Abstract
Introduction
We report an exploratory analysis of the efficacy and safety of certolizumab pegol (CZP) in Japanese patients with generalized pustular psoriasis (GPP) and erythrodermic psoriasis (EP) (NCT03051217).
Methods
Patients ≥ 20 years with GPP or EP were randomized 1:1 to open-label CZP 400 mg every 2 weeks (Q2W) or 200 mg Q2W (400 mg weeks 0/2/4) for 16 weeks; patients who achieved “much improved” or “very much improved” on the Global Improvement Score (GIS; for GPP) or a PASI 50 response (≥ 50% reduction from baseline Psoriasis Area and Severity Index; for EP) continued to week 52. Efficacy outcomes assessed included Clinical Global Impression of Improvement (CGI-I), Dermatology Life Quality Index (DLQI 0/1), and Itch Numeric Rating Scale (INRS 0). GIS and Japanese Dermatological Association (JDA) severity index were assessed in patients with GPP, and PASI and Physician’s Global Assessment (PGA) in patients with EP. Treatment-emergent adverse events (TEAEs) were evaluated through weeks 0–52.
Results
Of 22 patients randomized, 19 completed week 52. At week 16, all reported outcomes improved with both CZP doses and were generally maintained through week 52. At week 52, 6/7 GPP and 12/12 EP patients achieved CGI-I response (“improved” or “remission”). Also, 4/7 GPP and 7/12 EP patients achieved DLQI 0/1; 2/7 GPP and 2/12 EP patients achieved INRS 0. Meanwhile, 6/7 patients with GPP achieved GIS response, and JDA severity index was reduced from baseline. We found that 9/12 and 5/12 patients with EP achieved PASI 90 and PGA 0/1, respectively. Overall, three serious TEAEs were reported in three CZP 400 mg Q2W-treated patients.
Conclusion
CZP treatment over 16 weeks improved the signs and symptoms of GPP and EP, and improvements were maintained through week 52. No new safety signals were identified.
Trial Registration
ClinicalTrials.gov identifier, NCT03051217.
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Why carry out this study? |
Certolizumab pegol (CZP), an Fc-free PEGylated anti-tumor necrosis factor (TNF) biologic, dosed at 400 mg every 2 weeks (Q2W) and 200 mg Q2W over 52 weeks in Japanese patients, showed clinically meaningful improvements in moderate to severe plaque psoriasis (PSO), with no new safety signals identified. |
Due to the similarity between the pathogenesis of generalized pustular psoriasis (GPP), erythrodermic psoriasis (EP), and PSO, biologic therapies such as anti-TNF and anti-interleukin (IL-12/23, IL-23, and IL-17) treatments, which have demonstrated short- and long-term efficacy and favorable safety profiles in PSO, have also been evaluated in GPP and EP. |
Here, we present the efficacy and safety of 52-week CZP as an add-on treatment in Japanese patients with GPP and EP. |
What was learned from the study? |
Treatment with both doses of CZP resulted in consistent improvements at week 16 across all efficacy endpoints assessed, and these improvements were maintained through week 52. At week 52, 6/7 GPP and 12/12 EP patients achieved Clinical Global Impression of Improvement response, while 4/7 GPP and 7/12 EP patients achieved Dermatology Life Quality Index 0/1. No new safety signals were identified with 52 weeks of CZP treatment. |
This study provides preliminary evidence to support use of CZP as a feasible treatment option for Japanese patients with GPP and EP. |
Introduction
Generalized pustular psoriasis (GPP) and erythrodermic psoriasis (EP) are severe and potentially life-threatening forms of psoriasis [1]. Patients with GPP experience recurrent flare-ups of sudden widespread sterile pustulosis [2], while patients with EP typically present with generalized cutaneous symptoms such as erythema, edema, pruritus, and occasionally, exudative lesions and palmoplantar or diffuse desquamation [3]. EP may develop slowly from chronic psoriasis, or may appear abruptly in patients with mild psoriasis [4]. Both GPP and EP are characterized by systemic inflammation and extracutaneous organ involvement, which can result in significant morbidity and, in severe cases, mortality [2, 3].
In Japan, the estimated prevalence of psoriasis is 0.3% [5]. Among patients with psoriasis in Japan, the prevalence of GPP and EP is estimated to be 1.1% and 0.4%, respectively [5]. The prevalence of GPP and EP varies depending on ethnicity, with Asians reporting a higher prevalence compared with Caucasians (GPP: 9% versus 3% and EP: 4% versus 2% of patients with psoriasis) [6].
The clinical management of GPP and EP is challenging due to various factors including the complexity of the disease and the limited clinical evidence available to support treatment strategies [7, 8]. Current conventional treatment for GPP and EP includes retinoids, cyclosporine, methotrexate, and ultraviolet (UV) phototherapy. However, many patients do not respond to these therapies [2]. Additionally, treatments can be associated with agent-specific safety concerns, such as teratogenicity with retinoids and nephrotoxicity with cyclosporine [2, 3, 7, 8]. Due to the similarity between the pathogenesis of GPP/EP and plaque psoriasis (PSO), biologic therapies such as anti-tumor necrosis factor (TNF) and anti-interleukin (IL-12/23, IL-23, and IL-17) treatments, which have demonstrated short- and long-term efficacy and favorable safety profiles in PSO, have also been evaluated in GPP and EP [2, 3, 7, 8]. In Japan, the Japanese Dermatological Association (JDA) recommends the use of anti-TNF and other biologics (such as anti-IL-17 and anti-IL-12/23) for the treatment of skin symptoms of GPP [9].
