Long-term safety and effectiveness of etanercept in JIA: an 18-year experience from the BiKeR registry

Background

At present, etanercept represents the most commonly prescribed biologic agent for juvenile idiopathic arthritis (JIA) treatment. Children and adolescents with JIA are often treated with etanercept over long periods, sometimes even into adulthood. The objectives of this analysis were to determine the long-term safety of etanercept compared to a biologic-naïve cohort and to assess the long-term treatment response upon continuous etanercept exposure using data from the German biologics registry (BiKeR).

Methods

JIA patients newly exposed to etanercept were documented in the BiKeR registry from January 2001 to March 2019, and baseline characteristics, effectiveness, and safety parameters were analysed. Response to treatment was assessed according to 10-joint Juvenile Arthritis Disease Activity Score (JADAS10), JADAS-defined minimal disease activity and remission, JIA-American College of Rheumatology (ACR) improvement criteria, and ACR-inactive disease definition. Safety assessments were based on adverse event (AE) reports.

Results

A total of 2725 new etanercept users with a diagnosis of JIA were registered. Of these, etanercept was received as a first-line biologic by 95.8% and as monotherapy without concomitant methotrexate by 31.5%. After nine years on continuous treatment, 68.1% of patients presented minimal disease activity, 43.1% JADAS-defined remission on drug, and 36.6% ACR-inactive disease. JIA-ACR30/50/70/90 response rates were still 82/79/71/54% after nine years of treatment. Overall, 2053 AEs (34.3/100PY), including 226 serious AEs (SAE, 3.8/100PY), were observed upon etanercept, compared to 1345 AEs [35.6/100PY; p = 0.3] and 52 SAEs (1.4/100PY; p = 0.0001) in the biologic-naïve cohort. Respective exposure-adjusted rates for etanercept and biologic-naïve patients were 0.9/100PY and 0.2/100PY (p = 0.0001) for serious infections, 0.4/100PY and 0.1/100PY (p = 0.01) for zoster reactivation, 0.3/100PY and 0.03/100PY (p = 0.015) for inflammatory bowel disease, and 1.9/100PY and 1.4/100PY (p = 0.09) for uveitis. Three and two malignancies were documented in the etanercept and biologic-naïve groups, as well as three and one deaths, respectively.

Conclusions

No new safety signal was observed, especially no increased risk for malignancies or autoimmune disorders other than inflammatory bowel disease. However, SAEs and serious infections, though infrequent, were more often reported on etanercept than in biologic-naïve patients. In addition, etanercept demonstrated a long-term maintenance of clinical benefits up to nine years of continuous treatment.

Treatment of juvenile idiopathic arthritis (JIA) represents a major challenge in paediatric rheumatology. Diverse treatment options are currently available. Methotrexate is the most commonly prescribed conventional disease-modifying anti-rheumatic drug (DMARD). Within biologics, etanercept, a tumour necrosis factor inhibitor (TNFi), was the first drug to be approved for JIA in 2001 and represents at present the favoured first-line biologic agent for JIA patients [1]. Etanercept is approved for use in polyarticular JIA in children older than 2 years of age and for use in psoriatic arthritis (PsA) and enthesitis-related arthritis (ERA) in patients older than 12 years of age. For systemic JIA or persistent oligoarthritis, etanercept is not approved, so that its use in these conditions is mostly reserved for children who experience refractory disease [2]. From 2001 to present, the increasing use of etanercept in patients with JIA has raised awareness of rare serious adverse events, such as malignancies and autoimmune conditions, including, but not limited to, uveitis, inflammatory bowel disease, and demyelinating disorders [3,4,5]. Also, etanercept treatment may be required over many years in JIA patients, sometimes even into adulthood. Yet, knowledge about its safety and effectiveness in the long-term is limited.

The German registry for biologics in paediatric rheumatology (BiKeR) is one of the largest national registries on the use of biologics in JIA. Over a period of 18 years, it has accumulated a large quantity of data on etanercept-treated JIA patients. We performed a systematic review of the BiKeR registry to evaluate the long-time safety and effectiveness of etanercept in JIA. A biologic-naïve cohort was used as a comparator for long-term safety analyses.

