Development of a quantitative relationship between CAR-affinity, antigen abundance, tumor cell depletion and CAR-T cell expansion using a multiscale systems PK-PD model

Singh, Anumeha; Zheng, Xirong; Lin-Schmidt, Xiefan; Chen, Wenbo; Carpenter, Thomas; Zong, Alice; Wang, Weirong; Heald, Donald

doi:10.1080/19420862.2019.1688616

Cited by 84 publications

(104 citation statements)

References 39 publications

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“…95 A second example of the application of mechanistic modeling to IO is the quantitative modeling of chimeric antigen receptor T cell therapies. 96,97 Agent-based and individual-based simulations are increasingly used for this application, with these simulations being, of course, spatially resolved in their outputs. 98 This does, of course, increase their computational cost.…”

Section: Mathematical Modeling Approaches To Translation In Oncologymentioning

confidence: 99%

Opportunities for Quantitative Translational Modeling in Oncology

Yates

Byrne

Chapman

et al. 2020

Clin Pharma and Therapeutics

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A 2‐day meeting was held by members of the UK Quantitative Systems Pharmacology Network () in November 2018 on the topic of Translational Challenges in Oncology. Participants from a wide range of backgrounds were invited to discuss current and emerging modeling applications in nonclinical and clinical drug development, and to identify areas for improvement. This resulting perspective explores opportunities for impactful quantitative pharmacology approaches. Four key themes arose from the presentations and discussions that were held, leading to the following recommendations: Evaluate the predictivity and reproducibility of animal cancer models through precompetitive collaboration. Apply mechanism of action (MoA) based mechanistic models derived from nonclinical data to clinical trial data. Apply MoA reflective models across trial data sets to more robustly quantify the natural history of disease and response to differing interventions. Quantify more robustly the dose and concentration dependence of adverse events through mathematical modelling techniques and modified trial design.

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Section: Mathematical Modeling Approaches To Translation In Oncologymentioning

confidence: 99%

Opportunities for Quantitative Translational Modeling in Oncology

Yates

Byrne

Chapman

et al. 2020

Clin Pharma and Therapeutics

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“…Since the year 2011, there have been rapid developments in the field of immunotherapy, and a range of immunocheckpoint inhibitors (ICIs) have been approved for a range of metastatic cancers, including malignant melanoma, lung, kidney, and bladder cancers [1][2][3][4][5]. In recent years, the clinical trial results of genetically engineered immune cells, including chimeric antigen receptor T-cell (CAR-T), TCRengineered T-cell (TCR-T), chimeric antigen receptor natural killer cell (CAR-NK) and more, in the treatment of hematological tumors have also been encouraging [6][7][8]. Immunotherapy has nowadays developed into a new and promising therapy in addition to surgery, radiotherapy, chemotherapy, and molecular targeted therapy [9].…”

Section: Introductionmentioning

confidence: 99%

T‐cell receptor repertoire analysis for the diagnosis and treatment of solid tumor: A methodology and clinical applications

Li¹,

Yuan

Tian

et al. 2020

Cancer Communications

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T cells, which are involved in adaptive immunity, are essential in the elimination of tumor cells. Mature T cells can specifically recognize the antigen on the major histocompatibility complex (MHC) molecule through T-cell receptors (TCR). The unique rearrangement mechanisms during T-cell maturation provide great diversity to TCR, ensuring specific recognition between T cells and antigens. Thus, TCR repertoire analysis occupied an important position in T-cell regarding research. Nowadays, next-generation sequencing technology allows the simultaneous detection of TCR sequences with high throughput, and several evaluation indexes facilitate the measure of TCR repertoire. Based on this new methodology, discoveries are made across a range of tumor types. Results have shed light on the TCR repertoire differences between cancer patients and healthy control as well as between individual's lesions, paracancer, and peripheral blood samples. The potential of TCR repertoire as a biomarker for immunotherapy efficacy is also widely studied as TCR repertoire represents different baseline within individuals and shows dynamic change during treatment. Accurate delineation of the T-cell repertoire can further the understanding of the immune system response to tumorigenesis. Still, existing researches are insufficient to clarify the specific clinical implications of TCR dynamic change and the definite role of TCR repertoire diversity during the treatment process. The results of some studies are even

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“…The high-dose cohort exhibited a significantly higher proliferation rate (ρ), and higher capacity (Cmax) compared to the low-dose cohort (data not shown). Studies also observed limited CAR-T expansion at a low dose (< 5 x 10 7 ) 37,38 , and no CAR-T expansion at very low doses (< 10 6 ) 39 , indicating a potential threshold of dose to assure rapid CAR-T expansion and a steep dose-response curve for CAR-T therapy 2,35,40 .…”

mentioning

confidence: 97%

“…In solid tumors, cancer cells are often spatially restricted 34 , providing poor antigen accessibility to CAR-T cells. CAR-T cells have to extravasate into the tumor bed, migrate toward the tumor cells, contact, and then engage the tumor cells 7,35 . Differences in tissue accessibility and delivery rate for CAR-T cells may account for large variability on proliferation rate constant (ρ) between two solid tumor trials ( Fig 4B).…”

mentioning

confidence: 99%

“…The contraction and persistent phases are mathematically exchangeable but with different parameter interpretation in comparison with previous models. Along with the rapid expansion of CAR-T candidates, more mechanistic cellular kinetics and dynamics models are warranted to disentangle the complicated relationships between target engagement, tumor burdens, as well as the dynamic native immune systems 35 .…”

mentioning

confidence: 99%

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Model-based Cellular Kinetic Analysis of Chimeric Antigen Receptor-T Cells in Humans

Liu

Ayyar

Zheng

et al. 2020

Preprint

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Chimeric antigen receptor (CAR)-T cell therapy has achieved considerable success in treating B-cell hematologic malignancies. However, the challenges of extending CAR-T therapy to other tumor types, particularly solid tumors, remain appreciable. There are substantial variabilities in CAR-T cellular kinetics across CAR-designs, CAR-T products, dosing regimens, patient responses, disease types, tumor burdens, and lymphodepletion conditions. As a 'living drug', CAR-T cellular kinetics typically exhibit four distinct phases: distribution, expansion, contraction, and persistence. The cellular kinetics of CAR-T may correlate with patient responses, but which factors determine CAR-T cellular kinetics remain poorly defined. Herein, we developed a cellular kinetic model to retrospectively characterize CAR-T kinetics in 218 patients from 7 trials and systematically compared CAR-T kinetics across patient populations and tumor types. Based on our analysis results, CAR-T cells exhibited a significantly higher cell proliferation rate constant and capacity but a lower contraction rate constant in patients who responded to treatment. CAR-T cells proliferate at a higher rate constant in hematologic malignancies than in solid tumors. Within the assessed dose ranges (107‒109 cells), CAR-T doses were weakly correlated with CAR-T cellular kinetics and patient response status, suggesting steep dose-response curves. In conclusion, the developed CAR-T cellular kinetic model adequately characterized the multiphasic CAR-T cellular kinetics and supported systematic evaluations of the potentially influencing factors, which can have significant implications for the development of more effective CAR-T therapies.

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Development of a quantitative relationship between CAR-affinity, antigen abundance, tumor cell depletion and CAR-T cell expansion using a multiscale systems PK-PD model

Cited by 84 publications

References 39 publications

Opportunities for Quantitative Translational Modeling in Oncology

Opportunities for Quantitative Translational Modeling in Oncology

T‐cell receptor repertoire analysis for the diagnosis and treatment of solid tumor: A methodology and clinical applications

Model-based Cellular Kinetic Analysis of Chimeric Antigen Receptor-T Cells in Humans

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