Quantum Electrodynamics Coherence and Hormesis: Foundations of Quantum Biology.
Devyatkov law
Weber–Fechner law
coherence
dynamical order
hormesis
non-thermal effects
phase
quantum field theory
resonance
symmetry-breaking
water
Journal
International journal of molecular sciences
ISSN: 1422-0067
Titre abrégé: Int J Mol Sci
Pays: Switzerland
ID NLM: 101092791
Informations de publication
Date de publication:
12 Sep 2023
12 Sep 2023
Historique:
received:
01
06
2023
revised:
12
07
2023
accepted:
21
07
2023
medline:
29
9
2023
pubmed:
28
9
2023
entrez:
28
9
2023
Statut:
epublish
Résumé
"Quantum biology" (QB) is a promising theoretical approach addressing questions about how living systems are able to unfold dynamics that cannot be solved on a chemical basis or seem to violate some fundamental laws (e.g., thermodynamic yield, morphogenesis, adaptation, autopoiesis, memory, teleology, biosemiotics). Current "quantum" approaches in biology are still very basic and "corpuscular", as these rely on a semi-classical and approximated view. We review important considerations of theory and experiments of the recent past in the field of condensed matter, water, physics of living systems, and biochemistry to join them by creating a consistent picture applicable for life sciences. Within quantum field theory (QFT), the field (also in the matter field) has the primacy whereby the particle, or "quantum", is a derivative of it. The phase of the oscillation and not the number of quanta is the most important observable of the system. Thermodynamics of open systems, symmetry breaking, fractals, and quantum electrodynamics (QED) provide a consistent picture of condensed matter, liquid water, and living matter. Coherence, resonance-driven biochemistry, and ion cyclotron resonance (Liboff-Zhadin effect) emerge as crucial hormetic phenomena. We offer a paradigmatic approach when dealing with living systems in order to enrich and ultimately better understand the implications of current research activities in the field of life sciences.
Sections du résumé
BACKGROUND
BACKGROUND
"Quantum biology" (QB) is a promising theoretical approach addressing questions about how living systems are able to unfold dynamics that cannot be solved on a chemical basis or seem to violate some fundamental laws (e.g., thermodynamic yield, morphogenesis, adaptation, autopoiesis, memory, teleology, biosemiotics). Current "quantum" approaches in biology are still very basic and "corpuscular", as these rely on a semi-classical and approximated view. We review important considerations of theory and experiments of the recent past in the field of condensed matter, water, physics of living systems, and biochemistry to join them by creating a consistent picture applicable for life sciences. Within quantum field theory (QFT), the field (also in the matter field) has the primacy whereby the particle, or "quantum", is a derivative of it. The phase of the oscillation and not the number of quanta is the most important observable of the system. Thermodynamics of open systems, symmetry breaking, fractals, and quantum electrodynamics (QED) provide a consistent picture of condensed matter, liquid water, and living matter. Coherence, resonance-driven biochemistry, and ion cyclotron resonance (Liboff-Zhadin effect) emerge as crucial hormetic phenomena. We offer a paradigmatic approach when dealing with living systems in order to enrich and ultimately better understand the implications of current research activities in the field of life sciences.
Identifiants
pubmed: 37762305
pii: ijms241814003
doi: 10.3390/ijms241814003
pmc: PMC10530466
pii:
doi:
Substances chimiques
Water
059QF0KO0R
Types de publication
