Advanced search
Publication Cover
IETE Journal of Research Volume 49, 2003 - Issue 2-3: Cognitive Science
Submit an article Journal homepage
8
Views
1
CrossRef citations to date
0
Altmetric
Original Articles

Plasticity in Auditory Cortex after Receptor Damage: Excitatory and Inhibitory Processes

R RajanDepartment of Physiology, Monash University, Monash, VIC3800, Australia email: [email protected]View further author information
Pages 157-170 | Published online: 26 Mar 2015

REFERENCES

  • Rasmusson DD, Reorganization of raccoon somatosensory cortex following removal of the Fifth digit, Journal Comp Neurol, vol 205, pp 313–326, 1982.
  • Merzenich MM, Kaas JH, Wall JT, Sur M, Nelson RJ & Felleman DJ, Topographic reorganisation of somatosensory cortical areas 3B and 1 in adult monkeys following restricted deafferentation, Neuroscience, pp 833–55, 1983.
  • Merzenich MM, Nelson RJ, Stryker MP, Cynader MS, Schoppman A & Zook JM, Somatosensory cortical map changes following digit amputation in adult monkeys, Journal Comp Neurol, vol 224, pp 591–605, 1984.
  • Kelehan AM & Doetsch GS, Time-dependent changes in the functional organization of somatosensory cerebral cortex following digit amputations in adult raccoons, Somatosens Res, vol 2, pp 49–81, 1984.
  • Calford MB & Tweedale R, Immediate and chronic changes in responses of somatosensory cortex in adult flying-fox after digit amputation. Nature, vol 332, pp 446–448, 1988.
  • Robertson D & Irvine DRF, Plasticity of frequency organization in auditory cortex of guinea pigs with partial unilateral deafness, Journal Comp Neurol, vol 282, pp 456–471, 1989.
  • Kaas JH, Krubitzer LA, Chino YM, Langton AL, Polley EH & Blair N, Reorganisation of retinotopic cortical maps in adult mammals after lesions of the retina, Science, vol 248, pp 229–231, 1990.
  • Heinen SJ & Skavenski AA, Recovery of visual responses in foveal VI neurons following bilateral foveal lesions in adult monkey, Exp Brain Res, vol 83, pp 670–674, 1991.
  • Pons TP, Garraghty PE, Ommaya AK, Kaas JH, Taub E & Mishkin M, Massive cortical reorganization after sensory deafferentation in adult macaques, Science, vol 252, pp 1857–1860, 1991.
  • Chino YM, Kaas JH, Smith EL III, Langton AL & Cheng H, Rapid reorganisation of cortical maps in adult cats following restricted deafferentation in retina, Vision Res, vol 32, pp 789–796, 1992.
  • Gilbert CD & Weisel TN, Receptive field dynamics in adult primary visual cortex, Nature, vol 356, pp 150–152, 1992.
  • Rajan R, Irvine DRF, Wise LZ & Heil P, Effect of unilateral partial cochlear lesions in adult cats on the representation of lesioned and unlesioned cochleas in primary auditory cortex. Journal Comp Neurol, vol 338, pp 17–49, 1993.
  • Schwaber MK, Garraghty PE & Kaas JH, Neuroplasticity of the adult primate auditory cortex following cochlear hearing loss, Am Journal Otology, vol 14, pp 252–258, 1993.
  • Darian-Smith C & Gilbert CD, Topographic reorganisation in the striate cortex of the adult cat and monkey is cortically mediated, Journal Neurosci, vol 15, pp 1631–1647, 1995.
  • Schmid LM, Rosa MG, Calford MB & Ambler JS, Visuotopic reorganisation in the primary visual cortex of adult cats following monocular and binocular retinal lesions, Cerebral Cortex, vol 6, pp 388–405, 1996.
  • M M Merzenich, P L Knight and G L Roth, Representation of cochlea within primary auditory cortex of the cat, Journal Neurophysiol, 38, 231–249, 1975.