Certolizumab pegol (CZP) is a unique Fc-free PEGylated anti-TNF biologic. PEGylation increases the half-life of CZP to 14 days [10]. Unlike other anti-TNF agents, CZP lacks the IgG Fc region that binds the neonatal Fc receptor for IgG (FcRn), and therefore results in no to minimal placental transfer from mothers to infants [11]. In Japan, CZP is currently approved for the treatment of GPP, EP, PSO, psoriatic arthritis, and rheumatoid arthritis [12].
CZP dosed at 400 mg every 2 weeks (Q2W) and 200 mg Q2W over 52 weeks in Japanese patients showed clinically meaningful improvements in moderate to severe PSO, with no new safety signals identified compared with previously reported data in PSO [13, 14]. CZP efficacy and safety has also been demonstrated through 144 weeks, in three global phase 3 trials (CIMPASI-1, CIMPASI-2, and CIMPACT) in North America and Europe [15, 16]. Here, we present the efficacy and safety of 52-week CZP treatment in Japanese patients with GPP and EP.
Methods
Study Design
This study was an exploratory analysis of a 52-week, phase 2/3, double-blind, placebo-controlled, multicenter, randomized trial conducted in Japan (NCT03051217) [13, 14]. Patients were enrolled across 18 sites in Japan and were randomized 1:1 to open-label CZP 400 mg Q2W and CZP 200 mg Q2W (with a loading dose of CZP 400 mg Q2W at weeks 0, 2, and 4), for 16 weeks of treatment during the initial treatment period (Fig. 1). Patients who achieved a “much improved” or “very much improved” response on the Global Improvement Score (GIS; for patients with GPP) or a PASI 50 response (defined as at least 50% reduction from baseline Psoriasis Area and Severity Index; for patients with EP) continued their randomized treatment to week 52. During the maintenance period, patients in the CZP 200 mg Q2W group who failed to achieve a response could have their dose increased to CZP 400 mg Q2W, at the discretion of the investigator. In the opinion of the investigator, if the patient failed to achieve a response with the CZP 400 mg Q2W dose, the patient could be withdrawn from the study. Patients were withdrawn if they developed, in the opinion of the investigator, an aggravation of the primary disease or concomitant disease with hospitalization. All CZP treatments were administered subcutaneously at the study site by trained site personnel not involved in any other study procedures.
This study protocol was reviewed by the institutional review board (IRB) of each institution prior to implementation. Written informed consent was obtained from all patients. The study was carried out in accordance with the applicable regulatory and International Council for Harmonization-Good Clinical Practice requirements, and the Helsinki Declaration of 1964, and its later amendments.
Study Participants
Eligible patients were ≥ 20 years of age with a diagnosis of GPP (based on the JDA criteria for GPP diagnosis) [9] or EP at screening. Patients with a diagnosis of EP had a history of plaque-type PSO and ≥ 80% of baseline body surface area (BSA) affected by PSO. All patients were of Japanese ethnicity.
Patients were excluded if they had a history of primary failure to any prior biologic therapy (no response within the first 12 weeks of treatment); had a total score of ≥ 14 at baseline on the JDA Severity Index (for patients with GPP); had a differential diagnosis of the erythroderma (e.g., erythroderma caused by lymphoma or drug eruption) other than EP (for patients with EP); had a history of chronic or recurrent infection, including active or untreated latent tuberculosis (assessed using an interferon-γ release assay), or were at high risk of infection; had a history of a lymphoproliferative disorder; had class III or IV congestive heart failure (New York Heart Association 1964 criteria) [17]; had a history of, or suspected to have, demyelinating disease of the central nervous system; were breastfeeding, pregnant, or planned to become pregnant/had a partner who planned to become pregnant during the study or within 5 months of the last dose of study drug.
Efficacy Evaluations
The following clinical assessments were made through weeks 0–52: Clinical Global Impression of Improvement response (CGI-I, defined as “remission” or “improved”), Dermatology Life Quality Index 0/1 (defined as absolute DLQI score of ≤ 1), Itch Numeric Rating Scale (INRS 0; defined as absolute INRS score of 0), and absolute INRS scores. Additionally, GIS response (defined as “very much improved,” “much improved,” or “minimally improved”) and JDA Severity Index were assessed in patients with GPP. PASI 75/90 response (defined as ≥ 75/90% reduction from baseline PASI) and Physician’s Global Assessment (PGA) response (defined as absolute score of 0 or 1 with ≥ 2-point improvement from baseline on a five-point scale) were assessed in patients with EP.