Journal Article
Review
Langues
eng
Sous-ensembles de citation
IM
Références
Bioelectromagnetics. 1998;19(1):41-5
pubmed: 9453705
Biol Trace Elem Res. 1990 Jul-Dec;26-27:385-400
pubmed: 1704742
Bioelectromagnetics. 1996;17(6):467-74
pubmed: 8986364
Bioelectromagnetics. 2002 Oct;23(7):522-30
pubmed: 12224056
Phys Chem Chem Phys. 2011 Nov 28;13(44):19918-24
pubmed: 21915406
Physiol Chem Phys Med NMR. 2012;42:1-64
pubmed: 24437002
J Theor Biol. 2010 Aug 21;265(4):511-6
pubmed: 20493195
Bioelectromagnetics. 1994;15(5):385-98
pubmed: 7802707
Electromagn Biol Med. 2007;26(4):315-25
pubmed: 18097820
Electromagn Biol Med. 2017;36(3):279-288
pubmed: 28632082
Science. 1983 Jun 17;220(4603):1283-5
pubmed: 6857248
Phys Rev Lett. 1988 Aug 29;61(9):1085-1088
pubmed: 10039515
Bioelectromagnetics. 1991;12(2):71-5
pubmed: 2039557
Nature. 1972 Jan 14;235(5333):109-11
pubmed: 4550399
Proc Natl Acad Sci U S A. 2009 Sep 8;106(36):15214-8
pubmed: 19706484
Bioelectromagnetics. 2006 Jan;27(1):16-25
pubmed: 16283642
Electromagn Biol Med. 2017;36(2):115-122
pubmed: 27399207
Microb Cell. 2014 Apr 23;1(5):145-149
pubmed: 28357236
J Phys Chem B. 2011 Jun 16;115(23):7693-8
pubmed: 21595433
Cell Mol Biol (Noisy-le-grand). 2005 Dec 14;51(7):677-702
pubmed: 16359619
Electromagn Biol Med. 2007;26(1):45-62
pubmed: 17454082
Int J Radiat Biol. 2011 Apr;87(4):409-15
pubmed: 21457072
Bioelectromagnetics. 1990;11(2):169-87
pubmed: 2242052
Radiat Environ Biophys. 1986;25(1):65-74
pubmed: 3714975
Med Hypotheses. 2000 May;54(5):685-8
pubmed: 10859665
Int J Radiat Biol Relat Stud Phys Chem Med. 1987 Nov;52(5):787-93
pubmed: 3500146
Bull Math Biol. 1976;38(2):111-8
pubmed: 178391
Cell Biophys. 1984 Mar;6(1):33-52
pubmed: 6204761
Nat Commun. 2013;4:2401
pubmed: 24029922
J Acupunct Meridian Stud. 2019 Feb;12(1):29-36
pubmed: 30056215
Radiat Res. 1987 May;110(2):219-31
pubmed: 3575652
Cells. 2022 Dec 13;11(24):
pubmed: 36552798
Crit Rev Toxicol. 2001 Jul;31(4-5):353-424
pubmed: 11504172
Cold Spring Harb Perspect Biol. 2022 May 17;14(4):
pubmed: 34400551
Science. 1961 Jan 13;133(3446):80-6
pubmed: 17769332
Electromagn Biol Med. 2006;25(4):227-43
pubmed: 17178583
Science. 1995 Jul 14;269(5221):198-201
pubmed: 17789847
Kybernetik. 1967 Nov;4(2):44-8
pubmed: 5617419
Biofizika. 2008 Sep-Oct;53(5):817-21
pubmed: 18954010
Int J Mol Sci. 2023 Feb 17;24(4):
pubmed: 36835509
Bioelectromagnetics. 1997;18(2):156-65
pubmed: 9084866
Science. 1984 Feb 24;223(4638):818-20
pubmed: 6695183
Am J Epidemiol. 1979 Mar;109(3):273-84
pubmed: 453167
Electromagn Biol Med. 2020 Jul 2;39(3):227-238
pubmed: 32447985
Biomagn Res Technol. 2008 Jan 25;6:1
pubmed: 18218145
J Anat. 1983 Oct;137 (Pt 3):513-36
pubmed: 6654743
Electromagn Biol Med. 2009;28(1):46-52
pubmed: 19337894
Nucleic Acids Res. 2004 Jan 1;32(Database issue):D293-5
pubmed: 14681416
Sci Rep. 2015 Dec 17;5:18353
pubmed: 26678416
Environ Health Perspect. 2004 May;112(6):687-94
pubmed: 15121512
Biomagn Res Technol. 2004 Nov 30;2(1):8
pubmed: 15571630
J R Soc Interface. 2018 Nov 14;15(148):
pubmed: 30429265
J Phys Chem Lett. 2011 Feb 18;2(6):532-536
pubmed: 22003430
J Acupunct Meridian Stud. 2010 Dec;3(4):291-7
pubmed: 21185545
Nature. 1975 Mar 6;254(5495):66-7
pubmed: 1167627
Adv Colloid Interface Sci. 2006 Nov 23;127(1):19-27
pubmed: 16952332
J Pediatr Surg. 1974 Dec;9(6):853-58
pubmed: 4473530
Riv Biol. 2001 May-Aug;94(2):237-58
pubmed: 11702650
Toxicol Appl Pharmacol. 2007 Jul 1;222(1):122-8
pubmed: 17459441
Aging (Albany NY). 2011 Sep;3(9):821-8
pubmed: 21931183
Physiol Chem Phys. 1977;9(2):131-47
pubmed: 414240
Bioelectromagnetics. 1995;16(3):207-10
pubmed: 7677797
Physiol Chem Phys Med NMR. 2007;39(2):111-234
pubmed: 19256352