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Literature DB >> 7365332

Biased random walk models for chemotaxis and related diffusion approximations.

Abstract

Stochastic models of biased random walk are discussed, which describe the behavior of chemosensitive cells like bacteria or leukocytes in the gradient of a chemotactic factor. In particular the turning frequency and turn angle distribution are derived from certain biological hypotheses on the background of related experimental observations. Under suitable assumptions it is shown that solutions of the underlying differential-integral equation approximately satisfy the well-known Patlak-Keller-Segel diffusion equation, whose coefficients can be expressed in terms of the microscopic parameters. By an appropriate energy functional a precise error estimation of the diffusion approximation is given within the framework of singular perturbation theory.

Mesh：

Year: 1980 PMID： 7365332 DOI： 10.1007/bf00275919

Source DB: PubMed Journal: J Math Biol ISSN： 0303-6812 Impact factor: 2.259

28 in total

9. Deterministic model of dermal wound invasion incorporating receptor-mediated signal transduction and spatial gradient sensing.

Authors: Jason M Haugh
Journal: Biophys J Date: 2006-01-13 Impact factor: 4.033

10. Derivation of a bacterial nutrient-taxis system with doubly degenerate cross-diffusion as the parabolic limit of a velocity-jump process.

Authors: Ramón G Plaza
Journal: J Math Biol Date: 2019-01-02 Impact factor: 2.259

Biased random walk models for chemotaxis and related diffusion approximations.

1. A response regulator model in a simple sensory system.

2. Trajectories of human granulocytes.

3. Chemotaxis in Escherichia coli analyzed by three-dimensional tracking.

4. Mathematical aspects of bacterial chemotaxis.

5. A descriptive theory of cell migration on surfaces.

6. Effects of leukocyte random motility and chemotaxis in tissue inflammatory response.

7. Model for chemotaxis.

8. Analysis of a densitometry assay for bacterial chemotaxis.

9. Amoeboid movement as a correlated walk.

10. Transient response to chemotactic stimuli in Escherichia coli.

1. Stochastic models for cell motion and taxis.

2. A new interpretation of the Keller-Segel model based on multiphase modelling.

3. Quantitative analysis of the regulation of leukocyte chemosensory migration by a vascular prosthetic biomaterial.

4. Cell balance equation for chemotactic bacteria with a biphasic tumbling frequency.

5. Models for contact-mediated pattern formation: cells that form parallel arrays.

6. Derivation of hyperbolic models for chemosensitive movement.

7. Lattice-Boltzmann model for bacterial chemotaxis.

8. Kinetic models for chemotaxis: hydrodynamic limits and spatio-temporal mechanisms.

9. Deterministic model of dermal wound invasion incorporating receptor-mediated signal transduction and spatial gradient sensing.

10. Derivation of a bacterial nutrient-taxis system with doubly degenerate cross-diffusion as the parabolic limit of a velocity-jump process.