The German BiKeR registry has been documenting treatment of JIA with biologics since 2001 and has been extensively described in previous reports [6, 7]. It was approved by the ethics committee of the physician board Aerztekammer Nordrhein, Duesseldorf. The BiKeR registry is registered in the European Network of Centres for Pharmacoepidemiology and Pharmacovigilance (ENCePP [8]). Written consent was obtained from patients and parents, and repeated when the patient became an adult. Pseudonymized data were collected for each JIA patient starting a biologic therapy and belonging to the seven ILAR-defined JIA categories [9] as determined by the reporting physician. Dose and frequency of administration were documented. Patient assessment regarding effectiveness and occurrence of adverse events (AEs) was performed at baseline and at follow-up after three and six months and every six months thereafter. After discontinuation of treatment, patients were followed up every six months with a request to report any AE, and patients transitioning to adult care are followed up by the JuMBO registry [10]. Patients of the registry newly starting treatment with etanercept from January 2001 to March 2019 were included in the study if they had assessments at baseline and at least at the three-month visit, irrespective of diagnosis. All follow-up forms received prior to April 2019 were evaluated. Reasons for discontinuation of etanercept treatment were also documented. Multiple reasons could be given. JIA patients who newly started methotrexate treatment and never received biologics were recruited between 2005 and 2011 till inclusion of 1500 patients and served as the control group for long-term safety analyses.

Assessment of effectiveness

Effectiveness parameters were defined as follows. The JIA-American College of Rheumatology (ACR) improvement criteria and the Juvenile Arthritis Disease Activity Score (JADAS) were calculated as previously described [11, 12]. JIA-ACR core set parameters consist of (i) physician global assessment of disease activity (PhysVAS) on a 10-cm visual analogue scale (VAS); (ii) parent/patient global assessment of overall well-being (PatVAS) on a 10-cm VAS; (iii) the Childhood Health Assessment Questionnaire (CHAQ); (iv) the number of joints with active arthritis, defined by the presence of swelling or, if no swelling is present, limitation of motion accompanied by pain, tenderness, or both; (v) the number of joints with limited range of motion; and (vi) the erythrocyte sedimentation rate (ESR). The ACR-inactive disease definition was used according to Wallace et al. [13], requiring no active uveitis or arthritis, no fever, rash, splenomegaly, serositis, generalised lymphadenopathy or elevation of ESR/C-reactive protein (CRP), best possible PhysVAS, and duration of morning stiffness ≤ 15 min. JADAS10 was chosen, which considers a maximum of ten active joints besides PatVAS, PhysVAS, and ESR or CRP, all equally weighted. Rates of JADAS-minimal disease activity (MDA) and JADAS-remission, respectively defined as JADAS10 ≤ 3.8 and JADAS10 ≤ 1, were calculated according to the definition of Consolaro et al. [14]. For each timepoint, all patients with complete data set were considered. Data from patients who discontinued etanercept treatment due to remission were analysed for disease activity also after therapy withdrawal, and rates of JADAS-MDA and JADAS-remission off-biologics were determined.

Safety analysis

Safety was analysed based on AE reporting for all patients during the whole treatment period. AEs and serious AEs (SAEs) were defined according to the International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use (ICH) E6 Section 1.2 [15]. Exposure-adjusted AE rates were calculated per 100 patient-years (PY) with 95% confidence interval (CI). AEs and SAEs were attributed to the etanercept treatment if the patient had been treated with etanercept at the time of the occurrence of the AE or during the last 90 days prior to the AE occurrence, regardless of a possible cotreatment with methotrexate. Malignancies, pregnancies, and deaths were additionally analysed in the ever-treated population.

Statistical analysis

For the comparison of baseline characteristics, the chi-squared, Fisher’s exact, or Mann-Whitney U test was used, depending on data distribution. Mean changes from baseline in each effectiveness parameter were compared using the unpaired t test. Differences in AE rates were analysed using risk ratios (RRs) and the Wald test. A p value < 0.05 was considered statistically significant. Analyses were conducted with IBM SPSS Statistics version 23 (IBM Corp., Armonk, NY, USA) and SAS 9.3 (SAS Institute, Cary, NC, USA).