Safety Evaluations
Safety data were reported for all patients who received ≥ 1 dose of CZP through weeks 0–52. Adverse events (AEs) were classified according to the Medical Dictionary for Regulatory Activities (MedDRA) version 18.1. Treatment-emergent AEs (TEAEs) were defined as events with onset at the time on or after the first dose of study medication and up to 70 days after the final dose of study medication. Serious AEs were defined as AEs that met one or more of the following criteria: death; life-threatening; significant or persistent disability or incapacity; congenital anomaly or birth defect (including that occurring in a fetus); an important medical event that may jeopardize the patient and may require surgical intervention; initial inpatient hospitalization or prolongation of hospitalization. The predefined AEs of interest (AEOI) were: serious infections, including opportunistic infections; malignancies, including lymphoma; congestive heart failure; demyelinating-like disorders; aplastic anemia, pancytopenia, thrombocytopenia, neutropenia, and leukopenia; serious bleeding events; lupus and lupus-like illness; serous skin reactions such as Stevens–Johnson syndrome, toxic epidermal necrosis and erythema multiforme; potential Hy’s law case, defined as ≥ 3 × the upper limit of normal (ULN) in alanine transaminase (ALT) or aspartate transaminase (AST) with coexisting ≥ 2 × ULN in total bilirubin, in the absence of ≥ 2 × ULN in alkaline phosphatase (ALP), with no alternative explanation for the biochemical abnormality.
Statistical Analyses
The full analysis set (FAS) consisted of randomized patients who received at least one dose of CZP and who had valid efficacy assessment (JDA score or PASI for patients with GPP and EP, respectively) for baseline and for at least one post-baseline visit. The GPP and EP set consisted of patients in the FAS with GPP and EP, respectively, at baseline. The safety set (SS) consisted of randomized patients with GPP or EP who received at least one dose of study medication.
Data are summarized descriptively according to patients’ originally randomized treatment group at week 0. Data during the maintenance treatment period were summarized according to the treatments that patients received. Observed case data are presented. No statistical tests were performed.
Results
Patient Disposition and Baseline Characteristics
Of the 24 patients screened, 22 patients were randomized to CZP 400 mg Q2W (GPP: n = 3; EP: n = 8) and CZP 200 mg Q2W (GPP: n = 4, EP: n = 7; Fig. 2). Demographics and baseline disease characteristics were generally balanced across the CZP treatment groups (Table 1). In patients with GPP, the mean (standard deviation [SD]) baseline JDA total score was 6.3 (4.0) for the CZP 400 mg Q2W group and 5.5 (2.4) for the CZP 200 mg Q2W group. In patients with EP, the mean (SD) baseline PASI was 43.7 (17.9) for the CZP 400 mg Q2W group and 34.3 (9.2) for the CZP 200 mg group. Four patients with GPP and 10 patients with EP were receiving concomitant systemic medications for PSO (Supplementary Table 1).
In total, 19 patients completed week 52 (CZP 400 mg Q2W, GPP: n = 3, EP: n = 7; CZP 200 mg Q2W, GPP: n = 4, EP: n = 5). Three patients (two with EP and one with GPP) on CZP 200 mg Q2W had their dose increased to CZP 400 mg Q2W in the maintenance treatment period (Fig. 2).
Efficacy Outcomes from Weeks 0 to 52 in Patients with GPP
CGI-I Response
At week 2, 6/7 patients achieved a CGI-I response. The number of patients who achieved a CGI-I response increased over time, and by week 16, all patients achieved a CGI-I response (Fig. 3a; Supplementary Fig. 1). The response was generally maintained at week 52, with CGI-I response observed in 6/7 patients.
DLQI 0/1
At week 2, none of the patients achieved DLQI 0/1. The number of patients who achieved DLQI 0/1 increased over time through to week 16. At week 16, 2/7 patients achieved DLQI 0/1. At week 52, the response improved with 4/7 patients achieving DLQI 0/1 (Fig. 4a). Absolute DLQI scores for each patient over 52 weeks are shown in Supplementary Fig. 2a.
INRS 0 and Score
At week 2, none of the patients achieved INRS 0. At week 16, 1/7 patients with GPP achieved INRS 0. At week 52, INRS 0 was achieved by 2/7 patients (Table 2). Reductions from baseline were generally observed in INRS scores at weeks 16 and 52 (Fig. 5a). Absolute INRS scores for each patient over 52 weeks are shown in Supplementary Fig. 3a.
GIS Response
At week 2, all patients with GPP achieved a GIS response, and this was maintained through to week 16. At week 52, 6/7 patients achieved a GIS response (Table 2). GIS responses for each patient over 52 weeks are shown in Supplementary Fig. 4.
JDA Severity Index Total Score
In patients with GPP, improvements from baseline were observed in the mean JDA total scores (2.0–2.5) at week 16; further improvements were observed through week 52 (1.7–2.0) (Fig. 6). Generally, improvements from baseline were also observed in the subtotal for skin symptoms and for systemic symptoms and laboratory findings (Table 3). JDA severity scores for each patient over 52 weeks are shown in Supplementary Fig. 5.
