Efficacy and safety results from a randomized double-blind study comparing proposed biosimilar ABP 798 with rituximab reference product in subjects with moderate-to-severe rheumatoid arthritis

Eligible subjects included men or women ≥ 18 and ≤ 80 years old with an RA diagnosis (based on meeting the 2010 American College of Rheumatology [ACR]/European League Against Rheumatism [EULAR] classification criteria for RA) [14] for a duration of at least 6 months. Other eligibility criteria included the presence of active RA (defined as ≥ 6 swollen joints and ≥ 6 tender joints based on 66/68 joint count excluding distal interphalangeal joints) at screening and baseline and erythrocyte sedimentation rate (ESR) ≥ 28 mm/h and/or serum C-reactive protein (CRP) > 1.0 mg/dL at screening. Subjects must also have had inadequate response [15] or intolerance to other disease-modifying anti-rheumatic drugs (DMARDs), including intolerance or inadequate response to 1 or more TNF inhibitor therapies. Subjects must have received methotrexate for ≥ 12 consecutive weeks and been on a stable dose (7.5 to 25 mg/week; oral or subcutaneous) for ≥ 8 weeks prior to receiving the investigational product (IP). Subjects taking oral corticosteroids (≤ 10 mg prednisone or equivalent per day) must have been on a stable dose for ≥ 4 weeks before IP initiation, and those receiving nonsteroidal anti-inflammatory drugs (NSAIDs) or low potency analgesics were to have been on a stable dose for ≥ 2 weeks prior to screening.

Exclusion criteria included a diagnosis of Class IV RA (according to ACR revised response criteria) [16], Felty’s syndrome (RA, splenomegaly, and granulocytopenia), history of prosthetic or native joint infection, active infection for which systemic anti-infectives were used ≤ 4 weeks or serious infection ≤ 8 weeks prior to first dose of IP, or malignancy ≤ 5 years (with the exception of treated and considered cured cutaneous squamous or basal cell carcinoma, in situ cervical cancer, or in situ breast ductal carcinoma).

This study was a randomized, double-blind, active-controlled study conducted at 57 centers in 6 countries (Bulgaria, Estonia, Germany, Hungary, Poland, and the USA; ClinicalTrials.​gov NCT02792699) (Fig. 1a). The study was conducted in accordance with the terms of the Declaration of Helsinki, Good Clinical Practice guidelines, and all applicable regulatory requirements.

Over the course of the study, 2 doses of IP were administered, consisting of 2 intravenous (IV) infusions of IP (1000 mg, administered 2 weeks apart). Subjects were randomized (1:1:1) to receive the first dose of either ABP 798, rituximab US, or rituximab EU in a double-blinded manner. At week 24, subjects in the ABP 798 or rituximab EU groups received the second dose of the same treatment, while those in the rituximab US group transitioned to receive ABP 798 for their second dose. Randomization was stratified by geographic region, seropositivity (rheumatoid factor [RF] positive and/or cyclic citrullinated peptide [CCP] positive vs. RF negative, and CCP negative), and number of prior biologic therapies used for RA (1 vs. > 1). Premedications were given according to local guidance and the approved product label; these included acetaminophen, an antihistamine, and methylprednisone 100 mg IV or equivalent 30 min before each infusion.

The total study duration was up to 52 weeks, including a screening period of up to 4 weeks. The first dose was administered on days 1 (week 0) and 15 (week 2), and the second dose on week 24 and week 26. The second dose may have been administered prior to week 24 in individual subjects (i.e., any time between week 16 and week 24), as deemed necessary by the investigator. The end of study (EOS) assessment was conducted at week 48 (or 24 weeks after the first infusion of the second dose for subjects re-treated before week 24).

Disease assessments were conducted at baseline (day 1), week 8, week 12, week 24, week 40, and week 48 (EOS).

Subjects were monitored throughout the study for adverse events (AEs) and concomitant medication use. Clinical laboratory and vital signs were assessed at multiple time points during the study; these data are reported separately [13].

Blood samples for antidrug antibody (ADA) assessments were collected at baseline, week 2, week 24, week 30, and EOS.

Efficacy assessments were secondary objectives in this study. The primary efficacy endpoint was the change from baseline of Disease Activity Score 28-joint C-reactive protein (DAS28-CRP) at week 24. Secondary efficacy endpoints included DAS28-CRP change from baseline at other time points; ACR20 (20% improvement in American College of Rheumatology core set measurements), ACR50 (at least 50% improvement compared with baseline), and ACR70 (at least 70% improvement compared to baseline) at weeks 8, 12, 24, 40, and 48 and hybrid ACR at weeks 8, 12, 24, 40, and 48.

