Scaling and continuum percolation model for enzyme-catalyzed gel degradation

D. Lairez; J. P. Carton; G. Zalczer; J. Pelta

doi:10.1103/PhysRevLett.98.228302

Scaling and continuum percolation model for enzyme-catalyzed gel degradation

D. Lairez
, J. P. Carton
, G. Zalczer
, J. Pelta

Research output: Contribution to journal › Article › peer-review

Abstract

Enzyme-catalyzed gel degradation is inherently controlled by diffusion of enzymes in the gel. We report kinetics measurements on the gelatin-thermolysin system, varying solvent viscosity as well as gel and enzyme concentrations. Scaling relations and reduced variables are proposed which are shown to account for the experimental results. Finally, we argue that the nontrivial experimental dependence on enzyme concentration for the degradation time demonstrates that enzyme random walk is self-attracting, leading to a continuum percolation model for gel degradation.

Original language	English
Article number	228302
Journal	Physical Review Letters
Volume	98
Issue number	22
DOIs	https://doi.org/10.1103/PhysRevLett.98.228302
Publication status	Published - 1 Jun 2007
Externally published	Yes

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title = "Scaling and continuum percolation model for enzyme-catalyzed gel degradation",

abstract = "Enzyme-catalyzed gel degradation is inherently controlled by diffusion of enzymes in the gel. We report kinetics measurements on the gelatin-thermolysin system, varying solvent viscosity as well as gel and enzyme concentrations. Scaling relations and reduced variables are proposed which are shown to account for the experimental results. Finally, we argue that the nontrivial experimental dependence on enzyme concentration for the degradation time demonstrates that enzyme random walk is self-attracting, leading to a continuum percolation model for gel degradation.",

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AU - Zalczer, G.

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AB - Enzyme-catalyzed gel degradation is inherently controlled by diffusion of enzymes in the gel. We report kinetics measurements on the gelatin-thermolysin system, varying solvent viscosity as well as gel and enzyme concentrations. Scaling relations and reduced variables are proposed which are shown to account for the experimental results. Finally, we argue that the nontrivial experimental dependence on enzyme concentration for the degradation time demonstrates that enzyme random walk is self-attracting, leading to a continuum percolation model for gel degradation.

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DO - 10.1103/PhysRevLett.98.228302

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JO - Physical Review Letters

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Scaling and continuum percolation model for enzyme-catalyzed gel degradation

Abstract

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