Keywords
Quantum biology
Anti-aging
Health preservation
Mitochondria
Quantum coherence
Biophotons
Submitted : 2026-03-23
Accepted : 2026-04-07
Published : 2026-04-22
Abstract
Objective: To establish the theoretical system and technical specifications of Intentional Physiological Therapy (IPT), and explore its application value in anti-aging health preservation. Methods: Based on interdisciplinary research of quantum biology, neuroscience, aging biology and systems medicine, an intention-quantum-physiology coupling model was constructed by integrating microtubule quantum computing theory, mitochondrial quantum metabolism theory and biophoton communication mechanism; the technical system and evaluation standards of IPT were established through literature analysis, theoretical deduction and preliminary experimental verification. Results: (1) The quantum decoherence theory of aging was proposed, holding that aging is the gradual loss of quantum coherence at cell-tissue-system level driven by environmental perturbations and internal metabolic noise. (2) A four-level intention regulation model (molecular-gene, cell-tissue, organ-system, whole-integration) was established to realize multi-scale quantum state regulation. (3) The core technical system of IPT was designed, including quantum awareness training, mitochondrial intention regulation, biofield resonance and environment-assisted quantum ecology, forming a closed-loop regulation system. (4) Quantum optimization strategies for anti-aging were proposed for different age groups and physiological states. Conclusion: IPT provides a new quantum biological paradigm for anti-aging health preservation, breaking the limitations of traditional molecular biology research, with significant theoretical innovation, technical feasibility and broad application prospects, worthy of further in-depth research and clinical verification.
References
World Health Organization, 2015, Global Report on Aging and Health. WHO.
Harman D, 1956, Aging: A Theory Based on Free Radical and Radiation Chemistry. Journal of Gerontology, 11(3): 298–300.
Blackburn E, Greider C, Szostak J, 2006, Telomeres and Telomerase: The Path to Discovery. Cell, 126(4): 823–826.
Horvath S, 2013, DNA Methylation Age of Human Tissues and Cell Types. Genome Biology, 14(10): R115.
Black D, Sussman J, Johnson D, et al., 2013, Mindfulness-Based Stress Reduction and Health Care Utilization Among Older Adults: A Randomized Controlled Trial. JAMA Internal Medicine, 173(12): 1148–1154.
Kabat-Zinn J, 2003, Mindfulness-Based Interventions in Context: Past, Present, and Future. Clinical Psychology: Science and Practice, 10(2): 144–156.
Luders E, Toga A, Lepore N, et al., 2008, The Default Mode Network and Self-Referential Processing in Aging. NeuroImage, 40(4): 1602–1608.
Engel G, Calhoun T, Read E, et al., 2007, Evidence for Wavelike Energy Transfer Through Quantum Coherence in Photosynthetic Systems. Nature, 446(7137): 782–786.
Liu X, Wang C, Zhang Y, et al., 2015, Mitoflashes Are Quantized Mitochondrion-Native Reactive Oxygen Species Events That Are Enhanced During Cellular Reprogramming. Cell Metabolism, 21(5): 786–799.
Kerskens C, López Pérez D, 2022, Evidence for Quantum Entanglement in the Human Brain. Physics of Life Reviews, 42: 100–110.
Ball P, 2011, Quantum Biology: Life’s Quantum Leap. Nature, 474(7352): 478–480.
McFadden J, 2000, Quantum Evolution: How Quantum Theory Explains the Evolution of Life. W. W. Norton & Company.
Lambert N, Thomas J, Easton M, et al., 2013, Quantum Coherence in Photosynthesis: A Biophysical Basis for Quantum Biology. Journal of Physics: Condensed Matter, 25(41): 414006.
Huelga S, Plenio M, 2013, Quantum Coherence in Biological Systems. Nature Physics, 9(11): 779–786.
Fisher M, 2015, Quantum Cognition: The Possibility of Processing with Nuclear Spins in the Brain. Annals of Physics, 362: 593–602.
Klinman J, 2006, Quantum Tunneling in Enzyme Catalysis. Chemical Reviews, 106(12): 4881–4893.
Ben-Naim A, 2013, Quantum Coherence in Protein Folding. Journal of Physical Chemistry B, 117(45): 13823–13829.
Ritz T, Adem S, Schulten K, 2000, A Model for Photoreceptor-Based Magnetoreception in Birds. Biophysical Journal, 78(2): 707–718.
Hiscock J, Ritz T, 2016, The Radical Pair Mechanism of Magnetoreception. Annual Review of Biophysics, 45: 299–324.
Gohler B, Paltauf G, Fabian B, et al., 2011, Chiral-Induced Spin Selectivity in Electron Transport Through DNA Hairpins. Nature Chemistry, 3(12): 922–926.
Naaman R, Paltauf G, Waldeck D, 2019, Chiral-Induced Spin Selectivity Effects in Chemistry and Biology. Chemical Reviews, 119(19): 10635–10674.
Demetrius L, Mebazaa A, 2014, Quantum Metabolism: A New Paradigm for Aging. Biogerontology, 15(3): 267–276.
Wang C, Liu X, Zhang Y, et al., 2016, Quantized Mitochondrial Membrane Potential Oscillations Regulate Cell Fate. Nature Communications, 7: 12144.
Demetrius L, Wilson C, Brooks S, 2017, Mitochondrial Quantum Efficiency and the Evolution of Longevity. Aging Cell, 16(4): 789–796.
Zhang Y, Liu X, Wang C, et al., 2018, Mitochondrial Quantum Coherence and Longevity in Naked Mole Rats. Aging, 10(11): 3872–3885.
Penrose R, Hameroff S, 2014, Consciousness in the Universe: A Review of the Orch OR Theory. Physics of Life Reviews, 11(1): 39–78.
Hameroff S, Penrose R, 1996, Orchestrated Objective Reduction of Quantum Coherence in Brain Microtubules: The “Orch OR” Model for Consciousness. Mathematics and Computers in Simulation, 40(3–4): 453–480.
Hameroff S, 2010, Quantum Consciousness: The Penrose-Hameroff Orch OR Theory of Consciousness. Scholarpedia, 5(11): 10315.
Buffenstein R, 2005, The Naked Mole-Rat: A New Long-Lived Model for Human Aging Research. Journal of Gerontology: Biological Sciences, 60(11): 1369–1377.
da Silva J, Williams G, 2018, Quantum Coherence and Longevity in Turtles. Biogerontology, 19(3): 285–294.