Summary
The topographic organization of the climbing fiber (CF) responses was mapped in the rostral vermal cortex (lobules III, IV, and Va) of the cerebellum. Extracellular, single-unit recordings were obtained from 699 Purkinje cells in cats anesthetized with sodium pentobarbitol. Approximately 72% of the CF responses were elicited by low-threshold or deep tactile stimulation, whereas the remaining units were unresponsive to any peripheral stimulation. On the basis of response characteristics, the vermal cortex was separated into an approximately 1-mm-wide medial zone and a 1 to 1.5-mm-wide lateral zone. The medial zone contained many unresponsive cells, except along the midline, where about 35% of the CF responses were elicited by deep stimulation at the base of the tail. The majority (78%) of the CF responses within the lateral vermal cortex represented various areas of the hindpaw, although representations of the forepaw (8%), tail (4%), and chin (0.6%), as well as unresponsive units (10%), were evident. The lateral vermal cortex contained a mediolateral topography of different receptive fields, although the topography was not sharply defined or equally displayed in all animals. The medial part of the lateral zone contained a representation of the ipsilateral forelimb in lobules IV and Va; the middle part had a representation of the medial or the lateral half of the hindpaw; and the lateral portion of the zone had an extensive representation of the distal hindpaw. The CF responses with similar receptive fields were often found in patches, which in some areas were arranged in layers from the inner to the outer areas of the sublobules. A particular body surface may be represented in multiple patches and in different lobules. Activation of the majority of CF responses within a sublobule may occur only during selected behaviors.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Andersson G, Eriksson L (1981) Spinal, trigeminal, and cortical climbing fibre paths to the lateral vermis of the cerebellar anterior lobe in the cat. Exp Brain Res 41: 71–81
Andersson G, Oscarsson O (1978) Climbing fiber microzones in cerebellar vermis and their projection to different groups of cells in the lateral vestibular nucleus. Exp Brain Res 32: 565–579
Armstrong DM, Harvey RJ, Schild RF (1974) Topographical localization in the olivo-cerebellar projection: An electrophysiological study in the cat. J Comp Neurol 154: 287–302
Bloedal JR (1973) Cerebellar afferent systems: A review. In: Progress in Neurobiology, 2(1). Pergamon Press, Oxford, England, pp 1–68
Brodal A, Kawamura K (1980) Olivocerebellar projection: A review. Adv Anat Embryol Cell Biol 64: 1–140
Courville J, Faraco-Cantin F (1980) Topography of olivocerebellar projection: An experimental study in cat with autoradiographic tracing method. In: Courville J, de Montigny C, Lamarre Y (eds) The inferior olivary nucleus: Anatomy and physiology. Raven Press, New York, pp 235–277
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: 195–215
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, Táboříková H (1972b) Integration by Purkinje cells of mossy and climbing fiber inputs from cutaneous mechanoreceptors. Exp Brain Res 15: 498–520
Gellman R, Houk JC, Gibson AR (1983) Somatosensory properties of the inferior olive of the cat. J Comp Neurol 215: 228–243
Ghez C, Fahn S (1981) The cerebellum. In: Kandel ER, Schwartz JH (eds) Principles of neural science. Elsevier, New York, pp 334–346
Gilman S, Bloedal JR, Lechtenberg R (1981) Disorders of the Cerebellum. F.A. Davis Co., Philadelphia, pp 53–70
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
Kitai ST, Táboříková H, Tsukahara N, Eccles JC (1969) The distribution to the cerebellar anterior lobe of the climbing and mossy fiber inputs from the plantar and palmar cutaneous afferents. Exp Brain Res 7: 1–10
Larsell O, Jansen J (1970) The comparative anatomy and histology of the cerebellum from monotremes through apes. University of Minnesota Press, Minneapolis
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, Schmidt RF (1977) Somatotopic studies on the vermal cortex of the cerebellar anterior lobe of unanesthetized cats. Exp Brain Res 27: 479–490
Levin S, Pearsall G, Ruderman RJ (1978) Von Frey's method of measuring pressure sensibility in the hand: An engineering analysis of the Weinstein-Semmes pressure aesthesiometer. J Hand Surg 3: 211–216
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. American Medical Association, Chicago, pp 525–537
Oscarsson O (1980) Functional organization of olivary projection to the cerebellar anterior lobe. In: Courville J, de Montigny C, Larmarre 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, Laxer KD (1981) Localization of cutaneously elicited climbing fiber response in lobule V of the monkey cerebellum. Brain Behav Evol 18: 157–168
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
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, Gibson JM, Welker W (1978) Fractured somatotopy in granule cell tactile areas of rat cerebellar hemispheres revealed by micromapping. Brain Behav Evol 15: 94–140
Snider RS (1950) Recent contributions to the anatomy and physiology of the cerebellum. Arch Neurol Psychiat 64: 196–219
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 (1969) The importance of fiber connections in the comparative anatomy of the mammalian cerebellum. In: Llinás R (ed) Neurobiology of cerebellar evolution and development. American Medical Association, Chicago, pp 493–514
Voogd J, Bigare F (1980) Topographical distribution of olivary and cortico nuclear fibers in the cerebellum: A review. In: Courville J, de Montigny 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. Topographic features of climbing fiber input in the rostral vermal cortex of the cat cerebellum. Exp Brain Res 55, 445–454 (1984). https://doi.org/10.1007/BF00235275
Received:
Issue Date:
DOI: https://doi.org/10.1007/BF00235275