Study population

Within the JIA patients who initiated etanercept treatment for the first time between 2001 and 2019, 2725 were eligible for the analysis. Mean etanercept dose was 0.79 ± 0.21/kg/week. The administration regimen was once weekly in 56.9% of patients and twice weekly in 43.1%. Overall, the majority of etanercept-treated patients in Germany showed to be diagnosed with (rheumatoid factor (RF)-negative) polyarthritis, extended oligoarthritis, or ERA, although the cohort subtype distribution varied considerably over the years (Fig. 1). Rates of etanercept-treated patients with RF-negative polyarthritis and with ERA increased over time (23.5 and 9.8% in 2001, 37.2 and 22.1% in 2018, respectively), while percentages of patients with systemic JIA or RF-positive polyarthritis decreased (20.4 and 19.4% in 2001, 0.9 and 8.0% in 2018, respectively). The comparison cohort of 1517 JIA biologic-naïve patients starting methotrexate significantly differed from the etanercept cohort for subtype distribution (Table 1). Age at disease onset was comparable between the cohorts, while age at baseline was significantly higher in the etanercept group (12.1 ± 4.4 versus 9.8 ± 4.8 years; p < 0.0001; Table 1). Disease duration at baseline, as calculated from symptom onset to start of cohort defining treatment, was also significantly higher in the etanercept cohort (4.1 ± 3.7 versus 2.1 ± 2.8 years; p < 0.0001). However, a significant decrease in the mean disease duration at etanercept start was observed over time (from 6.0 ± 3.9 in 2001 to 3.3 ± 3.1 years in 2018; p = 0.0001; Supplementary figure S1a). At baseline, 86.5% of etanercept patients had been pretreated with methotrexate, while only 4.2% had been preexposed to other biologics. Concomitant treatment at baseline with systemic steroids was observed more frequently in the biologic-naïve group (91.9 versus 35.7%; p = 0.0001; Table 1). All disease activity parameters at baseline, except for mean ESR levels, were significantly higher in the etanercept cohort. However, the mean JADAS10 at etanercept treatment initiation showed to decrease significantly over the years (from 20.6 ± 7.8 in 2001 to 10.7 ± 5.8 in 2018; p = 0.003; Supplementary figure S1b).

Subtype distribution per recruitment year in the etanercept cohort. sJIA, systemic juvenile idiopathic arthritis; RF-neg PA, rheumatoid factor-negative polyarthritis; RF-pos PA, rheumatoid factor-positive polyarthritis; poJIA, persistent oligoarthritis; eoJIA, extended oligoarthritis; ERA, enthesitis-related arthritis; PsA, psoriatic arthritis; unclass JIA, unclassified juvenile idiopathic arthritis

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Effectiveness

On etanercept, the mean JADAS10 decreased from 15.3 ± 7.5 at baseline to 5.6 ± 5.7 (p < 0.0001) after 3 months and to 4.1 ± 5.3 (p < 0.0001) after 12 months of treatment (Fig. 2). Patients recruited in the most recent years achieved a lower JADAS10 after 12 months on etanercept compared to those enrolled in the earlier years, although the difference did not reach significance (2.3 ± 2.0 in 2018 compared to 6.9 ± 7.2 in 2001; p = 0.0637; Supplementary figure S1b).

Mean JADAS10 as efficacy measure over time. Mean 10-joint Juvenile Arthritis Disease Activity Score (JADAS10) in JIA patients over the course of etanercept treatment. ***p < 0.001

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JADAS-defined minimal disease activity (MDA; JADAS ≤ 3.8) was reached at months 3, 12, and 24 in 844 (45.9%), 990 (58.6%), and 734 (61.8%) etanercept patients, and in 252 (63.0%), 120 (63.8%), and 49 (68.1%) patients after 5, 7, and 9 years. JADAS-remission (JADAS ≤ 1) was reached at months 3, 12, and 24 in 315 (17.2%), 591 (35.0%), and 449 (37.8%) patients, and in 175 (43.8%), 76 (40.4%), and 31 (43.1%) patients after 5, 7, and 9 years (Fig. 3). Over the course of the years, the percentage of patients who reached JADAS-MDA and JADAS-remission following 12 months of etanercept treatment increased, respectively, from 43.1 and 20.9% in 2001 to 72.8 and 45.6% in 2018 (Supplementary figure S1c).

