Summary
The fine grain organization of the climbing fiber (CF) representation for the intermediate cortex of lobules III, IV, and Va was examined. Data were obtained from cats anesthetized with sodium pentobarbital. Through extracellular recording techniques, CF responses were identified in 814 Purkinje cells; 74% were elicited by mechanical stimulation of various body surfaces. Of the CF responses elicited by stimulation, 60% involved the ipsilateral hindlimb, 36% represented parts of the forelimb, and only 4% represented areas of the face, tail, or abdomen. Hindlimb representation predominated in lobules III and IV, and forelimb representation was mainly confined to lobule Va. No distinct parasagittal zones that involved all three lobules were identified. In general, the organization for most sublobules could be best described as a mixture of patches of forelimb or hindlimb representations. Within the patches there was considerable diversity of receptive field types, particularly for the extremities. The receptive fields involving the distal phalanges were generally smaller than those for the proximal areas, but a range in field sizes was evident for both distal and proximal regions. More than half of either the forelimb or the hindlimb representation was limited to the distal paw areas; the two middle toes received the most frequent representation. Representations of the proximal limb areas were generally centered around either the wrist or the heel, or around the elbow or knee, but many of these receptive fields also extended to the phalanges. The multiple representation of various areas of forelimb and hindlimb throughout the rostral intermediate cortex was consistent with the type of organization that had been identified in other regions of the anterior lobe, although each cortical area contained a unique proportional CF representation of various body areas.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Adrian ED (1943) Afferent areas in the cerebellum connected with the limbs. Brain 66: 289–315
Bloedel JR, Courville J (1981) A review of cerebellar afferent systems. In: Brooks VB (ed) Handbook of physiology. Am Physiol Soc, Bethesda, MD, pp 735–829
Bloedel JR, Roberts WJ (1969) Functional relationship among neurons of the cerebellar cortex in the absence of anesthesia. J Neurophysiol 32: 75–84
Brodal A, Kawamura K (1980) Olivocerebellar projection: a review. Springer, New York
Chan-Palay V, Palay SL, Brown JT (1977) Sagittal organization of the olivocerebellar and reticulocerebellar projections: autoradiographic studies with 35S-Methionine. Exp Brain Res 30: 561–576
Eccles JC, Faber DS, Murphy JT, Sabah NH, Táboříková H (1971) Afferent volleys in limb nerves influencing impulse discharges in cerebellar cortex. II: Purkinje cells. Exp Brain Res 13: 54–77
Eccles JC, Provini L, Strata P, Táboříková H (1968) Topographical investigations on the climbing fiber inputs from forelimb and hindlimb afferents to the cerebellar anterior lobe. Exp Brain Res 6: 196–215
Eccles JC, Sabah NH, Schmidt RF, Táboříková H (1972a) Cutaneous mechanoreceptors influencing impulse discharges in cerebellar cortex. III. In: Purkyne cells by climbing fiber input. Exp Brain Res 15: 484–497
Eccles JC, Sabah NH, Schmidt RF, Taborikova H (1972b) Integration by Purkinje cells of mossy and climbing fiber inputs from cutaneous mechanoreceptors. Exp Brain Res 15: 498–520
Ekerot CF, Larson B (1979a) The dorsal spino-olivocerebellar system in the cat. I. Functional organization and termination in the anterior lobe. Exp Brain Res 36: 201–217
Ekerot CF, Larson B (1979b) The dorsal spino-olivocerebellar system in the cat. II. Somatotopical organization. Exp Brain Res 36: 218–232
Ekerot CF, Larson B (1980) Termination in overlapping sagittal zones in the cerebellar anterior lobe of mossy and climbing fiber paths activated from dorsal funiculus. Exp Brain Res 38: 163–171
Gellman R, Houk JC, Gibson AR (1983) Somatosensory properties of the interior olive of the cat. J Comp Neurol 215: 228–243
Groenewegen HJ, Voogd J, Freedman SL (1979) The parasagittal zonation within the olivocerebellar projection. II. Climbing fiber distribution in the intermediate and hemispheric part of cat cerebellum. J Comp Neurol 183: 551–601
Haines DE, Patrick GW, Satrulee P (1982) Organization of cerebellar corticonuclear fiber system. In: Palay SL, Chan-Palay V (eds), The cerebellum —new vistas. Springer, Berlin Heidelberg New York, pp 320–367
