Modeling the Dichotomy of the Immune Response to Cancer: Cytotoxic Effects and Tumor-Promoting Inflammation

Overview

Journal Bull Math Biol

Publisher Springer

Specialties Biology
Public Health

Date 2017 Jun 7

PMID 28585066

Citations 12

Authors

Kathleen P Wilkie

Philip Hahnfeldt

Affiliations

Soon will be listed here.

Abstract

Although the immune response is often regarded as acting to suppress tumor growth, it is now clear that it can be both stimulatory and inhibitory. The interplay between these competing influences has complex implications for tumor development, cancer dormancy, and immunotherapies. In fact, early immunotherapy failures were partly due to a lack in understanding of the nonlinear growth dynamics these competing immune actions may cause. To study this biological phenomenon theoretically, we construct a minimally parameterized framework that incorporates all aspects of the immune response. We combine the effects of all immune cell types, general principles of self-limited logistic growth, and the physical process of inflammation into one quantitative setting. Simulations suggest that while there are pro-tumor or antitumor immunogenic responses characterized by larger or smaller final tumor volumes, respectively, each response involves an initial period where tumor growth is stimulated beyond that of growth without an immune response. The mathematical description is non-identifiable which allows an ensemble of parameter sets to capture inherent biological variability in tumor growth that can significantly alter tumor-immune dynamics and thus treatment success rates. The ability of this model to predict non-intuitive yet clinically observed patterns of immunomodulated tumor growth suggests that it may provide a means to help classify patient response dynamics to aid identification of appropriate treatments exploiting immune response to improve tumor suppression, including the potential attainment of an immune-induced dormant state.

Citing Articles

Practical parameter identifiability and handling of censored data with Bayesian inference in mathematical tumour models.

Porthiyas J, Nussey D, Beauchemin C, Warren D, Quirouette C, Wilkie K NPJ Syst Biol Appl. 2024; 10(1):89.

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Mitigating non-genetic resistance to checkpoint inhibition based on multiple states of immune exhaustion.

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Optimal dosage protocols for mathematical models of synergy of chemo- and immunotherapy.

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Analysis of the Equilibrium Phase in Immune-Controlled Tumors Provides Hints for Designing Better Strategies for Cancer Treatment.

Atsou K, Khou S, Anjuere F, Braud V, Goudon T Front Oncol. 2022; 12:878827.

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Modeling cancer immunoediting in tumor microenvironment with system characterization through the ising-model Hamiltonian.

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