Multi-Approach and Multi-Scale Model of CD4+ T Cells Predicts Switch-Like and Oscillatory Emergent Behaviors in Inflammatory Response to Infection

Wertheim, Kenneth Y.; Puniya, Bhanwar Lal; Fleur, Alyssa La; Shah, Ab Rauf; Barberis, Matteo; Helikar, Tomáš

doi:10.1101/2020.02.26.964502

Cited by 2 publications

(2 citation statements)

References 38 publications

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“…Supporting these efforts, several network-based models have been developed to capture T cell signalling dynamics [53]. Some of them integrate different modelling approaches, such as logical, constraint-based, agent-based, and ODE models, to capture processes taking place at different spatial scales [54].…”

Section: Network Approaches For Cancer Immunotherapy Optimisationmentioning

confidence: 99%

The Multiple Dimensions of Networks in Cancer: A Perspective

2021

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This perspective article gathers the latest developments in mathematical and computational oncology tools that exploit network approaches for the mathematical modelling, analysis, and simulation of cancer development and therapy design. It instigates the community to explore new paths and synergies under the umbrella of the Special Issue “Networks in Cancer: From Symmetry Breaking to Targeted Therapy”. The focus of the perspective is to demonstrate how networks can model the physics, analyse the interactions, and predict the evolution of the multiple processes behind tumour-host encounters across multiple scales. From agent-based modelling and mechano-biology to machine learning and predictive modelling, the perspective motivates a methodology well suited to mathematical and computational oncology and suggests approaches that mark a viable path towards adoption in the clinic.

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Section: Network Approaches For Cancer Immunotherapy Optimisationmentioning

confidence: 99%

The Multiple Dimensions of Networks in Cancer: A Perspective

2021

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“…Furthermore, multi-scale models also considered both cell-cell communications and molecular signaling. Examples include a model predicting mucosal immune response to Helicobacter pylori infection (22) , and a model predicting CD4+ T cell response to influenza infection (23) . However, most of these works have either focused on limited aspects of the immune system (e.g., cell types) or modeled a single infection or a coinfection.…”

Section: Introductionmentioning

confidence: 99%

Immune Digital Twin Blueprint: A Comprehensive Mechanistic Model of the Human Immune System

Puniya

Moore

Mohammed

et al. 2020

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The human immune system, which protects against pathogens and diseases, is a complex network of cells and molecules. The effects of complex dynamical interactions of pathogens and immune cells on the immune response can be studied using computational models. However, a model of the entire immune system is still lacking. Here, we developed a comprehensive computational model that integrates innate and adaptive immune cells, cytokines, immunoglobulins, and nine common pathogens from different classes of virus, bacteria, parasites, and fungi. This model was used to investigate the dynamics of the immune system under two scenarios: (1) single infection with pathogens, and (2) various medically relevant pathogen coinfections. In coinfections, we found that the order of infecting pathogens has a significant impact on the dynamics of cytokines and immunoglobulins. Thus, our model provides a tool to simulate immune responses under different dosage of pathogens and their combinations, which can be further extended and used as a tool for drug discovery and immunotherapy. Furthermore, the model provides a comprehensive and simulatable blueprint of the human immune system as a result of the synthesis of the vast knowledge about the network-like interactions of various components of the system.

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Multi-Approach and Multi-Scale Model of CD4+ T Cells Predicts Switch-Like and Oscillatory Emergent Behaviors in Inflammatory Response to Infection

Cited by 2 publications

References 38 publications

The Multiple Dimensions of Networks in Cancer: A Perspective

The Multiple Dimensions of Networks in Cancer: A Perspective

Immune Digital Twin Blueprint: A Comprehensive Mechanistic Model of the Human Immune System

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