Safety endpoints included treatment-emergent adverse events (TEAEs) and serious adverse events (SAEs).

The number and percentage of subjects who developed binding ADAs and neutralizing ADAs were assessed.

Clinical equivalence was evaluated for the primary efficacy endpoint of change in DAS28-CRP from baseline at week 24 using the full analysis set (FAS), which included all subjects randomized in the study. A sample size of approximately 300 patients was to be randomized in this study; this provided > 90% power at a 2-sided 0.05 significance level to demonstrate equivalence in DAS28-CRP change from baseline at week 24 between the ABP 798 group and the pooled rituximab RP (rituximab EU + rituximab US) group with a margin ranging from − 0.6 to 0.6, assuming a standard deviation (SD) of 1.4 and a true mean difference of zero. The margin was chosen based on previously published findings [17, 18]. The approach for primary efficacy analysis of clinical equivalence depended on the results of the primary PK similarity assessment previously performed and reported [12, 13]. Because PK similarity had been established between rituximab US and rituximab EU, data from the 2 rituximab RP treatment groups (rituximab EU and rituximab US) were combined into a single-pooled rituximab RP group.

Clinical equivalence was tested by comparing the 2-sided 90% CI of the change from baseline at week 24 of DAS28-CRP between ABP 798 and the pooled rituximab RP groups with an equivalence margin of (− 0.6, 0.6). The 2-sided 90% CI was obtained using a repeated measures analysis in which data from all assessed post-baseline time points prior to week 24 were included.

Sensitivity analysis of the primary efficacy endpoint of DAS28-CRP change from baseline at week 24 was conducted on the per protocol analysis set (which included all subjects randomized in the study who had 2 full infusions of the first dose, completed the week 24 disease assessment, and did not experience a protocol deviation that affected their evaluation for the secondary objective of the study to assess clinical efficacy) to test the robustness of the primary efficacy analysis results. Other sensitivity analyses conducted included using an ANCOVA model for the week 24 DAS28-CRP change from baseline data adjusting for stratification factors and baseline DAS28-CRP results, analysis exploring the impact of additional baseline covariates, and a tipping point analysis to assess the sensitivity of results to the different assumptions of missing week 24 DAS28-CRP change from baseline data. Subgroup analyses of the primary efficacy endpoint were also conducted using the same repeated measures analysis model.

Analysis of the secondary efficacy endpoints of DAS28-CRP at other time points (weeks 8, 12, 40, and 48); ACR 20, 50, and 70 at weeks 8, 12, 24, 40, and 48; and hybrid ACR at weeks 8, 12, 24, 40, and 48 were summarized descriptively by treatment (ABP 798/ABP 798, rituximab EU/rituximab EU, or rituximab US/ABP 798).

Subject incidences of AEs, grade ≥ 3 AEs, fatal AEs, SAEs, adverse events of interest (AEOIs), AEs leading to discontinuation from IP or discontinuation from study, and subject incidence of ADAs were summarized using descriptive statistics. AEOIs are defined as clinically noteworthy events for a particular product or class of products that a sponsor may wish to monitor carefully. In this study, prespecified AEOIs included infusion reactions including hypersensitivity, cardiac disorders, serious infections, progressive multifocal leukoencephalopathy, hematological reactions, hepatitis B reactivation, opportunistic infections, hypogammaglobulinemia, severe mucocutaneous reactions, and gastrointestinal perforation. Safety laboratory parameters and vital sign measurements were summarized using descriptive statistics at each scheduled visit.

A total of 311 subjects were randomized and treated with IP (ABP 798, N = 104; rituximab EU, N = 104; rituximab US, N = 103); of these, 289 subjects completed treatment (infusions for the first dose [weeks 0 and 2] and the second dose [weeks 24 and 26]) (ABP 798/ABP 798, n = 97; rituximab EU/rituximab EU, n = 99; rituximab US/ABP 798, n = 93), and 282 competed the completed the study (week 48/EOS) (Fig. 1b). Fifty-five subjects (17.7%) received the first infusion of their second dose between weeks 16 and 24 (ABP 798/ABP 798, n = 21; rituximab EU/rituximab EU, n = 22; rituximab US/ABP 798, n = 12). Twenty-two subjects (7.1%) discontinued IP early (ABP 798/ABP 798, n = 7; rituximab EU/ rituximab EU, n = 5; rituximab US/ABP 798, n = 10). The most common reason for discontinuing IP was an AE (ABP 798/ABP 798, n = 3; rituximab EU/ rituximab EU, n = 1; rituximab US/ABP 798, n = 6). No major imbalance was observed among treatment groups.

