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Advances in Dermatology and Allergology/Postȩpy Dermatologii i Alergologii logoLink to Advances in Dermatology and Allergology/Postȩpy Dermatologii i Alergologii
. 2017 Apr 13;34(2):131–137. doi: 10.5114/ada.2017.67077

Long-term treatment of chronic plaque psoriasis with biological drugs can control platelet activation: targeting the bridge between inflammation and atherothrombosis

Bartłomiej Kwiek 1,, Joanna Narbutt 2, Anna Sysa-Jędrzejowska 3, Andrzej Langner 1, Aleksandra Lesiak 2
PMCID: PMC5420605  PMID: 28507492

Abstract

Introduction

Platelet activation is elevated in moderate to severe psoriasis, and the reduction in platelet activation during short-term treatment has already been demonstrated. Soluble P-selectin is a well-established marker of platelet activation.

Aim

To show whether the long-term treatment of psoriasis with biological drugs can reduce elevated platelet activation.

Material and methods

An observational study of 27 patients with chronic plaque psoriasis, treated with infliximab, adalimumab, etanercept, or ustekinumab for up to 12 months was conducted. Psoriasis area and severity index (PASI), serum P-selectin and interleukin (IL)-6 were monitored throughout the treatment.

Results

There was no significant correlation between PASI and platelet activation in our patients. After 3 months of treatment, a significant reduction in PASI and IL-6 was found, while P-selectin was not significantly reduced. When a cohort of patients who had shown elevated P-selectin prior to the treatment was evaluated, a significant reduction in P-selectin was observed in all 8 patients following 3 months; a reduction that was sustained after 6 and 12 months of therapy.

Conclusions

We conclude that PASI is not a good predictor of platelet activity in patients with PASI near to 10. Biological drugs reduce platelet activation in patients who have increased platelet activation prior to treatment, and this effect is stable during chronic therapy.

Keywords: psoriasis, atherothrombosis, comorbidities, platelets, P-selectin, biological

Introduction

Psoriasis is a chronic inflammatory disease. In the course of moderate to severe psoriasis, local inflammatory events in the skin occur in parallel with the systemic hyperinflammatory status reflected by elevated proinflammatory cytokines such as tumor necrosis factor α (TNF-α), interleukin (IL)-12, IL-23, and IL-6 [1].

Chronic inflammatory diseases, including psoriasis, may be associated with an increased risk of cardiovascular disease (CVD) [24]. Severe chronic plaque psoriasis is estimated to reduce lifespan by 3–4 years, and this could be at least in part related to CVD. Psoriasis has been shown to worsen the prognosis following myocardial infarction [5].

There are several hypotheses concerning the link between the pathophysiology of psoriasis and CVD [69]. Platelets are one of the key players in the pathogenesis of atherothrombosis and CVD, and their activation is a risk factor for the outcome of myocardial infarction, stroke, and pulmonary embolism [10, 11]. Antiplatelet treatment reduces the morbidity and mortality in the course of CVD [12].

Platelet activation has been shown in several studies to be elevated in moderate to severe psoriasis, and this seems to be correlated with disease severity [1319]. Yet the significance of antiplatelet treatment for psoriasis comorbidities and psoriasis comorbidity-related deaths remains unknown. Reductions in platelet activation during short-term antipsoriatic treatment has already been shown; however, there has been only one report on the effect of long-term treatment [13, 14, 16, 18]. Biological treatments targeting TNF-α or IL-12/IL-23 are now widely used in the treatment of moderate to severe psoriasis, for both induction and long-term disease-control therapy. It has been speculated that some psoriasis therapies may increase CVD, while others may decrease CVD, and there is mounting evidence of a reduction in the CVD risk following anti-TNF-α treatment [20]. It is still unclear whether the reduction in CVD after such treatment is drug-specific or follows adequate control of skin and/or joint disease. Biomarkers of such control should be available.

Platelet activation markers are good candidates for such biomarkers [13]. There are several direct and indirect methods of platelet activation measurements. Soluble P-selectin is well-established and reliable, and is one of the most accessible indirect markers of platelet activation [13].

Aim

The aim of this study is thus to confirm previous observations of increased platelet activity in chronic plaque psoriasis in a selected subgroup of patients qualified to biological treatment. We also wanted to confirm whether the severity of the disease, as measured by the psoriasis area and severity index (PASI), is correlated with platelet activity in these patients. Further, we wanted to monitor platelet activity during long-term therapy with etanercept, infliximab, adalimumab, and ustekinumab.

Material and methods

The study was designed as an observational cohort study; the procedures followed were in accordance with the Helsinki Declaration of 1975, as revised in 1983, and approved by the local ethical committee. Patients with chronic plaque psoriasis who had been qualified to biological treatment at the Department of Dermatology, Medical University of Lodz were enrolled to this study after giving their informed consent. The decision to employ biological treatment was based on the following criteria: PASI > 10 or body surface area (BSA) > 10% or dermatological life quality index (DLQI) greater than 10 and lack of any contraindications for biological treatment such as tuberculosis, or history of cancer. In addition, patients needed to be resistant to or otherwise unable to use phototherapy, methotrexate, or cyclosporine A.

