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Rituximab (RTX) is a chimeric monoclonal anti-CD20 antibody used in the treatment of various rheumatic diseases.1 Although generally well tolerated, infusion-related reactions (IRR) represent the most common adverse event associated with treatment and are difficult to predict. In patients undergoing treatment for rheumatoid arthritis, the incidence of IRR is quoted as 3%–4%2 3; however, in systemic lupus erythematosus (SLE) this is significantly higher at 19%.4 To date, few studies have assessed the role antidrug antibodies (ADA) play in the lack of response or development of IRR to RTX in SLE. Here, we investigate how the presence of ADA relates to IRR and effectiveness of RTX therapy in SLE.
Fifty-seven patients fulfilling American College of Rheumatology criteria were recruited from the lupus clinic at University College London Hospital, UK. All patients were receiving RTX for active SLE (British Isles Lupus Assessment Group [BILAG] A or 2B scores) for the first time. Confirmed IRR were recorded in electronic health records. Baseline characteristics including complement C3 (C3), double-stranded DNA antibody titres (dsDNA) and BILAG score were recorded at the time of treatment and at each subsequent clinic visit. CD19 positive lymphocyte (CD19) levels were measured at 1 and 6 months following treatment. IRR were classified in accordance with Common Terminology Criteria for Adverse Events v4 criteria (online supplementary table 1).5 Presence of ADA was assessed via a bridging electrochemiluminescence assay using biotinylated and ruthenylated RTX as capture and detection. Χ2 with Bonferroni correction was used to compare categorical differences between ADA+ and ADA- groups. Paired t-test was used to assess for differences immediately prior to and at 6 months following treatment.
As shown in table 1, ADA were identified in 37% of patients following treatment. ADA+ patients were younger both at diagnosis (p=0.03) and at the time of first treatment with RTX (p<0.001). In spite of low overall numbers, ADA were more commonly seen in males (p=0.04). There was no significant difference in concomitant treatment, disease manifestation and ethnicity. At the time of treatment, there was no difference in C3, dsDNA titres or BILAG. Figure 1 demonstrates that at 6 months post-treatment, ADA- patients show a significant increase in C3 levels (p=0.003) and reduction in dsDNA antibody binding (p=0.008) in keeping with effective response to treatment. In ADA+ patients, although normalisation of C3 was seen at 6 months (p=0.007), there was no observed improvement in dsDNA titres (p=0.96). Both ADA+ and ADA- patients displayed a significant improvement in global BILAG score 6 months after treatment (p<0.0001). There was no difference in CD19 between ADA+ and ADA- patients at either 1 or 6 months post-treatment. Of the 57 patients recruited, 25 patients underwent retreatment with RTX (18 ADA+ and 7 ADA- patients). All ADA+ patients developed IRR, whereas no IRR was reported in those who were ADA- (p<0.001). Severe reactions resulting in hospitalisation were seen in three cases in which ADA titres were >1500 IU. In one such case, subsequent treatment with ofatumumab (a fully humanised anti-CD20 monoclonal antibody) was well tolerated without the occurrence of further IRR.
We demonstrate that ADA to RTX are common in those undergoing treatment for SLE and have a clear association with subsequent IRR. Contrary to previous studies,6 our findings suggest that CD19 count is not affected by ADA, however the presence of ADA appeared to impair normalisation of dsDNA titres following treatment. If validated, these findings may support routine screening for ADA prior to treatment with RTX, thus potentially identifying patients at risk of developing IRR and prompting greater caution and enhanced surveillance. In the context of high ADA titres, this may necessitate the use of an alternate B-cell depleting agent (such as ofatumumab).
CW and MM are joint first authors.
Handling editor Josef S Smolen
Collaborators The ABIRISK Consortium.
Contributors CW, MM, EJ and CM were involved in the design of the study and data interpretation. CW, ES and MM performed the research, collected, analysed and interpreted the data. DAI provided BILAG information; AS performed ADA assays. CW, MM, EJ and CM wrote the manuscript. CW, MM are joint first authors. All authors approved reviewed and approved the manuscript’s content before submission.
Funding The study was performed as part of the Innovative Medicines Initiative Joint Undertaking under grant agreement no 115303, resources of which are composed of financial contribution from the European Union’s Seventh Framework Program (FP7/2007–2013) and European Federation of Pharmaceutical Industries and Associations (EFPIA) in kind contribution. CW and CM are funded by LUPUS UK (176255; 174935). CW is funded by Versus Arthritis (549143). MM was funded by a Wellcome Trust grant awarded to CM (090406/Z/09/Z).
Competing interests None declared.
Patient consent for publication Obtained.
Ethics approval Ethics approval for this study was approved by the South Central - Hampshire B Research Ethics Committee (Ref 14/SC/1200)
Provenance and peer review Not commissioned; externally peer reviewed.
Data sharing statement There are no unpublished data relating to this study.
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