Abstract
Animate as opposed to inanimate matter has had the unique propensity to grow more complex and more adaptively responsive to environmental change over the hundreds of millions of years in which its existence on earth has been recorded. Its increasingly adaptive responsiveness is the crux of its endurance and evolution. Genetic mutation and natural selection have, since the time of Darwin, been seen as the dual mechanisms responsible for the increasing adaptation, explaining how a species develops and adapts to nature with augmenting efficiency. The process is slow and requires millions of years. Even the highly developed behavioral patterns and complex societies of insects are explicable in terms of natural selection if account is taken of the brief generational and maturational time and the large number of individuals produced in each generation.
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References
Anlezark, G.M., Crow, T.J., and Greenway, A.P. Impaired learning and decreased cortical norepinephrine after bilateral locus coeruleus lesions. Science 181, 682–684 (1973).
Chamberlain, T.J., Halick, P., and Gerard, R.W. Fixation of experience in the rat spinal cord. J. Neurophysiol. 26, 662–673 (1963).
Chan-Palay, V. Cerebellar Dentate Nucleus. Springer-Verlag, Berlin (1977).
Descarries, L., Beaudet, A., and Watkins, K.C. Serotonin nerve terminals in adult rat neocortex. Brain Res. 100, 563–588 (1975).
Dingman, W., and Sporn, M.B. The incorporation of 8-azaguanine into rat brain RNA and its effect on maze learning by the rat: An inquiry into the biochemical basis of memory. J. Psychiat. Res. 1, 1–11 (1961).
Dismukes, R.K., and Rake, A.V. Involvement of biogenic amines in memory formation. Psychopharmacologia 23, 17–25 (1972).
Duncan, C.P. The retroactive effect of electroshock on learning. J. Comp. Physiol. Psychol. 42, 32–44 (1949).
Ebbinghaus, H. Uber das Gedachtnis. Duncker, Leipzig (1885).
Gallagher, M., Kapp, B.S., Musty, R.E., and Driscoll, P.A. Memory formation: evidence for a specific neurochemical system in the amygdala. Science 198, 423–425 (1977).
Gerard, R.W. Physiology and psychiatry. Am. J. Psychiat. 106, 161–173 (1949).
Hebb, D.O. The Organization of Behavior, John Wiley & Sons, New York (1949).
Jarvick, M.E. Effects of chemical and physical treatments on learning and memory. Ann. Rev. Psychol. 62, 125–132 (1970).
Kasamatsu, T., and Pettigrew, J.D. Depletion of brain catecholamines: failure of ocular dominance shift after monocular occlusion in kittens. Science 194, 206–209 (1976).
Kety, S.S. The incorporation of experience into the central nervous system, in Deafferentation Experimentale et Clinique. J. de Ajuriaguerra, ed. Georg et Cie, Geneva (1965), pp. 251–256.
Kety, S.S. The biogenic amines in the central nervous system: Their possible roles in arousal, emotion and learning, in The Neurosciences: Second Study Program. F.O. Schmitt, ed. Rockefeller University Press, New York (1970), pp. 324–336.
Kety, S.S. Biological concomitants of effective states and their possible role in memory processes, in Neural Mechanisms of Learning and Memory. M.R. Rosenzweig and E.L. Bennett, eds. MIT Press, Cambridge (1976), pp.321–336.
Korsakoff, S.S. Etude medico-psychologique sur une forme des maladies de la memo ire. Revue Philosophique 5, 501–530 (1889).
Lashley, K.S. In search of the engram. Symp. Soc. Exper. Biol., 4, 454–482 (1950).
Libet, B., and Tosaka, T. Dopamine as a synaptic transmitter and modulator in sympathetic ganglia: a different mode of synaptic action. Proc. Natl. A cad. Sci. USA 67, 667–673 (1970).
McEntee, W.J., and Mair, R.G. Memory impairment in Korsakoff’s psychosis: a correlation with brain noradrenergic activity. Science 202, 905–907 (1978).
Murphy, D.L., Henry, G.M., and Weingartner, H. Catecholamines and memory: enhanced verbal learning during L-dopa administration. Psychopharmacologia 27,319–326 (1972).
Randt, C.T., Quartermain, D., Goldstein, M. and Anagnoste, B. Norepinephrine biosynthesis inhibition: effects on memory in mice. Science 172, 498–499 (1971).
Ribot, T.A. The Diseases of Memory. Appleton Co., New York (1882).
Sherrington, C.S. Chapter in Foster’s Neurophysiology. (1887), p. 1117.
Thompson, R.F., Berger, T.W., Berry, S.D., and Hoehler, F.K. The search for the engram II. Presented at the 50th Anniversary Symposium, Dept. of Psychology, U. of Texas at Austin (1978).
van Ree, J.M., Bohus, B., Versteeg, D.H.G., and de Wied, D. Neurohypophyseal principles and memory processes. Biochem. Pharmacol. 27, 1793–1800 (1978).
Widrow, B., and Angell, J.B. Reliable trainable networks for computing and control. Aerospace Engineering 21, 78–123 (1962).
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Kety, S.S. (1982). The Evolution Of Concepts Of Memory. In: Beckman, A.L. (eds) The Neural Basis of Behavior. Springer, Dordrecht. https://doi.org/10.1007/978-94-011-6302-6_5
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DOI: https://doi.org/10.1007/978-94-011-6302-6_5
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