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01.06.2010

Representation of Movement Velocity in the Rat's Interpositus Nucleus During Passive Forelimb Movements

verfasst von: Maria Stella Valle, Gianfranco Bosco, Antonino Casabona, Angelo Garifoli, Valentina Perciavalle, Marinella Coco, Vincenzo Perciavalle

Erschienen in: The Cerebellum | Ausgabe 2/2010

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Abstract

The interpositus nucleus (IN) receives a large amount of sensory information from the limbs and, in turn, elaborates signals for movement control. In this paper, we tried to gather evidence on the possibility that neurons in the IN may elaborate sensory representations of the forelimb kinematics and, particularly, of the movement velocity vector. For this purpose, the forepaw of anesthetized rats was attached to a computer-controlled robot arm displaced passively along two types of trajectories (circular and figure eight), with the limb joints unconstrained. The firing activity of single cells was recorded and related to limb position and the two components of the movement velocity vector, namely, movement speed and direction. By using multiple regression analysis, we found that 12 out of 85 (14%) neurons were modulated by position, 18 out of 85 (21%) neurons were modulated by direction, 24 out of 85 (28%) neurons were modulated by movement speed, and 31 out of 85 (37%) neurons were sensitive to the full movement velocity vector. Most of the neurons modulated only by the speed component of the velocity vector (19 out of 24) were located in the posterior portion of the IN, whereas neurons in the anterior portion were mostly related to both components of the velocity vector. These results suggest that sensory information related to whole-limb movement velocity may be encoded by the IN, indicating also that the posterior interpositus may preferentially represent movement speed.

Giaquinta G, Valle MS, Caserta C, Casabona A, Bosco G, Perciavalle V (2000) Sensory representation of passive movement kinematics by rat's spinocerebellar Purkinje cells. Neurosci Lett 285:41–44CrossRefPubMed

Bosco G, Giaquinta G, Valle MS, Caserta C, Casabona A, Perciavalle V (2000) Distribution of spinocerebellar Purkinje cell responses to passive forelimb movements in the rat. Eur J NeuroSci 12:4063–4073CrossRefPubMed

Valle MS, Bosco G, Poppele R (2000) Information processing in the spinocerebellar system. NeuroReport 11:4075–4079CrossRefPubMed

Valle MS, Eian J, Bosco G, Poppele RE (2008) Cerebellar cortical activity in the cat anterior lobe during hindlimb stepping. Exp Brain Res 187:359–372CrossRefPubMed

Giaquinta G, Casabona A, Valle MS, Bosco G, Perciavalle V (1999) On the relation of rat's external cuneate activity to global parameters of forelimb posture. NeuroReport 10:3075–3080PubMedCrossRef

Garifoli A, Caserta C, Bosco G, Lombardo SA, Casabona A, Perciavalle V (2002) Kinematic features of passive forelimb movements and rat cuneate neuron discharges. NeuroReport 13:267–271CrossRefPubMed

Bosco G, Poppele RE (2002) Encoding of hindlimb kinematics by spinocerebellar circuitry. Arch Ital Biol 140:185–192PubMed

Thach WT (1968) Discharge of Purkinje and cerebellar nuclear neurons during rapidly alternating arm movements in the monkey. J Neurophysiol 31:785–797PubMed

Burton JE, Onoda N (1977) Interpositus neuron discharge in relation to a voluntary movement. Brain Res 121:167–172CrossRefPubMed

10.

Harvey RJ, Porter R, Rawson JA (1979) Discharges of intracerebellar nuclear cells in monkeys. J Physiol 297:559–580PubMed

11.

Miall RC, Weir DJ, Stein JF (1987) Visuo-motor tracking during reversible inactivation of the cerebellum. Exp Brain Res 65:455–464CrossRefPubMed

12.

MacKay WA (1988) Unit activity in the cerebellar nuclei related to arm reaching movements. Brain Res 442:240–254CrossRefPubMed

13.

van Kan PL, Houk JC, Gibson AR (1993) Output organization of intermediate cerebellum of the monkey. J Neurophysiol 69:57–73PubMed

14.

van Kan PL, Horn KM, Gibson AR (1994) The importance of hand use to discharge of interpositus neurones of the monkey. J Physiol 480:171–190PubMed

15.

Gibson AR, Horn KM, Stein JF, Van Kan PL (1996) Activity of interpositus neurons during a visually guided reach. Can J Physiol Pharmacol 74:499–512CrossRefPubMed

16.

Milak MS, Shimansky Y, Bracha V, Bloedel JR (1997) Effects of inactivating individual cerebellar nuclei on the performance and retention of an operantly conditioned forelimb movement. J Neurophysiol 78:939–959PubMed

17.

Mason CR, Miller LE, Baker JF, Houk JC (1998) Organization of reaching and grasping movements in the primate cerebellar nuclei as revealed by focal muscimol inactivations. J Neurophysiol 79:537–554PubMed

18.

Martin JH, Cooper SE, Hacking A, Ghez C (2000) Differential effects of deep cerebellar nuclei inactivation on reaching and adaptive control. J Neurophysiol 83:1886–1899PubMed

19.

Cooper SE, Martin JH, Ghez C (2000) Effects of inactivation of the anterior interpositus nucleus on the kinematic and dynamic control of multijoint movement. J Neurophysiol 84:1988–2000PubMed

20.

Monzee J, Smith AM (2004) Responses of cerebellar interpositus neurons to predictable perturbations applied to an object held in a precision grip. J Neurophysiol 91:1230–1239CrossRefPubMed

21.

