Advanced search
Publication Cover
British Journal of Neurosurgery Volume 4, 1990 - Issue 4
Submit an article Journal homepage
46
Views
32
CrossRef citations to date
0
Altmetric
Review Article

Plasticity in the adult and neonatal central nervous system

Adrian J. Bower Department of Anatomy, University of Queensland, Australia
Pages 253-264 | Published online: 06 Jul 2009

References

  • Kohler I. Experiments with goggles. Scient Am 1962; 206: 62–86
  • Melville-Jones G. Plasticity in the adult vestibulo-ocular reflex arc. Phil Trans R SOC Lond Ser B 1974; 278: 319–34
  • Paige G D. Vestibuloocular reflex and its interaction with visual-following mechanisms in the Squirrel monkey. II Response characteristics and plasticity following unilateral inactivation of the horizontal canal. J Neurophysiol 1983; 49: 152–68
  • Baarsma E A, Collewiln H. Vestibulo-oculo and optokinetic reactions to rotation and their interaction in the rabbit. J Physiol (Lond) 1974; 238: 603–25
  • Maioli C, Precht W, Reid S. Short and long term modification of vestibuloocular response dynamics following unilateral vestibular nerve lesions in the cat. Exp Brain Rrs 1983; 59: 259–74
  • Hart C W, McKinley P A, Peterson B W. Compensation following acute unilateral total loss of peripheral vestibular function. The Vestibular System, M Graham, in press
  • Fetter M, Zee D S, Procter L R. Effect of lack of vision and of occipital lobectomy upon recovery from unilateral labyrinthectomy in rhesus monkey. J Neurophysiol 1988; 59: 394–407
  • Alkon D. Calcium mediated reduction of ionic currents: A biophysical memory trace. Science 1984; 226: 1037–45
  • Baudry M. Mechanisms of synaptic plasticity in mammalian brain: implications for theories of learning and memory. Neural Plasticity: A Lifespan Approach. Neurology and Neurobiology, T L Petit, G O Ivy. Alan R Liss, New York 1988; Vol 36: 125–142
  • Kandel E R, Schwartz J H. Molecular biology of learning: modulation of transmitter release. Science 1982; 218: 433–43
  • Nelson R B, Routtenberg A, Hyman C, Pfenninger K H. A phosphoprotein (F1) directly related to neural plasticity in adult brain may be identical to a major growth cone membrane protein. Neurosci Abs 1985; 11: 269
  • Routtenberg A. Protein kinase C activation leading to protein F1 phosphorylation may regulate synaptic plasticity by presy-naptic terminal growth. Behav Neural Biol 1985; 44: 186–200
  • Dunn A J. Neurochemistry of learning and memory: an evaluation of recent data. Ann Rev Psych 1980; 31: 343–90
  • Petit T L, Markus E J. The cellular basis of learning and memory. The anatomical sequel to neuronal use. Neuroplasticity, Learning and Memory, N W Milgram, C M MacLeod, T L Petit. Alan R Liss, New York 1987; 87–124
  • Vrensen G, Cardozo Nunes J. Changes in size and shape of synaptic connections after visual training: An ultrastructural approach to synaptic plasticity. Brain Res 1981; 218: 79–97
  • Scott B S, Becker L E, Petit T L. Neurnbiology of Down's syndrome. Prog Neurobiol 1983; 21: 199–237
  • Petit T L. Developmental effects of lead: Its mechanism in intellectual functioning and neural plasticity. Neurotoxicol 1986; 7: 481–94
  • Bailey C H, Chen M. Morphological basis of long term habituation and sensitization in Aplysia. Science 1983; 220: 91–3
  • Fwster A P. Spontaneous regeneration of cut axons in the adult rat brain. J Comp Neurol 1982; 210: 335–56
  • Woods B T, Teuber H-L. Changing patterns of childhood aphasia. Ann Neurol 1979; 3: 273–80
  • Post-Lesion Neurol Plasticity, H Flohr. Springer-Verlag, Berlin 1988
