Focus on Phase-Resonant Morphogenesis: Endogenous Microplastics as Bioelectrical Adaptation Phenomena

Microplastics have long been regarded as synthetic remnants of industrial activity. However, emerging environmental data challenge this assumption. Microplastic particles are now detected even in remote ecosystems—Antarctic snow, deserts, and high-altitude air columns—where industrial contamination is implausible. This study proposes a natural mechanism of phase-resonant condensation, in which polymeric microstructures emerge under coupled electromagnetic, thermal, and plasma field interactions. Comparative analyses suggest that nodular and hypertrophic cellular formations correspond to bioelectrical overdrive states, where hormonal resonance induces structural expansion to sustain electrical coherence. These findings indicate that both phenomena—endogenous microplastic formation and nodular morphogenesis—arise from a shared phase-resonant adaptation process linking cellular and environmental scales. Disease and pollution may thus be reinterpreted as complementary manifestations of a continuous bioelectromagnetic field dynamic, inviting a broader understanding of coherence as a fundamental organizing principle in living and planetary systems. Their presence in polar regions, often interpreted solely as evidence of long-range pollution, may alternatively reflect the unique electromagnetic geometry of the poles, which serve as natural convergence zones for field-aligned particulate processes.Such condensates therefore act not as passive residues but as emergent coherence-stabilizing artifacts, revealing how living and environmental systems co-generate structure under conditions of phase stress.