Abstract
Aim
Mycosis fungoides [(MF)— the most common primary cutaneous T-cell lymphoma —] is difficult to diagnose early, and treatment access is uneven in middle-income settings; therefore, we aimed to describe current practice, identify barriers, and propose guideline-aligned, resource-adapted solutions.
Materials and Methods
Cross sectional anonymous online survey of dermatologists (May–June 2025) on diagnostic workflows/access, treatments, and barriers. Analyses were performed using SPSS v23, with descriptive statistics and Spearman’s rho correlations. Two-tailed P < 0.05 was considered significant.
Results
Among 239 respondents, 61.1% managed MF; 49.3% reported diagnostic uncertainty, and T cell receptor testing was rarely available. The use of diagnostic algorithms and structured training was inconsistent. Basic topical agents and retinoids were widely available, whereas advanced systemic and device-based options were scarce. Barriers clustered around registration and market availability, workforce constraints, and equipment and maintenance issues. Reported workarounds included evidence-based substitutions, interim symptom-directed therapy, repeat biopsies, and referrals; multidisciplinary tumor boards were underused.
Conclusion
MF care is heterogeneous and resource constrained. A four-component plan — a national diagnostic algorithm with a minimum package and a re-biopsy–consultation–multidisciplinary team loop; targeted capacity building; tiered treatment pathways prioritizing narrow-band ultraviolet B ± retinoids with clear referral thresholds; and system integration via centers of excellence, a national registry, and device uptime programs — may standardize care and improve outcomes.
INTRODUCTION
Mycosis fungoides (MF) is the most common form of primary cutaneous T-cell lymphoma (CTCL), representing the majority of CTCL cases worldwide.¹ It typically presents as slowly evolving erythematous or mildly pigmented, atrophic patches in sun-protected sites and may progress to infiltrated plaques, tumors, or erythroderma in advanced stages.1, 2 MF displays substantial clinicopathologic heterogeneity, making early diagnosis difficult. Lesions may mimic other dermatoses, such as eczema, psoriasis, or chronic dermatitis, and histopathologic findings are often non-specific.3, 4 In this context, clinicopathological correlation, supported by immunophenotyping and, where available, molecular testing, is essential, and multiple international guidelines recommend a multimodal diagnostic approach. However, real-world adherence to these recommendations varies widely depending on access to diagnostic resources, specialist expertise, and healthcare infrastructure.
Since accurate diagnosis forms the foundation for disease staging and staging is the principal determinant of treatment selection, these processes are intrinsically linked to ensuring optimal MF care. Early-stage disease is generally approached with skin-directed therapies, while advanced stages often require systemic agents, frequently in combination with skin-directed therapies for symptom control.5-7 The therapeutic hierarchy outlined in international guidelines is supported by systematic reviews and meta-analyses, which confirm the efficacy of these modalities but also reveal substantial variation in patient outcomes and treatment availability across healthcare systems.8-10 Such differences are often shaped by disparities in access to advanced diagnostic tools, limitations in the availability of systemic therapies, and inconsistent application of guideline-based protocols, all of which may lead to delays in diagnosis and deviations from evidence-based management.
We hypothesized that significant variability exists in both diagnostic and therapeutic practices for MF, shaped by disparities in resource availability and guideline implementation. To investigate this, we conducted a nationwide, cross-sectional survey among dermatologists in a middle-income country with universal health coverage, aiming to identify current practice patterns, barriers to optimal care, and locally adapted solutions to improve MF management within existing resource constraints.
MATERIALS AND METHODS
Survey Design
This cross-sectional, questionnaire-based study was conducted between May and June 2025 to evaluate current challenges and potential solutions regarding diagnosis and access to treatment for MF among dermatologists in Türkiye. The survey instrument was developed by the study team. It consisted of qualitative and quantitative items, including open-ended, multiple-choice, and multiple-selection questions. The questionnaire aimed to investigate dermatologists’ clinical experience with MF, diagnostic approaches, access to diagnostic modalities (e.g., histopathology, immunohistochemistry, molecular testing), treatment preferences (topical or device-based skin-directed therapies, systemic therapies), and barriers encountered in treatment access (e.g., reimbursement, availability, institutional limitations). Institutions were classified by service scope and technical capacity; rankings were based on technical resources, patient volume, and academic staff, in the following order: University Hospital, Training and Research Hospital, City Hospital, State Hospital, and Private Clinic. The content of the questionnaire is presented in Supplementary Table 1. The final version of the questionnaire was created using Google Forms. A survey link was generated and disseminated to Turkish dermatologists through dermatology-focused professional WhatsApp and Facebook groups on three separate occasions at two-week intervals, to enhance response rates and ensure representative participation.