  • Goldberger M E. Altered kinetic patterns and synapse recovery of motor behaviour after hindlimb deafferentation in cats. Post-Lesion Neural Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 249–58
  • Wall P D. The presence of ineffective synapses and the circumstances which unmask them. Phil Trans R Sac land Ser B 1977; 278: 361–72
  • Calford M B, Tweedale R. Immediate and chronic changes in responses of somatosensory cortex in adult flying foxes after digit amputation. Nature 1988; 332: 446–8
  • van der Loos H, Welker E. Development and plasticity of somatosensory brain maps. Development, Organisation and Processing in Somatosensory Pathways, M Rowe, W D Willis. Alan R Liss, New York 1985; 53–67
  • Wall J T, Felleman D J, Kaas J H. Recovery of normal topography in the somatosensory cortex of nionkeys after nerve crush and regeneration. Science 1983; 221: 771–3
  • Wall J T, Kaas J H, Felleman D J. Functional recovery in the somatosensory cortex of monkeys with regenerated nerves: replication versus integration. Development, Organisation and Processing in Somatosensory Pathways, M Rowe, W D Willis. Alan R Liss, New York 1985; 277–87
  • Menenich M M, Nelson R J, Stryker M P, Cynader M S, Schoppmann A, Zook J M. Somatosensory cortical map changes following digit amputation in adult monkeys. J Comp Neurol 1984; 224: 591–605
  • Pons T P, Garraghty P E, Mishkin M. Plasticity in nonprimary somatosensory cortex of adult monkeys. Post Lesion Neurol Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 511–18
  • Meyers D E R, Snow P J. Somatotopically inappropriate projections of single hair follicle afferent fibres to the cat spinal cord. J Physiol (Lond) 1984; 347: 59–73
  • Wilson P, Meyers D E R, Snow P J. Changes of spinal circuitry in response to alterations of input: an evaluation of the development and basis of contemporary theories. Effects of Injury on Trigeminal and Spinal Somatosensory Systems, L M Pubols, B J Sessle. Alan R Liss, New York 1987; 227–38
  • Snow P J, Nudo R J, Rivers W, Jenkins W M, Merzenich M M. Somatotopically inappropriate projections from thalamocorti-cal neurons to the S1 cortex of the cat demonstrated by the use of intracortical microstimulation. Somatosens Res 1988; 5: 349–70
  • Oppenheim R W. Neuronal cell death and some related regressive phenomena during neurogenesis: a selective historical review and progress report. Studies in Developmental Neurobiology, Essays in Honour of Victor Hamburger, W M Cowan. Oxford University Press, Oxford 1981; 74–133
  • Hollyday M, Hamburger V. Reduction of naturally occurring motor neuron loss by enlargement of the periphery. J Comp Neurol 1976; 170: 311–20
  • Cowan W M, Fawcett J W, Oleary D D M, Stanfield B B. Regressive events in neurogenesis. Science 1984; 225: 1258–65
  • Cragg B G. The density of synapses and neurons in normal, mentally defective and aging human brains. Brain 1975; 98: 81–90
  • Terry R D. Interrelations among the lesions of normal and abnormal aging of the brain. Aging of the brain and Alzeheimer's disease. Progress in Neurobrology, D F Swaab, E Fliers, M Mirmmiran, W A Van Gool, F Van Haaren, 1986; Vol 70: 41–48
  • Terry R D, Deteresa R, Hansen L A. Neocortical cell counts in normal human adult aging. Annals Neurology 1987; 21: 530–539
  • West M J, Gunderson H J G. Unbiased stereological estimation of the number of neurons in the human hippocampus. J Comp Neurol 1990; 296: 1–22
  • Rakic P. Guidance of neurons migrating to the fetal monkey cortex. Brain Res 1971; 33: 471–6