Hiss E, Leicht R, Schmidt RF (1977) Cutaneous receptive fields of cerebellar Purkinje cells of unanesthetized cats. Exp Brain Res 27: 319–333
Ito M (1984) The cerebellum and neural control. Raven Press, New York
Joseph JW, Shambes GM, Gibson JM, Welker W (1978) Tactile projections to granule cells in caudal vermis of the rat's cerebellum. Brain Behav Evol 15: 141–149
Kassel J, Shambes GM, Welker W (1984) Fractured cutaneous projections to the granule cell layer of the posterior cerebellar hemisphere of the domestic cat. J Comp Neurol 225: 458–468
Künzle H (1975) Autoradiographic tracing of the cerebellar projections from the lateral reticular nucleus in the cat. Exp Brain Res 22: 255–266
Leicht R, Rowe MJ, Schmidt RF (1973) Cutaneous convergence onto the climbing fiber input to cerebellar Purkinje cells. J Physiol (Lond) 228: 601–618
Leicht R, Rowe MJ, Schmidt RF (1977) Mossy and climbing inputs from cutaneous mechanoreceptors to cerebellar Purkinje cells in unanesthetized cats. Exp Brain Res 27: 459–477
McCollum G, Robertson LT (1984) Information conveyed by the tactile receptive fields of climbing fibers. Soc Neurosci Abst 10: 538
Molinari HM (1984) Ascending somatosensory projections to the dorsal accessory olive: an anatomical study in cats. J Comp Neurol 223: 110–123
Molinari HM (1985) Ascending somatosensory projections to the medial accessory portion of the inferior olive: a retrograde study in cats. J Comp Neurol (in press)
Oscarsson O (1969) The sagittal organization of the cerebellar anterior lobe as revealed by the projection patterns of the climbing fiber system. In: Llinás R (ed) Neurobiology of cerebellar evolution and development. Am Med Assoc, Chicago, pp 525–537
Oscarsson O (1980) Functional organization of olivary projection to the cerebellar anterior lobe. In: Courville JJ, de Montigny C, Lamarre Y (eds), The inferior olivary nucleus: anatomy and physiology. Raven Press, New York, pp 278–289
Oscarsson O, Sjölund B (1977a) The ventral spino-olivocerebellar system in the cat. I. Identification of five paths and their termination in the cerebellar anterior lobe. Exp Brain Res 28: 469–486
Oscarsson O, Sjölund B (1977b) The ventral spino-olivocerebellar system in the cat. III. Functional characteristics of five paths. Exp Brain Res 28: 505–520
Robertson LT (1984a) Topographic features of climbing fiber input in the rostral vermal cortex of the cat cerebellum. Exp Brain Res 55: 445–454
Robertson LT (1984b) Somatic sensory representation by climbing fiber responses in the paramedian lobule of the cat cerebellum. Soc Neurosci Abst 10: 538
Robertson LT, Laxer KD, Rushmer DS (1982) Organization of climbing fiber input from mechanoreceptors to lobule V vermal cortex of the cat. Exp Brain Res 46: 281–291
Robertson LT, Schrank E (1981) Climbing fiber input from mechanoreceptors to lobule VI of the cat cerebellum. Soc Neurosci Abst 7: 641
Rushmer DS, Roberts WJ, Augter G (1976) Climbing fiber responses of cerebellar Purkinje cells to passive movement of the cat forepaw. Brain Res 106: 1–20
Rushmer DS, Woollacott MH, Robertson LT, Laxer KD (1980) Somatotopic organization of climbing fiber projections from low threshold cutaneous afferents to pars intermedia of cerebellar cortex in the cat. Brain Res 181: 17–30
Shambes GM, Beermann DH, Welker WI (1978a) Multiple tactile areas in the cerebellar cortex: another patchy cutaneous projection to granule cell columns in the rat. Brain Res 156: 123–128
Shambes GM, Gibson JM, Welker WI (1978b) Fractured somatotopy in granule cell tactile areas of rat cerebellar hemispheres revealed by micromapping. Brain Behav Evol 15: 94–140
Snider RS, Stowell AA (1944) Receiving areas of tactile, auditory and visual systems in the cerebellum. J Neurophysiol 7: 331–357
Thach WT (1967) Somatosensory receptive fields of single units in cat cerebellar cortex. J Neurophysiol 30: 675–696
Voogd J, Bigaré F (1980) Topographical distribution of olivary and cortico nuclear fibers in the cerebellum: a review. In: Courville J, deMontigny C, Lamarre Y (eds) The inferior olivary nucleus: anatomy and physiology. Raven Press, New York, pp 207–234
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Robertson, L.T. Somatosensory representation of the climbing fiber system in the rostral intermediate cerebellum. Exp Brain Res 61, 73–86 (1985). https://doi.org/10.1007/BF00235622
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00235622