Abstract
The preceding chapter has presented a detailed theory of the biological basis of intelligence. This chapter reports a major research study that was carried out in an attempt to verify some of the specific predictions made by the theory.
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References
Berger H (1929) Uber das Elektrenkephalogramm des Menschen. Arch Psychiatr Nervenkr 87: 527–570
Blinkhorn SF, Hendrickson DE (1982) Averaged evoked responses and psychometric intelligence. Nature 295: 596–597
Blomberg R, Cohen RS, Siekevitz P (1977) The structure of postsynaptic densities isolated from dog cerebral cortex. II. Characterisation and arrangement of some of the major proteins within the structure. J Cell Biol 74: 204–225
Callaway E (1975) Brain electrical potentials and individual psychological differences. Grune & Stratton, New York
Cattell RB (1963) Theory of fluid and crystallized intelligence: a critical experiment. J Educ Psychol 54: 1–22
Creutzfeldt OD, Rosina A, Ito M, Probst W (1969) Visual evoked response of single cells and of the EEG in primary visual area of the cat. J Neurophysiol 32: 127–139
Ellingson RJ (1966) Relationship between EEG and test intelligence: a commentary. Psychol Bull 65: 91–98
Ertl JP, Schafer EWP (1969) Brain response correlates of psychometric intelligence. Nature 223: 421–422
Eysenck HJ, Eysenck SBG (1975) Manual of the Eysenck personality questionnaire. Hodder & Stoughton, London
Fox SS, O’Brien JH (1965) Duplication of evoked potential waveform by curve of probability of firing of a single cell. Science 147: 838
Grab DJ, Carlin RK, Siekevitz PP (to be published) Ann NY Acad Sci
Grab DJ, Berzins K, Cohen RS, Siekevitz P (1979) J Biol Chem 254: 8690–8696
Grundke-Iqbal I, Johnson AB, Wisniewski HM,Terry RD, Iqbal K (1979) Evidence that alzheimer neurofibrillary tangles originate from neurotubules. Lancet 17: 578–580
Hendrickson AE (1972) An integrated molar/molecular model of the brain. Psychol Rep 30: 343–368
Hendrickson DE (1972) An examination of individual differences in cortical evoked response, PhD thesis, University of London
Hendrickson DE, Hendrickson AE (1980) The biological basis of individual differences in intelligence. Pers Individ Diff 1: 3–33
Hyams JS, Stebbings H (1979) Microtubule associated cytoplasmic transport. In: Roberts K, Hyams JS (eds) Microtubules. Academic Press,London, pp 487–530
Jarlfors V, Smith DS (1969) Association between synaptic vesicles and neurotubules. Nature 224: 710–711
Jasper HH (1958) Report of the committee on methods of clinical examination in electroencephalography.EEG Clin Neurophysiol 10: 370
Katz B (1966) Nerve, muscle, and synapse.McGraw-Hill, London
Kelly OT, Cotman CW (1977) Identification of glycoproteins and proteins at synapses in the central nervous system. J Biol Chem 252: 786–793
Lin CT, Dedman JR, Brinkley BR, Means AR (1980) Localization of calmodulin in rat cerebellum by immunoelectron microscopy. J Cell Biol 85: 473–480
Luduena RF (1979) Biochemistry of tubulin. In: Roberts K, Hyams JS (eds) Microtubules. Academic Press, London, pp 65–116
Matus A (1981) The postsynaptic density. TINS 4: 51–53
Matus AI, Taff-Jones DH (1978) Morphology and molecular composition of isolated postsynapticjunctional structures. Proc R Soc Lond [Biol] 203:135–151
Matus AI, Walters BB (1975) Ultrastructure of the synaptic junctional lattice isolated from a mammalian brain. J Neurocytol 4: 369–375
Matus AI, Walters BB, Mughal S (1975) Immunohistochemical demonstration of tubulin associated with microtubules and synaptic junctions in mammalian brain. J Neurocytol 4: 733–744
Osborne RR (1970) Heritability estimates for the visual evoked response. Life Sci 9: 481–490
Peters A, Palay SL, Webster HF (1970) The fine structure of the nervous system. The cells and their processes. Hoeber, New York
Saville P (1971) A British supplement to the manual of the Wechsler adult intelligence scale.Psychol Corp, New York
Scheele RB, Borisy GG (1979) In Vitro assembly of microtubules. In: Roberts K, Hyams JS (eds) Microtubules. Academic Press, London, pp 175–254
Shelanski ML (1973) Microtubules. In: Schneider DJ (ed) Proteins of the nervous system. Raven Press, New York, pp 227–242
Shelanski ML, Feit H, Berry RW, Daniels MP (1972) Some biochemical aspects of neurotubule and neurofilament proteins. In: Davison AN, Mandel P, Morgan IG (eds) Functional and structural proteins of the nervous system. Plenum Press, New York, pp 55–67
Shucard DW, Horn JL (1972) Evoked cortical potential and measurement of human abilities. J Comp Physiol Psychol 78: 59–68
Taxi J (1967) Observations on the ultrastructure of the ganglionic neurons and synapses of the frog. Rana esculenta L. In: Hyden H (ed) The neuron. Elsevier, London, pp 221–252
Vaughan HG (1969) The relationship of brain activity to scalp recording of event-related potentials. In: Donchin E, Lindsley DB (eds) Average evoked potentials. NASA SP-191, Washington DC, p 45
Vogel W, Broverman DM (1964) Relationship between EEG and test intelligence: a critical review. Psychol Bull 62: 132–144
Walters BB, Matus AI (1975) Tubulin in postsynaptic junctional lattice. Nature 257: 496–498
Wechsler D (1955) Manual for the Wechsler adult intelligence scale. Psych Corp, New York
Westrum LE, Gray EG (1977) Microtubules associated with postsynaptic ‘thickenings’. J Neurocytol 6: 505–518
Wood JG, Wallace RW, Whitaker JN, Cheung WY (1980) Immunocytochemical localization of calmodulin and a heat-stable calmodulinbinding protein in basal ganglia of mouse brain. J Cell Biol 84: 66–76
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Hendrickson, D.E. (1982). The Biological Basis of Intelligence. Part II: Measurement. In: Eysenck, H.J. (eds) A Model for Intelligence. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-68664-1_7
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DOI: https://doi.org/10.1007/978-3-642-68664-1_7
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