Measures of treatment efficacy over time. Rates of Juvenile Disease Activity Score (JADAS)10-minimal disease activity (JADAS10 ≤ 3.8) and JADAS10-remission (JADAS10 ≤ 1) and rates of patients reaching inactive disease according to Wallace et al. [13] upon etanercept treatment

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ACR-inactive disease according to Wallace et al. [13] was reached at months 3, 12, and 24 by 166 (25.0%), 248 (42.8%), and 180 (46.3%) etanercept patients, and in 84 (46.9%), 43 (48.9%), and 15 (36.6%) patients after 5, 7, and 9 years (Fig. 3). Improvement according to JIA-ACR30/50/70/90 criteria was reached in 74/64/45/24% of patients at month 3, in 81/75/61/42% of patients at month 12, and in 82/76/64/46% of patients at month 24 (Fig. 4). JIA-ACR30/50/70/90 response rates were 84/80/68/53% after 5 years, 82/79/69/57% after 7 years, and 82/79/71/54% after 9 years on etanercept.

ACR improvement rates over time. Improvement rates of disease activity parameters over the course of etanercept treatment according to the JIA-American College of Rheumatology (ACR) criteria

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The effectiveness parameters JADAS-MDA, JADAS-remission, and ACR-inactive disease were also evaluated in an intention-to-treat (ITT) analysis, with patients who discontinued due to remission considered as responders, and patients discontinuing for any other reason as non-responders. In this analysis, JADAS-MDA was reached by 40.2, 41.2, and 33.8% of patients at months 3, 12, and 24, and by 21.3, 19.7, and 19.0% after 5, 7, and 9 years. JADAS-remission was reached by 15.1, 25.6, and 23.9% of patients at months 3, 12, and 24, and by 19.7, 19.1, and 18.7% after 5, 7, and 9 years. ACR-inactive disease was reached by 18.8, 27.0, and 25.0% of patients at months 3, 12, and 24, and by 19.6, 19.2, and 18.8% after 5, 7, and 9 years.

Discontinuations and remission rates off-biologics

Over 18 years of observation, etanercept was discontinued by 1655 (60.7%) patients. Rates and reasons for discontinuation are listed in Table 2. The most common reason for discontinuation was remission (23.9%), followed by inefficacy (21.8%) and intolerance (7.1%). Of the 652 patients discontinuing due to remission, 521 patients had available data one year after etanercept withdrawal. In the first year, 126 (24%) patients relapsed, and 395 (76%) remained without etanercept or other biologic agents. Of these, 214 (54%) maintained at least JADAS-MDA and 121 (31%) remained in JADAS-remission off-biologics (Supplementary figure S2). Five years after etanercept discontinuation, 105 patients remained without etanercept or other biologic agents, of which 27 (26%) maintained at least JADAS-MDA and 11 (11%) JADAS-remission off-biologics.

Safety

During 5988 patient-years of etanercept exposure, a total of 2053 AEs were reported to the registry (Table 3). No significant difference in exposure-adjusted AE rates was observed between etanercept (34.3/100PY) and biologic-naïve patients (35.6/100PY; p = 0.3). The AEs qualifying as serious (SAEs) were significantly more frequent in the etanercept cohort (3.8 versus 1.4/100PY; p = 0.0001). The incidence of serious infections was significantly higher in the etanercept group (0.9 versus 0.2/100PY; p = 0.0001), while neutropenia rates were comparable in the two cohorts (0.07 versus 0.05/100PY; p = 0.8). All reported opportunistic infections, but for one case of latent tuberculosis, were herpes zoster reactivation, and were more often observed under etanercept (0.4 versus 0.1/100PY; p = 0.01). The case of latent tuberculosis consisted in a positive Quantiferon Gold test without any clinical symptom or change in chest radiograph and was documented in a patient on methotrexate and with previous etanercept treatment.