Efficacy Outcomes in Patients Who Underwent Dose Titration
One patient with GPP on CZP 200 mg Q2W had their dose increased to CZP 400 mg Q2W in the maintenance treatment period. At week 52, CGI-I response was achieved (Fig. 3a). The GPP patient who underwent dose titration also achieved a GIS response at week 52 (Table 2).
Efficacy Outcomes from Weeks 0 to 52 in Patients with EP
CGI-I Response
At week 2, 9/15 patients achieved a CGI-I response. The number of patients who achieved a CGI-I response increased over time, and by week 16, all patients (14/14) achieved a CGI-I response (Fig. 3b; Supplementary Fig. 1). The response was generally maintained at week 52, with all patients (12/12) achieving a CGI-I response at week 52.
DLQI 0/1
At week 2, 2/15 patients achieved DLQI 0/1. The number of patients who achieved DLQI 0/1 increased over time through to week 16. At week 16, 6/14 patients achieved DLQI 0/1. At week 52, the response improved with 7/12 patients achieving DLQI 0/1 (Fig. 4b). Absolute DLQI scores for each patient over 52 weeks are shown in Supplementary Fig. 2b.
INRS 0 and Score
At week 2, 2/15 patients achieved INRS 0. At week 16, 3/14 EP patients achieved INRS 0. At week 52, INRS 0 was achieved by 2/12 patients (Table 2). Reductions from baseline were generally observed in INRS scores at weeks 16 and 52 (Fig. 5b). Absolute INRS scores for each patient over 52 weeks are shown in Supplementary Fig. 3b.
PASI Response
At week 4, 4/15 patients achieved PASI 75 or PASI 90 response, and the response improved over time, with 9/14 patients achieving response at week 16. At week 52, 10/12 patients achieved PASI 75 response and 9/12 achieved PASI 90 response (Table 2). At week 16, a reduction from baseline in absolute PASI was observed in both CZP groups (mean [SD]: 8.2 [9.2] for the CZP 400 mg Q2W group and 6.9 [10.2] for the CZP 200 mg Q2W group). Further reduction was observed during weeks 16–52 with week 52 mean (SD) score of 3.2 (3.2) for the CZP 400 mg Q2W/CZP 400 mg Q2W group, 4.5 (4.5) for the CZP 200 mg Q2W/CZP 200 mg Q2W group, and 1.2 (0.6) for the CZP 200 mg Q2W/CZP 400 mg Q2W group (Fig. 7). Absolute PASI scores for each patient over 52 weeks are shown in Supplementary Fig. 6.
PGA 0/1
At week 8, 2/14 patients achieved PGA 0/1 response, and the response improved over time with 4/14 patients achieving response at week 16; the response was maintained through week 52 (Table 2). Absolute PGA scores for each patient over 52 weeks are shown in Supplementary Fig. 7.
Efficacy Outcomes in Patients Who Underwent Dose Titration
Two patients with EP on CZP 200 mg Q2W had their dose increased to CZP 400 mg Q2W in the maintenance treatment period. At week 52, CGI-I response was achieved by both patients (Fig. 3b). At week 52, among both patients with EP who underwent dose titration, one patient achieved DLQI 0/1, one patient achieved INRS 0, both achieved PASI 75 and PASI 90, and one patient achieved PGA 0/1 (Table 2).
Safety
After 52 weeks of CZP treatment, the patient exposures were 4.2 patient-years (PY) and 3.8 PY for patients with GPP receiving CZP 400 mg Q2W and CZP 200 mg Q2W, respectively. For patients with EP, patient exposures were 9.6 PY and 5.7 PY for the CZP 400 mg Q2W and CZP 200 mg Q2W group, respectively (Table 4). TEAEs were reported in 7/7 GPP and 14/15 EP patients. The most common TEAE was nasopharyngitis, which was reported in 2/7 GPP and 7/15 EP patients. In total, three serious TEAEs were reported in three CZP 400 mg Q2W-treated patients: one case of neutropenia reported in a patient with GPP, one case of erythema multiforme reported in a patient with EP (both considered drug-related by the investigator), and one case of pustular psoriasis reported in a patient with GPP (Table 4). No other AEOIs were reported from weeks 0–52; there were no opportunistic infections (including active tuberculosis), malignancies (including lymphoma), TEAEs related to congestive heart failure, serious cardiovascular events, serious skin disorders (such as Stevens–Johnson), lupus, or deaths. In total, three patients with EP discontinued CZP due to TEAEs: one patient receiving CZP 400 mg Q2W discontinued due to erythema multiforme, and two patients receiving CZP 200 mg Q2W discontinued, one due to latent tuberculosis and one due to psoriasis.
Discussion
This is the first study to report the safety and efficacy of CZP treatment in patients with GPP and EP. Treatment with CZP 400 mg Q2W and 200 mg Q2W doses resulted in consistent improvements at week 16 across all efficacy endpoints assessed, and these improvements were maintained through week 52. No new safety signals were identified with 52 weeks of CZP treatment.