Participants
The target population comprised dermatologists actively practicing in Türkiye who manage patients with MF in various clinical settings. Informed consent was obtained digitally prior to survey participation. The first page of the online survey included an information section outlining the purpose of the study, data use, and confidentiality. Only participants who provided digital consent could proceed to complete the remaining parts of the questionnaire. Respondents not managing MF patients were included only in descriptive analyses; items requiring direct MF management experience were analyzed within the subgroup actively managing MF.
Statistical Analysis
All responses were collected anonymously. Data were exported to IBM SPSS Statistics version 23 for analysis. Descriptive statistics were used to summarize the data, with categorical variables presented as frequencies and percentages. Correlations between ordinal variables were assessed using Spearman’s rank correlation coefficient (rho). All statistical tests were two-tailed, and a P-value < 0.05 was considered statistically significant.
RESULTS
Participant Characteristics
A total of 239 dermatologists participated in the study. Figure 1 shows the distribution of participants by gender, professional experience, institution type, and academic title. Among them, 38.9% (n = 93) did not manage MF patients, most often due to inadequate technical resources (57.0%, n = 53), a preference to refer patients to specialized centers (43.0%, n = 40), no MF patient admissions (32.3%, n = 30), limited clinical experience (10.8%, n = 10), or lack of interest in MF care (7.5%, n = 7).
The remaining 61.1% (n = 146) reported actively managing MF patients. Most followed 0–5 patients annually (35.6%, n = 52), followed by 6–10 patients (22.6%, n = 33), 11–20 patients (13.7%, n = 20), and > 20 patients (28.1%, n = 41). Patient volume correlated positively with years of clinical experience (Spearman’s ρ = 0.45, P < 0.001). In daily practice, participants primarily referenced European Organisation for Research and Treatment of Cancer (EORTC) guidelines (35.6%, n = 52), National Comprehensive Cancer Network (NCCN) guidelines (30.8%, n = 45), or national experience (21.2%, n = 31), with relatively similar proportions across these three sources.
Diagnostic Approaches, Challenges, and Solutions
Figure 2 summarizes the reported diagnostic modalities. Clinical examination, multiple or repeat biopsies, and basic immunohistochemistry were used by more than 85% of respondents, whereas advanced tests, such as human T-cell lymphotropic virus-1/2 serology and T-cell receptor (TCR) gene rearrangement, were rarely or never applied.
Diagnostic challenges were common: 49.3% (n = 72) reported diagnostic uncertainty, and 41.1% (n = 60) did not use diagnostic algorithms or were unfamiliar with them. The most frequent obstacles were non-specific histopathology (79.5%, n = 116), atypical presentations (54.8%, n = 80), and clinicopathological discrepancies (51.4%, n = 75). Other reported barriers included pathologist inexperience (48.6%, n = 71) and limited access to advanced molecular techniques (19.2%, n = 28).
When facing such challenges, dermatologists most often performed clinical re-evaluation at follow-up (72.6%, n = 106) or performed repeated biopsies (69.9%, n = 102). Other strategies included symptomatic or topical treatment (49.3%, n = 72), pathology consultation (37.7%, n = 55), multidisciplinary discussion (19.2%, n = 28), and referral to specialized centers (24.7%, n = 36). The specific links between diagnostic barriers and adopted solutions are illustrated in Figure 3.
