA

Key words: mycosis fungoides, cutaneous T-cell lymphoma, flame-retardant clothing, flame-retardant chemicals, occupational-related 
exposure

Citation: Park KE, Ramachandran V, Tran J, Joshi TP, Garg N. Association of Flame-Retardant Clothing with Mycosis Fungoides: A 
Retrospective Analysis. Dermatol Pract Concept. 2022;12(2):e2022091. DOI: https://doi.org/10.5826/dpc.1202a91

Accepted: October 21, 2021; Published: April 2022

Copyright: ©2022 Park KE et al. This is an open-access article distributed under the terms of the Creative Commons Attribution-
NonCommercial License (BY-NC-4.0), https://creativecommons.org/licenses/by-nc/4.0/, which permits unrestricted noncommercial use, 
distribution, and reproduction in any medium, provided the original authors and source are credited.

Funding: None.

Competing interests: None.

Authorship: All authors have contributed significantly to this publication

Corresponding author: Tejas P. Joshi, BS School of Medicine Baylor College of Medicine, One Baylor Plaza, Houston, TX, USA.  
E-mail: tejas.joshi@bcm.edu

Introduction: Mycosis fungoides (MF), the most prevalent form of cutaneous T-cell lymphoma 
(CTCL), has been associated with a variety of environmental and occupational exposures. Flame-re-
tardant clothing (FRC), in contrast to flame-resistant clothing, is chemically treated and may constitute 
a previously unrecognized occupational hazard. 

Objectives: To report an association between FRC and MF. 

Methods: After encountering several young male patients whose onset of MF coincided with the oc-
cupational use of FRC and occupation as fire fighters, we did a retrospective search. Additional biopsy 
proven MF patients with use of FRC were identified by the EPIC electronic medical record using the 
search terms “CTCL, mycosis fungoides, flame, and flame-retardant.”

Results: Eight MF patients, all males, ranging in age from 31 years to 64 years (median age, 35 years) 
with exposure to FRC were identified. MF remission was noted in three patients who discontinued 
FRC use and in one patient who used a cotton undershirt barrier, while disease persistence was noted 
in one patient who continued to use FRC.  

Conclusions: FRC appears to be associated with development of MF through chronic antigen stimu-
lation. Use of FRC is an occupational hazard for fire fighters. Any patient whose MF coincides with 
use of FRC should avoid further exposure through avoidance or switching to clothing made from 
inherently flame-resistant fibers. 

ABSTRACT



2 Original Article | Dermatol Pract Concept. 2022;12(2):e2022091

Introduction

Mycosis fungoides (MF), the most common form of cuta-

neous T-cell lymphoma (CTCL), is characterized initially by 

eczematous skin lesions containing clonal epidermotropic 

memory CD4+ T-cells [1]. Tan et al first suggested that MF is 

a disease of “chronic antigen   stimulation” but the “antigen” 

is unknown [2]. Our finding of significant HLA-DR5 and 

DQ-301 associations with MF also supports the possibility 

of antigen restriction [3] (MF. As in other non-Hodgkin lym-

phomas, increased rates of MF have also been reported in 

association with occupational exposures to Agent Orange, 

aromatic hydrocarbons, and pesticides [4,5]. There have 

also been several reports of non-random clustering of MF, 

which further implicate possible environmental or occupa-

tional exposure as triggers for MF [6–8]. Moreover, we have 

demonstrated the presence of geographic hot spots in Texas, 

a finding consistent with the hypothesis that MF is triggered 

by particular exposures [9,10]. 

If occupation-related exposure is associated with in-

creased MF risk, then it may result from chronic antigenic 

exposure to skin and inherent immune system-altering 

properties of the compounds [11]. Occupations previously 

reported to be associated with MF include painters, fire 

fighters, the military, and oil and chemical plant workers, 

which require specific workplace attire such as flame-re-

tardant clothing (FRC). Unlike flame-resistant clothing 

which is made of inherently flame-resistant fibers, FRC 

is chemically treated and may be worn against the skin. 

While the specific chemicals used vary by manufacturers, 

historically these have included compounds such as bromi-

nated and chlorinated flame-retardants, as well as formal-

dehyde-based flame-retardants [12]. Many flame-retardant 

chemicals have been banned or voluntarily withdrawn from 

the market; however, they have been replaced with other 

brominated flame retardants. Previous studies have shown 

brominated and chlorinated flame retardants to be asso-

ciated with adverse health effects, including reproductive 

toxicity, neurologic impairment, hormonal disturbances, 

and cancer [13–15]. The Epilymph study, a multicenter 

case-control study, demonstrated a significantly increased 

risk of mature B-cell lymphomas in patients exposed to bro-

minated flame retardants [16].  

