Summary
This paper reports evidence linking dorsolateral prefrontal cortex with one of the cognitive abilities that emerge between 7.5–12 months in the human infant. The task used was Piaget's Stage IV Object Permanence Test, known as AB (pronounced “A not B”). The AB task was administered (a) to human infants who were followed longitudinally and (b) to intact and operated adult rhesus monkeys with bilateral prefrontal and parietal lesions. Human infants displayed a clear developmental progression in AB performance, i.e., the length of delay required to elicit the AB error pattern increased from 2–5 s at 7.5–9 months to over 10 s at 12 months of age. Monkeys with bilateral ablations of dorsolateral prefrontal cortex performed on the AB task as did human infants of 7.5–9 months; i.e., they showed the AB error pattern at delays of 2–5 s and chance performance at 10 s. Unoperated and parietally operated monkeys succeeded at delays of 2, 5, and 10 s; as did 12 month old human infants. AB bears a striking resemblance to Delayed Response, the classic test for dorsolateral prefrontal function in the rhesus monkey, and indeed performance on AB and Delayed Response in the same animals in the present study was fully comparable. These findings provide direct evidence that AB performance depends upon dorsolateral prefrontal cortex in rhesus monkeys and indicates that maturation of dorsolateral prefrontal cortex may underlie the developmental improvement in AB performance of human infants from 7.5–12 months of age. This improvement marks the development of the ability to hold a goal in mind in the absence of external cues, and to use that remembered goal to guide behavior despite the pull of previous reinforcement to act otherwise. This confers flexibility and freedom to choose and control what one does.
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References
Acredolo L, Adams A, Goodwyn SW (1984) The role of selfproduced movement and visual tracking in infant spatial orientation. J Exp Child Psychol 38: 312–327
Alexander GE, Goldman FS (1978) Functional development of the dorsolateral prefrontal cortex: an analysis utilizing reversible cryogenic depression. Brain Res 143: 233–250
Arnsten AFT, Goldman-Rakic PS (1985) Alpha-adrenergic mechanisms in prefrontal cortex associated with cognitive decline in aged non-human primates. Science 230: 1273–1276
Anderson RM, Hunt SC, VanderStoep A, Pribram KH (1976) Object permanency and delayed response as spatial context in monkeys with frontal lesions. Neuropsychologia 14: 481–490
Battig K, Rosvold HE, Mishkin M (1960) Comparison of the effects of frontal and caudate lesions on delayed response and alternation in monkeys. J Comp Physiol Psychol 4: 400–404
Bauer RH, Fuster JM (1976) Delayed-matching and delayed-response deficit from cooling dorsolateral prefrontal cortex in monkeys. J Comp Physiol Psychol 90: 293–302
Bremner JG (1978) Egocentric versus allocentric spatial coding in nine-month-old infants: factors influencing the choice of code. Dev Psychol 14: 346–355
Bremner JG, Bryant PE (1977) Place versus response as the basis of spatial errors made by young infants. J Exp Child Psychol 23: 162–171
Bremner JG, Knowles LS (1984) Piagetian stage IV search errors with an object that is directly accessibly both visually and manually. Percept 13: 307–314
Brody BA, Pribram KH (1978) The role of frontal and parietal cortex in cognitive processing. Brain 101: 607–633
Brozoski T, Brown RM, Rosvold HE, Goldman PS (1979) Cognitive deficit caused by depletion of dopamine in prefrontal cortex of rhesus monkey. Science 205: 929–931
Bugbee NM, Goldman-Rakic PS (1981) Functional 2-deoxyglucose mapping in association cortex: prefrontal activation in monkeys performing a cognitive task. Soc Neurosci Abstr 7: 416
Butterworth G (1975) Spatial location codes in determining search errors. Child Dev 46: 866–870
Butterworth G (1976) Asymmetrical search errors in infancy. Child Dev 47: 864–867
Butterworth G (1977) Object disappearance and error in Piaget's stage IV task. J Exp Child Psychol 23: 391–401
Cavada C, Goldman-Rakic PS (1986) Subdivisions of area 7 in rhesus monkey exhibit selective patterns of connectivity with limbic visual and somatosensory cortical areas. Soc Neurosci Abstr 12: 262
