Variational Percolation Bounds for Cellular Membrane Occlusion
Abstract
Malignant membranes cluster nutrient transporters within glycan-rich domains, sustaining metabolism through redundant intake routes. A theoretical framework links interfacial chemistry to transport suppression and energetic or redox collapse. The model unites a screened Poisson-Nernst-Planck electrodiffusion problem, an interfacial potential of mean force, and a reduced energetic-redox module connecting flux to ATP/NADPH balance. From this structure, capacitary-spectral bounds relate total flux to the inverse principal eigenvalue (Jtot <= C*exp(-beta*chieff)*P(theta)). Two near-orthogonal levers, geometry and field strength, govern a linear suppression regime below a percolation-type knee, beyond which conductance collapses. A composite intake index Xi = wG*JGLUT + wA*JLAT/ASCT + wL*JMCT dictates energetic trajectories: once below a maintenance threshold, ATP and NADPH fall jointly and redox imbalance drives irreversible commitment. Normal membranes, with fewer transport mouths and weaker fields, remain above this threshold, defining a natural selectivity window. The framework demonstrates existence, regularity, and spectral monotonicity for the self-adjoint PNP operator, establishing a geometric-spectral transition that links molecular parameters such as branching and sulfonation to measurable macroscopic outcomes with predictive precision.
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