Nonlocal Models in Biology and Life Sciences: Sources, Developments, and Applications

TL;DR

This review explores various nonlocal mathematical models in biology and life sciences, emphasizing their sources, developments, and diverse applications from cellular to nanoscale systems, including networks and materials.

Contribution

It provides a comprehensive overview of nonlocal models across multiple biological scales and introduces recent advances and future directions in the field.

Findings

Nonlocal models effectively describe pattern formation in biological systems.

Application of nonlocal interactions in brain dynamics enhances understanding of neurodegenerative diseases.

Nonlocal continuum models are useful in nanotechnology and biosensor development.

Abstract

Nonlocality is important in realistic mathematical models of physical and biological systems when local models fail to capture the essential dynamics and interactions that occur over a range of distances. This review illustrates different nonlocal mathematical models applied to biology and life sciences. The major focus has been given to sources, developments, and applications of such models. Among other things, a systematic discussion has been provided for the conditions of pattern formations in biological systems of population dynamics. Special attention has also been given to nonlocal interactions on networks, network coupling and integration, including brain dynamics models that provide an important tool to understand neurodegenerative diseases better. In addition, we have discussed nonlocal modelling approaches for cancer stem cells and tumor cells that are widely applied in the cell migration processes, growth, and avascular tumors in any organ. Furthermore, the discussed nonlocal continuum models can go sufficiently smaller scales, including nanotechnology, where classical local models often fail to capture the complexities of nanoscale interactions, applied to build biosensors to sense biomaterial and its concentration. Piezoelectric and other smart materials are among them, and these devices are becoming increasingly important in the digital and physical world that is intrinsically interconnected with biological systems. Additionally, we have reviewed a nonlocal theory of peridynamics, which deals with continuous and discrete media and applies to model the relationship between fracture and healing in cortical bone, tissue growth and shrinkage, and other areas increasingly important in biomedical and bioengineering applications. Finally, we provided a comprehensive summary of emerging trends and highlighted future directions in this rapidly expanding field.