CELMoDs are being actively trialed as a maintenance therapy after CAR T-cell treatment. The strategy is to leverage the CELMoDs' ability to enhance T-cell function and upregulate effector T-cells to boost the activity and persistence of the CAR-T product, potentially leading to more durable responses and preventing relapse.
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An exploratory strategy for DLBCL patients involves using ctDNA to detect minimal residual disease after CAR T-cell therapy. This allows for early intervention with bispecific antibodies when the disease burden is low, potentially preventing full clinical progression, a shift from reactive to proactive treatment.
BTK inhibitors like ibrutinib can improve T-cell function. When combined with liso-cel CAR-T, this synergistic effect dramatically improves outcomes in heavily pretreated patients, increasing the complete response rate from 20% to 45% and the overall response rate from 48% to 86%.
Despite exciting early efficacy data for in vivo CAR-T therapies, the modality's future hinges on the critical unanswered question of durability. How long the therapeutic effects last, for which there is little data, will ultimately determine its clinical viability and applications in cancer versus autoimmune diseases.
The efficacy of Siltacel stems from a powerful initial expansion that eliminates cancer upfront. The CAR-T cells are often undetectable beyond six months, indicating their curative potential comes from an overwhelming initial response rather than persistent, long-term immune policing of the disease.
Unlike older IMiDs where T-cell effects are secondary, CELMoDs have a powerful, independent pro-T-cell mechanism. This dual action is so significant that in the future, CELMoDs will be prescribed not just for their direct anti-myeloma effects, but specifically to enhance the efficacy of T-cell therapies like CAR-T and bispecific antibodies.
Using a BCMA bispecific antibody first can exhaust a patient's T-cells or cause tumors to lose the BCMA target, rendering a subsequent BCMA-targeted CAR-T therapy ineffective. The optimal sequence is CAR-T first, which preserves T-cell function and BCMA expression, leaving bispecifics as a viable later-line option.
To combat immunosuppressive "cold" tumors, new trispecific antibodies are emerging. Unlike standard T-cell engagers that only provide the primary CD3 activation signal, these drugs also deliver the crucial co-stimulatory signal (e.g., via CD28), ensuring full T-cell activation in microenvironments where this second signal is naturally absent.
Five-year follow-up from the CARTITUDE-1 trial suggests a potential cure for multiple myeloma is achievable. With roughly one-third of heavily pretreated patients remaining in remission at five years—and some confirmed as MRD-negative—the concept of a cure is now part of the operational discussion among specialists, a monumental shift for a disease long considered incurable.
Rather than expecting cell therapies (CAR-T, TIL) to eradicate every cancer cell, Dr. Radvanyi reframes them as powerful adjuvants. Their role is to inflict initial damage, kill tumor cells, and release antigens, creating an opportunity to prime a broader, secondary immune response with other modalities like vaccines or checkpoint inhibitors.
The success of CAR-T therapy hinges on the quality of the patient's own lymphocytes. Procuring T-cells earlier in the disease course, before they become exhausted from numerous prior therapies, results in a higher proportion of naive T-cells, leading to better CAR-T cell manufacturing and clinical outcomes.