Inflammatory bowel disease (IBD) occurred with significantly greater frequency in etanercept patients (0.3 versus 0.03/100PY; p = 0.015). Nineteen patients developed IBD on etanercept (14 female, 3 HLA-B27 positive). Of these, six patients were diagnosed with RF-negative polyarthritis, six with extended polyarthritis, four with ERA (of which three male and two HLA-B27 positive), and one each with RF-positive polyarthritis, PsA, and systemic JIA. Two developed a sacroiliitis, one an iridocyclitis, and one an alpha-1-antitrypsin deficiency. Mean age at arthritis onset was 6.8 ± 4.3 years, and mean age at IBD onset was 13.7 ± 2.7 years. Patients developed IBD after 2.3 ± 1.9 years on ongoing etanercept therapy. All 19 patients had been pretreated with MTX. Rates of psoriasis (0.07 versus 0.003/100PY; p = 0.4) and aggravation/new onset of uveitis (1.9 versus 1.4/100PY; p = 0.09) did not differ significantly between the two analysed cohorts. One patient in the etanercept cohort developed demyelination and none in the biologic-naïve control cohort. The lesion, a minor alteration of the periventricular white matter, was discovered incidentally in an asymptomatic patient and has been described earlier [7]. Other reported immune-mediated events were Henoch-Schonlein purpura, leukocytoclastic cutaneous vasculitis, and lupus-like syndrome in one patient each. All three patients were on etanercept treatment.

Fifteen reports of suicidal intention or ideation, suicide attempt, or depression were documented in the etanercept cohort. Six were observed in RF-negative and one in RF-positive polyarthritis patients, two cases in extended and one in persistent oligoarthritis patients, and two in ERA and three in PsA patients. In all, the occurrence of suicide intention/depression was significantly higher in the etanercept group than in the biologic-naïve group (0.25 versus 0.05/100PY; p = 0.04).

Three pregnancies occurred in patients under etanercept treatment at the time of conception. A 17-year-old patient who was treated with etanercept and methotrexate delivered at term a healthy 3360-g male infant after a pregnancy without complications. Treatment was interrupted as her pregnancy was diagnosed at 6 weeks of gestation. The child was developing normally at two months of age. An 18-year-old patient gave birth to a healthy male infant, weight and gestational age of which have not been reported by the documenting physician. At the age of six months, the child showed normal growth and development. The third patient decided on an induced abortion at 12 weeks of gestation. Additionally, a miscarriage after 12 weeks of gestation was reported to the registry in an 18-year-old patient, two years after discontinuation of etanercept. She had been treated with etanercept 50 mg weekly over nine months. The patient received hydroxychloroquine 300 mg daily from 20 months before conception through eight weeks of pregnancy. No pregnancy was recorded in the biologic-naïve cohort.

Three malignancies were documented in patients on etanercept at the time of diagnosis (0.05/100PY). An 18-year-old male patient developed a non-familial thyroid carcinoma. One case each of Hodgkin’s and non-Hodgkin’s lymphoma was reported in two male patients. Malignancies were reported to the registry in five other patients who had been exposed to etanercept in the past: two cases of lymphoproliferative disorder and one case each of anaplastic ependymoma, yolk sac carcinoma, and cervix dysplasia. All patients recovered. In the biologic-naïve cohort with methotrexate, two cases of acute lymphatic leukaemia (ALL) were documented (0.05/100PY). One patient recovered; the second died. All malignancy cases have been previously described [16].