Therapeutic Accessibility Challenges and Solutions
Treatment accessibility varied by category, as demonstrated in Figure 4. Among topical agents, corticosteroids (99.3%, n = 145), tacrolimus (89.7%, n = 131), pimecrolimus (88.4%, n = 129), and topical bexarotene (82.2%, n = 120) were widely available, while mechlorethamine (2.1%, n = 3) and carmustine (0.7%, n = 1) were rarely or never accessible.
Among participants, 78.5% (n = 117) had an active phototherapy unit; narrowband ultraviolet B was universally available in these centers (100.0%, n = 117), whereas psoralen ultraviolet A (PUVA) (41.9%, n = 49), ultraviolet A1 (17.1%, n = 20), and excimer laser (8.5%, n = 10) were less common. Radiotherapy was accessible to 43.8% (n = 64) of respondents, whereas total skin electron beam therapy (TSEBT) (12.3%, n = 18) and photodynamic therapy (PDT) (5.5%, n = 8) were accessible to only a minority.
Among systemic therapies, acitretin (100.0%, n = 146) and methotrexate (97.9%, n = 143) were almost universally accessible; bexarotene was moderately accessible (50.7%, n = 74); and advanced agents such as brentuximab vedotin (28.1%, n = 41), pegylated interferon alfa-2a (17.1%, n = 25), vorinostat (9.6%, n = 14), and mogamulizumab (5.5%, n = 8) were rarely or never accessible.
Reported barriers to access included lack of product registration (80.0%, n = 120), market unavailability (75.0%, n = 112), and limited clinical experience (60.0%, n = 90) for topical agents; lack of personnel (70.0%, n = 100) or device malfunction (65.0%, n = 93) for phototherapy; and lack of knowledge/experience (55.0%, n = 80) or market unavailability (50.0%, n = 73) for systemic treatments.
Accessibility limitations often led dermatologists to use alternative therapies (70.5%, n = 103) or to refer patients to better-equipped centers (57.5%, n = 84), with referral decisions guided by proximity to those centers, academic expertise, and technical capacity. Less common strategies included off-label or non-standardized treatments (6.8%, n = 10), observational management (4.8%, n = 7), and enrollment in clinical research (4.1%, n = 6). Table 1 summarizes selected treatment pathway modifications compared with major international guidelines, indicating whether these reflect guideline-endorsed alternatives, shifts in emphasis, or adaptations primarily driven by local clinical practice.
DISCUSSION
In this study, we evaluated differences in the implementation of diagnostic and therapeutic practices for MF among dermatologists and across centers. The results of this nationwide survey revealed substantial variability in MF diagnosis and treatment among dermatologists, with significant gaps in access to advanced diagnostic tools and therapies, frequent use of basic modalities, and adaptations in clinical practice driven by resource limitations, variable local expertise, and the absence of national guidelines.
Almost half of the respondents reported diagnostic uncertainty in MF, primarily due to non-specific histopathology and clinicopathological discrepancies. In early MF lesions, the alignment of atypical lymphocytes along the basal layer of the epidermis, the presence of numerous neoplastic lymphocytes in the epidermis, accompanied by minimal spongiosis, and papillary dermal fibrosis with characteristic wire bundle–like collagen fibers may be absent.11 Atypical clinical presentations were another important cause of diagnostic difficulties for dermatologists diagnosing MF. The difficulty in considering MF among preliminary clinical diagnoses stems from its ability to mimic a broad spectrum of dermatoses, ranging from common inflammatory conditions such as atopic dermatitis and psoriasis to infectious and granulomatous diseases.12 Similar diagnostic pitfalls have been described in multiple studies in which both dermatologists and dermatopathologists have faced challenges in differentiating early MF from benign inflammatory dermatoses in the absence of sufficient experience and repeated clinicopathological correlation.13
The survey results showed that 40% of dermatologists reported being unfamiliar with diagnostic algorithms. This finding highlights the need for wider implementation of algorithm-based approaches and points to a gap in training. In 2005, the International Society for Cutaneous Lymphomas proposed a diagnostic algorithm to improve the early diagnosis of MF. This algorithm includes four criteria: clinical findings, histopathological features, immunohistochemical results, and TCR gene rearrangement.14 Despite its high sensitivity, the algorithm’s utility in clinical practice may be limited by its relatively low specificity.15 The relatively high proportion of participants unfamiliar with diagnostic algorithms underscores a gap in structured diagnostic training, echoing the literature’s call for wider implementation of standardized workflows and algorithm-based approaches.16, 17
Limited access to advanced diagnostic tools, including TCR testing and comprehensive immunohistochemistry panels, represents a major barrier to the implementation of diagnostic algorithms in routine clinical practice, particularly in middle-income healthcare systems. In our study, the absence of TCR gene rearrangement testing likely reflects restricted access to specialized molecular laboratories and reimbursement constraints rather than indicating a lack of clinical relevance. This limitation may contribute to persistent diagnostic uncertainty, especially in early-stage disease, and hinder the full application of multimodal diagnostic approaches in real-world settings.
