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Executive Summary
Living systems achieve stability not by preserving static structures, but by maintaining coherence — stable phase relationships within and across biological scales. This work proposes a unified framework in which:
- Present-moment identity is encoded in the S⁷ coherence manifold, arising from seven coupled microtubule resonance modes.
The well-documented 9-band “triplet-of-triplets” pattern is the frequency-domain projection of this manifold. - Continuity of identity over time is maintained by 12-band mitochondrial recurrence cycles, observable through membrane potential oscillations and captured using dodecanogram (DDG) analysis.
This recurrence system determines whether the organism can return to itself after perturbation. - Anatomical form is stabilized by bioelectric morphogenetic fields, which act as spatial attractors.
Regeneration is not reconstruction — it is coherence re-entry into these attractor conditions. - Embodied coherence is propagated through the fascial tensegrity network, a continuous, hydrated proton-conductive matrix linking cytoskeleton to whole-organism dynamics.
This network provides the physical substrate of somatic memory and interoceptive integration.
Within this framework:
- Aging is the gradual narrowing of coherence bandwidth.
- Trauma is impaired re-entry to the coherence attractor.
- Cancer is secession from shared coherence.
- Meditation deepens the coherence attractor well.
- Psychedelics temporarily loosen attractor depth, requiring guided reintegration.
The model is experimentally testable. It predicts specific, measurable signatures in:
- Microtubule vibrational spectroscopy (9-band invariance),
- Mitochondrial ΔΨm recurrence analysis (12-band envelope structure),
- Tissue-level bioelectric topology (pattern-dependent regeneration),
- Fascial hydration and elasticity metrics (scale-lock integrity).
This synthesis offers a rigorous, biologically grounded account of how organisms maintain identity, heal, adapt, and transform.
