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Literature DB >> 21063873

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

James D Benson¹, Carmen C Chicone, John K Critser.

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.

Mesh：

Year: 2010 PMID： 21063873 DOI： 10.1007/s00285-010-0374-4

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

11 in total

1. A two-parameter model of cell membrane permeability for multisolute systems.

Authors: I I Katkov
Journal: Cryobiology Date: 2000-02 Impact factor: 2.487

2. Stability properties of elementary dynamic models of membrane transport.

Authors: Julio A Hernández
Journal: Bull Math Biol Date: 2003-01 Impact factor: 1.758

3. The point of maximum cell water volume excursion in case of presence of an impermeable solute.

Authors: Igor I Katkov
Journal: Cryobiology Date: 2002-06 Impact factor: 2.487

4. Optimal controls for a model with pharmacokinetics maximizing bone marrow in cancer chemotherapy.

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Journal: Math Biosci Date: 2005-09-28 Impact factor: 2.144

5. Exact solutions of a two parameter flux model and cryobiological applications.

Authors: James D Benson; Carmen C Chicone; John K Critser
Journal: Cryobiology Date: 2005-06 Impact factor: 2.487

6. Adjustments on the cryopreservation conditions reduce the incidence of boar ejaculates with poor sperm freezability.

Authors: Marta Hernández; Jordi Roca; María A Gil; Juan M Vázquez; Emilio A Martínez
Journal: Theriogenology Date: 2007-04-16 Impact factor: 2.740

Review 7. Membrane permeability modeling: Kedem-Katchalsky vs a two-parameter formalism.

Authors: F W Kleinhans
Journal: Cryobiology Date: 1998-12 Impact factor: 2.487

8. Cryobiology: the freezing of biological systems.

Authors: P Mazur
Journal: Science Date: 1970-05-22 Impact factor: 47.728

9. A generalized method for the minimization of cellular osmotic stresses and strains during the introduction and removal of permeable cryoprotectants.

Authors: R L Levin
Journal: J Biomech Eng Date: 1982-05 Impact factor: 2.097

10. A general model for the dynamics of the cell volume.

Authors: Julio A Hernández
Journal: Bull Math Biol Date: 2007-02-23 Impact factor: 1.758

8 in total

1. Mathematical properties of pump-leak models of cell volume control and electrolyte balance.

Authors: Yoichiro Mori
Journal: J Math Biol Date: 2011-11-01 Impact factor: 2.259

Review 2. Microfluidics for cryopreservation.

Authors: Gang Zhao; Jianping Fu
Journal: Biotechnol Adv Date: 2017-01-30 Impact factor: 14.227

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

1. A two-parameter model of cell membrane permeability for multisolute systems.

2. Stability properties of elementary dynamic models of membrane transport.

3. The point of maximum cell water volume excursion in case of presence of an impermeable solute.

4. Optimal controls for a model with pharmacokinetics maximizing bone marrow in cancer chemotherapy.

5. Exact solutions of a two parameter flux model and cryobiological applications.

6. Adjustments on the cryopreservation conditions reduce the incidence of boar ejaculates with poor sperm freezability.

Review 7. Membrane permeability modeling: Kedem-Katchalsky vs a two-parameter formalism.

8. Cryobiology: the freezing of biological systems.

9. A generalized method for the minimization of cellular osmotic stresses and strains during the introduction and removal of permeable cryoprotectants.

10. A general model for the dynamics of the cell volume.

1. Mathematical properties of pump-leak models of cell volume control and electrolyte balance.

Review 2. Microfluidics for cryopreservation.

3. Periodic oscillations of a model for membrane permeability with fluctuating environmental conditions.

4. Mathematical Modeling and Optimization of Cryopreservation in Single Cells.

5. Analytical optimal controls for the state constrained addition and removal of cryoprotective agents.

6. Effect of the polydispersity of RBCs on the recovery rate of RBCs during the removal of CPAs.

7. Mathematically optimized cryoprotectant equilibration procedures for cryopreservation of human oocytes.

8. Toxicity Minimized Cryoprotectant Addition and Removal Procedures for Adherent Endothelial Cells.