  • Reale RA & Imig TJ, Tonotopic organization in auditory cortex of the cat, Journal Comp Neurol, vol 192, pp 265–291, 1980.
  • Kiang NY-S, Watanabe T, Thomas EC & Clark LF, Discharge patterns of single fibers in the cat's auditory nerve, Cambridge, Mass, MIT Press, 1965.
  • Liberman MC, The cochlear frequency map for the cat: labelling auditory-nerve fibers of known chcracteristic frequency, Journal Acoust Soc Am, vol 72, pp 1441–1449, 1982.
  • Rajan R & Irvine DRF, Neuronal responses across cortical field Al in plasticity induced by peripheral auditory damage, Audiology & Neuro-Otology, vol 3, pp 123–144, 1998a.
  • Rajan R, Receptor organ damage causes loss of cortical surround inhibition without topographic map plasticity, Nature Neurosci, vol 1, pp 138–143, 1998.
  • Rajan R & Irvine DRF, Absence of plasticity of the frequency map in dorsal cochlear nucleus of adult cats after unilateral partial cochlear lesions. Journal Comp Neurol, vol 399, pp 35–46, 1998.
  • Kaltenbach JA, Meleca RJ & Falzarano PR, Alterations in the tonotopic map of the cochlear nucleus following cochlear damage, In Salvi RJ, Henderson, D, Fiorino F, and Colletti V (eds): Auditory System Plasticity and Regeneration. New York, Thieme Medical Publishers, pp 317–332, 1996.
  • DRF Irvine, R Rajan & M Brown, Injury- and use-related plasticity in auditory cortex, Audiology & Neuro-Otology, vol 6, pp 192–195, 2001.
  • R L Snyder and D G Sinex, Immediate changes in tuning of inferior colliculus neurons following acute lesions of cat spiral ganglion, Journal Neurophysiol, vol 87, pp 434–452, 2002.
  • Snyder RL, Sinex DG, McGee AD & Walsh EW, Acute spiral ganglion lesions change the tuning andf tonotopic organization of cat inferior colliculus neurons, Hearing Res, vol 147, pp 200–220, 2000.
  • Calford MB & Tweedale R, Acute changes in cutaneous receptive fields in primary somatosensory cortex after digit denervation in adult flying fox, Journal Neurophysiol, vol 65, pp 178–187, 1991.
  • M B Calford, R Rajan & D R F Irvine, Rapid changes in the frequency tuning of neurons in cat auditory cortex resulting from pure-tone-induced temporary threshold shift, Neuroscience, vol 55, pp 953–964, 1993.
  • D V Buonomano & M M Merzenich, Cortical plasticity: from synapses to maps, Annu Rev Neurosci, vol 21, pp 149–186, 1998.
  • Faggin BM, Nguyen KT & Nicoleiis MAL, Immediate and simultaneous sensory reorganization at cortical and subcortical levels of the somatosensory system, Proc Natl Acad Sci USA, vol 94, pp 9428–9433, 1997.
  • Hendry SHC & Jones EG, Reduction in number of immunostained GABAergic neurones in deprived-eye dominance columns of monkey area 17, Nature, vol 320, pp 750–753, 1986.
  • Hendry SHC & Kennedy MB, Immunoreactivity for a calmodulin-dependent protein kinase is selectively increased in macaque striate cortex after monocular deprivation, Proc Natl Acad Sci USA, vol 83, pp 1536–1540, 1986.
  • Ribak CE & Robertson RT, Effects of neonatal mococular enucleation on the number of GAD-positive puncta in rat visual cortex, Exp Brain Res, vol 62, pp 203–206, 1986.
  • Warren R, Tremblay N & Dykes RW, Quantitative study of glutamic acid decarboxylase-immunoreactive neurones and cytochrome oxidase activity in normal and partially deafferented rat hindlimb somatosensory cortex. Journal Comp Neurol, vol 288, pp 583–592, 1989.