Evidence suggests that targeted investment in diagnostic infrastructure and specialist training can significantly enhance early-stage diagnostic accuracy. These findings strengthen the case for developing a national MF guideline aligned with established frameworks such as EORTC, NCCN, and British Association of Dermatologists guidelines,5-7 but adapted to local realities using structured approaches.18
Treatment accessibility patterns in our data showed frequent use of guideline-consistent substitutions, including replacing oral bexarotene with acitretin or isotretinoin.5-7 However, other observed modifications, such as early introduction of pegylated interferon or topical tazarotene, lack robust evidence and are largely experience-driven. In several publications, the authors have developed algorithms based on local settings, specified the level of evidence, and clarified stepwise treatment approaches. In these examples, treatment protocols for classic MF have been specifically adapted to local resources and skin phototypes.19, 20
Prospective, multicenter evaluations are needed to determine the safety and efficacy of these practices. Given the rarity of MF, establishing real-world evidence registries could support the validation and refinement of these adaptations in diverse care settings.21
Barriers to device-based therapies, including PUVA, TSEBT, and PDT, were common and often led to referral of patients to higher-capacity centers. This aligns with literature showing that centralization of complex MF care in specialized centers facilitates access to multidisciplinary expertise and advanced technologies, ultimately improving care quality.22, 23 Establishing dedicated MF centers of excellence could address these gaps while also serving as hubs for clinician training, clinical trials, and teledermatology-assisted outreach.
Finally, multidisciplinary management emerged as an underutilized resource in our findings, with only a minority of respondents participating in regular tumor board discussions. Multiple studies confirm that integrated multidisciplinary clinics improve diagnostic accuracy, streamline therapeutic decision-making, and enhance patient outcomes in cutaneous lymphomas.22, 23 Expanding such collaborative models, particularly in resource-constrained environments, could help bridge the gap between guideline recommendations and real-world practice.
Study Limitations
Several limitations should be acknowledged. First, the voluntary, self-administered online survey may have introduced selection bias, as respondents with a particular interest in or experience with MF may have been more likely to participate, potentially limiting the representativeness of the sample. In addition, all data were self-reported, raising the possibility of recall bias and inaccurate estimation of clinical practices, diagnostic capabilities, and treatment accessibility.
Moreover, the cross-sectional design captures practices at a single point in time and does not account for temporal changes in healthcare infrastructure or policy. Institutional characteristics were based solely on participants’ reports without external verification. The lack of detailed information on patient outcomes, disease-stage distribution, or survival precludes direct assessment of clinical effectiveness.
Finally, the study was conducted within a middle-income healthcare system. While this context provides valuable insight into resource-limited settings, the generalizability of the findings to high-resource healthcare environments may be limited. In addition, the survey instrument was not formally validated, which should be considered when interpreting the results.
CONCLUSION
This study highlights substantial variability in diagnostic and therapeutic practices for MF, driven by challenges such as limited access to advanced diagnostic modalities, gaps in structured diagnostic training, and heterogeneous availability of treatments. The findings underscore the need to develop national guidelines aligned with international standards and adapted to local resource settings, to expand the use of standardized diagnostic algorithms, to strengthen specialist training, and to promote centralized, multidisciplinary care models to improve early diagnosis, optimize treatment decisions, and enhance overall patient outcomes.
