Stevens-Johnson Syndrome and toxic epidermal necrolysis: a multi-aspect comparative 7-year study from the People's Republic of China.

BACKGROUND: Stevens-Johnson Syndrome (SJS) and toxic epidermal necrolysis (TEN) are rare but severe cutaneous drug reactions. They are differentiated based on the fraction of the body surface area affected. Optimal therapy for SJS and TEN is a controversial issue.
OBJECTIVE: We compared the treatments given to and the clinical outcomes of 39 cases of SJS and 48 cases of TEN seen at a single institution between January 2007 and December 2013 for better understanding of the clinical characteristics and development of the two conditions.
METHODS: Demographic data, clinical characteristics, treatments given, and therapeutic responses observed were retrospectively collected.
RESULTS: The incidence rates of hypoproteinemia and secondary infections are significantly higher in TEN than in SJS (P=0.001 and P=0.002, respectively). The corticosteroid dose did not influence the time from the initiation of therapy to control of the lesions in SJS, but increasing the dosage of corticosteroids progressively decreased the time from the initiation of therapy to control of the lesions in TEN. With increases in the utilization ratio of intravenous immunoglobulin (IVIG), the length of the hospital stay became shorter, whereas the time from the initiation of therapy to control of the lesions remained the same in SJS. However, for TEN, both the length of the hospital stay and the time from the initiation of therapy to control of the lesions became shorter with increases in the utilization ratio of IVIG.
CONCLUSION: SJS and TEN are two variants of the same spectrum, and they differ from each other not only in the severity of epidermal detachment but also in other clinical parameters and their distinct clinical courses. Thus, differential treatment of both conditions may have benefits for their prognosis.

Introduction

Toxic epidermal necrolysis (TEN) and Stevens–Johnson Syndrome (SJS) are acute, potentially life-threatening skin and mucosal reactions, usually to drugs, which are characterized by epidermal detachment and mucositis.1 TEN occurs at an estimated incidence of 0.4–1.2 cases per million people per year,2–5 with an appreciable mortality rate of 20%–30%, which may be a conservative estimate given that TEN is under-reported.6 For SJS, the incidence varies from one to six cases per million people per year, and the mortality rate is about 5%.4,5 The difference between SJS and TEN relates to how much of the body surface is affected: SJS consists of epidermal detachment of less than 10% of the body surface area; for TEN, epidermal detachment is more than 30% of the body surface; and for SJS/TEN overlap syndrome, epidermal detachment is between 10% and 30%.7 Histopathology is similar for both diseases, but varies in degree depending on severity of the condition. TEN is more severe than SJS with identical pathology.8 There is now consensus that SJS and TEN are variations of the same condition.7

No controlled trials of therapy for SJS or TEN have been documented to date. Systemic corticosteroids and immunosuppressive drugs are widely used in addition to supportive therapy to halt the progression of these diseases, which is based on the concept that they are T-cell-mediated diseases with CD8+ cells acting as the major mediator of keratinocyte death.9–11 It was reported that interactions between the death receptor Fas (CD95) and its ligand present on epidermal cells might play an important role in the apoptosis that characterizes TEN, so the use of intravenous immunoglobulin (IVIG) is often recommended.12

Thus far, controversy has existed in the literature in relation to the clinical definitions of these diseases and whether they are distinct entities or a spectrum of one disease process. For better understanding of the clinical characteristics and development of the two conditions, we performed this retrospective study to compare SJS and TEN in multi-aspect with regards to demographic information, clinical manifestations, and therapeutic responses.

Methods

We retrospectively reviewed the medical records of all patients admitted to the First Affiliated Hospital of Nanjing Medical University, Nanjing, the People’s Republic of China, from January 2007 to December 2013 for SJS and TEN. For SJS, symptoms should include acute conditions characterized by mucous membrane erosions and skin lesions (described as macules, atypical target-like lesions, bulla, erosions) with less than 30% of maximum detachment of the skin surface area; for TEN, the symptoms should include more than 30% of maximum skin detachment in addition to the symptoms above. Based on the definition, SJS/TEN overlap cases were included in SJS.13–15 The case notes, charts, investigation results, and treatment records of these patients were retrospectively reviewed. Data obtained included the age, sex, medical history, presenting complaints, inciting drugs, duration between the initial consumption of the drug and the onset of symptoms, and score for toxic epidermal necrosis.16 Treatment regimens, the time from the initiation of therapy to control of the lesions (a halt of the progression of necrolysis and signs of re-epithelialization),17 duration of hospitalization, and mortality were also recorded. Since bicarbonate levels are not routinely determined in our department, that value was equally excluded when modified score for toxic epidermal necrosis (mSCORTEN) was calculated in the study.