Patients who had undergone systemic therapy (whether classic or biological) during the 4 weeks prior to the beginning of the treatment were excluded. So were patients with diseases or clinical situations that could influence platelet activation, such as other inflammatory skin diseases, arthritis other than psoriatic arthritis (PsA), chronic or acute inflammatory diseases, current severe infections, surgery within the last month, venous or arterial thromboembolism within the last 3 months, anticoagulation with vitamin K antagonists or low molecular weight heparin in the last 14 days, and uncontrolled diabetes. After excluding 2 patients because of their previous treatment with systemic therapy within the 4 weeks prior to the onset of the study, a total of 27 Caucasian patients (25–65 years old, mean: 50) treated with infliximab (6), adalimumab (12), etanercept (5), or ustekinumab (4) were included into the study. All drugs were dosed in accordance with standard regimens for chronic plaque psoriasis: infliximab 5 mg/kg intravenously followed by additional doses at week 2 and 6 and every 8 weeks thereafter, adalimumab 80 mg subcutaneously (s.c.) at week 0 and 40 mg on every other week starting 1 week after the initial dose, etanercept 50 mg s.c. per week in 2 patients and 2 × 50 mg s.c. weekly in 3 patients, 45 mg of ustekinumab s.c. at week 0, 4 and every 12 weeks later on (all patients weighed ≤ 100 kg). Disease severity assessment (PASI), platelet activity (serum P-selectin), and serum IL-6 were evaluated before and monitored during the treatment, for up to 12 months (3 to 12 months; mean: 9.4 months). Thirty three age- and sex-matched healthy control individuals from the same region of Poland were checked for serum P-selectin and IL-6.

Blood for cytokine analysis was collected from antecubital vein and centrifuged for 10 min at 1600 g to obtain serum that was immediately frozen. Aliquots were stored in –80°C until further use. P-selectin and IL-6 were measured with ELISA kits (R&D systems) and duplicate measurements were carried out according to the manufacturer’s instructions.

Statistical analysis

Statistical analysis was performed with Statistica 10.0 software (StatSoft). Data characterized by a normal distribution are expressed as means ± standard errors of the mean (SEM). Parameters not displaying such a distribution are expressed as medians with ranges, maximum and minimum. Student’s and Wilcoxon tests were used for comparison between two related groups and Mann-Whitney test for unrelated ones. Friedman test was used for comparison across multiple test attempts. Correlations are estimated according to Spearman’s rank correlation method. All p-values < 0.05 were considered statistically significant.

Results

We found no significant difference in serum P-selectin levels between our cohort of patients and the healthy controls (133.76 ng/ml, ranging from 74.13 ng/ml to 274.47 ng/ml vs. 153.53 ng/ml, ranging from 72.08 ng/ml to 195.79 ng/m, respectively) (Figure 1) and no correlation between PASI and serum P-selectin level before the treatment (Figure 2).

Figure 1.

Figure 1

P-selectin levels do not differ significantly between healthy controls and patients with psoriasis before treatment

N = 33 and 27 for controls and patients, respectively. Median, 25–75% and ranges are presented.

Figure 2.

Figure 2

We found no correlation between PASI and serum P-selectin before the treatment. No such correlation was found for PASI and IL-6 either

The PASI and IL-6 levels were reduced significantly after 3 months of therapy, while serum P-selectin did not change significantly (Figure 3 A). When patients treated with different drugs were analyzed separately, P-selectin was not changed significantly either (Figure 3 B). Further treatment for up to 12 months was continued in 17 out of 23 patients and did not change P-selectin level either (Figure 4).

Figure 3.

Figure 3

A – A reduction in PASI and serum IL-6 but not in serum P-selectin was seen after 3 months of treatment (all patients 27). B – Analysis of serum P-selectin change in subgroups treated with various drugs during 3 months of treatment – not significant changes were observed

Medians, 25–75% and ranges are presented.

Figure 4.

Figure 4

Treatment for up to 12 months was continued in 17 patients. Analysis of this group is presented in diagrams. The PASI (A) and IL-6 (C) were reduced throughout the treatment while P-selectin (B) was not significantly altered

Means + standard errors of the mean are presented.

Sub-group analysis of patients who had an elevated serum level of P-selectin at baseline (> 200 pg/ml) showed a significant reduction in platelet activity after 3 months of treatment. What is more, this effect sustained after 6 and 12 months of the observation (Figure 5).

Figure 5.