  • Altman J, Bayer S. Development of the precerebellar nuclei in the rat II. The intramural olivary migratory stream and the neurogenic organisation of the inferior olive. J Comp Neurol 1987; 257: 490–512
  • Innocenti G M, Camintini R. Postnatal shaping of collosal connections from sensory areas. Exp Brain Res 1980; 38: 381–94
  • Innocenti G M, Clarke S. Multiple sets of visual cortical neurons projecting transitorily through the corpus callosum. Neurosci Letts 1983; 41: 23–32
  • Stanfield B B, O'Leary D D M. The transient corticospinal projection from the occipital cortex during the postnatal development of the rat. J Comp Neurol 1985; 238: 236–48
  • O'Leary D D M, Stanfield B B. A transient pyramidal tract projection from the visual cortex in the hamster and its removal by selective collateral elimination. Dev Brain Res 1986; 27: 37–90
  • Sherrard R M, Bower A J. An ipsilateral olivocerebellar connection: an autoradiographic study in the unilaterally pedunculo-tomised neonatal rat. Exp Brain Res 1986; 61: 355–63
  • Bower A J, Payne J N. An ipsilateral olivocerebellar pathway in the normal neonatal rat demonstrated by the retrograde transport of TNe blue. Neurosci Letts 1987; 78: 138–44
  • Tolbert D L, Pannerton W M. Transient cerebrocerebellar projections in kittens: Postnatal development and topography. J Comp Neurol 1983; 212: 216–28
  • Innocenti G M. Transitory structures as substrate for development plasticity of the brain. Recovery from Brain Damage, M W Van Hof, J Mohn. Elsevier, Amsterdam 1982; 305–33
  • Tolbert D L, Pannenon W M. The transience of cerebrocerebellar projections is due to selectwe elimination of axon collaterals and not neuronal death. Dev Brain Res 1984; 16: 301–6
  • Stanfield B B, O'Leary D D M, Fricks C. Selective collateral elimination in early postnatal development restricts cortical distribution of pyramidal tract neurons. Nature 1982; 298: 372–3
  • Hubel D H, Weisel T N, LeVay S. Plasticity of ocular dominance columns in monkey striate cortex. Phil Trans R Soc Lond Ser B 1977; 278: 377–409
  • Hubel D H, Weisel T N. The period of susceptibility to the physiological effects of unilateral eye closure in kittens. J Physiol (Lond) 1977; 206: 419–36
  • Stryker M P, Sherk H. Modification of cortical orientation selectivity in the cat by restricted visual experience: a re-examination. Science 1975; 190: 904–5
  • Bower A J, Waddington G. A simple operative technique for the severence of the cerebellar peduncles of neonatal rats. J Neurosci Meths 1981; 4: 181–6
  • Angaut P, Alvarado-Mallart R M, Sotelo C. Compensatory climbing fibre innervation after unilateral pedunculotomy in the newborn rat: origin and topographic organisation. J Comp Neurol 1984; 236: 161–78
  • Sherrard R M, Bower A J, Payne J. lnnervatlon of the adult rat cerebellar hemisphere by fibres from the ipsilateral olive following unilateral neonatal pedunculotomy: an autoradiographic and retrograde fluorescent double labelling study. Exp Brain Res 1986; 62: 411–21
  • Voogd J, Gerrits N M, Marani E. Cerebellum. The Rat Nervous System, G Paxinos. Academic Press, London 1985; Vol 2: 251–91
  • Leong S K. Plasticity of cerebellar efferents after neonatal lesions in the albino rat. Neurosci Lett 1978; 7: 281–9
  • Levine S C, Hutenlocher P R, Banich M T, Duda E. Factors affecting cognitive functioning in hemiplegic children. Dev Med Child Neurol 1987; 29: 27–35
  • Hicks S P, D'Amato J C. Motor-sensory and visual behaviour after hemispherectomy in newborn and mature rats. Exp Neurol 1970; 29: 416–38