  • Welker E, Soriano E & van der Loos H, Plasticity in the barrel cortex of the adult mouse: effects of peripheral deprivation on GAD-immunoreactivity, Exp Brain Res, vol 74, pp 441–452, 1989.
  • Akhtar ND & Land PW, Activity-dependent regulation of glutamic acid decarboxylase in the rat barrel cortex: effects of neonatal versus adult sensory deprivation. Journal Comp Neurol, vol 307, pp 200–213, 1991.
  • Garraghty PE, LaChica EA & Kaas JH, Injury-induced reorganization of somatosensory cortex is accompanied by reductions in GABA staining, Somatosens and Motor Res, vol 8. pp 347–354, 1991.
  • Hendry SHC, Fuchs J, de Blas AL & Jones EG, Distribution and plasticity of immunocytochemically localized GABAA reccptors in adult monkey visual cortex, Journal Neurosci, vol 10, pp 2438–2450, 1990.
  • Rausell E. Cusick CG, Taub E & Jones EG, Chronic deafferentation in monkeys differentially affects nociceptive and nonnociceptive pathways distinguished by specific calcium-binding proteins and down-regulates λ-aminobutyric acid type A receptors at thalamic levels. Proc Natl Acad Sci USA, vol 89, pp 2571–2575, 1992.
  • Skangiel-Kramska J. Glazewski S, Jablonska B, Siucinska E & Kossut M, Reduction of GABAA receptor binding of [3H] muscimol in the barrel field of mice after peripheral denervation: transient and long-lasting effects, Exp Brain Res, vol 100, pp 39–46, 1994.
  • Rosier AM, Arckens L, Demeulemeester H, Orban GA, Eysel UT, Wu Y-J & Vandesande F, Effect of sensory deafferentation on immunorcactivity of GABAergic cells and on GABA receptors in the adult cat visual cortex. Journal Comp Neurol, vol 359, pp 476–489, 1995.
  • K D Mieheva & L Beaulieu, An anatomical substrate for experience-dependent plasticity of the rat barrel field cortex. Proc Natl Acad Sci USA, vol 92, pp 11834–11838, 1995.
  • D'Amelio F, Fox RA, Wu LC & Daunton NG, Quantitative changes of GABA-immunoreactive cells in the hindlimb representation of the rat somatosensory cortex after 14-day hindlimb unloading by tail suspension, Journal Neurosci Res, vol 44, pp 532–539, 1996.
  • Kyriazi HT, Carvell GE, Brumberg JC & Simons DJ, Quantitaive effects of GABA and bicuculline methiodide on receptive field properties of neurons in real and simulated whisker barrels, Journal Neurophysiol, vol 75. pp 547–560, 1996.
  • Jacobs KM & Donoghue JP, Reshaping the cortical motor map by unmasking latent intracortical connections. Science, vol 251, pp 944–947, 1991.
  • Jones EG, GABAergic neurons and their role in cortical plasticity in primates, Cerebral Cortex, vol 3, pp 361–372, 1993.
  • Ralston HJ III, Ohara PT, Meng XW, Wells J & Ralston DD, Transneuronal changes of the inhibitory circuitry in the macaque somatosensory thalamus following lesions of the dorsal column nuclei, Journal Comp Neurol, vol 371, pp 325–335, 1996.
  • S E Laskin & W A Spencer, Cutaneous masking II. Geometry of excitatory and inhibitory receptive fields of single units in somatosensory cortex of the cat, Journal Neurophysiol, vol 42, pp 1061–1082, 1979.
  • Janig W, Schoultz T & Spencer WA, Temporal and spatial parameters of excitation and afferent inhibition in cuneothalamic relay neurons, Journal Neurophysiol, vol 40, pp 822–835, 1977.
  • Janig W, Spencer WA & Younkin SG, Spatial and temporal features of afferent inhibition in thalamocortical relay cell, Journal Neurophysiol, vol 42, pp 1450–1460, 1979.