PK analysis previously established the PK similarity between rituximab EU and rituximab US [12, 13]. Therefore, as per protocol specification, the rituximab US and rituximab EU groups were combined into a single reference group (pooled rituximab RP) for the primary assessment of clinical equivalence between ABP 798 and rituximab RP. The results of repeated measure analysis of DAS28-CRP change from baseline at week 24 based on FAS are presented in Table 2 and Fig. 2. The mean decrease from baseline in DAS-CRP was − 2.197 (SD, 1.3689) for ABP 798 and − 2.125 (SD, 1.3250) for pooled rituximab RP groups. The 90% CI (− 0.225, 0.264) for the mean difference at week 24 between ABP 798 and the pooled rituximab group was within the predefined equivalence margin (− 0.6, 0.6), thus allowing a conclusion of clinical equivalence between ABP 798 and rituximab. For the comparison between ABP 798 and rituximab US for change from baseline in DAS-CRP, the difference between the means was − 0.070 (90% CI, − 0.353, 0.213), and the difference between the means for ABP 798 vs. rituximab EU was 0.110 (95% CI, − 0.171, 0.392).

Results of sensitivity analyses of the primary efficacy endpoint using the per-protocol analysis set were consistent with those of the primary efficacy analysis, further confirming the clinical equivalence between ABP 798 and rituximab RP (Table 3). Similar conclusions were drawn from other sensitivity analyses using an ANCOVA adjusting for stratification factors and baseline DAS28-CRP results, analysis exploring the impact of baseline covariates (Table 3), and a tipping point analysis. In addition, subgroup analyses also substantiated the results of the primary analysis for subgroups with larger sample size (i.e., age > 65 years, white race, female, binding ADA positive, binding ADA negative, geographic region of Europe, RF positive and/or CCP positive, 1 prior biologic use, and > 1 prior biologic use).

Mean decreases from baseline in DAS28-CRP were similar across the 3 study groups up to week 48, indicating improvement in disease activity that was maintained through the EOS (Fig. 3a). Over the study period (day 1 to week 48), a similar proportion of subjects achieved ACR20, ACR50, and ACR70 responses in the ABP 798/ABP 798, rituximab EU/rituximab EU, and rituximab US/ABP 798 groups (Fig. 3b). The mean hybrid ACR scores were also comparable across the 3 groups (Fig. 3b). Results from analysis of these secondary efficacy endpoints further supported a conclusion of clinical similarity across treatment groups and also indicated no impact of a single transition on efficacy.

All 311 subjects that received IP were included in the safety analysis. The frequency, type, and severity of TEAEs were similar between treatment groups for both the dose periods, i.e., from day 1 to the first infusion of the second dose and from day 1 to EOS (Table 4).

During the first dose period (day 1 to the first infusion of the second dose), approximately half of the subjects (140 [45.0%]) reported at least 1 TEAE across the 3 groups (ABP 798: 52 [50.0%]; rituximab EU: 44 [42.3%]; rituximab US: 44 [42.7%]) (Table 4). A total of 14 (4.5%) subjects experienced grade ≥ 3 TEAEs (ABP 798: 4 [3.8%]; rituximab EU: 6 [5.8%]; rituximab US: 4 [3.9%]); SAEs were reported in 4 (3.8%), 5 (4.8%), and 5 (4.9%) subjects, respectively. Overall, although there were numerical differences in all grade TEAEs, the majority of TEAEs were grade 1 or 2 in severity and were not thought to be clinically meaningful.

Over the entire study (from day 1 through the EOS), a similar proportion of subjects experienced all grade TEAEs in the 3 groups (ABP 798/ABP 798: 67 [64.4%]; rituximab EU/rituximab EU: 54 [51.9%]; rituximab US/ABP 798: 56 [54.4%]) (Table 4). Common AEs reported in ≥ 5% of subjects in any treatment group were upper respiratory tract infection, RA, nasopharyngitis, nausea, and bronchitis.

From day 1 through the EOS, a total of 23 (7.4%) subjects experienced grade ≥ 3 AEs (ABP 798/ABP 798: 5 [4.8%]; rituximab EU/rituximab EU: 9 [8.7%]; rituximab US/ABP 798: 9 [8.7%]) (Table 4). Grade ≥ 3 AEs that occurred in more than 1 subject overall were acute myocardial infarction (1 patient each in the ABP 798/ABP 798 and rituximab EU/rituximab EU groups), back pain (2 patients in the rituximab EU/rituximab EU group), and pneumonia (2 patients in the rituximab EU/rituximab EU group). The incidences of these AEs were similar in the 3 groups.