Objectives

After encountering 3 young males who presented with early 

MF lesions in areas where their skin was chronically ex-

posed to FRC, we performed a retrospective search. We 

report a case series of 8 patients who used FRC prior to 

developing MF and whose MF improved when FRC was no 

longer worn.

Methods

A retrospective chart review approved by the MD Anderson 

Institutional Review Board was performed by Dr. Naveen 

Garg at the University of Texas MD Anderson Cancer Center 

(MDACC) to identify and investigate MF patients with a his-

tory of exposure to FRC. All patients were seen by a CTCL 

expert dermatologist (Dr. Duvic) between May 1, 2009 and 

May 31, 2019. Inclusion criteria for this study were a patient 

age of 18 years or older, biopsy-proven MF confirmed by 

expert CTCL dermatopathologists at MDACC, and current/

prior exposure to FRC. Patients with use of FRC were iden-

tified by searching the EPIC electronic medical record using 

the Garg Lab search method to create the study population 

[17]. Search terms included “CTCL, mycosis fungoides, 

flame, and flame-retardant.” Eight patients met the inclusion 

criteria. Descriptive and demographic data were collected 

for each patient including demographics (age and sex), stage 

at presentation, location of skin involvement, treatment his-

tory, response to treatment, and length of follow-up.

Results

We identified 8 patients with MF who had worn FRC (Table 1). 

 All patients were men and ranged in age from 31 to 64 years 

(median, 35 years). We were unable to determine the exact 

brand of FRC used in 7 patients, although 1 patient (case #2) 

recalled having used “Bulwark” brand FRC. Three patients 

were diagnosed with stage IA MF, 3 with stage IB MF, 1 with 

stage IIB MF, and 1 with stage IIIB MF (erythroderma with 

blood involvement). Body surface area involvement ranged 

from 0.25% to 97% (median, 18.95%). In 4 patients, we 

were able to ascertain the period of FRC use preceding lesion 

appearance: 2 patients (cases #2 and #8) had worn FRC for 

2 years prior to development of MF; the other 2 patients had 

worn FRC for 3(case #1) and 4 (case #4) years before devel-

oping MF. The sequential nature of MF onset after a median 

of 2.5 years of starting FRC use is suggestive of a causal link 

between MF and cutaneous exposure to FRC. Unfortunately, 

we were unable to assess the exact duration of FRC use prior 

to MF development in any of the remaining four patients.  

Three patients (cases #1, 2 and 4) who discontinued use 

of FRC achieved near complete remission of MF with only 

minimal adjunctive treatment (natural UVB and topical tri-

amcinolone); 1 patient witnessed partial MF resolution after 

discontinuing FRC and complete regression following radia-

tion therapy. One patient (case #5), who continued to wear 

FRC required by his job, had complete remission of his MF 

by using a cotton undershirt barrier. One patient (case #3) 

continued to wear FRC without any barrier and has per-

sistent disease. The remission of disease in patients who dis-

continued FRC, and the persistence of malignancy in the 1 



Original Article | Dermatol Pract Concept. 2022;12(2):e2022091 3

Table 1. Mycosis Fungoides patients with a history of exposure to flame-retardant chemicals

Case 
No.

Age, 
Sex HPI

Rash 
Location

Initial 
Stage/

BSA
Topical 
steroid

Other 
Interventions

Cessation 
of FRC Follow-up

1 31, M 3 yr history of pink to 
light brown patches 
beginning after 
starting work at an oil 
refinery where he used 
FRC

Popliteal 
fossa, hips, 
flanks, and 
groin

IB/18.95% Y NS Y 6 mo

2 48, M 2 yr history of 
hypopigmented 
patches starting 2 yrs 
after beginning to 
wear Bulwark FRC

Arms, lower 
abdomen, 
thighs

IA/4.5% Y NB-UVB Y 1 yr

3 35, M Hyper- and 
hypopigmented 
patches with atrophy 
and telangiectasias of 
unknown duration 
recently diagnosed as 
MF; current FRC use

Axilla, hips, 
thighs, 
buttocks

IB/15% Y NS N 1.5 yrs

4 31, M 4 yr history of 
erythematous scaly 
patch located where 
flame-retardant 
harness rubbed 