  • Martin MR & Dickson JW, Lateral inhibition in the anteroventral cochlear nucleus of the cat: A microiontophoretic study. Hearing Res, vol 9, pp 35–41, 1983.
  • Dykes RW, Landry P. Metherate R & Hicks TP, Functional role of GABA in cat primary somatosensory cortex: shaping receptive fields of cortical neurons. Journal Neurophysiol, 52, vol pp 1066–1093, 1984.
  • Muller CM & Scheich H, Contribution of GABAergic inhibition to the response characteristics of auditory units in the avian forebrain. Journal Neurophysiol, vol 59. pp 1673–1689, 1988.
  • Ramoa AS, Paradiso MA & Freeman RD, Blockade of intracortical inhibition in kitten striate cortex: effects on receptive field properties and associated loss of ocular dominance plasticity, Exp Brain Res, vol 73, pp 285–296. 1988.
  • Alloway KD, Rosenthal P & Burton H, Quantitative measurements of receptive field changes during antagonism of GABAergic transmission in primary somatosensory cortex of cats, Exp Brain Res, vol 78, pp 514–532, 1989.
  • Alloway KD & Burton H, Bicuculline-induced alterations in neuronal responses to controlled tactile stimuli in the second somatosensory cortex of the cat: a microiontophoretic study, Somatosens Res, vol 3, pp 195–211, 1986.
  • Alloway KD & Burton H Differential effects of GABA and bicuculline on rapidly-and slowly-adapting neurons in primary somatosensory cortex of primates, Exp Brain Res. vol 85, pp 598–610, 1991.
  • Kaneko TP & Hicks TP, GABAB-related activity involved in synaptic processing of somatosensory information in S1 cortex of the anaesthetized cat, Br Journal Pharmacol, vol 100, pp 689–698, 1990.
  • Oka J-I & Hicks TP, Benzodiazepines and synaptic processing in the spatial domain within the cat's primary somatosensory cortex, Canadian Journal Physiol Pharmacol, vol 68, pp 1025–1040, 1990.
  • Caspary DM, Backoff PM, Finlayson PG & Palombi PS, Inhibitory inputs modulate discharge rate within frequency receptive fields of anteroventral cochlear nucleus neurons. Journal Neurophysiol, vol 72, vol 2124–2133, 1991.
  • PS Palombi & D M Caspary, GABA inputs control discharge rate primarily within frequency receptive fields of inferior colliculus neurons, Journal Neurophysiol, vol 75, pp 2211–2219, 1996.
  • Vater M, Habbicht H, Kössi M & Grothe B, The functional role of GABA and glycine in monaural and binaural processing in the inferior colliculus of horseshoe bats, Journal Comp Physiol, vol A 171, pp 541–553, 1992.
  • Yang L, Pollak GD & Resler C, GABAergic circuits sharpen tuning curves and modify response properties in the mustache bat inferior colliculus, Journal Neurophysiol, vol 68, pp 1760–1774, 1992.
  • Suga N & Manabe T, Neural basis of amplitude-spectrum representation in auditory cortex of the mustached bat, Journal Neurophysiol, vol 53, pp 1109–1145, 1982.
  • Müller CM & Scheich H, GABAergic inhibition increases the neuronal selectivity to natural sounds in the avian auditory forebrain, Brain Res, vol 41, pp 376–380, 1987.
  • Calford MB & Semple MN, Monaural inhibition in cat auditory cortex. Journal Neurophysiol, vol 73, pp 1876–1891, 1995.
  • Brosch M & Schreiner CE, Time course of forward masking tuning curves in cat primary auditory cortex, Journal Neurophysiol, vol 77, pp 923–943, 1997.
  • Horikawa J, Hosokawa Y. Kubota M, Nasu M & Taniguchi I, Optical imaging of spatiotemporal patterns of glutamatergic excitation and GABAergic inhibition in the guinea pig auditory cortex in vivo, Journal Physiol, vol 497, pp 629–638, 1996.