Data analysis was performed using the Statistical Package for Social Science (SPSS for Windows, version 16.0). Data from the time of the initiation of therapy to control of the lesions, the maximum dosage of corticosteroid, and the duration of hospital stay were presented as mean ± standard deviation, and the Kruskal–Wallis test for comparisons was performed. Categorical variables were compared among the groups of patients using the chi-square test. Multiple linear regression analysis was used to assess the relationship between the maximum dosage of corticosteroids and the year. We used binary logistic regression to study the relationship between the utilization rate of IVIG and the year, and the correlation between the albumin level and secondary infections. Cox regression analysis was used to analyze associations between the duration of the hospital stay and the maximum dosage of corticosteroids as well as the usage of IVIG, and also associations between the time from the initiation of therapy to control of the lesions and the maximum dosage of corticosteroids as well as the usage of IVIG. P<0.05 is considered statistically significant. All P-values are two-tailed.

Results

Demographics and treatments

Eighty-seven cases, including 39 SJS and 48 TEN, were studied. The age of SJS ranged from 7–84 years (average age, 44.15±19.45 years), and that of TEN ranged from 10–84 years (average age, 42.98±21.71 years). Females predominated in both the SJS and TEN, with a ratio of 1.17:1 (21:18) and 1.67:1 (30:18), respectively. Drugs considered to be related to SJS and TEN are listed in Table 1. These drugs were dominated by antiepileptics (38.4%) and antibiotics (23.1%) in SJS and by antiepileptics (31.3%) and nonsteroidal anti-inflammatory drugs (20.8%) in TEN. However, there was no significant difference in the constituent ratio of causative drugs between the two groups (P=0.121).

Table 1

Demographics of the patients

Drug used	SJS (n)	TEN (n)
Antiepileptics	15	15
Carbamazepine	12	13
Lamotrigine	2	1
Phenobarbital	1	1
Antibiotics	9	6
Amoxicillin	3	1
Cephalosporins	4	3
Metronidazole	2	0
Levofloxacin	0	1
Antipodagrics	5	6
Allopurinol	5	6
Nonsteroidal anti-inflammatory drugs	1	10
Traditional Chinese medicine	3	6
Other drugs	6	5

Abbreviations: n, number; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

The mean maximum doses of corticosteroids were 98.62±35.67 mg in SJS and 190.87±131.41 mg in TEN. The mean utilization rates of IVIG were 39.19% in SJS and 65.08% in TEN. The mean maximum dose of corticosteroids and the mean utilization rate of IVIG were higher in TEN than in SJS (P=0.000 and P=0.018, respectively). However, the mean number of days of corticosteroids use along with maximum dose of corticosteroids was 6.38±3.02 days in SJS and 6.13±3.58 days in TEN, which was of no significant difference between SJS and TEN (P=0.258).

Comparisons of complications and mortality of SJS and TEN

Hepatic involvement with elevation of liver enzymes (alanine transaminase [ALT] or aspartate transaminase [AST] ≥2 times the upper limit of normal), renal involvement with elevation of urea and creatinine (urea or creatinine was greater than the upper limit of normal) as well as hypoproteinemia and secondary infections are common complications in SJS and TEN.17 Abnormalities of ALT, AST, urea, and/or creatinine mostly occur in the first week after onset in TEN, while abnormalities of AST and urea usually occur in the first week after onset in SJS. However, abnormalities of ALT mostly occur in the second week after onset in SJS, and there was no abnormality of creatinine in SJS (Figure 1A and B). Hypoproteinemia mostly occurred in SJS and TEN patients in the second week after onset (Figure 1C). There was no difference in the incidence of hepatic involvement and renal involvement between SJS and TEN (P=0.138 and P=0.210, respectively). However, the incidence rate of hypoproteinemia and secondary infections is significantly higher in TEN than in SJS (P=0.001 and P=0.002, respectively). Two cases died of TEN (4.2%, 2:48), while no patient died in the SJS group. No significant difference was found in mortality ratio between the two groups (P=0.502, according to Fisher exact test).