In all patients ever treated with etanercept, five deaths were reported, three of these during drug exposure. Two deaths occurred during adolescence and three in adulthood. One patient with systemic JIA died due to septic shock while on treatment with etanercept, after having been pretreated with cyclophosphamide and chlorambucil years before. A second patient with systemic JIA succumbed to heart failure by macrophage activation syndrome (MAS), one year after discontinuation of etanercept due to inefficacy. Both deaths occurred at the age of 16 years and have been formerly reported [17]. Of the three deaths during adulthood, one occurred in a 22-year-old due to perimyocarditis with arrhythmia, eight weeks after voluntary discontinuation of etanercept. A second patient died at the age of 22 years by suicide, seven years after etanercept discontinuation, and a third one died at the age of 23 years due to pseudomembranous enterocolitis by a septic urinary tract infection with renal failure and pancytopenia after 13 years of etanercept exposure. The events were considered as not related to etanercept treatment. In the biologic-naïve group, one death was reported. A 13-year-old female patient on methotrexate succumbed to ALL.

The current registry study represents the largest cohort of etanercept-treated JIA patients studied. To our knowledge, it is the first report on safety and effectiveness of etanercept including all JIA categories and following patients up to nine years of continuous treatment.

A significant improvement from baseline was observed in all analysed efficacy parameters already after three months of treatment. These improvements were maintained during up to nine years of sustained drug use, in accordance to observations from previous studies [18,19,20]. Patients who had been recruited in most recent years (2016–2018) had higher JADAS-MDA and JADAS-remission responses after one year of treatment compared with patients recruited in earlier years (2001–2003). This is likely reflective of the shorter disease duration and lower disease activity at the start of treatment of the formers, supporting the increasing evidence in the literature indicating a positive prognostic effect of an early aggressive treatment due to a suggested window of opportunity [21].

Next to an as-observed analysis evaluating disease activity in patients who continued treatment, we performed an effectiveness analysis in the ITT population. In this analysis, the percentage of patients reaching JADAS-remission or ACR-inactive disease stayed stable over time, while the percentage of patients presenting JADAS-MDA decreased over time. However, this represents a conservative assessment, since it presumes that all patients lost to follow-up did poorly, while only 28.9% of the patients discontinued due to inefficacy or intolerance. Of note, one third of the patients who discontinued due to remission remained in clinical remission off-biologics one year after etanercept withdrawal.

Incidence of adverse events was low, and no new safety signal emerged with long-term continuous etanercept exposure. Rates of SAE and serious infection were higher than in biologic-naïve patients, remaining yet low in both groups. By interpreting these data, it should be considered that patients initiating etanercept, according to JIA therapy recommendations, were mostly those who failed to respond or responded inadequately to treatment with ≥ 1 conventional DMARD, hence, those with a refractory JIA. They presented longer disease duration and higher disease activity, and had received more previous treatments, so one or more of these factors may have accounted for the higher serious infection rate. In fact, as described by Beukelman et al. [22], it is hypothesised that, in JIA patients, the underlying disease process itself, independently from treatment, might increase the risk of serious infections. The comedication with methotrexate, documented in two thirds of the etanercept cohort, may be also a contributing factor, as it was showed in prior studies that serious infections had a higher incidence in patients treated with etanercept-methotrexate combination treatment compared to monotherapy [3]. The rates for serious infections in the here analysed etanercept cohort were similar to those reported in other long-term registry studies [19, 20], but lower than what described in long-term controlled clinical trials [18, 23]. While other studies have also found higher serious infection rates upon etanercept [3, 24], others have described comparable rates to non-biological treatments. A large study comparing Medicaid data from 2713 new TNFi users found no significant difference in hospitalised infection rates between TNFi and methotrexate treatments [25]. In our study, herpes zoster reactivation was the only opportunistic infection reported, and it was more often observed in etanercept than in biologic-naïve patients with methotrexate, similarly to what described by other groups [23, 24].

Incidence of new-onset IBD was higher in etanercept than in biologic-naïve patients, which is consistent with previous findings [26]. Since etanercept was shown to be ineffective in Crohn’s disease, gastrointestinal manifestations in patients with IBD-associated arthritis may occur more likely under treatment with etanercept [27]. Rates of other autoimmune disorders, mostly psoriasis and uveitis, were comparable within the two groups. Only one case of suspected demyelination has been reported to our registry in conjunction with etanercept exposure. In the data from the large multinational Pharmachild/PRINTO pharmacovigilance study, demyelination was also a rare event [28].