Cornell EH (1979) The effects of cue reliability on infants' manual search. J Exp Child Psychol 28: 81–91
Diamond A (1983) Behavior changes between 6 to 12 months of age: what can they tell us about how the mind of the infant is changing? Unpublished doctoral dissertation. Harvard University
Diamond A (1985) Development of the ability to use recall to guide action, as indicated by infants' performance on AB. Child Dev 56: 868–883
Diamond A (1988) Abilities and neural mechanisms underlying AB performance. Child Dev 59
Diamond A (1988) Differences between adult and infant cognition: is the crucial variable presence or absence of language? In: Weiskrantz L (ed) Thought without language. Oxford University Press, Oxford, pp 337–370
Diamond A, Goldman-Rakic PS (1986) Comparative development in human infants and infant rhesus monkeys of cognitive functions that depend on prefrontal cortex. Neurosci Abstr 12: 742
Evans WF (1973) The stage IV error in Piaget's theory of concept development: an investigation of the rise of activity. Unpublished doctoral dissertation. University of Houston
Evans WF, Gratch G (1972) The stage IV error in Piaget's theory of object concept development: difficulties in object conceptualization or spatial localization? Child Dev 43: 682–688
Fagen JW, Rovee-Collier C (1982) A conditioning analysis of infant memory. In: Isaacson RL, Spear NE (eds) The expression of knowledge: neurobehavioral transformations of information into action. Plenum, New York, pp 67–111
Fox N, Kagan J, Weiskopf S (1979) The growth of memory during infancy. Gen Psychol Monogr 9: 91–130
Freedman M, Oscar-Berman M (1986) Bilateral frontal lobe disease and selective delayed response deficits in humans. Behav Neurosci 100: 337–342
Fulton JE, Jacobsen CF (1935) The functions of the frontal lobes, a comparative study in monkeys. Adv Mod Biol 4: 113–123
Fuster JM (1973) Unit activity in prefrontal cortex during delayresponse performance: neuronal correlates of transient memory. J Neurophysiol 36: 61–78
Fuster JM (1980) The prefrontal cortex. Raven Press, New York
Fuster JM, Alexander GE (1971) Neuron activity related to short-term memory. Science 173: 652–654
Goldfield EC, Dickerson DJ (1981) Keeping track of locations during movement in 8- to 10-month-old infants. J Exp Child Psychol 32: 48–64
Goldman PS (1971) Functional development of the prefrontal cortex in early life and the problem of neuronal plasticity. Exp Neurol 32: 366–387
Goldman-Rakic PS (1987) Circuitry of primate prefrontal cortex and regulation of behavior by representational knowledge. In: Plum F, Mountcastle V (eds) Handbook of physiology, Vol 5, pp 373–417
Goldman PS, Rosvold HE (1970) Localization of function within the dorsolateral prefrontal cortex of the rhesus monkey. Exp Neurol 27: 291–304
Goldman PS, Rosvold HE, Mishkin M (1970) Evidence for behavioral impairment following prefrontal lobectomy in the infant monkey. J Comp Physiol Psychol 70: 454–463
Gratch G (1975) Recent studies based on Piaget's view of object concept development. In: Cohen LB, Salapatek P (eds) Infant perception: from to cognition, Vol 2. Academic Press, New York
Gratch G, Appel KJ, Evans WF, Le Compte GK, Wright NA (1974) Piaget's stage IV object concept error: evidence of forgetting or object conception? Child Dev 45: 71–77
Gratch G, Landers WF (1971) Stage IV of Piaget's theory of infant's object concepts: a longitudinal study. Child Dev 42: 359–372
Gross CG, Weiskrantz L (1962) Evidence for dissociation of impairment on auditory discrimination and delayed response following lateral frontal lesions in monkeys. Exp Neurol 5: 453–476
Harlow HF, Davis RT, Settlage PH, Meyer DR (1952) Analysis of frontal and posterior association syndromes in brain-damaged monkeys. J Comp Physiol Psychol 54: 419–429
Harris PL (1973) Perseverative errors in search by young infants. Child Dev 44: 28–33
Harris PL (1974) Perseverative search at a visibly empty place by young infants. J Exp Child Psychol 18: 535–542
Harris PL (1986) The development of search. In: Salapatek P, Cohen LB (eds) Handbook of infant perception. Academic Press, New York
Hyvärinen J (1982) The parietal cortex of monkey and man. Springer, New York
