DEPLETION AND RECOVERY OF NORMAL B-CELLS DURING AND AFTER TREATMENT WITH CHEMOIMMUNOTHERAPY, IBRUTINIB OR VENETOCLAX

ABSTRACT

Background: Infectious complications are a major cause of morbidity and mortality in Chronic Lymphocytic Leukaemia (CLL). Therapeutic approaches that deplete CLL cells also affect normal B-cells. Optimal treatment would result in eradication of CLL cells and recovery of normal immune function. FLAIR (ISRCTN01844152) is a phase III trial for previously untreated CLL comparing ibrutinib plus rituximab (IR) with fludarabine, cyclophosphamide and rituximab (FCR) and subsequently amended to also compare ibrutinib plus venetoclax (I+V) and ibrutinib alone (I) with FCR. Measurable residual disease (MRD) and normal B-cell levels were assessed at multiple timepoints. Aims: To assess the depletion of normal B-cells during treatment and recovery after end of treatment. Methods: Participants aged under 75 years with <20% TP53-deleted cells were initially randomised to FCR or IR and subsequently to FCR, IR, I+V or I with the IR arm closed after randomisation of 771 participants to FCR/IR. FCR was given for 6 cycles, while treatment in the IR, I and I+V arms continued for up to 6 years except in participants attaining <0.01% MRD who continued treatment for the time taken to achieved MRD <0.01% and then stopped if MRD remained <0.01%. Month (M) 24 was earliest permitted stopping point. MRD flow cytometry was performed according to ERIC guidelines (panel CD19/5/20/43/79/81+ROR1, acquisition of 0.5-2.2 million cells, BD Biosciences Lyric). Additional analysis of normal B-cell subsets was performed in a cohort of >500 patients (panel CD19 to identify B-cells, CD20/5/79b+ROR1 and CD3 to exclude CLL & contaminating cells, with CD27/ 38/IgD/IgM to characterise normal B-cell subsets using a Coulter Cytoflex LX). Results: Normal B-cells were undetectable during FCR treatment and only rarely detectable until 12 months after last FCR cycle. Circulating normal B-cells were reduced in number or undetectable in participants receiving ibrutinibcontaining regimens with greater depletion in the I+V and IR arms relative to I monotherapy. B-progenitors persist through FCR treatment but were depleted during I, I+R or I+V treatment. Normal B-cell levels at 24 and 36 months after randomisation, with time off-treatment if applicable, are shown in Figure 1. In the ibrutinib-containing arms (IR, I, and I+V), there was a trend towards fewer COVID-associated SAE at any time point for participants with detectable B-cells at 24M (4/181, 2.2%) compared to those with no detectable B-cells (14/344, 4.1%) and COVID-associated SAEs were not observed in FCR-treated participants who had recovered any level of normal B-cells by 24M (0/215). However, the data on COVID infections are limited and there was no apparent association between normal B-cell levels at 24M with the proportion of participants experiencing an infectious SAE overall. Assessment of normal B-cell subsets during ibrutinib-based treatment demonstrated a mix of naïve and memory B-cells. Serological response to COVID infection/vaccination in this cohort is currently being performed. Participants stopping I+V treatment at 24-30 months post-randomisation due to MRD eradication showed rapid recovery of normal naive B-cells within 6-12 months after end of treatment in the vast majority (>95%) of evaluable cases. Summary/Conclusion: Normal circulating B-cells are depleted during treatment with rituximab but can persist at a low level during I, IR or I+V treatment. Most patients in remission after treatment with FCR or I+V show recovery of normal B-cells at 12 months of stopping treatment.