Brain hackers/bib/subatomic

Gustav Bernroider and Sisir Roy. Quantum entanglement of K+ ions, multiple channel states and the role of noise in the brain. In Fluctuations and Noise in Biological, Biophysical, and Biomedical Systems III, edited by Nigel G. Stocks, Derek Abbott, Robert P. Morse, Proc. of SPIE Vol. 5841 (SPIE, Bellingham, WA, 2005)

Anatoly L. Buchachenko, Dmitry A. Kuznetsov, and Natalia N. Breslavskaya. Ion-Radical Mechanism of Enzymatic ATP Synthesis: DFT Calculations and Experimental Control. J. Phys. Chem. B 2010, 114, 2287–2292

Anatoly L. Buchachenko, Dmitry A. Kuznetsov, and Natalia N. Breslavskaya. Chemistry of Enzymatic ATP Synthesis: An Insight through the Isotope Window. Chem. Rev. 2012, 112, 2042–2058

Anatoly L. Buchachenko et al. Dependence of Mitochondrial ATP Synthesis on the Nuclear Magnetic Moment of Magnesium Ions. Doklady Biochemistry and Biophysics, Vol. 396, 2004, pp. 197–199. Translated from Doklady Akademii Nauk, Vol. 396, No. 6, 2004, pp. 828–830.

Anatoly L. Buchachenko et al. Magnetic isotope effect of magnesium in phosphoglycerate kinase phosphorylation. PNAS August 2, 2005 vol. 102 no. 31 10793–10796

Anatoly L. Buchachenko, Dmitry A. Kouznetsov, Natalia N. Breslavskaya, and Marina A. Orlova. Magnesium Isotope Effects in Enzymatic Phosphorylation. J. Phys. Chem. B 2008, 112, 2548-2556

A.L.Buchachenko and V.L.Berdinskii. Chemically Induced Radio-frequency Emission and Chemical Radiophysics. Translated from Uspekhi Khimii, 52 3 - 1 9 (1983)

Anatoly L. Buchachenko, Nikita N. Lukzen and J. Boiden Pedersen. On the magnetic field and isotope effects in enzymatic phosphorylation. Chemical Physics Letters 434 (2007) 139–143

A.L. Buchachenko et al. Calcium induced ATP synthesis: Isotope effect, magnetic parameters and mechanism. Chemical Physics Letters 505 (2011) 130–134

Anatoly L. Buchachenko and Dmitry A. Kuznetsov. Magnetic Field Affects Enzymatic ATP Synthesis J. AM. CHEM. SOC. 2008, 130, 12868–12869

A. L. Buchachenko and D. A. Kouznetsov. Efficiency of ATP Synthase as a Molecular Machine. Biophysics, 2008, Vol. 53, No. 3, pp. 219–222.

A. L. Buchachenko and D. A. Kuznetsov. Magnesium Magnetic Isotope Effect: A Key to the Mechanochemistry of Phosphorylating Enzymes as Molecular Machines. Molecular Biology, 2006, Vol. 40, No. 1, pp. 9–15.

A. L. Buchachenko, D. A. Kuznetsov, and V. L. Berdinsky. New Mechanisms of Biological Effects of Electromagnetic Fields. Biophysics, 2006, Vol. 51, No. 3, pp. 489–496.

P. T. Callaghan and M. Le Gros. Nuclear spins in the Earth's magnetic field. Am. J. Phys. 50(8), Aug. 1982

Chiabrera A, Bianco B, Tommasi T, Moggia E. 1992. Langevin–Lorentz and Zeeman–Stark models of bioelectromagnetic effects. Acta Pharm 42:315–322.

Aarholt E et al. NMR Conditions in Biological Systems. Pp. 75-104 in "Modern Bioelectricity" (Marino A A, ed., 1988).

Ruyten WM. 1990a. Magnetic and optical resonance of two-level quantum systems in modulated fields. i. bloch equation approach. PhysRevAAtomicMolOptPhys42(7):4226–4245.

Ruyten WM. 1990b. Magnetic and optical resonance of two-level quantum systems in modulated fields. ii. floquet hamiltonian approach. Phys Rev A Atomic Mol Opt Phys 42(7):4246–4254.

Wenjun J.Sun et al. Calcium Efflux of Plasma Membrane Vesicles Exposed to ELF Magnetic Fields. Test of a Nuclear Magnetic Resonance Interaction Model. Bioelectromagnetics. 2012 Oct;33(7):535-42.

V. O. Ponomarev and V. V. Novikov. Effect of Low-Frequency Alternating Magnetic Fields on the Rate of Biochemical Reactions Proceeding with Formation of Reactive Oxygen Species. Biophysics, 2009, Vol. 54, No. 2, pp. 163–168.

Klaus Schulten. Magnetic field effects on radical pair processes in chemistry and biology. In J. H. Bernhard, editor, Biological Effects of Static and Extremely Low Frequency Magnetic Fields, pp. 133-140. MMV Medizin Verlag, Munich, 1986.

C. Timmel, U. Till, B. Brocklehurst, K. McLauchlan, P. Hore, Effects of weak magnetic fields on free radical recombination reactions, Mol. Phys. 95 1998. 71–89.

J. Walleczek, Magnetokinetic effects on radical pairs: a paradigm for magnetic field interactions with biological systems at lower than thermal energy, in: M. Blank Ed.., Electromagnetic fields: Biological Interactions and Mechanisms, Vol. 250, American Chem. Soc., Washington, 1995, 395–420

Yabuzaki T, Nakayama S, Murakami Y, Ogawa T. 1974. Interaction between a spin-1/2 atom and a strong rf field. Phys Rev A 10(6):1955–1963.

S. D. Zakharov. On the Possible Fundamental Unity of Magnetobiological “Resonances”. Biophysics, 2010, Vol. 55, No. 4, pp. 561–564.