Figure 1

Hepatic involvement (A), renal involvement (B), and hypoproteinemia (C) distribution in patients with TEN and SJS.

Abbreviations: ALB, albumin; ALT, alanine transaminase; AST, aspartate transaminase; Scr, serum creatinine; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis; W, weeks.

Hypoproteinemia

Table 2 shows the clinical characteristics of SJS and TEN grouped according to albumin levels, quartile values of which were used as cutoff points. Patients in quartiles I, II, III, and IV had increasingly higher albumin levels. Among SJS patients, the distribution of the duration of hospital stays (P=0.38), the time from the initiation of therapy to control of the lesions (P=0.825) and the maximum dosage of corticosteroids (P=0.167) were similar among the four groups. In contrast, the frequency distribution of the use of IVIG (P=0.00) differed among the groups; however, among TEN patients, all were similar among the four groups. The results of the binary logistic regression analysis indicated that albumin levels are significantly associated with secondary infections among TEN (β=−0.201, P=0.009) and are not significantly associated with secondary infections among SJS (β=−0.019, P=0.808).

Table 2

Clinical characteristics of SJS and TEN grouped according to albumin level quartile values used as cutoff points

Variable	Group	Albumin levels				F or χ2	P-value
		0–25.8 g/L	25.9–31 g/L	31.1–35.1 g/L	≥35.1 g/L
Duration of hospital stay (days)	SJS	18.62±5.44	15.29±3.99	12.14±2.34	14.50±3.41	8.410	0.380
	TEN	25.00±10.43	22.00±9.53	19.08±7.16	18.55±7.66	2.080	0.550
Time from initiation of therapy to control of lesions (days)	SJS	3.50±2.24	3.00±1.63	4.00±2.20	3.40±1.43	0.902	0.825
	TEN	5.50±3.12	5.12±3.10	5.69±2.59	4.82±2.56	0.785	0.853
Maximum dosage of steroid (mg)	SJS	94.29±25.33	85.71±15.12	87.50±21.21	122.60±55.10	5.069	0.167
	TEN	212.50±129.13	185.50±120.69	175.08±126.41	191.82±163.39	1.063	0.786
Number of usages of IVIG	SJS	12	2	2	1	16.322	0.000
	TEN	9	10	10	4	6.849	0.095

Note: Data shown are mean ± standard deviation.

Abbreviations: IVIG, intravenous immunoglobin; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Comparison of corticosteroids usage in succeeding years

To examine the independent association between the treatment year and the maximum dosage of corticosteroids, multiple linear regression analysis was performed. In this model, the maxi mum dosage of corticosteroids was employed as the dependent variable, and independent variables included the year, age, sex, and mSCORTEN. In the final model, among SJS and TEN patients, sex (βSJS=−0.029, PSJS=0.863; βTEN=0.104, PTEN=0.496, respectively), age (βSJS=0.060, PSJS=0.710; βTEN=0.115, PTEN=0.513, respectively), and mSCORTEN (βSJS=0.000, PSJS=0.998; βTEN=−0.052, PTEN=0.766, respectively) have no effect on the maximum dosage of corticosteroids, while each successive year of treatment (βSJS=−0.524, PSJS=0.002; βTEN=−0.461, PTEN=0.004, respectively) leads to a gradual decrease to it in both diseases. However, the severity of both diseases was the same, since there was no significant difference in mSCORTEN during these years (Figure 2).

Figure 2

Corticosteroid usage and mSCORTEN in succeeding years in SJS patients and TEN patients.

Abbreviations: mSCORTEN, modified score for toxic epidermal necrosis; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Comparison of IVIG usage in succeeding years

To evaluate the association between the utilization rate of IVIG and the treatment year, binary logistic regression analysis was conducted. In the analysis, the utilization rate of IVIG was employed as the dependent variable, while the covariate variables included age, sex, mSCORTEN, and the year. The results of that analysis (Table 3) indicated that the treatment year was significantly associated with the utilization rate of IVIG among SJS patients (β=1.796, P=0.038), but there was no significant association with the utilization rate of IVIG among TEN patients (β=1.280, P=0.198). Therefore, the number of SJS patients who used IVIG increased in succeeding years, while the number of TEN patients who used IVIG was constant over this period (Figure 3).

