CAR T Cell therapy
Chimeric Antigen Receptor (CAR) T-cell therapy has changed the course of treatment for numerous hematologic malignancies like leukemia, lymphoma, and multiple myeloma. China is at the forefront of CAR T-cell research with the maximum number of registered CAR T-cell clinical trials in the world.
The clinical triumphs notwithstanding, disease relapse, manufacturing complexities, and issues related to safety are some of the challenges remaining. The article discusses China’s experience with CAR T-cell therapy and suggests strategies to make its efficacy and safety in treating hematologic cancer stronger.
Fig: Structure and process of CAR T Cell therapy
Rise of CAR T Cell therapy in China
Over the past few decades, hematologic malignancy treatment has come a long way. Despite that, morbidity and mortality have still been very high. With knowledge of molecular genetics, our insight into how the immune system and cancer cells interact has heightened our awareness of T cells as the key to immunotherapy. Adoptive cell therapies, specifically with genetically modified CARs, have been constructed in order to specifically target cancer cells and elicit particular immune reactions.
CAR T-cell treatments have shown stunning effectiveness in malignancies such as acute lymphoblastic leukemia (ALL), large B-cell lymphoma (LBCL), and multiple myeloma (MM), revolutionizing cancer immunotherapy. Of note, China is now a CAR T-cell hotspot, with multiple clinical trials investigating diverse targets and approaches.
Fig: CAR T Trials in China vs USA
Challenges in CAR T-Cell Therapy
Despite promising outcomes, CAR T-cell therapy faces several challenges:
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Disease Relapse: Some patients experience relapse due to antigen loss or the emergence of antigen-negative tumor variants.
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Manufacturing Complexities: Producing CAR T cells involves intricate processes, including T-cell collection, genetic modification, expansion, and reinfusion, which can be time-consuming and costly.
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Safety Concerns: Adverse events like cytokine release syndrome (CRS) and neurotoxicity pose significant risks, necessitating effective management strategies.
Strategies to Enhance CAR T-Cell Therapy
To overcome these challenges, Chinese researchers and clinicians have implemented several strategies:
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Targeting Multiple Antigens: Developing CAR T cells that target multiple antigens can reduce the risk of relapse due to antigen loss.
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Improving Manufacturing Processes: Streamlining production through automated systems and optimizing protocols can enhance efficiency and reduce costs.
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Enhancing Safety Profiles: Implementing safety switches and developing strategies to manage adverse events can improve patient outcomes.
Summary of the article published in Haematologica (Strategies to optimize chimeric antigen receptor T-cell therapy in hematologic malignancies: Chinese experience)
Summary
Overview of CAR T Cell therapy in China
China has surpassed the USA in the number of CAR T-cell clinical studies, particularly in hematologic malignancies. As of December 2022, there were 458 CAR T-cell trials from China registered on ClinicalTrials.gov, with 73% focused on hematologic malignancies. CD19 and B-cell maturation antigen (BCMA) are the most common targets in Chinese trials. Compared to the USA, China has a higher proportion of trials using multi-target CAR T cells.
Approved CAR T Cell therapies in China
Two CD19-targeted CAR T-cell therapies have been approved in China for large B-cell lymphoma:
- Axicabtagene ciloleucel (Yescarta)
- Relmacabtagene autoleucel (Carteyva)
Strategies to improve CAR T Cell therapy
Acute Lymphoblastic Leukemia
- Allogeneic CAR T cells to overcome limitations of autologous therapy
- Universal off-the-shelf CAR T cells
- Targeting CD7 for T-cell ALL
- Combining multiple targets (e.g. CD19/CD22) to prevent antigen escape
- Optimizing CAR design with different co-stimulatory domains
Acute Myeloid Leukemia
- Exploring targets like CD33, CD38, CLL1, and CD123
- CLL1-targeted CAR T cells showed promise in pediatric AML
Lymphoma
- CD19 remains the primary target, with 50-100% overall response rates
- Multi-target approaches combining CD19 with CD22, CD20, etc.
- Personalized multi-CAR T-cell regimens based on patient’s tumor antigen profile
- Combining CAR T cells with other therapies like chemotherapy or radiation
- Armored CAR T cells to overcome inhibitory tumor microenvironment
Multiple Myeloma
- BCMA-targeted CAR T cells have shown great success
- Dual-epitope binding CAR T cells (e.g. LCAR-B38M)
- Combining BCMA with other targets like CD19 or CD38
- Fourth-generation CAR T cells expressing additional cytokines
Challenges and future direction
Despite promising results, several challenges remain:
- Relapse and resistance
- Management of cytokine release syndrome (CRS) and neurotoxicity
- Manufacturing complexities and high costs
- Limited efficacy in solid tumors
Future research is focused on:
- Optimizing CAR designs and manufacturing processes
- Developing off-the-shelf allogeneic products
- Combining CAR T cells with other therapies
- Exploring new targets and multi-target approaches
- Improving management of adverse events
Conclusion
CAR T-cell therapy is rapidly advancing in China, offering new hope for patients with hematologic malignancies. Continued innovation and addressing current challenges will be crucial to extend the benefits of this therapy to more patients.
Dr He Huang
Professional Positions
- Professor and Chancellor at Zhejiang University School of Medicine
- Associate Dean of Zhejiang University School of Medicine
- Director of Bone Marrow Transplantation Center at The First Affiliated Hospital, Zhejiang University School of Medicine
- Vice Director of the Institute of Hematology, Zhejiang University
Education
- M.D. and Ph.D. from Zhejiang University School of Medicine (1990-1993)
- Master of Medicine from Zhejiang University School of Medicine (1987-1990)
- Bachelor of Medicine from Zhejiang University School of Medicine (1979-1984)
Research Focus
- Clinical practice and research on hematology, specializing in hematopoietic stem cell transplantation (HSCT)
- Improving effectiveness of HSCT and long-term quality of life for patients
- Developing new transplant strategies
- Basic research on stem cell biology and hematological molecular biology
Notable Achievements
- Performed the first successful unrelated donor bone marrow transplant for leukemia in mainland China in 1998
- Awarded the National Prize of Science and Technology for outstanding work on unrelated donor HSCT in China in 2003
- Published about 170 papers in peer-reviewed journals
- Awarded 15 national invention patents