From day 1 through the EOS, SAEs occurred in 24 subjects and were balanced across the treatment groups (ABP 798/ABP 798: 8 [7.7%]; rituximab EU/rituximab EU: 8 [7.7%]; rituximab US/ABP 798: 8 [7.8]) (Table 4). No deaths were reported in the study. Three (2.9%) subjects in the ABP 798/ABP 798 treatment group, 7 (6.7%) subjects in the rituximab EU/rituximab EU treatment group, and 5 (4.9%) subjects in the rituximab US/ABP 798 treatment group experienced grade ≥ 3 events that were also SAEs. SAEs that occurred in more than 1 subject included acute myocardial infarction, urinary tract infection, back pain, and pneumonia; there were no notable differences in the incidence or severity of SAEs among the 3 groups.

In terms of AEOIs, from day 1 until the EOS, 25 (24.0%) subjects in the ABP 798/ABP 798 group, 15 (14.4%) subjects in the rituximab EU/rituximab EU group, and 23 (22.3%) subjects in the rituximab US/ABP 798 group experienced an AEOI (Table 4). Infusion reactions, including hypersensitivity, were the most common AEOI reported (ABP 798/ABP 798: 16 [15.4%]; rituximab EU/rituximab EU: 9 [8.7%]; rituximab US/ABP 798: 16 [15.5%]). Hypersensitivity AEOIs observed were grade 1 or 2 pruritus, erythema, headache, and rash; no anaphylaxis events were reported. A total of 14 patients experienced hematologic reaction AEOIs (ABP 798/ABP 798: 5 [4.8%]; rituximab EU/rituximab EU: 2 [1.9%]; rituximab US/ABP 798: 7 [6.8%]). The most common of these events was anemia (ABP 798/ABP 798: 3 [2.9%]; rituximab EU/rituximab EU: 0 [0.0%]; rituximab US/ABP 798: 5 [4.9%]). Aside from grade 3 lymphopenia in one patient in the rituximab EU/rituximab EU group, all of the hematologic reaction AEOIs were grade 1 or 2, and none were SAEs. Overall, while numerical differences were observed across treatment groups from day 1 through the EOS, review of the type, nature, and severity of the individual AEOIs did not generate new safety signals compared with those known for the rituximab RP in general.

From day 1 through the EOS, AEs led to IP or study discontinuation in 12 subjects (ABP 798/ABP 798: 3 [2.9%]; rituximab EU/rituximab EU: 2 [1.9%]; rituximab US/ABP 798: 7 [6.8%]) (Table 4). Adverse events leading to IP or study discontinuation were mostly infusion reaction events (i.e., hypersensitivity, urticaria, blister, erythema, pruritus, rash, and rash pruritic), which are expected events with rituximab. The numerical differences observed across treatment groups are not considered clinically meaningful, and no safety trends were noted.

Also, following the single transition from rituximab US to ABP 798, the incidences of all grade TEAEs, grade ≥ 3 AEs, SAEs, AEOIs, and AEs leading to IP or study discontinuations were similar across the 3 groups. Any numerical differences between groups in safety, particularly EOIs including the subcategory of infusion reactions, may be attributable to differences that occurred during dose period 1 prior to switching, indicating that the single switch did not impact safety.

Immunogenicity assessments were done for all 311 subjects (Table 5). At baseline, a total of 7 (6.7%) subjects in the ABP 798/ABP 798 group, 10 (9.6%) subjects in the rituximab EU/rituximab EU group, and 6 (5.8%) subjects in the rituximab US/ABP 798 group tested positive for pre-existing binding ADAs; pre-existing neutralizing ADAs were observed in 2 (1.9%), 2 (1.9%), and 3 (2.9%) subjects, respectively.

Post-baseline, immunogenicity data for the first dose period have previously been reported [12]. From day 1 through the EOS, 14 (14.4%) subjects in the ABP 798/ABP 798 group, 13 (13.8%) subjects in the rituximab EU/rituximab EU group, and 20 (20.6%) subjects in the rituximab US/ABP 798 group developed binding ADAs. Of these, the ADA results were transient (i.e., negative results at the subject’s last time point tested within the study period) for 8 (8.2%), 8 (8.5%), and 11 (11.3%) subjects, respectively. Neutralizing antibodies were detected in 8 (8.2%) subjects in the ABP 798/ABP 798 group, 4 (4.3%) subjects in the rituximab EU/rituximab EU group, and 10 (10.3%) subjects in the rituximab US/ABP 798 groups; the results were transient for 7 (7.2%), 2 (2.1%), and 5 (5.2%) subjects, respectively.