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Advances in Dermatology and Allergology/Postępy Dermatologii i Alergologii
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vol. 34
 
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Original paper

Insulin resistance, diabetes mellitus and thyroid dysfunction in patients with palmoplantar pustulosis: a case-controlled study

Hatice Ataş
,
Müzeyyen Gönül

Adv Dermatol Allergol 2017; XXXIV (3): 268-272
Online publish date: 2017/05/29
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Introduction

Palmoplantar pustulosis (PPP) is a chronic pustular inflammatory skin disease. Its characteristics include chronically recurring sterile pustules frequently occurring with additional findings, such as yellow-brown macules (remnants of resolving pustules), erythema, scales and fissures on the palms of the hands and soles of the feet. It usually occurs in middle-aged women who smoke, and erupts repeatedly over months or years [1, 2]. Unfortunately, the pathogenesis of PPP is not well understood. Several factors may contribute to this disease, including genetics, tobacco use and autoimmune disorders [3, 4]. Additional studies are necessary to clarify the relationship between PPP and autoimmune disorders, such as thyroid disease, gluten sensitivity and type 2 diabetes mellitus [3, 5, 6].

Aim

In this study, we aimed to investigate the possible relationships between PPP, insulin resistance and thyroid dysfunction.

Material and methods

This was a single centre, case-control study performed in the Department of Dermatology at the Diskapi Yildirim Beyazit Training and Research Hospital in Ankara, Turkey. Approval for this research was obtained from the Institutional Ethics Committee, and informed written consent was obtained from all of the subjects.
The controls were selected from the patients admitted to the dermatology clinic for nevi. The inclusion criteria for the patients with PPP were the following: a) recurring pustulosis on the feet or hands with a negative bacteriological study, b) no signs of psoriasis or eczema on the rest of the skin, and no personal history of psoriasis, c) diagnosed with PPP after clinical and/or histopathological investigations, d) no systemic treatment over the previous 3 months, including steroids, immunosuppressant agents, retinoids and phototherapy and e) no vascular events, chronic hepatic diseases, chronic renal diseases, malignancies, pregnancy, connective tissue disorders, Crohn’s disease, coeliac disease, or any disease that could affect the immune system.
The patients were interviewed with regard to their a) past history of tonsillitis, autoimmune disease, thyroid disease and beginning of PPP symptoms, b) family history of PPP, diabetes and thyroid disease and c) tobacco use (classified as A = non-smoker (NS), B = smoker (S), B1 = smoker of 10 cigarettes or less/day and B2 = smoker of more than 10 cigarettes/day). All of the participants were analysed for their thyroid function, anti-thyroid peroxidase antibody (anti-TPO) levels, fasting glucose, fasting insulin levels and homeostatic model assessment (HOMA) index for insulin resistance (IR). Venous blood samples were taken from the subjects after 8 hours of fasting. The chemiluminescent immunometric assay method was used for the serum insulin (< 12 mU/l), free T3 (FT3) (range: 2.3–4.2 pg/ml), free T4 (FT4) (range: 0.74–1.52 ng/dl), anti-TPO (< 35 U/ml) and anti-thyroglobulin (anti-TG) (< 40 U/ml). Spectrophotometric methods were used to measure the thyroid-stimulating hormone (TSH) (0.55–4.78 mIU/l) and fasting blood glucose (70–100 mg/dl).
The HOMA index uses the formula described by Matthews et al. [7]: insulin (mU/l) × (glucose (mmol/l)/22.5). The cut-off point to define IR was above 2.6 µU/ml in the HOMA.

Statistical analysis

The data were analysed using SPSS 15.0 software. The descriptive analyses were presented using the median, range and tables of the frequencies for the variables. A 2or Fisher’s exact test was used for the discrete variables and the Student’s t test or Mann-Whitney U test was used for the continuous variables, after detecting the normality according to the Kolmogorov-Smirnov test, which was used to compare the variables between the PPP and control groups, where appropriate. For the multivariate analysis, the possible factors (age, gender, smoking, family history of PPP, diabetes mellitus and thyroid disease, time of disease onset, duration of PPP, FT3, FT4, TSH, anti-TPO, anti-TG, fasting blood glucose, insulin levels and HOMA index) identified with the univariate analyses were further entered into the logistic regression analysis to determine the independent predictors of PPP. A p-value of less than 0.05 was considered to show a statistically significant result.