Current recommended first-line treatment in the management of GPP and EP are retinoids (such as etretinate and acitretin) and cyclosporine [3, 9]. However, these treatments are associated with safety concerns (including teratogenicity and renal toxicity, and long-term AEs) [2, 3, 8]. In severe cases of GPP and EP, where rapid and effective treatments are essential to prevent complications and mortality, the response observed with conventional agents is often inadequate [2, 3, 7, 8]. As such, there is a need for new treatment options for patients with these severe forms of psoriasis. Although current treatment options for GPP are based on therapies indicated for PSO due to the similarities in pathophysiology, recent evidence has identified the role of IL-36 as a key contributor in the pathophysiology of GPP, compared with PSO, which is predominantly driven by the TNF-α/IL-23/IL-17 axis [8, 18, 19]. As such, anti-IL-36 therapies are currently being studied for the treatment of GPP. Clinical trials for these anti-IL-36 therapies are still ongoing, although phase 1 results have been promising [20]. However, given that these anti-IL-36 therapies are still in very early stages of development and clinical trials, it is still uncertain if they will demonstrate efficacy with a good safety profile. On the other hand, anti-TNFs are available now and are well established in other chronic inflammatory diseases. For patients with GPP and EP, anti-TNFs will provide more immediate and certain treatment options.
With CZP treatment, more than half of the patients achieved CGI-I response at week 2, and by week 16, all patients were CGI-I responders. Improvements in patient health-related quality of life and severity of itch (as measured by DLQI 0/1 and INRS 0, respectively) were also observed for both CZP-treated groups at week 16. In patients with GPP, improvements were observed as early as week 2 and through week 16, based on the GIS response and JDA severity index. In patients with EP, improvements in PASI 75, PASI 90, and PGA 0/1 response were observed at week 16 in both CZP-treated groups. These results suggest that CZP may be a feasible treatment option for patients with GPP and EP due to the rapid onset of response observed across efficacy outcomes. Furthermore, as CZP has previously demonstrated minimal levels of placental transfer from mothers to infants [11], and no to minimal transfer from plasma into breast milk, it may be a viable option for female patients of childbearing age with GPP or EP [21], at various stages of their family planning journey. As both GPP and EP are potentially life-threatening and may result in adverse pregnancy outcomes [22, 23], CZP may provide additional benefits to these patients.
Generally, the improvements observed at week 16 across the collection of efficacy endpoints were maintained through week 52. At week 52, PASI 75 response achieved by patients with EP was comparable to the PASI 75 response achieved by Japanese patients with PSO treated with CZP (CZP 400 mg Q2W: 44/53 [83.0%]; CZP 200 mg Q2W: 35/48 [72.9%]) [14]. During the maintenance treatment period, three patients (two with EP and one with GPP) in the CZP 200 mg Q2W group did not achieve response and underwent a dose escalation to receive CZP 400 mg Q2W, at the discretion of the investigator. At week 52, these patients achieved improvements across most efficacy endpoints. These data suggest that dose escalation may be a useful strategy in patients with EP and GPP who do not achieve adequate response with CZP 200 mg Q2W.
The results of this study are comparable to those of other studies evaluating the efficacy of biologics in Japanese patients with GPP and EP. In a phase 3 trial evaluating the efficacy of the anti-TNF adalimumab, in Japanese patients with GPP (n = 10), the mean change from baseline (CfB) in the total JDA score at week 52 was approximately −6.0 [24]. This was similar to the reduction observed in this study (mean CfB: −4.7). In phase 3 trials of Japanese patients with EP, mean (SD) CfB in absolute PASI at week 52 was −39.9 (9.9) for ixekizumab (anti-IL-17, n = 8) [25, 26] and −36.9 (13.4) for guselkumab (anti-IL-23, n = 10) [27]. This was also comparable to the results observed in this study (CZP 400 mg Q2W/CZP 400 mg Q2W: −41.7 [18.9], CZP 200 mg Q2W/CZP 200 mg Q2W: −22.1 [6.6], and CZP 200 mg Q2W/CZP 400 mg Q2W: −41.8 [1.6]). In Japanese patients with EP, improvements from baseline PASI were observed to be faster with ixekizumab (week 1 CfB, −21.7) [28], than with CZP in this study (week 2 CfB, CZP 400 mg Q2W: −15.7 and CZP 200 mg Q2W: −18.7). By week 12, 100% achieved PASI 75 with ixekizumab [28], compared with 62.5–66.7% with CZP. It is important to note that, owing to the small patient population and difference in study design and population of these trials, comparisons of data between these studies should be interpreted with caution.
Over 52 weeks of treatment, although the incidence of TEAEs and serious TEAEs were slightly higher in this group of patients compared with Japanese patients with PSO, no new safety signals were identified when compared with previously reported data for CZP in other indications, and other anti-TNF medications approved for PSO [16, 29,30,31,32].
Limitations of this trial include a lack of active comparator and the exclusion of patients with history of primary failure to biologic therapy. As this was a clinical trial, the strict inclusion and exclusion criteria may affect the generalizability of these results to clinical practice, and therefore there is a need to use real-world data to monitor the long-term efficacy and safety of CZP in patients with GPP and EP. Lastly, due to the low prevalence of GPP and EP, this study had a small sample size. As such, the results should be interpreted with caution. Sample sizes were also small in clinical trials that evaluated the efficacy of other biologics for the treatment of GPP and EP in Japanese patients, with patient numbers ranging from 10 to 21 [24,25,26,27, 33, 34].