Monzee J, Drew T, Smith AM (2004) Effects of muscimol inactivation of the cerebellar nuclei on precision grip. J Neurophysiol 91(3):1240–1249CrossRefPubMed

22.

Burton JE, Onoda N (1978) Dependence of the activity of interpositus and red nucleus neurons on sensory input data generated by movement. Brain Res 152:41–63CrossRefPubMed

23.

Soechting JF, Burton JE, Onoda N (1978) Relationships between sensory input, motor output and unit activity in interpositus and red nuclei during intentional movement. Brain Res 152:65–79CrossRefPubMed

24.

Cody FW, Moore RB, Richardson HC (1981) Patterns of activity evoked in cerebellar interpositus nuclear neurones by natural somatosensory stimuli in awake cats. J Physiol 317:1–20PubMed

25.

Casabona A, Valle MS, Bosco G, Perciavalle V (2008) Comparison of neuronal activities of external cuneate nucleus, spinocerebellar cortex and interpositus nucleus during passive movements of the rat's forelimb. Neuroscience 157:271–279CrossRefPubMed

26.

Casabona A, Valle MS, Bosco G, Garifoli A, Lombardo SA, Perciavalle V (2003) Anisotropic representation of forelimb position in the cerebellar cortex and nucleus interpositus of the rat. Brain Res 972:127–136CrossRefPubMed

27.

Casabona A, Valle MS, Bosco G, Perciavalle V (2004) Cerebellar encoding of limb position. Cerebellum 3:172–177CrossRefPubMed

28.

Paxinos G, Watson C (1998) The rat brain in stereotaxic coordinates. Academic, San Diego

29.

Bosco G, Poppele RE (1999) Low sensitivity of dorsal spinocerebellar neurons to limb movement speed. Exp Brain Res 125:313–322CrossRefPubMed

30.

MacKay WA, Murphy JT (1974) Responses of interpositus neurons to passive muscle stretch. J Neurophysiol 37:1410–1423PubMed

31.

Kawaguchi S, Ono T (1974) Responses of interpositus neurones to inputs from muscle receptors. Exp Brain Res 21:375–386CrossRefPubMed

32.

Eccles JC, Rosen I, Scheid P, Taborikova H (1972) Cutaneous afferent responses in interpositus neurones of the cat. Brain Res 42:207–211CrossRefPubMed

33.

Armstrong DM, Cogdell B, Harvey R (1975) Effects of afferent volleys from the limbs on the discharge patterns of interpositus neurones in cats anaesthetized with alpha-chloralose. J Physiol 248:489–517PubMed

34.

Rowland NC, Jaeger D (2005) Coding of tactile response properties in the rat deep cerebellar nuclei. J Neurophysiol 94:1236–1251CrossRefPubMed

35.

Armstrong DM, Edgley SA (1988) Discharges of interpositus and Purkinje cells of the cat cerebellum during locomotion under different conditions. J Physiol 400:425–445PubMed

36.

Holdefer RN, Houk JC, Miller LE (2005) Movement-related discharge in the cerebellar nuclei persists after local injections of GABA(A) antagonists. J Neurophysiol 93:35–43CrossRefPubMed

37.

Eccles JC, Ito M, Szentagothai J (1967) Cerebellum as a neuronal machine. Springer, New York

38.

Thach WT (1970) Discharge of cerebellar neurons related to two maintained postures and two prompt movements. II. Purkinje cell output and input. J Neurophysiol 33:537–547PubMed

39.

Houk JC, Keifer J, Barto AG (1993) Distributed motor commands in the limb premotor network. Trends Neurosci 16:27–33CrossRefPubMed

40.

Thach WT (1978) Correlation of neural discharge with pattern and force of muscular activity, joint position, and direction of intended next movement in motor cortex and cerebellum. J Neurophysiol 41:654–676PubMed

41.

Thach WT, Perry JG, Kane SA, Goodkin HP (1993) Cerebellar nuclei: rapid alternating movement, motor somatotopy, and a mechanism for the control of muscle synergy. Rev Neurol (Paris) 149:607–628

42.

Gellman R, Houk JC, Gibson AR (1983) Somatosensory properties of the inferior olive of the cat. J Comp Neurol 215:228–243CrossRefPubMed

43.

Gellman R, Gibson AR, Houk JC (1985) Inferior olivary neurons in the awake cat: detection of contact and passive body displacement. J Neurophysiol 54:40–60PubMed

44.

Apps R, Hartell N (1995) Gating of spino-olivocerebellar pathways in the awake cat. In: Taylor A, Gladden MH, Durbaba R (eds) Alpha and gamma motor systems. Plenum, New York, pp 403–405

45.

Apps R, Atkins MJ, Garwicz M (1997) Gating of cutaneous input to cerebellar climbing fibres during a reaching task in the cat. J Physiol 502:203–214CrossRefPubMed

Titel: Representation of Movement Velocity in the Rat's Interpositus Nucleus During Passive Forelimb Movements
verfasst von: Maria Stella Valle
Gianfranco Bosco
Antonino Casabona
Angelo Garifoli
Valentina Perciavalle
Marinella Coco
Vincenzo Perciavalle
Publikationsdatum: 01.06.2010
Verlag: Springer-Verlag
Erschienen in: The Cerebellum / Ausgabe 2/2010
Print ISSN: 1473-4222
Elektronische ISSN: 1473-4230
DOI: https://doi.org/10.1007/s12311-010-0160-2

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