Results

This study included 33 patients with PPP (31 females, 2 males, median age of 40 years old) and 27 age- and gender-matched controls (23 females, 4 males, median age of 38 years old). The other demographic and laboratory characteristics of the subjects can be seen in Tables 1 and 2. The fasting glucose, insulin and HOMA index were not significant between the PPP patients and the controls (p = 0.52, p = 0.31 and p = 0.22, respectively). In addition, the IR according to the insulin and HOMA index was not found to be a significant risk factor for PPP (p > 0.05). The ratios of tobacco use were 90% in the PPP group and 63% in the control group, and there was a statistically significant difference between the groups (p < 0.009). A history of thyroid disease was found in 21% of the PPP patients, compared to 7% of the controls (p = 0.17). This rate was increased to 60% in the PPP group and 22% in the control group (p = 0.003) when all of the thyroid abnormalities, including the history of thyroid disease and laboratory parameters, were evaluated. The median anti-TPO levels were 30 U/ml in the PPP group and 20 U/ml in the control group. A significant difference was detected between the PPP and control groups according to the anti-TPO levels (p = 0.009). If the anti-TPO level was ≥ 21 U/ml, both the sensitivity and specificity of the anti-TPO were 67%. The median anti-TPO level was 34 U/ml in women with PPP and 11.5 U/ml in men with PPP. The autoantibody abnormality rate in patients with PPP was three-times higher than that in the control group (42% vs. 15%, p = 0.02). The gender and tobacco use were predictive for PPP in the multivariate analysis (OR = 141.7, p < 0.0001 and OR = 147.6, p = 0.006, respectively). An anti-TPO > 35 U/ml and the presence of a thyroid abnormality were found to be independent risk factors in the univariate analysis (OR = 4.2, p = 0.025 and OR = 5.4, p = 0.004, respectively), but not in the multivariate analysis (p = 0.39 and p = 0.07, respectively) (Table 3).