Conclusion
Overall, these data show CZP efficacy in Japanese patients with GPP and EP over 52 weeks of treatment, with no new safety signals identified. This study provides preliminary evidence to support use of CZP as a feasible treatment option for patients with GPP and EP.
References
Langley RG, Krueger GG, Griffiths CE. Psoriasis: epidemiology, clinical features, and quality of life. Ann Rheum Dis. 2005;64(Suppl 2):ii18–23 (discussion ii4–5).
Boehner A, Navarini AA, Eyerich K. Generalized pustular psoriasis—a model disease for specific targeted immunotherapy, systematic review. Exp Dermatol. 2018;27(10):1067–77.
Singh RK, Lee KM, Ucmak D, et al. Erythrodermic psoriasis: pathophysiology and current treatment perspectives. Psoriasis (Auckl). 2016;6:93–104.
Weigle N, McBane S. Psoriasis. Am Fam Physician. 2013;87(9):626–33.
Kubota K, Kamijima Y, Sato T, et al. Epidemiology of psoriasis and palmoplantar pustulosis: a nationwide study using the Japanese national claims database. BMJ Open. 2015;5(1): e006450.
Yan D, Afifi L, Jeon C, Cordoro KM, Liao W. A cross-sectional study of the distribution of psoriasis subtypes in different ethno-racial groups. Dermatol Online J. 2018;24(7). https://doi.org/10.5070/D3247040909.
Falto-Aizpurua LA, Martin-Garcia RF, Carrasquillo OY, et al. Biological therapy for pustular psoriasis: a systematic review. Int J Dermatol. 2020;59(3):284–96.
Gooderham MJ, Van Voorhees AS, Lebwohl MG. An update on generalized pustular psoriasis. Expert Rev Clin Immunol. 2019;15(9):907–19.
Fujita H, Terui T, Hayama K, et al. Japanese guidelines for the management and treatment of generalized pustular psoriasis: the new pathogenesis and treatment of GPP. J Dermatol. 2018;45(11):1235–70.
Weir N, Athwal D, Brown D, et al. A new generation of high-affinity humanized PEGylated Fab’ fragment anti-tumor necrosis factor-α monoclonal antibodies. Therapy. 2006;3(4):535–46.
Mariette X, Förger F, Abraham B, et al. Lack of placental transfer of certolizumab pegol during pregnancy: results from CRIB, a prospective, postmarketing, pharmacokinetic study. Ann Rheum Dis. 2018;77(2):228–33.
Pharmaceuticals and Medical Devices Agency. Available at https://www.info.pmda.go.jp/go/interview/1/820110_3999437G1022_1_014_1F.pdf (in Japanese). Accessed July 2021.
Umezawa Y, Sakurai S, Hoshii N, Nakagawa H. Certolizumab pegol for the treatment of moderate to severe plaque psoriasis: 16-week results from a phase 2/3 Japanese study. Dermatol Ther (Heidelb). 2021;11(2):513–28.
Umezawa Y, Asahina A, Imafuku S, et al. Efficacy and safety of certolizumab pegol in Japanese patients with moderate to severe plaque psoriasis: 52-week results. Dermatol Ther (Heidelb). 2021;11(3):943–60.
Gordon K, Warren RB, Gottlieb AB, et al. Long-term efficacy of certolizumab pegol for the treatment of plaque psoriasis: three-year results from two randomised Phase 3 trials (CIMPASI-1 and CIMPASI-2). Br J Dermatol. 2021;184(4):652–62.
Blauvelt A, Paul C, Kerkhof PVD, et al. Long-term safety of certolizumab pegol in plaque psoriasis: pooled analysis over 3 years from three phase 3, randomised, placebo-controlled studies. Br J Dermatol. 2021;184(4):640–51.
Criteria Committee, New York Heart Association. Diseases of the heart and blood vessels: nomenclature and criteria for diagnosis. 6th ed. Boston: Little, Brown and Co; 1964. p. 114.
Marrakchi S, Guigue P, Renshaw BR, et al. Interleukin-36-receptor antagonist deficiency and generalized pustular psoriasis. N Engl J Med. 2011;365(7):620–8.
Onoufriadis A, Simpson MA, Pink AE, et al. Mutations in IL36RN/IL1F5 are associated with the severe episodic inflammatory skin disease known as generalized pustular psoriasis. Am J Hum Genet. 2011;89(3):432–7.
Bachelez H, Choon SE, Marrakchi S, et al. Trial of spesolimab for generalized pustular psoriasis. N Engl J Med. 2021;385(26):2431–40.
Clowse ME, Förger F, Hwang C, et al. Minimal to no transfer of certolizumab pegol into breast milk: results from CRADLE, a prospective, postmarketing, multicentre, pharmacokinetic study. Ann Rheum Dis. 2017;76(11):1890–6.
