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Mathematical Model for Chemical Reactions in Electrolyte Applied to Cytochrome $c$ Oxidase: an Electro-osmotic Approach

A mathematical model for chemical reactions in electrolytes is developed using an Energy variational method consistent with classical thermodynamics. Electrostatics and chemical reactions are included in properly defined energetic and dissipative functionals. The energy variation method is generalized to deal with open systems with inputs of charge, mass, and energy. The open systems can transform input energy of one type into output energy of another type. The generalized method is used to analyze the conversion of electrical current into proton flow by cytochrome c oxidase, an important enzyme in mitochondria that helps generate the 'energetic currency of life' ATP. The structure of the oxidase guides flows of current and mass that interact according to the energetic and dissipative functionals of the generalized theory. Kirchhoff's current law provides important coupling when the enzyme is in its natural setting in the mitochondrial membrane. The natural function of the enzyme is the result. Electron flows are converted into proton flows and gradients.

preprint2022arXivOpen access
Shixin XuRobert EisenbergZilong SongHuaxiong Huang
physics.chem-ph
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Shixin XuRobert EisenbergZilong SongHuaxiong Huang

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