Table 3

Results of the binary logistic regression analysis

Effect	Group	β	P-value
Constant	SJS	−1.179E3	0.038
	TEN	−495.446	0.198
Sex	SJS	0.346	0.678
	TEN	0.648	0.393
Age	SJS	−0.024	0.250
	TEN	−0.028	0.150
mSCORTEN	SJS	1.117	0.037
	TEN	0.050	0.914
Year	SJS	0.586	0.038
	TEN	0.247	0.198

Abbreviations: mSCORTEN, modified score for toxic epidermal necrosis; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Figure 3

IVIG usage in succeeding years in SJS patients and TEN patients.

Abbreviations: IVIG, intravenous immunoglobin; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Associations between the duration of the hospital stay and the maximum dosage of corticosteroids as well as the usage of IVIG

To evaluate the associations between the duration of the hospital stay and the maximum dosage of corticosteroids as well as the usage of IVIG, Cox regression analysis was conducted. In the analysis, the duration of the hospital stay was employed as the dependent variable, while the covariate variables included age, sex, mSCORTEN, the maximum dosage of corticosteroids, and the usage of IVIG. The results of the Cox regression analysis (Table 4) indicated that the duration of the hospital stay was significantly associated with the usage of IVIG (β=−0.922, P=0.030; β=−1.046, P=0.016), but there was no significant association with the maximum dosage of corticosteroids (β=−0.006, P=0.202; β=−0.003, P=0.063) among SJS and TEN patients.

Table 4

Results of the Cox regression analysis of associations between duration of hospital stay and the maximum dosage of corticosteroids as well as the usage of IVIG

Variable	Group	β	P-value
Sex	SJS	−0.568	0.127
	TEN	−0.289	0.442
Age	SJS	0.013	0.215
	TEN	0.001	0.905
mSCORTEN	SJS	−0.336	0.219
	TEN	0.106	0.623
Maximum dosage of corticosteroids	SJS	−0.006	0.202
	TEN	−0.003	0.063
Usage of IVIG	SJS	−0.992	0.030
	TEN	−1.046	0.016

Abbreviations: IVIG, intravenous immunoglobin; mSCORTEN, modified score for toxic epidermal necrosis; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Associations between the time from the initiation of therapy to control of the lesions and the maximum dosage of corticosteroids as well as the usage of IVIG

To evaluate the associations between the time from initiation of therapy to control of the lesions and the maximum dosage of corticosteroids as well as the usage of IVIG, Cox regression analysis was conducted. In that analysis, the time from the initiation of therapy to the control of lesions was employed as the dependent variable, while the covariate variables included age, sex, mSCORTEN, the maximum dosage of corticosteroids, and the usage of IVIG. The results of the Cox regression analysis (Table 5) indicated that the time from the initiation of therapy to control of the lesions was significantly associated with the usage of IVIG as well as the maximum dosage of corticosteroids among TEN patients, (βcorticosteroids=−0.003, Pcorticosteroids=0.028; β=−0.71, P=0.046). However, there was no significant association with the usage of IVIG as well as the maximum dosage of corticosteroids (βcorticosteroids=0.001, Pcorticosteroids=0.81; β=0.512, P=0.19) among SJS patients.

Table 5

Results of the Cox regression analysis of associations between time from initiation of therapy to control of the lesions and the maximum dosage of corticosteroids as well as the usage of IVIG

Variable	Group	β	P-value
Sex	SJS	−0.668	0.076
	TEN	0.441	0.183
Age	SJS	0.011	0.286
	TEN	−0.011	0.309
mSCORTEN	SJS	−0.065	0.786
	TEN	−0.133	0.601
Maximum dosage of corticosteroids	SJS	0.001	0.810
	TEN	−0.003	0.028
Usage of IVIG	SJS	0.512	0.190
	TEN	−0.710	0.046

Abbreviations: IVIG, intravenous immunoglobin; mSCORTEN, modified score for toxic epidermal necrosis; SJS, Stevens–Johnson Syndrome; TEN, toxic epidermal necrolysis.