  • Sharp F R, Evans K L. Bilateral C14 2-deoxyglucose uptake by motor pathways after unilateral neocortical lesions in the rat. Dev Brain Res 1983; 6: 1–11
  • Naus C G, Flummerfelt B A, Hrycyshyn A W. Topographical specificity of abherent cerebellorubral projections following hemicerebellectomy in the rat. Brain Res 1984; 309: 1–15
  • Gramsbergen A, Ijkema-Paarson J. CNS plasticity after hemiscerebellectomy in the young rat. Quantitative relations between aberrent and normal cerebello-rubral projections. Neurosci Lett 1982; 33: 129–34
  • Gramsbergen A, Ijkema-Paarsn J. Do early lesions affect cell death in the central nervous system? A study on the effects of early cerebellar hemispherectomy in rats. J Comp Neurol 1987; 255: 617–24
  • Huttenlocher P R, Raichelson R. Post-lesion neural plasticity in cerebral cortex: The response of rat sensorimotor cortex to neonatal ablation of the opposite hemisphere. Post-Lesion Neural Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 165–72
  • Shieh J Y, Leong S K, Wong W C. An electron microscope study of the corticorubral fibres after neonatal deep cerebellar lesions in albino rats. Brain Res 1986; 335: 201–6
  • Castro A J, Mihailoff G A. Corticopontine remodelling after cortical and/or cerebellar lesions in new born rats. J Comp Neurol 1983; 219: 112–23
  • Kasamatsu T, Pettigrew J D. Depletion of brain catecholamines: failure of ocular dominance shift after monocular deprivation. Science 1976; 194: 206–9
  • Bear M F, Singer W. Modulation of visual cortical plasticity by acetylcholine and noradrenaline. Nature, 320: 172–6
  • Bijlsma W A, Jennekens F G I, Schotman P, Gispen W H. Neurotrophic factors and regeneration in the peripheral nervous system. Psychoneuroendocrinology 1984; 9199–215
  • Dekker A J A M, Princen M M, de Nijs H, Leede L G J, Broekkamp C L E. Acceleration of recovery from sciatic nerve damage by the ACTH (4–9) ANALOG Org. 2766; different routes of administration. Peptides 1987; 8: 1057–9
  • Edwards P M, van der Zee C EEM, Verhaagen J, Schotman P, Jennekens F G I, Gispen W H. Evidence that the neurotrophic actions of a-MSH may derive from its ability to mimic the actions of a peptide formed in degenerating nerve stumps. J Neurol Sci 1984; 64: 333–40
  • de Koning P, Gispen W H. Org 2766 improves functional and electrophysiological aspects of regeneration sciatic nerve in the rat. Peptides 1987; 8: 415–22
  • Igarishi M, Lshii M, Ishikawa K, Himi T. Comparative effects of some neurotropic agents on balance compensation after unilateral and bilateral (two-staged) labyrinthectomy in Squirrel monkeys. Post-Lesion Neurol Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 627–34
  • Lsaacson R L, Poplawsky A. ACTH 4–9 analog (Org 2766) speeds recovery from septal hyperemotionalality in the rat. Behav Neurol Biol 1983; 39: 52–9
  • Hannigan J H, Isaacson R L. The effects of Org 2766 on the performance of sham, neocortical, and hippocampal-lesioned rats in a food search task. Pharmacol Biochem Behav 1985; 23: 1019–27
  • Nyacas C, Veldhis H D, de Wied D. Beneficial effect of chronic treatment with Org 2766 and a-MSH on impaired reversal learning of rats with bilateral lesions of the parafacicular area. Brain Res Bull 1985; 15257–65
  • Richter-Landsberg C, Bruns I, Flohr H. ACTH (4–10) and ACTH (1–24) influence neurite outgrowth and neural development of fetal rat cerebral cultures. Post-Lesion Neural Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 614–26
  • Selye H. Stress in Health and Disease. Butterworth, London 1976
  • Scheff S W, Cotman C W. Chronic glucocorticoid therapy alters axonal sprouting in the hippocampal dentate gyrus. Exp Neurol 1982; 76: 644–54
