Corticoreticular Pathways in the Cat. I. Projection Patterns and Collaterization

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Corticoreticular Pathways in the Cat. I. Projection Patterns and Collaterization

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. I. Projection patterns and collaterization. J.Neurophysiol. 80: 389-405, 1998. This paper summarizes and comparesthe projection patterns and the receptive fields of cortical neuronsin areas 4 and 6 that project to the pontomedullary reticularformation (PMRF). A total of 326 neurons were recorded in area4 and 129 in area 6 in four awake, unrestrained cats that werechronically implanted with arrays of electrodes in the PMRF andthe pyramidal tract (PT). In area 4, 47% of the neurons projectedto the caudal PT but not to the PMRF (PTNs); 19% were activatedonly from the PMRF [corticoreticular neurons (CRNs)], whereas27% were activated from both the PT and the PMRF (PTN/CRNs). MorePTN/CRNs conducted at velocities >20 m/s (82%) than did CRNs (23%).In area 6, only 19% of the neurons were identified as PTNs, 12%were PTN/CRNs and 31% were CRNs; a further 38% could not be activatedfrom either structure. Collateral branches within the PMRF conductedat maximum velocities of 20 m/s (average = 6.5 m/s). No significantdifferences in the conduction velocities of the collateral brancheswere found either between fast and slow PTNs or between area 4and area 6 neurons. A large proportion of neurons in area 4 (85/173,49%) were activated by passive manipulation of the more distal,contralateral forelimb, with approximately equal numbers beingclassed as PTNs, PTN/CRNs and CRNs. Most neurons in area 6 forwhich a receptive field could be found were excited by lightlytouching or tapping the face and neck; a receptive field couldnot be determined for 39% of the area 6 neurons compared withonly 5% of those in area 4. Finally, there was evidence that neuronsin quite widespread areas of the pericruciate cortex, includingboth areas 4 and 6 projected onto similar, restricted regionsof the PMRF. The fact that the cortical projection from area 4to the PMRF includes a high percentage of fast PTNs with a receptivefield on the distal forelimb is consistent with the view thatthis projection may serve to integrate movement and the dynamicpostural adjustments that accompany them. The fact that the corticalprojection from area 6 to the PMRF is primarily from slow PTNswith receptive fields on the face, neck and back is consistentwith a role for this cortical area in adjusting the general postureof the animal on which movements are superimposed.

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				G. P Siegmund, J T. Inglis, and D. J Sanderson Startle response of human neck muscles sculpted by readiness to perform ballistic head movements J. Physiol., August 15, 2001; 535(1): 289 - 300. [Abstract] [Full Text] [PDF]

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				K. Matsuyama and T. Drew Vestibulospinal and Reticulospinal Neuronal Activity During Locomotion in the Intact Cat. I. Walking on a Level Surface J Neurophysiol, November 1, 2000; 84(5): 2237 - 2256. [Abstract] [Full Text] [PDF]

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				B. Kably and T. Drew Corticoreticular Pathways in the Cat. II. Discharge Activity of Neurons in Area 4 During Voluntary Gait Modifications J Neurophysiol, July 1, 1998; 80(1): 406 - 424. [Abstract] [Full Text] [PDF]