Discussion

TEN and SJS are rare, potentially life-threatening acute exfoliative drug-induced skin and mucosal disorders.18 The categorization of erythema multiforme (EM), SJS, and TEN remains a topic of ongoing controversy because of the incomplete elucidation of their pathogenesis. The first description of TEN in 1956 by Lyell19 made no reference to EM or SJS. However, it soon became evident that severe forms of SJS could evolve to TEN and that the same drugs could induce both disorders. Because detachment of the epidermis is a major prognosis factor, Bastuji-Garin et al20 proposed SJS, SJS/TEN overlap, and TEN as classifications based on the severity of the epidermal detachment. Epidermal detachment of less than 10% of the body surface area is classified as SJS, more than 30% as TEN, and 10%–30% as SJS/TEN overlap.21,22 The present opinion is that SJS and TEN are severity variants of the same drug-induced process. However, until it has been clarified that common etiologies and pathologic process are involved, some experts believe that this classification scheme is imperfect.7, 23,24

Our study is the first to compare SJS and TEN from multiple aspects such as clinical features and therapeutic responses. In contrast to earlier studies25 showing that the incidences of hepatic involvement and renal involvement in TEN are higher than in SJS, our series had an equal incidence. Abnormalities of ALT, AST, urea, and creatinine in TEN usually occur within the first week after the onset, while abnormalities of AST and urea usually occur in SJS within the first week after onset. However, the abnormality of ALT in SJS usually occurs within the second week after the onset, and there is no abnormality of creatinine in SJS. Although hepatic and renal involvement in TEN and SJS usually occur within the first week after the onset of the diseases, it should be noted that delayed hepatic and renal involvement will occur in a considerable number of patients. Therefore, clinicians should closely monitor liver and kidney functions in later stages of the diseases.

In the course of SJS and TEN, hypoproteinemia ought to be considered as a solitary complication regarding its strategic role in the prognosis of the disease and its response to drug therapy. Not only can hypoproteinemia induce an increased incidence of infections and slow the healing of skin lesions, but it also decreases the therapeutic effect of certain drugs because albumin can be used as a carrier for many drugs such as corticosteroids and antibiotics. The incidence rates of hypoproteinemia and secondary infections are significantly higher in TEN than in SJS. Hypoproteinemia mostly occurs in SJS and TEN in the second week after the onset, which is mainly due to the loss of plasma after the outbreak of vesiculobullous. In this study, the incidence of secondary infections increases with the decrease in serum albumin levels in TEN, while there is no significant association between secondary infections and serum albumin levels in SJS using the binary logistic regression analysis. The lower the albumin levels are, the higher the incidences of infection and edema are, and the slower the onset time of corticosteroids therapy is. The disease conditions of patients whose albumin levels are lower are usually worse, which might make doctors choose IVIG as a supplementary therapy. In our study, the IVIG differed significantly among the four groups of various albumin levels in SJS patients.

There is currently no specific or classified treatment for TEN or SJS because of their complex pathogenesis. Systemic administration of corticosteroids and IVIG are still controversial in many countries, but these two treatments have become mainstream in the People’s Republic of China.