  • Rajan R, Auditory response areas altered by intermodulation distortion products from background tones, Neuroreport, vol 8, pp 3177–3182, 1997.
  • Pearson JC, Finkel LH & Edelman GM, Plasticity in the organization of adult cerebral cortical maps: A computer simulation based on neuronal group selection, Journal Neurosci, vol 7, pp 4209–4223, 1987.
  • Jenison RL, A computational model of reorganization in auditory cortex in response to cochlear lesions, In: Modelling Sensorineural Hearing Loss, Jesteadt W, editor, pp 49–65, Mahwah, New Jersey: Lawrence Erlbaum Associates Publishers, 1997.
  • Rajan R, Plasticity of excitation and inhibition in the receptive field of primary auditory cortical neurons after limited receptor organ damage. Cerebral Cortex, vol 11, pp 171–182, 2001.
  • Kilgard MP, Pandya PK, Vazquezx JL, Rathbun DL, Engineer ND & Moucha R, Spectral features control temporal plasticity in auditory cortex. Audiology & Neuro- Otology, vol 6, pp 196–202, 2001.
  • Rodieck RW, Quantitative analysis of cat retinal ganglion cell response to visual stimuli. Vision Res, vol 5, pp 583–601, 1965.
  • Enroth-Cugell C & Robson JG, The contrast sensitivity of retinal ganglion cells, Journal Physiol, vol 187, pp 517–522, 1966.
  • Hammond P, Contrasts in spatial organization of receptive fields at geniculate and retinal levels: centre, surround and outer surround, Journal Physiol, vol 228, pp 115–137, 1973.
  • Hickey TL, Winters RW & Pollack JG, Centre-surround interactions in two types of on-centre retinal ganaglion cells in the cat, Vision Res, vol 13, pp 1511–1526, 1973.
  • Dawis S, Shapley R, Kaplan E & Tranchina D, The receptive field organization of X-cells in the cat: spatiotemporal coupling and asymmetry, Vision Res, vol 24, pp 549–564, 1984.
  • Hawken MJ & Parker AJ, Spatial properties of neurons in the monkey striate cortex, Proc Roy Soc, London B, vol 231, pp 251–288, 1987.
  • Chapman B & Stone LS, Turning a blind eye to cortical receptive fields, Neuron, vol 16, pp 9–12, 1996.
  • Parker AJ & Hawken MJ, Two-dimensional spatial structure of receptive fields in monkey striate cortex. Journal Opt Soc Am, vol 5, pp 598–605, 1988.
  • Shamma SA, Speech processing in the auditory system II: Lateral inihibition and the central processing of speech evoked activity in the auditory nerve, Journal Acoust Soc Am, vol 78, pp 1622–1632, 1985.
  • Volkov IO & Galazjuk AV, Formation of spike response to sound tones in cat auditory cortex neurons: interaction of excitatory and inhibitory effects, Neurosci, vol 43, pp 307–321, 1991.
  • Cai D, DeAngelis GC & Freeman RD, Spatiotemporal receptive field organization in the lateral geniculate nucleus of cats and kittens, Journal Neurophysiol, vol 78. pp 1045–1061, 1997.
  • Sanes JN, Suner S & Donoghue JP (1990) Dynamic organization of primary motor cortex output to target muscles in adult rats, I, Long-term patterns of reorganization following motor or mixed peripheral nerve lesions, Exp Brain Res, vol 79, pp 479–491, 1990.
  • Pettet MW & Gilbert CD, Dynamic changes in receptive-field size in cat primary visual cortex, Proc Natl Acad Sci USA, vol 89, pp 8366–8370, 1992.
  • Rajan R, Irvine DRF & Cassell JF, Normative N1 audiogram data for the barbiturate-anaesthetised domestic cat, Hearing Res, vol 53, pp 153–158, 1991.

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.