Парадоксы эволюции. Как наличие ресурсов и отсутствие внешних угроз приводит к самоуничтожению вида и что мы можем с этим сделать. Алексей Макарушин

Чтение книги онлайн.

Читать онлайн книгу Парадоксы эволюции. Как наличие ресурсов и отсутствие внешних угроз приводит к самоуничтожению вида и что мы можем с этим сделать - Алексей Макарушин страница 25

Парадоксы эволюции. Как наличие ресурсов и отсутствие внешних угроз приводит к самоуничтожению вида и что мы можем с этим сделать - Алексей Макарушин Интеллектуальный научпоп. Медицина не для всех

Скачать книгу

М.: АСТ.

      3. Ноу Л. (2020) Эгоистичная митохондрия. Как сохранить здоровье и отодвинуть старость. – СПб: Питер.

      4. Блюменфельд Л. А. (1977). Проблемы биологической физики. – М.: Наука.

      5. Dobzhansky T. (1973) Nothing in Biology Makes Sense except in the Light of Evolution. Am. Biol. Teacher35, 125–129.

      6. Pross A. (2012). What is Life? How Chemistry Becomes Biology, Oxford University Press, United Kingdom.

      7. Laughlin S. B., de Ruyter van Steveninck R. R. and Anderson J. C. (1998) The metabolic cost of neural information. Nat. Neurosci. 1, 36–41.

      8. Gatenby, R. A. and Frieden, B. R. (2013). The critical roles of information and nonequilibrium thermodynamics in evolution of living systems. Bull. Math. Biol. 75, 589–601.

      9. Schroedinger E. (1944). What is Life? The Physical Aspect of the Living Cell, Cambride University Press.

      10. Nunn A. V., Guy G. W. and Bell J. D. (2014). The intelligence paradox; will ET get the metabolic syndrome? Lessons from and for Earth. Nutr. Metab. 11, 34.

      11. Lane N. and Martin W. (2010). Theenergetics of genome complexity. Nature 467, 929–934.

      12. Tulving E. (1985). How many memory systems are there? Am. Psychol. 40, 385–398.

      13. Howarth C., Gleeson P. and Attwell D. (2012). Updated energy budgets for neural computation in the neocortex and cerebellum. J. Cereb. Blood Flow Metab. 32, 1222–1232.

      14. Harris J. J., Jolivet R. and Attwell D. (2012). Synaptic energy use and supply. Neuron 75, 762–777.

      15. Attwell D. and Laughlin S. B. (2001). An energy budget for signaling in the grey matter of the brain. J. Cereb. Blood Flow Metab. 21, 1133–1145.

      16. Hudetz, A. G. (2012). General anesthesia and human brain connectivity. Brain Connect. 2, 291–302.

      17. Krueger J. M., Frank M. G., Wisor J. P. and Roy S. (2015) Sleep function: toward elucidating an enigma. Sleep Med. Rev. 28, 42–50.

      18. Penrose R. (1994). Shadows of the Mind; ASearch for the Missing Science of Consciousness, Oxford University Press, Great Britain.

      19. Tarlaci S. and Pregnolato M. (2016). Quantum neurophysics: fromnon-living matter to quantum neurobiology and psychopathology. Int. J. Psychophysiol. 103, 161–173.

      20. Al-Khalili J. and McFadden J. (2014). Life on the Edge: The Coming of Age of Quantum Biology, Transworld Publishers, Great Britain.

      21. Lovley D. R. and Malvankar N. S. (2015). Seeing is believing: novel imaging techniques help clarify microbial nanowire structure and function. Environ. Microbiol. 17, 2209–2215.

      22. Tamulis A. and Grigalavicius M. (2014). Quantum entanglement in photoactive prebiotic systems. Syst. Synth. Biol. 8, 117–140.

      23. Engel G. S., Calhoun T. R., Read E. L., Ahn T. K., Mancal T., Cheng Y. C., Blankenship, R. E. and Fleming, G. R. (2007). Evidence for wavelike energy transfer through quantum coherence in photosynthetic systems. Nature 446, 782–786.

      24. Fassioli F., Dinshaw R., Arpin P. C. and Scholes G.D. (2014). Photosynthetic light harvesting: excitons and coherence. J. R. Soc. Interface 11, 20130901.