Figure 5

A – A reduction of P-selectin during 3 months of treatment in all 8 patients with elevated P-selectin before treatment (P-selectin > 200 ng/ml) regardless of the drug used. B – In patients who have continued the treatment throughout 12 months, a reduction in P-selectin was sustained (n = 6)

Discussion

We were unable to confirm previous reports of elevated markers of platelet activity in psoriatic patients compared to healthy controls. There may be several reasons for this finding, of which one is the small sample size of 27 patients. The sample sizes employed in previous studies that have proven this hypothesis varied between 8 and 106 (Table 1) [1319, 21, 22].

Table 1.

Studies reporting on markers of platelet activation in psoriasis

Study N PASI N of PsA Treatment duration Platelet activation marker Platelet activity and PASI correlation
Ludwig et al., 2004 8 4/8 patients with PASI of around 20 or more NR Mean 27 days P-selectin Positive, based on pre- and post-treatment
Karabudak et al., 2008 20 13 ±7 NR NR MPV Higher level when compared with healthy controls but no correlation
Tamagawa-Mineoka et al., 2010 21 Median PASI: 16.2; range: 12.2–18.7 NR 4 patients for 4 weeks sP-selectin PDMP Positive, based on pretreatment
Canpolat et al., 2010 106 PASI 17 in patients with PsA and 10.7 in patients without PsA 48 Not treated MPV Positive
Garbaraviciene et al., 2010 47 Not stated (moderate to severe disease) NR Time of hospitalization (not specified) P-selectin and sP-selectin Positive, based on pre- and post-treatment
Pelletier et al., 2011 52 18 (14–25) NR Not treated PDMP Higher level when compared with healthy controls but no correlation
Saleh et al., 2013 25 Mean PASI 30 for male and 15 for female NR Not treated P-selectin MPV Positive for moderate to severe disease when measured with P-selectin, not present for mild psoriasis
Capo et al., 2014 59 15.5 27 Anti-TNF-α for 6 months MPV Reverse correlation with MPV
Takeshita et al., 2014 53 3 patients with BSA > 10; 21 patients with BSA 3–10 15 Patients on treatment PDMP Higher level when compared with healthy controls but no correlation

N – number of patients, PsA – psoriatic arthritis, NR – not reported, MPV – mean platelet volume, sP-selectin – soluble P-selectin, PDMP – platelet-derived microparticles.

Another possibility is the influence of joint disease. An association between psoriatic arthritis and platelet activation has been previously reported [15, 21, 23, 24]. Up to 40% of psoriatic patients have joint disease, and a clear cut-off point between skin and joint input to the induction of platelet activation in these patients cannot be easily indicated. The status of joint disease was not reported in the majority of previous studies focused on skin psoriasis (Table 1). Analysis of patients with P-selectin > 200 ng/ml has shown slightly higher rates of PsA within this group (Table 2, not significant), but arthritis severity was not studied.

Table 2.

Basic characteristics of two subgroups of patients: those with high (> 200 ng/ml) and those with low (< 200 ng/ml) serum P-selectin levels

Parameter P-selectin high P-selectin low
Number of patients 8 19
PASI 13.1 8.8
PsA, n (%) 4 (50) 5 (26) (NS)
Gender (M/F) 4/4 11/8 (NS)
Age [years] 46.4 52.2 (NS)

NS – not significant difference.

The other explanation for not finding a significant elevation of soluble P-selectin in our study population is that the patients included generally had PASI values of around 10, with only 4 patients having PASI > 12. In previous studies, patients with more severe disease were included, and one study has shown that in patients with mild disease, platelet activation was similar to the control group (Table 1) [18].

This is probably also important for the lack of correlation between PASI and P-selectin in our patients. One of the biggest limitations of measuring disease severity with PASI is its lack of sensitivity for mild disease. All values between one and nine percent of the affected area are given a grade of one, although the surface described may be nine times bigger. This indicates that there could be a certain threshold point where platelets are activated.

The question remains if there are differences between evaluated drugs in their influence on platelet activity. We were not able to see a statistically significant reduction in serum P-selectin when the subgroups of patients treated with different drugs were analyzed separately (Figure 3 B).

A subgroup of patients (8 out of 27) had serum P-selectin > 200 ng/ml, a level not observed in any of healthy individuals from the control group. We have seen a reduction in P-selectin levels during 12 months of treatment only in these patients, which indicates that both anti-TNF-α and anti-IL-12/23 normalize rather than decrease platelet activation.

Conclusions

The results of our study suggest that in patients with relatively low PASI, there are some who already show increased platelet activation. Identifying these patients could help in choosing an adequate treatment to reduce platelet activity – a well-established risk factor for CVD. Our findings suggest that treatment modalities based on biological interventions with either anti-TNF-α or anti-IL-12/23 are good candidates for long-term treatments that can control platelet activation.

Acknowledgments

The study was supported by Project of National Center of Science, Grant No. UMO-2013/11/B/NZ5/00037. and Medical University of Warsaw grant no.: 1M4/W1/10.

Conflict of interest

The authors declare no conflict of interest.

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