Discussion

The exact incidence and prevalence of PPP are not well known [8, 9]. Moreover, a determination of the prevalence of PPP was not possible according to our study, but we can say that it is a rare disease in our clinic.
The PPP is a pustular skin disorder that usually occurs in adults [2]. Although PPP is listed among the pustular variants of psoriasis in many textbooks, a recent genetic study has provided evidence that PPP may not be related to psoriasis [4]. In general, the disease is found in people between 20 and 60 years of age, which is compatible with our patients’ age range (23–60 years old) [10]. Women and smokers are more frequently affected [1, 2]. According to gender in PPP patients, an 8.8-fold increased risk was found in the females when compared to the males in the multivariate analysis (OR = 141.7, p < 0.0001) in this study.
Tobacco use plays a role in the pathogenesis of PPP; however, the prevalence of tobacco use in patients with PPP is different based on different studies (range: 42–100%) [9, 11]. In this study, the ratio was 90% in 33 patients with PPP. When we compared it with the rate of the control group, the difference was found to be highly significant (90% vs. 63%, p < 0.009). Smoking was a 32.7-fold increased risk factor for PPP in the multivariate analysis (HR = 147.6, p = 0.006).
The relationships between PPP and certain clinical features, such as gluten sensitivity, thyroid disease, diabetes mellitus and focal infections (like tonsillitis) have been demonstrated in recent studies [5, 6, 12, 13]. The increased frequency of thyroid disorders varies based on different studies, while the prevalence of thyroid pathologies is about 5% in the general population [3]. The rate in the control group was 7% according to the history of thyroid disease in our study. In addition, high frequencies of thyroid disease and thyroid autoantibodies were found in the patients with PPP in one previous study [13]. In another study of PPP, 3 (25%) and 2 (16%) of 12 patients were diagnosed with thyroid diseases and antimicrosomal antibodies, respectively [3]. In these studies, the patients were compared with the general population, not with a control group; however, we used a case-control study.
The prevalence of thyroid pathologies in PPP ranged from 16% to 25% in some studies, and these rates are significantly higher than these found in the general population [3, 13–15]. Our rate was 21% according to the history of thyroid disease in the PPP group, which was three-times higher than in the control group (21% vs. 7%). Hashimoto’s disease, multinodular goitre and hypothyroidism are the major associated thyroid disorders [3]. In this study, Hashimoto’s disease was found in 4 patients, a multinodular goitre in one patient, Graves in 1 patient and subclinical hypothyroidism in one patient. When we considered all thyroid abnormalities, including thyroid function, TSH, T4, anti-TPO and anti-TG autoantibody abnormalities and a positive thyroid disease history, this rate was 60% in the PPP group and 22% in the control group. When we investigated the thyroid autoantibodies, the abnormality rate of the patients with PPP was approximately three times higher than in the controls (42% vs. 15%, p = 0.02). Thyroid antigen antibodies are more common in women, with a rate of 8.4% in the general population [16]. Gul et al. reported the frequency of thyroid autoantibodies in healthy Turkish individuals as 9.9% [17]; however, this rate has been reported as 22.5% in women with PPP [13]. In this study, a moderate correlation between the gender and anti-TPO levels was found (r = 0.361, p = 0.039), while the anti-TPO rate was three-times higher in women than in men in the PPP group. However, in previous studies, the anti-TPO level was not been evaluated in a multivariate analysis. Moreover, the anti-TPO level was an independent risk factor in the univariate analysis, but not in the multivariate analysis in our study. High autoantibody levels can be related to the female gender because of the high tendency toward PPP in females.
Gimenez-Garcia et al. [3] demonstrated that all of their patients with PPP exhibiting thyroid dysfunction were also smokers. However, this possible association between PPP and thyroid dysfunction could be attributed to tobacco use rather than the presence of PPP [3]. Tobacco use can induce vasoconstriction or cause immune system dysfunctions, such as functional and morphological alterations in the polymorphonuclear leucocytes and an exaggerated release of chemotactic factors [12, 18]. Moreover, giving up the habit does not generally lead to the disappearance of PPP [19], which explains the significance of immune dysregulation. However, we did not find any correlation between the autoantibodies and tobacco use.
Type 2 diabetes mellitus is more frequent among women (23–76 years old, mean age 55 years) with PPP in Sweden [5]. In addition, an increased predisposition toward diabetes in PPP has been discussed by Uehara [20]. An abnormal glucose tolerance test was found in 55 (66.3%) of 83 patients with PPP, and the deranged carbohydrate metabolism may be partly responsible for the increased susceptibility to focal infections in patients with PPP [20]. Several pathogenic factors, such as the serum calcium, tobacco use and obesity, which may predispose patients to type 2 diabetes should be taken into consideration, but these variables are not enough to explain the excess risk of diabetes in patients with PPP [5].
The IR is a subnormal biological response to normal insulin concentrations. The IR and relative insulin deficiency, with complex interactions among many genes and environmental factors, are the two of the major causes of type 2 diabetes mellitus [21–23]. The fasting insulin concentration is a useful marker to identify those subjects with IR, and the optimal cut-off point has been identified as 15.7 mU/l (109 pmol/l) for insulin [24]. In another study, the 75th and 90th percentiles defined as the cut-off values for IR and HOMA were 12–17.2 mU/l and 2.6–4.1 µU/ml, respectively. However, IR has not been previously studied in PPP patients. Although the fasting blood glucose, fasting insulin and HOMA index in the patients with PPP were slightly higher than in the controls, the fasting blood glucose, insulin cut-off level (12 mU/l) and HOMA index were not found to be useful in the evaluation of PPP. No correlations were found in these parameters between the controls and the PPP patients. Moreover, these parameters were not effective or predictive in the uni/multivariate analyses (p > 0.05).
Tobacco use and female gender have been shown to increase the risk of PPP in several other studies. Correspondingly, female gender and smoking were the most important risk factors for PPP according to our study. Based on the results of previous studies, the anti-TPO rate is normally 8.4% in the general population, but it is 22.5% in patients with PPP. In our study, the rates of thyroid pathologies and autoantibodies were 60% and 42%, respectively, which could be associated with the high anti-TPO levels in the female gender. Although there have been study results regarding the increased risk of type 2 diabetes and impaired carbohydrate metabolism, IR has not been previously studied in PPP patients. In our research, no correlation was detected between IR and PPP; however, additional studies are necessary to clarify the relationships between PPP, thyroid disease and diabetes mellitus.

Conflict of interest

The authors declare no conflict of interest.

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