Trivedi MK, Vaughn AR, Murase JE. Pustular psoriasis of pregnancy: current perspectives. Int J Womens Health. 2018;10:109–15.
Johansen CB, Egeberg A, Jimenez-Solem E, Skov L, Thomsen SF. Psoriasis and adverse pregnancy outcomes: a nationwide case-control study in 491,274 women in Denmark. JAAD Int. 2022;7:146–55.
Morita A, Yamazaki F, Matsuyama T, et al. Adalimumab treatment in Japanese patients with generalized pustular psoriasis: results of an open-label phase 3 study. J Dermatol. 2018;45(12):1371–80.
Saeki H, Nakagawa H, Nakajo K, et al. Efficacy and safety of ixekizumab treatment for Japanese patients with moderate to severe plaque psoriasis, erythrodermic psoriasis and generalized pustular psoriasis: results from a 52-week, open-label, phase 3 study (UNCOVER-J). J Dermatol. 2017;44(4):355–62.
Okubo Y, Mabuchi T, Iwatsuki K, et al. Long-term efficacy and safety of ixekizumab in Japanese patients with erythrodermic or generalized pustular psoriasis: subgroup analyses of an open-label, phase 3 study (UNCOVER-J). J Eur Acad Dermatol Venereol. 2019;33(2):325–32.
Sano S, Kubo H, Morishima H, et al. Guselkumab, a human interleukin-23 monoclonal antibody in Japanese patients with generalized pustular psoriasis and erythrodermic psoriasis: efficacy and safety analyses of a 52-week, phase 3, multicenter, open-label study. J Dermatol. 2018;45(5):529–39.
Saeki H, Nakagawa H, Ishii T, et al. Efficacy and safety of open-label ixekizumab treatment in Japanese patients with moderate-to-severe plaque psoriasis, erythrodermic psoriasis and generalized pustular psoriasis. J Eur Acad Dermatol Venereol. 2015;29(6):1148–55.
Curtis JR, Mariette X, Gaujoux-Viala C, et al. Long-term safety of certolizumab pegol in rheumatoid arthritis, axial spondyloarthritis, psoriatic arthritis, psoriasis and Crohn’s disease: a pooled analysis of 11 317 patients across clinical trials. RMD Open. 2019;5(1): e000942.
Gordon K, Papp K, Poulin Y, et al. Long-term efficacy and safety of adalimumab in patients with moderate to severe psoriasis treated continuously over 3 years: results from an open-label extension study for patients from REVEAL. J Am Acad Dermatol. 2012;66(2):241–51.
Reich K, Nestle FO, Papp K, et al. Infliximab induction and maintenance therapy for moderate-to-severe psoriasis: a phase III, multicentre, double-blind trial. Lancet. 2005;366(9494):1367–74.
Tyring S, Gordon KB, Poulin Y, et al. Long-term safety and efficacy of 50 mg of etanercept twice weekly in patients with psoriasis. Arch Dermatol. 2007;143(6):719–26.
Imafuku S, Honma M, Okubo Y, et al. Efficacy and safety of secukinumab in patients with generalized pustular psoriasis: a 52-week analysis from phase III open-label multicenter Japanese study. J Dermatol. 2016;43(9):1011–7.
Yamasaki K, Nakagawa H, Kubo Y, Ootaki K. Efficacy and safety of brodalumab in patients with generalized pustular psoriasis and psoriatic erythroderma: results from a 52-week, open-label study. Br J Dermatol. 2017;176(3):741–51.
Acknowledgements
Funding
This study was sponsored by UCB Pharma. This article was based on the original study PS0017 (NCT03051217) sponsored by UCB Pharma. The journal's Rapid Service Fee was funded by UCB Pharma.
Medical Writing, Editorial, and Other Assistance
The authors thank the patients, the investigators and their teams who took part in this study. The authors also acknowledge Sadayoshi Onodera, PhD, UCB Pharma, Japan, for publication coordination and Yi Ling Teo, PhD, Costello Medical, Singapore, for medical writing and editorial assistance based on the authors’ input and direction. Support for third-party writing assistance for this article was funded by UCB Pharma in accordance with Good Publication Practice (GPP3) guidelines (http://www.ismpp.org/gpp3).
Authorship
All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this article, take responsibility for the integrity of the work as a whole, and have given their approval for this version to be published.
Author Contributions
Substantial contributions to study conception and design: YO, YU, SS, NH, HN; substantial contributions to analysis and interpretation of the data: YO, YU, SS, NH, HN; drafting the article or revising it critically for important intellectual content: YO, YU, SS, NH, HN; final approval of the version of the article to be published: YO, YU, SS, NH, HN.