Thigh IA/0.25% Y UV-B Y 2 yr

5 47, M 10 yr history of 
“psoriasis,” 4 yr 
history of exposure 
to flame retardant 
clothing; wears cotton 
undershirt after 
previous urticarial 
reaction to FRC

Scalp, arms, 
trunk, legs

IB/54% Y PUVA, topical 
nitrogen 
mustard

Cotton 
undershirt 
barrier

13 yrs

6 35, M History of flame-
retardant exposure 
since age 18 with 
erythematous patches 
diagnosed as MF at 
OSH; presented with 
unrelated rash

Dorsal feet IA/% 
unknown

Unknown PUVA Unknown 6 mos at 
OSH

7 64, M 4 yr history of 
erythematous patches 
with desquamation 
initially on lower 
legs with previous 
exposure to FRC 

Generalized IIIB/97% Y ECP, 
Bexarotene 
225 mg

Unknown 5 mo

8 35, M 10 yr history of 
erythematous patches, 
plaques, and tumors 
that began 2 yrs after 
starting job with 
exposure to FRC and 
gamma-radiation

Head, 
trunk, and 
extremities

IIB/48% Y TSEB; 
bexarotene 
300 mg

Y 3 mo

BSA = body surface area; FRC = Flame-retardant clothing; M = male; N = no; No = number; NS = natural sunlight; ECP = Extracorporeal 
photopheresis; TSEB = total skin electron beam; PUVA = psoralen + ultraviolet A; NB-UVB = narrow band ultraviolet B; OSH = outside 
hospital; Y = yes; yr = year.



4 Original Article | Dermatol Pract Concept. 2022;12(2):e2022091

patient who continued FRC use, further implicate FRC as the 

trigger for MF induction.  

While we are unable to exclude the possibility that other 

factors (eg environmental and occupational exposures inde-

pendent of FRC use) could have also initiated MF in our 

patients, the distribution of lesions in sun shielded areas 

in most of our patients is also consistent with FRC use (al-

though it should be noted that presentation of MF lesions 

in sun shielded areas is also common in MF not associated 

with FRC). Seven of the 8 patients (cases #1-5, 7-8) we re-

port had MF lesions in skin regions that directly contacted 

FRC, suggesting that FRC exposure to the skin may have 

induced malignancy of skin resident T-cells. Notably, patient 

#4 reported a history of an erythematous scaly patch on the 

thigh at the exact location where the FRC harness rubbed, 

further strengthening the association between FRC and MF. 

Altogether, considering the temporal and spatial nature of 

the association between MF and FRC, we suggest that FRC 

could be the offending agent in the development of MF in 

our patients. Of note, treatment with topical steroids and 

UVB therapy was successful in producing remissions in ear-

ly-stage IA or IB patients; MF did not recur following re-

moval of the clothing and topical therapy. 

Conclusions

Although the precise mechanism(s) through which FRC 

could have induced MF in our patients is unclear, we spec-

ulate that chemicals in FRC may have been absorbed in ex-

posed skin causing mutations in T-cells or acting as antigens 

driving T-cell proliferation. Indeed, dermal absorption of 

flame retardants has been demonstrated in both in vitro and 

human studies [18,19]. Additionally, there have been other 

reports of undefined skin rashes associated with FRC which 

could have been undiagnosed MF [13,14,20]. Moreover, our 

proposed explanation of MF induction is consistent with the 

paradigm of MF pathogenesis first suggested by Tan et al, 

who first hypothesized that MF results from persistent an-

tigen stimulation [2]. Although we did not have the means 

to conduct a patch test for FRC components, we note that 

a positive patch test would have lent further support to our 

hypothesis of antigen stimulation. Patch testing for evalua-

tion of future MF patients with history of exposure to FRC 

may be suggested to further elucidate the mechanism of MF 

induction by FRC. 

FRC use appears to be associated with MF and may 

be an unrecognized occupational hazard for firefighters or 

other chronically exposed individuals. Patients who develop 

suspicious rashes in areas of contact with FRC should have 

skin biopsies for diagnosis. Patients with MF coinciding with 

FRC use should limit further exposure through avoidance or 

switching to clothing made from inherently flame-resistant 

fibers. Newer inherently flame-resistant clothing alternatives 

use next-generation polymers and fibers rather than chemi-

cal flame-retardants. Additionally, unlike FRC, clothing from 

inherently flame-resistant fibers does not lose efficacy with 

repeated washes [21], and therefore represents both a safer 

and more economical option compared to FRC. 

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