  • Bohn M C, Goldstein M, Black I B. Expression and development of phenyethanol amine N-methyl transferase (PNMT) in rat brain stem; Studies with glucocorticoids. Dev Biol 1986; 114: 180–93
  • Gorio A. Ganglioside enhancement of neuronal differentiation, plasticity and repair. Clin Neurobiol 1986; 2: 241–96
  • Obata K, Oide M, Handa S. Effects of glycolipids on in vitro development of neuromuscular junction. Nature 1977; 266: 369–71
  • Katoh-Semba R, Skaper S D, Varon S. Interaction of GMI gangliosides with PC12 pheochromocytoma cells: serum and NGF dependent effects on neurite growth (and proliferation). Neurosci Res 1984; 12: 299–310
  • Toffano G, Agnati L F, Fuxe K, Aldino C, Consolazione A, Valenti G, Savoini G. Effect of GM1 ganglioside treatment on recovery of dopaminergic nigro-striatal neurons after different types of lesion. Acra Physiol Scand 1984; B122: 313–21
  • Consolazione A, Aldino C, Cavicchioli L, Leon A, Toffano G. Gangliosides as a tool for studying the repair of adult mammalian brain after injury. Model Systems of Development and Aging in the Nervous System, A Vernadakis. Martinus Nijhoff, The Hague 1987; 443–452
  • Vaccarino F, Guidotti A, Costa E. Sphingoglycolipid inhibition of glutamate-mediated protein kinase C translocation and activation. PNAS 1987; 84: 8707–11
  • Fusco M, Dona M, Tessari F, Hallman H, Jonsson G, Gorio A. GMI ganglioside counteracts selective neurotoxin-induced lesion of the developing serotonin neurons in rat spinal cord. J Neurosci Res 1986; 15: 467–79
  • Tanaka K, Dora E, Urbanics R, Greenberg J H, Toffano G, Reivich M. Effect of the ganglioside GM1 on cerebral metabolism, microcirculation, recovery of kinetics of ECoG and histology, during recovery period following focal ischaemia in rats. Stroke 1986; b17: 1170–8
  • Karpiak S E, Li Y S, Mahadik S P. Gangliosides (GM1 and AGF2) reduce mortality due to ischaemia: protection of membrane function. Stroke 1987; 18: 184–7
  • Greenberg J H, Komatsumoto S, Dara E, Tanaka K, Hiwkey W, Toffano G, Reivich M. The effects of GMI in focal ischaemia in the cat. J Cereb Blood Flow Metab 1987; 7: S180
  • Aldinio C, Seren S, Lazzaro A. Ischaemia-induced neuronal cell injury: effects of the inner ester derivative of GMI ganglioside. Soc Neurosci 17th annual meeting Abs 418.9. 1987
  • Consolazione A, Vantini G, Seren S, Toffano G, Leon A. Role of gangliosides in functional recovery of damaged nervous system. Post-Lesion Neuronal Plasticity, H Flohr. Springer-Verlag, Berlin 1988; 655–60

Reprints and Corporate Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

To request a reprint or corporate permissions for this article, please click on the relevant link below:

Order Reprints Request Corporate Permissions

Academic Permissions

Please note: Selecting permissions does not provide access to the full text of the article, please see our help page How do I view content?

Obtain permissions instantly via Rightslink by clicking on the button below:

Request Academic Permissions

If you are unable to obtain permissions via Rightslink, please complete and submit this Permissions form. For more information, please visit our Permissions help page.

Related research

People also read lists articles that other readers of this article have read.

Recommended articles lists articles that we recommend and is powered by our AI driven recommendation engine.

Cited by lists all citing articles based on Crossref citations.
Articles with the Crossref icon will open in a new tab.