List of Investigators
The authors would like to thank the PS0017 Study Group: Masatoshi Abe of Kojinkai Sapporo Skin Clinic, Satoru Arai of St Luka’s International Hospital, Akihiko Asahina of The Jikei University Hospital, Yoshihide Asano of The University of Tokyo Hospital, Koki Endo of Iwate Medical University Hospital, Takafumi Etoh of Tokyo Teishin Hospital, Susumu Fujiwara of Kobe University Hospital, Mari Higashiyama of Nippon Life Saiseikai Public Interest Foundation and Nippon Life Hospital, Masaru Homma of Asahikawa Medical University Hospital, Atsuyuki Igarashi of NTT Medical Center Tokyo, Shinichi Imafuku of Fukuoka University Hospital, Norito Katoh of University Hospital Kyoto Prefectural University, Akira Kawada of Kindai University Hospital, Mayumi Komine of Jichi Medical University Hospital, Atsuko Matsuo of Kumamoto Shinto General Hospital, Hiroshi Mitsui of The Fraternity Memorial Hospital, Akimichi Morita of Nagoya City University Hospital, Osamu Nemoto of Kojinkai Sapporo Skin Clinic, Eisaku Ogawa of Shinshu University Hospital, Chika Ohata of Kurume University Hospital, Yukari Okubo of Tokyo Medical University Hospital, Shigetoshi Sano of Kochi Medical School Hospital, Mariko Seishima of Gifu University Hospital, Fumiaki Shirasaki of Shirasaki Dermatology Clinic, Yayoi Tada of Tokyo Teikyo University Hospital, Shunsuke Takahagi of Hiroshima University Hospital, Hidetoshi Takahashi of Takagi Dermatological Clinic, Chiharu Tateishi of Osaka City University Hospital, Tadahis Terui of Nihon University Itabashi Hospital, Yoshiki Tokura of Hamamatsu University Hospital, Hideshi Torii of Tokyo Yamate Medical Center, Noriko Umegaki of Keio University Hospital, Toshiyuki Yamamoto of Fukushima Medical University Hospital, Keiichi Yamanaka of Mie University Hospital, Kenshi Yamasaki of Tohoku University Hospital and Masahiro Amano of University of Miyazaki Hospital.
Prior Presentation
This manuscript is based on work that has been previously presented at the 2019 Annual Meeting of the Japanese Society for Psoriasis Research (30–31 August 2019) and 2020 Annual Meeting of the Japan Dermatological Association Congress (Virtual, 4–7 June 2020).
Disclosures
Yukari Okubo: Received research grants from Eisai, Maruho, Shiseido, and Torii Pharmaceutical; current consulting/advisory board agreements from AbbVie, Amgen, Boehringer Ingelheim, Bristol Myers Squibb, Eli Lilly, Janssen and Sun Pharma; speakers bureau from AbbVie, Amgen, Boehringer Ingelheim, Bristol Myers Squibb, Celgene, Eisai, Eli Lilly, Janssen, Jimro, Kyowa Kirin, LEO Pharma, Maruho, Mitsubishi Tanabe Pharma, Novartis, Pfizer, Sanofi, Sun Pharma, Taiho Pharmaceutical, Torii Pharmaceutical and UCB Pharma; clinical trials sponsored by AbbVie, Amgen, Boehringer Ingelheim, Bristol Myers Squibb, Celgene, Eli Lilly, Janssen, LEO Pharma, Maruho, Pfizer, Sun Pharma and UCB Pharma. Yoshinori Umezawa: Consultant and/or speaker fees from AbbVie GK, Janssen Pharmaceutical K.K., Kyowa Hakko Kirin Co., Ltd., Maruho Co., Ltd. and UCB Pharma. Shinya Sakurai: Employee of UCB Pharma. Naoki Hoshii: Employee of UCB Pharma. Hidemi Nakagawa: Consultant, honoraria and/or speaker fees from AbbVie GK, Bristol-Myers Squibb, Eli Lilly Japan K.K., Janssen Pharmaceutical K. K., Japan Tobacco Inc., Kyowa Hakko Kirin Co., Ltd., LEO Pharma, Maruho Co., Ltd., Mitsubishi-Tanabe Pharma, Novartis Pharma K.K., Torii Pharmaceutical Co., Ltd. and UCB Pharma.
Compliance with Ethics Guidelines
This study protocol was reviewed by the institutional review board (IRB) of each institution prior to implementation. Written informed consent was obtained from all patients. The study was carried out in accordance with the applicable regulatory and International Council for Harmonization-Good Clinical Practice requirements, and the Helsinki Declaration of 1964, and its later amendments.
Data Availability
Underlying data from this manuscript may be requested by qualified researchers six months after product approval in the US and/or Europe, or global development is discontinued, and 18 months after trial completion. Investigators may request access to anonymized individual patient-level data and redacted trial documents which may include: analysis-ready datasets, study protocol, annotated case report form, statistical analysis plan, dataset specifications, and clinical study report. Prior to use of the data, proposals need to be approved by an independent review panel at http://www.Vivli.org and a signed data sharing agreement will need to be executed. All documents are available in English only, for a pre-specified time, typically 12 months, on a password protected portal.
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Okubo, Y., Umezawa, Y., Sakurai, S. et al. Efficacy and Safety of Certolizumab Pegol in Japanese Patients with Generalized Pustular Psoriasis and Erythrodermic Psoriasis: 52-Week Results. Dermatol Ther (Heidelb) 12, 1397–1415 (2022). https://doi.org/10.1007/s13555-022-00741-x
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DOI: https://doi.org/10.1007/s13555-022-00741-x