细胞体积动态、全局稳定性及最优控制的通用模型。

A general model for the dynamics of cell volume, global stability, and optimal control.

作者信息

Benson James D, Chicone Carmen C, Critser John K

机构信息

Mathematical and Computational Sciences Division, National Institute of Standards and Technology, Gaithersburg, MD, USA.

出版信息

J Math Biol. 2011 Aug;63(2):339-59. doi: 10.1007/s00285-010-0374-4. Epub 2010 Nov 10.

DOI:10.1007/s00285-010-0374-4

PMID:21063873

Abstract

Cell volume and concentration regulation in the presence of changing extracellular environments has been studied for centuries, and recently a general nondimensional model was introduced that encompassed solute and solvent transmembrane flux for a wide variety of solutes and flux mechanisms. Moreover, in many biological applications it is of considerable interest to understand optimal controls for both volume and solute concentrations. Here we examine a natural extension of this general model to an arbitrary number of solutes or solute pathways, show that this system is globally asymptotically stable and controllable, define necessary conditions for time-optimal controls in the arbitrary-solute case, and using a theorem of Boltyanski prove sufficient conditions for these controls in the commonly encountered two-solute case.

摘要

几个世纪以来，人们一直在研究细胞在不断变化的细胞外环境中的体积和浓度调节，最近引入了一个通用的无量纲模型，该模型涵盖了多种溶质和通量机制下的溶质和溶剂跨膜通量。此外，在许多生物学应用中，了解体积和溶质浓度的最优控制具有相当重要的意义。在这里，我们研究了这个通用模型到任意数量溶质或溶质途径的自然扩展，证明了该系统是全局渐近稳定且可控的，定义了任意溶质情况下时间最优控制的必要条件，并利用博尔蒂扬斯基定理证明了在常见的双溶质情况下这些控制的充分条件。

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细胞体积动态、全局稳定性及最优控制的通用模型。

A general model for the dynamics of cell volume, global stability, and optimal control.

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