Corticoreticular Pathways in the Cat. II. Discharge Activity of Neurons in Area 4 During Voluntary Gait Modifications

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Corticoreticular Pathways in the Cat. II. Discharge Activity of Neurons in Area 4 During Voluntary Gait Modifications

Bouchra Kably¹ and Trevor Drew²

¹ Centre Hospitalier, Hôpital des Spécialités, Service du Neurophysiologie, BP 6220 Rabat Institute, Morocco; and ² Department of Physiology, University of Montréal, Montreal, Quebec H3C 3J7, Canada

Kably, Bouchra and Trevor Drew. Corticoreticular pathways in the cat. II. Discharge activity of neurons in area 4 duringvoluntary gait modifications. J. Neurophysiol. 80: 406-424, 1998.We propose that the descending command from area 4 that is responsible,in part, for the change in limb trajectory required to step overan obstacle in one's path also plays a role in triggering theanticipatory postural modifications that accompany this movement.To test this hypothesis, we recorded the discharge characteristicsof identified classes of corticofugal neurons in area 4 of thecat. Neurons were identified either as: pryamidal tract neurons(PTNs) if their axon projected to the caudal pyramidal tract (PT)but not to the pontomedullary reticular formation (PMRF); as corticoreticularneurons (CRNs) if their axon projected to the PMRF but not tothe PT; and as PTN/CRNs if their axon projected to both structures.Altogether, the discharge properties of 212 corticofugal neurons(109 PTNs, 66 PTN/CRNs, and 37 CRNs) within area 4 were recordedduring voluntary gait modifications. Neurons in all three classesshowed increases in their discharge frequency during locomotionand included groups that increased their discharge either duringthe swing phase of the modified step, during the subsequent stancephase, or in the stance phase of the cycle preceding the stepover the obstacle. A slightly higher percentage of CRNs (39%)discharged in the stance phase prior to the gait modificationthan did the PTNs or PTN/CRNs (20% and 17% respectively). In 37electrode penetrations, we were able to record clusters of 3 ormore neurons within 500 µm of each other. In most cases, PTN/CRNsrecorded in close proximity to PTNs had similar receptive fieldsand discharged in a similar, but not identical, manner duringthe gait modifications. Compared with adjacent PTNs, CRNs normallyshowed a more variable pattern of activity and frequently dischargedearlier in the step cycle than did the PTNs or PTN/CRNs. We interpretthe results as providing support for the original hypothesis.We suggest that the collateral branches to the PMRF from corticofugalneurons with axons that continue at least as far as the caudalPT provide a signal that could be used to trigger dynamic posturalresponses that are appropriately organized and scaled for themovements that are being undertaken. We suggest that the morevariable and earlier discharge activity observed in CRNs mightbe used to modify the postural support on which the movementsand the dynamic postural adjustments are superimposed.

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