The use of corticosteroids is based on the idea that corticosteroids probably suppress immunological responses by inhibiting the functions of cytotoxic T lymphocytes and also inhibit interferon gamma mediated apoptosis.26 Moreover, corticosteroids have pleomorphic effects on the immune system, including the inhibition of chemokines and numerous cytokines like TNF-alpha.27 In 1983, Kim et al28 suggested that treatment of SJS and TEN with glucocorticoids is associated with increased morbidity and mortality mainly due to secondary infections. Since the 1980s, several studies stated that corticosteroids not only enhance the risk of sepsis but also delay the epithelialization.29,30 However, In a case-control analysis of patients selected from EuroSCAR/RegiSCAR studies, it was shown that long-term corticosteroid use prior to the onset of disease may prolong the latency (time from drug initiation to the onset of disease) and progression of disease but does not influence severity or mortality.31 In this study, we concluded that the maximum dosage of corticosteroids gradually decreased with the increase of the year in the two diseases using multiple linear regression analysis. Nevertheless, the severities of the diseases are the same according to the insignificant difference in mSCORTEN during these years. The maximum dosage of corticosteroids also has no influence on the time from the initiation of therapy to the control of the lesions in SJS. With an increase in the maximum dosage of corticosteroids, the time from the initiation of therapy to the control of the lesions becomes shorter and shorter in TEN. Therefore, we conclude that there is a difference in the response to corticosteroid therapy between SJS and TEN. The maximum dosage of corticosteroids decreasing with years of treatment might be ascribed to the fact that, to some extent, Chinese dermatologists are much more aware of the update of the strategic and double-sided role of corticosteroids, along with controllable and different dose ranges in treatment of SJS and TEN. SJS and TEN belong to severe drug eruption and are often accompanied by systemic involvement; after all, they manifest transient disease process. Most of the patients would be cured by treatment at last. The death or complications of a considerable number of patients occurring later in the disease may be caused by excessive use of corticosteroids. The dermatologists should weigh benefits and side effects of certain doses of corticosteroids in the treatment of SJS and TEN. In practice, it is relatively difficult to determine the precise doses of corticosteroids for the particular conditions. In our opinion, the doses of corticosteroids that can control temperature and the rapid development of lesions in the case of supportive treatment should be considered adequate. The diseases can be controlled gradually.

IVIG seems to have many advantages in the treatment of TEN and SJS. In 1998, Viard et al12 published a new proposal for therapy based on the use of IVIG, with excellent clinical findings, on the basis of their ability to inhibit the Fas–Fas ligand-mediated apoptosis of keratinocytes. However, a prospective noncomparative study performed by Bachot et al32 and a single institutional analysis with nonimmunoglobin-treated controls carried out by Brown et al33 do not show a significant improvement in the mortality of TEN patients treated with IVIG and may indicate a potential detriment in their use, especially in elderly patients and in patients with impaired renal function. On the contrary, Metry et al,34 Tristani-Firouzi et al,35 Aires et al36 and Trent et al37 conducted a number of retrospective and prospective studies to examine the efficacy and safety of IVIG in TEN patients and found that IVIG has a beneficial effect in TEN. The total IVIG therapeutic dose was also set at 2 g/kg in five infusions in the present study, which is consistent with empirical therapeutic dose reported in the literatures. With an increasing utilization ratio of IVIG, the length of the hospital stay has become significantly shorter, whereas the time from the initiation of therapy to control of the lesions remains the same in SJS. For TEN, both the length of the hospital stay and the time from the initiation of therapy to control of the lesions has become shorter as an increasing utilization ratio of IVIG. Therefore, we deduced that there is also a difference in the response to IVIG between SJS and TEN.

Earlier studies had shown that there might be different responses to corticosteroids and IVIG between SJS and TEN. Tripathi et al38 concluded that SJS must be distinguished from TEN since SJS is steroid responsive, but TEN has not been observed to improve with systemic corticosteroids. Tan et al39 had inferred from a small sample (only three cases of TEN, seven cases of SJS/TEN overlap, and 18 cases of SJS) and a descriptive survey without a strict statistical analysis that steroid therapy with high-dose corticosteroids was effective in SJS, whereas IVIG showed efficacy in TEN according to their experience. In any case, there is no such comparative study using the regression model which simultaneously balances and excludes other possible impacting factors focusing on evaluation of the efficacy of IVIG in the treatment of TEN and SJS in the published literature. The results we obtained from this study indicate that corticosteroids and IVIG are effective in shortening the time from the initiation of therapy to control of the lesions in TEN while both corticosteroids and IVIG are not effective in shortening the time from the initiation of therapy to the control of lesions in SJS, which confirms our previous presumption and allows a better understanding of different responses to corticosteroids and IVIG of SJS and TEN.

SJS varies from TEN in clinical manifestations, therapeutic responses to corticosteroids, and IVIG, probably due to distinguished pathogenesis of both diseases, which is not covered in this study. Nevertheless, the variation could not be totally attributed to differences of severity related to the extent of diseases. We consider SJS and TEN as two variants of the same spectrum, and they differ from each other not only in the severity of epidermal detachment but also in other clinical parameters and their distinct clinical courses. Thus, we believe that differential treatment of both conditions may have benefits for their prognosis.