B-cell malignancies are a diverse group of cancers that arise from abnormal growth and
proliferation of B-cells, a type of cells that plays a crucial role in the immune system. The
function of B-cells comprises the production of antibodies (immunoglobulins). Antibodies bind
to specific molecules (antigens) on the surface of pathogens (e.g. viruses, bacteria) marking
them for destruction by other components of the immune system. B-cell malignancies can arise
from various stages of B-cell development and can manifest as a range of clinical
presentations, from lymphomas with diverse clinical courses to aggressive leukemias.
Treatment options for B-cell malignancies vary depending on the specific type of cancer and
the stage of disease. Recently a broad array of newer immunotherapies became available[Feins
2019]. Specifically, the introduction of anti-CD19 and anti- BCMA (B cell maturation antigen)
targeted chimeric antigen receptor T- cell therapy (CAR-T) represents a major treatment
breakthrough in treatment of many B-cell malignancies[Sterner 2021, Haslauer 2021].
CAR-T therapy for B-cell malignancies involves extracting lymphocytes from a patient's blood
and modifying them to produce chimeric antigen receptors (CARs) that can recognize and bind
to proteins CD19 or BCMA expressed on cancer cells. The modified cells are then infused into
the patient's bloodstream, where they seek out and bind to cancer cells expressing the target
proteins. Once attached, the CAR-T cells are activated and initiate the destruction of the
bound cancer cells. While CAR-T cell therapy has shown remarkable success in clinical
trials[Sterner 2021, Haslauer 2021], it is a new and complex treatment with potential side
effects such as cytokine release syndrome, neurotoxicity, and a significant impact on the
host immune system[Kampouri 2022]. The tumor antigens targeted by CAR-T cells are also
expressed on healthy B-cells (CD-19) and plasma-cells (BCMA). Therefore, CAR-T therapy leads
to a decline in healthy B-cell populations with a subsequent decrease in antibody production
(hypogammaglobulinemia)[Haslauer 2021]. The negative effects of CAR-T cell therapies on
antibody concentrations leave individuals at risk of infection for a prolonged period[Wang
2020, Stewart 2021]. Currently, there is limited knowledge about the extent of loss of
immunity against vaccine preventable diseases after CAR-T cell therapy[Kampouri 2022, Walti
2021]. High-quality evidence on how to prevent infections in CAR-T recipients and
particularly on the necessity of re-vaccination against common vaccine-preventable pathogens,
is lacking. Expert opinion statements recommend re-vaccinating these patients 6-12 months
after CAR-T therapy against the most common pathogens[Hill 2020, Wudhikarn 2022]. Based on
available recommendations and the vaccine-guidelines provided by the Swiss Federal Office of
Public Health (FOPH) revaccination is started 6 months after CAR-T Therapy for inactivated
vaccines and 12 months after CAR-T Therapy for life-attenuated vaccines.
With the present cohort study, the investigators aim to explore to which extent patients lose
their humoral immunity to vaccine preventable pathogens after CAR-T cell therapies.
Additionally, the investigators assess vaccine responses to routinely administered
vaccinations in this population to examine whether re-vaccination after 6 months, as
suggested in expert-opinion based recommendations[Hill 2020, Los-Arcos 2021] , is a
reasonable approach. The vaccinations that are administered during the study period are usual
care interventions according to published expert-opinion based guidelines[Hill 2020,
Los-Arcos 2021, Plotkin 2010, FOPH]. These vaccines are presently administered to all CAR-T
recipients at the University Hospital Bern and will be also administered to all CAR-T
patients during the study period irrespective of study participation.
The results of this cohort study will reveal if present expert-opinion based vaccination
recommendations for CAR-T patients are reasonable or if there will be need for adapting the
recommendations (e.g. if it turns out that CAR-T patients do not lose protective immunity to
vaccine preventable pathogens or if the study reveals that immunization according to present
vaccine schedules do not elicit protective antibody levels). Furthermore, this project could
increase fundamental understanding of immunological responses to common vaccines in the
immunosuppressed population.
The present project falls into the risk category A according to art. 7 (HRO): It is a cohort
study (no study intervention) with blood sampling (low risk sampling according to HRO art.
7.3.) Sampling includes minimal risk (e.g. hematoma after blood draw, uncomfortable feeling
during procedure) for patients. Within this project, the investigators will exclusively use
methods that are readily available in clinical practice (flow-cytometric analysis of
lymphocyte populations, serology). Therefore, the gained knowledge will be immediately
applicable in clinical practice and the results of this sub-project will help improving
present vaccine strategies for CAR-T patients. Vaccination schedules are according to
official recommendations by the Swiss Federal Office of Public Health and according to
expert-opinion based guidelines and do not differ from patients not included in the study.