CHEMOTACTIC REACTION ENHANCEMENT IN ONE DIMENSION

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2024-01-01

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Abstract

Chemotaxis, which involves the directed movement of cells in response to a chemical gradient, plays a crucial role in a broad variety of biological processes. Examples include bacterial motion, the development of single-cell or multicellular organisms, and immune responses. Chemotaxis directs bacteria’s movement to find food (e.g., glucose) by swimming toward the highest concentration of food molecules. In multicellular organisms, chemotaxis is critical to early development (e.g., movement of sperm towards the egg during fertilization). Chemotaxis also helps mobilize phagocytic and immune cells at sites of infection, tissue injury, and thus facilitates immune reactions. In this paper, we study a PDE system that describes chemotactic processes in one dimension, which may correspond to a thin channel, the setting relevant in many applications: for example, spermatozoa progression to the ovum inside a Fallopian tube or immune response in a blood vessel. Our objective is to obtain qualitatively precise estimates on how chemotaxis improves reaction efficiency, when compared to purely diffusive situation. The techniques we use to achieve this goal include a variety of comparison principles and analysis of mass transport for a class of Fokker-Planck operators.

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10.4310/CMS.2024.V22.N5.A5

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Gong, Y, and A Kiselev (2024). CHEMOTACTIC REACTION ENHANCEMENT IN ONE DIMENSION. Communications in Mathematical Sciences, 22(5). pp. 1287–1305. 10.4310/CMS.2024.V22.N5.A5 Retrieved from https://hdl.handle.net/10161/31791.

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Scholars@Duke

Kiselev

Alexander A. Kiselev

William T. Laprade Distinguished Professor of Mathematics

My current research interests focus on mathematical fluid mechanics and mathematical biology.
In the past, I have also worked on reaction-diffusion equations and spectral theory of Schredinger operators. 


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