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Electromagnetic and Redox Governance of Biological Structure: A Unified Framework Linking Protein Conformation, DNA Topology, Viral Vulnerability, and Energy-Field Dynamics

Miguel Angel Cartagena

2025Zenodo (CERN European Organization for Nuclear Research)14 citationsDOIOpen Access PDF

Abstract

Biological structure and function traditionally are described in terms of chemical interactions: covalent bonding, hydrogen bonding, ionic interactions, and solvent effects. However, recent cross-disciplinary insights suggest a deeper, unifying substrate beneath chemistry: electron distribution and electromagnetic (EM) field interactions. This paper develops a comprehensive, multi-scale theoretical framework in which proteins, nucleic acids, viral architectures, and enzymatic processes are reconceptualized as electromagnetic geometries whose biological behavior emerges from the dynamics of electron organization, redox state, and light-matter interactions. I synthesize findings across biochemistry, structural biology, quantum chemistry, photophysics, electrostatics, and systems biology to show that: Protein folding, viral spike stability, and protease activity are fundamentally governed by electron distribution within molecular orbitals. DNA secondary structures, including the i-motif; are EM- and redox-responsive nano-switches that dynamically alter genetic accessibility. Light introduces quantized energy into biological systems, altering electronic states, generating reactive oxygen species, and reshaping molecular conformations. Oxidation reconfigures electron density, collapsing biomolecules into alternative minima in their energy landscapes. Protease-substrate recognition depends on charge topology, dipole architecture, and orbital alignments, all of which are modulated by redox and photonic states. Viral proteins, including SARS-CoV-2 spike, represent delicate EM-dependent metastable geometries that are disproportionately sensitive to electron redistribution. I formalize these relationships using energetic landscapes, quantum transition rules, and geometric-electromagnetic analogies. This yields a unifying explanatory model where biological processes emerge as recursive collapse phenomena in electron- and field-governed information structures, consistent with modern quantum biology and biophysics. This integrative perspective leads to new conceptual predictions about viral robustness, DNA regulation, protein dynamics, and cellular coherence, offering a scientific foundation for future explorations of EM-biological coupling without practical or hazardous applications. The work reframes life not merely as chemistry, but as structured electromagnetic information expressed through chemistry.

Topics & Concepts

BiomoleculeChemical physicsMolecular biophysicsNucleic acidQuantumChemistryDNANanotechnologyFunction (biology)ElectronBiophysicsPhysicsBiological systemMolecular dynamicsField (mathematics)Electromagnetic fieldQuantum dotLiving matterIonic bondingProtein structureRedoxSupramolecular chemistryComputational biologyIntrinsically disordered proteinsProtein foldingDipoleStructural biologyProtein dynamicsProtein–protein interactionBiologyWave functionElectronic structureSystems biologyBiofield Effects and BiophysicsPhotoreceptor and optogenetics researchFractal and DNA sequence analysis
Electromagnetic and Redox Governance of Biological Structure: A Unified Framework Linking Protein Conformation, DNA Topology, Viral Vulnerability, and Energy-Field Dynamics | Litcius