Jacobsen CF (1935) Functions of frontal association areas in primates. Arch Neurol Psychiatr 33: 558–560
Jacobsen CF (1936) Studies of cerebral functions in primates. I. The function of the frontal association areas in monkeys. Comp Psychol Monogr 13: 1–60
Kojima S, Goldman-Rakic PS (1982) Delay related activity of prefrontal cortical neurons in rhesus monkeys performing delayed response. Brain Res 248: 43–49
Kojima S, Kojima M, Goldman-Rakic PS (1982) Operant behavioral analysis of delayed response performance in rhesus monkeys with prefrontal lesions. Brain Res 248: 51–59
Luria AR, Homskaya ED (1964) Disturbance in the regulative role of speech with frontal lobe lesions. In: Warren JM, Akert K (eds) The frontal granular cortex and behavior. McGraw-Hill, New York, pp 353–371
Mesulam M-M, Van Hoesen GW, Pandya DN, Geschwind N (1977) Limbic and sensory connections of the inferior parietal lobule (Area PG) in the rhesus monkey: a study with a new method for horseradish peroxidase histochemistry. Brain Res 136: 393–414
Meyer DR, Harlow HF, Settlage PH (1951) A survey of delayed response performance by normal and brain-damaged monkeys. J Comp Physiol Psychol 44: 17–25
Miles RC, Blomquist A (1960) Frontal lesions and behavioral deficits in monkey. J Neurophysiol 23: 471–484
Millar WS, Watson JS (1979) The effect of delayed feedback on infant learning reexamined. Child Dev 50: 747–751
Milner B (1964) Some effects of frontal lobectomy in man. In: Warren JM, Akert K (eds) The frontal granular cortex and behavior. McGraw-Hill, New York, pp 313–334
Mountcastle VB, Lynch JC, Georgopoulos A, Sakata H, Acuna C (1975) Posterior parietal association cortex of the monkey: command functions for operations within extrapersonal space. J Neurophysiol 38: 871–908
Nauta WJH (1971) The problem of the frontal lobe: a reinterpretation. J Psychiat Res 8: 167–187
Neilson I (1982) An alternative explanation of the infant's difficulty in the stage III, IV, and V object-concept tasks. Perception 11: 577–588
Niki H (1974) Differential activity of prefrontal units during right and left delayed response trials. Brain Res 70: 346–349
Niki H, Watanabe M (1976) Prefrontal unit activity and delayed response: relation to cue location versus direction of response. Brain Res 105: 78–88
Piaget J (1952) The origins of intelligence in children. Basic Books, New York, Original French edition, 1936
Piaget J (1954) The construction of reality in the child. Basic Books, New York, Original French edition, 1937
Pinsker HM, French GM (1967) Indirect delayed reactions under various testing conditions in normal and midlateral frontal monkeys. Neuropsychologia 5: 13–24
Pohl W (1973) Dissociation of spatial discrimination deficits following frontal and parietal lesions in monkeys. J Comp Physiol Psychol 82: 227–239
Rovee-Collier C (1986) The rise and fall of infant classical conditioning research: its promise for the study of early development. In: Lipsitt LP, Rovee-Collier C (eds) Advances in infancy research, Vol 4. Ablex, Norwood NJ, pp 139–159
Schacter DL, Moscovitch M, Tulving E, McLachlan DR, Freedman M (1986) Mnemonic precedence in amnesic patients: an analogue of the AB error in infants? Child Dev 57: 816–823
Schuberth RE (1982) The infant's search for objects: alternatives to Piaget's theory of object concept development. In: Lipsitt LP, Rovee-Collier CK (eds) Advances in infancy Research, Vol 2. Ablex, Norwood NJ, PP 137–182
Squire LR, Zola-Morgan S (1983) The neurobiology of memory: the case for correspondence between the findings for human and non-human primates. In: Deutsch JA (ed) The physiological basis of memory. Academic Press, New York
Ungerleider LG, Brody BA (1977) Extrapersonal spatial orientation: the role of posterior parietal, anterior frontal, and inferotemporal cortex. Exp Neurol 56: 263–280
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Diamond, A., Goldman-Rakic, P.S. Comparison of human infants and rhesus monkeys on Piaget's AB task: evidence for dependence on dorsolateral prefrontal cortex. Exp Brain Res 74, 24–40 (1989). https://doi.org/10.1007/BF00248277
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DOI: https://doi.org/10.1007/BF00248277