      25. Lim J., Palecek D., Caycedo-Soler F., Lincoln C. N., Prior J., von Berlepsch H., Huelga S. F., Plenio M.B., Zigmantas D. and Haue, J. (2015). Vibronic origin of long-lived coherence in an artificial molecular light harvester. Nat. Commun. 6, 7755.

      26. Weber S., Ohmes E., Thurnauer M. C., Norris J. R. and Kothe G.(1995). Light-generated nuclear quantum beats: a signature of photosynthesis. Proc. Natl. Acad. Sci. U.S.A. 92, 7789–7793.

      27. Craddock T. J., Friesen D., Mane J., Hameroff S. and Tuszynski J. A. (2014). The feasibility of coherent energy transfer in microtubules. J. R. Soc. Interface 11, 20140677.

      28. Craddock T. J., Priel A. and Tuszynski J. A. (2014). Keeping time: could quantum beating in microtubules be the basis for the neural synchrony related to consciousness? J. Integr. Neurosci. 13, 293–311.

      29. Winkler J.R. and Gray H.B. (2014). Long-range electron tunneling. J. Am. Chem. Soc. 136, 2930–2939.

      30. Hayashi T. and Stuchebrukhov A. A. (2011). Quantum electron tunneling in respiratory complex I. J. Phys Chem. B115, 5354–5364.

      31. Moser C. C., Farid T. A., Chobot S. E. and Dutton P. L. (2006). Electron tunneling chains of mitochondria. Biochim. Biophys. Acta. 1757, 1096–1109.

      32. De Vries S., Dorner K., Strampraad M. J. and Friedrich T. (2015). Electron tunneling rates in respiratory complex I are tuned for efficient energy conversion. Angew Chem. Int. Ed. Engl. 54, 2844–2848.

      33. Trixler F. (2013). Quantum tunnelling to the origin and evolution of life. Curr. Org. Chem. 17, 1758–1770.

      34. Vattay G., Salahub D., Csabai I., Nassimi A. and Kaufmann S. A. (2015). Quantum criticality at the origin of life. J. Phys. Conf. Ser. 626, 012023.

      35. Zhang Y., Gennady P. B. and Kais S. (2015). The radical pair mechanism and the avian chemical compass: quantum coherence and entanglment. Int. J. Quantum Chem. 115, 1327–1341.

      36. Gane S., Georganakis D., Maniati K., Vamvakias M., Ragoussis N., Skoulakis E. M. and Turin L. (2013). Molecular vibration-sensing component in human olfaction. PloS One8, e55780.

      37. Vattay G., Kauffman S. and Niiranen S. (2014). Quantum biology on the edge of quantum chaos. PloS One9, e8901.

      38. Aon M. A., Cortassa S. and O’Rourke B. (2008). Mitochondrial oscillations in physiology and pathophysiology. Adv. Exp. Med. Biol. 641, 98–117.

      39. Cortassa S., O’Rourke B. and Aon M. A. (2014). Redox-optimized ROSbalance and the relationship between mitochondrial respiration and ROS. Biochim. Biophys. Acta. 1837, 287–295.

      40. Allen J. F. (2015). Why chloroplasts and mitochondria retain their own genomes and genetic systems: colocation for redox regulation of gene expression. Proc. Natl. Acad. Sci. USA. 112, 10231–10238.

      41. Mailloux R. J. and Harper, M.E. (2011). Uncoupling proteins and the control of mitochondrial reactive oxygen species production. Free Radic. Biol. Med. 51, 1106–111.

      42. Moradi N., Scholkmann F. and Salari V. (2015) A study of quantum mechanical probabilities in the classical Hodgkin – Huxley model. J. Integr. Neurosci. 14, 1–17.

      43. Summhammer J., Salari V. and Bernroide, G. (2012). Aquantum-mechanical description of ion motion within the confining potentials of voltage-gated ion channels. J. Integr. Neurosci. 11, 123–135.

      44. Skulachev V. P. (2001). Mitochondrial filaments and clusters as intracellular power-transmitting cables. Trends Biochem. Sci. 26, 23–29.

      45. Wai T. and Langer T. (2016). Mitochondrial dynamics and metabolic regulation. Trends Endocrinol. Metab. 27, 105–117.

      46. Tamulis

Скачать книгу