Prior studies have suggested that patients with JIA may be at increased risk of malignancy [4]. In our study, treatment with etanercept did not associate with a higher incidence of malignancies. Similar results were reported in a Scandinavian registry study [5] as well as in the Pharmachild registry [28].

The interpretation of the results provided here is potentially influenced by the classic limitations accompanying registry studies, such as lack of blinding, lack of randomisation, and, for the long-term efficacy analysis, lack of an internal comparator. Comparison analyses between the two groups in terms of efficacy were, for the nature itself of the study as a registry analysis and not a randomised controlled clinical trial, not feasible. In addition, the majority of the etanercept patients had already received methotrexate and, as per JIA treatment recommendations, had failed to respond or responded inadequately to it, if a switch or escalation of treatment was required. Moreover, in two thirds of etanercept patients, methotrexate was not discontinued, but etanercept was added to it. Similarly, the biologic-naïve group used as a comparator for the long-term safety assessment presented significant differences at baseline to the etanercept group. This is due to the fact that while the latter had a refractory and more active disease, the former had just begun treatment with methotrexate as first-line DMARD.

Yet, registry studies remain of great importance because they reflect routine care and allow investigation of safety and effectiveness in a complete spectrum of patients and in a real-world setting. Differently, decisions in randomised clinical trials (RCTs) may be influenced by protocol and inclusion/exclusion criteria generate a mostly homogeneous study population of selected patients, e.g. by excluding determinate subtypes, comorbidities, or concomitant drugs. Moreover, in the present analysis, the high number of patients and the long study period allow detection of rare adverse events and adverse events occurring with long-term exposure.

While no increased rates of malignancies and autoimmune disorder other than IBD were observed under etanercept, SAE and serious infection ratios were lower in the biologic-naïve patients with methotrexate, highlighting the high tolerability of the latter. Moreover, long-term etanercept treatment demonstrated a sustained efficacy in this large cohort of JIA patients.

Not applicable.

ACR:

American College of Rheumatology

AE:

Adverse event

ALL:

Acute lymphatic leukaemia

BiKeR:

Biologics in paediatric rheumatology registry

CHAQ:

Childhood Health Assessment Questionnaire

CI:

Confidence interval

CRP:

C-reactive protein

DMARD:

Disease-modifying anti-rheumatic drug

ENCePP:

European Network of Centres for Pharmacoepidemiology and Pharmacovigilance

ERA:

Enthesitis-related arthritis

ESR:

Erythrocyte sedimentation rate

HLA:

Human leucocyte antigen

IBD:

Inflammatory bowel disease

ICH:

International Council for Harmonisation of Technical Requirements for Pharmaceuticals for Human Use

IL:

Interleukin

ILAR:

International League of Associations for Rheumatology

JADAS:

Juvenile Disease Activity Score

JADAS10:

10-joint Juvenile Disease Activity Score

JIA:

Juvenile idiopathic arthritis

JIA-ACR:

American College of Rheumatology improvement criteria for JIA

JRA:

Juvenile rheumatoid arthritis

JuMBO:

Juvenile arthritis-methotrexate-biologics long-term observation

MAS:

Macrophage activation syndrome

MDA:

Minimal disease activity

NSAIDs:

Nonsteroidal anti-inflammatory drugs

PatVAS:

Parent/patient global assessment of overall well-being on a 10-cm VAS

PhysVAS:

Physician global assessment of disease activity on a 10-cm VAS

PRINTO:

Paediatric Rheumatology International Trials Organisation

PsA:

Psoriasis arthritis

PY:

Patient-years

RCTs:

Randomised clinical trials

RF:

Rheumatoid factor

RR:

Risk ratio

SAE:

Serious adverse event

SD:

Standard deviation

TNF:

Tumour necrosis factor

TNFi:

Tumour necrosis factor inhibitor

VAS:

Visual analogue scale

The authors thank Rainer Berendes, Michael Borte, Gundula Böschow, Normi Brück, Dennis Conzelmann, Wolfgang Emminger, Maria Fasshauer, Isa Feddersen, Dirk Föll, Hermann Girschick, Johannes-Peter Haas, Daniel Haselbusch, Christian Huemer, Markus Hufnagel, Tilmann Kallinich, Martin Kirschstein, Rolf Michael Küster, Hartwig Lehmann, Eggert Lilienthal, Kristina Linnemann, Thomas Lutz, Veronica Ntam, Nils Onken, Prasad Thomas Oommen, Martina Prelog, Jürgen Quietzsch, Christoph Rietschel, Betina Rogalski, Peggy Rühmer, Michaela Sailer-Höck, Klaus Tenbrock, Angelika Thon, Olaf Zimmermann, and especially all patients and their families for participating in the registry.

The BiKeR registry is supported by an unrestricted grant from Pfizer, Germany; Abbvie, Germany; MSD, Germany; and Roche, Germany. Study design, data collection, analysis, interpretation of the data, writing of the manuscript, and publication of this article are not influenced by the study sponsors and are full and sole responsibility of the authors.

Authors and Affiliations

1. Division of Paediatric Rheumatology, Sankt Augustin Asklepios Children’s Hospital, 53757 Sankt Augustin, Germany

   Giulia Armaroli, Ariane Klein & Gerd Horneff

2. Cologne University, Medical School, Cologne, Germany

   Ariane Klein & Gerd Horneff

3. Division of Paediatric Rheumatology, Northwest German Rheumatology Center, St. Josef Stift, Sendenhorst, Germany

   Gerd Ganser

4. Paediatric Rheumatology Medical Center, Goettingen, Germany

   Michael J. Ruehlmann

5. Division of Paediatric Pulmonology, Allergology and Immunology, Hannover Medical School, Hannover, Germany

   Frank Dressler

6. Division of Paediatric Rheumatology, Olgahospital, Stuttgart, Germany

   Anton Hospach

7. German Rheumatism Research Center, Charité University Hospital, Berlin, Germany

   Kirsten Minden

8. Department of Paediatrics, Berlin-Buch Helios Hospital, Berlin, Germany

   Ralf Trauzeddel

9. Paediatric Rheumatology Medical Center, Hamburg, Germany

   Ivan Foeldvari

10. Department of Paediatrics, Tuebingen University, Tuebingen, Germany

    Jasmin Kuemmerle-Deschner

11. Division of Paediatric Rheumatology, Prof. Hess Children’s Hospital, Bremen, Germany

    Frank Weller-Heinemann

12. Department of Paediatrics, St. Marien Hospital, Amberg, Germany

    Andreas Urban

Contributions

All authors made substantial contributions to the acquisition of data. AG, GH, and AK analysed and interpreted the data. All authors approved the final version of the manuscript for publication.

Corresponding author

Correspondence to Giulia Armaroli.

Ethics approval and consent to participate

The German BiKeR Registry was approved by the responsible independent ethics committee of the Aerztekammer Nordrhein, Duesseldorf. Written informed consent was obtained from patients and parents/legal guardians and repeated if patient became adult. Only pseudonymized data were collected.

Consent for publication

Not applicable.

Competing interests

AK has received congress travel fees from Sobi and Sandoz as well as advisory board honoraria from Celgene. FD has received honoraria for lectures from Pfizer, Abbvie, and Novartis. AH has received advisory board honoraria from Novartis, Chugai-Roche, and Sobi. KM has received honoraria from Abbvie, GSK, Biermann, Medac, and Sanofi. IF discloses advisory board participation for Novartis, Genzyme, Bayer, Lilly, Pfizer, Abbvie, and Sanofi. JKD has received consultant/speaker fees from Novartis and Sobi, as well as pharmaceuticals and grant support from Sobi and Novartis. FWH has received speaker honoraria from Pfizer, Abbvie, Novartis, Sobi, and Roche. GH has received research funds, advisory board membership, and honorary fees from Abbvie, Pfizer, Novartis, and Roche/Chugai. The other authors have declared no competing interests.

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