Interdependence of Spatial Properties and Projection Patterns of Medial Vestibulospinal Tract Neurons in the Cat

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Interdependence of Spatial Properties and Projection Patterns of Medial Vestibulospinal Tract Neurons in the Cat

S. I. Perlmutter, Y. Iwamoto, J. F. Baker, and B. W. Peterson

Department of Physiology, Northwestern University School of Medicine, Chicago, Illinois 60611

Perlmutter, S. I., Y. Iwamoto, J. F. Baker, and B. W. Peterson. Interdependence of spatial properties and projectionpatterns of medial vestibulospinal tract neurons in the cat. J.Neurophysiol. 79: 270-284, 1998. Activity of vestibular nucleusneurons with axons in the ipsi- or contralateral medial vestibulospinaltract was studied in decerebrate cats during sinusoidal, whole-bodyrotations in many planes in three-dimensional space. Antidromicactivation of axon collaterals distinguished between neurons projectingonly to neck segments from those with collaterals to C₆ and/oroculomotor nucleus. Secondary neurons were identified by monosynapticactivation after labyrinth stimulation. A three-dimensional maximumactivation direction vector (MAD) summarized the spatial propertiesof 151 of 169 neurons. The majority of secondary neurons (71%)terminated above the C₆ segment. Of these, 43% had ascending collateralsto the oculomotor nucleus (VOC neurons), and 57% did not (VC neurons).The majority of VOC and VC neurons projected contralaterally andipsilaterally, respectively. Most C₆-projecting neurons couldnot be activated from oculomotor nucleus (V-C₆ neurons) and projectedprimarily ipsilaterally. All VO-C₆ neurons projected contralaterally.The distributions of MADs for secondary neurons with differentprojection patterns were different. Most VOC (84%) and contralaterallyprojecting VC (91%) neurons had MADs close to the activation vectorof a semicircular canal pair, compared with 54% of ipsilaterallyprojecting VC (i-VC) and 39% of V-C₆ neurons. Many i-VC (44%)and V-C₆ (48%) neurons had responses suggesting convergent inputfrom horizontal and vertical canal pairs. Horizontal and verticalgains were comparable for some, making it difficult to assigna primary canal input. MADs consistent with vertical-verticalcanal pair convergence were less common. Type II yaw or type IIroll responses were seen for 22% of the i-VC neurons, 68% of theV-C₆ neurons, and no VOC cells. VO-C₆ neurons had spatial propertiesbetween those of VOC and V-C₆ neurons. These results suggest thatsecondary VOC neurons convey semicircular canal pair signals toboth ocular and neck motor centers, perhaps linking eye and headmovements. Secondary VC and V-C₆ neurons carry more processedsignals, possibly to drive neck and forelimb reflexes more selectively.Two groups of secondary i-VC neurons exhibited vertical-horizontalcanal convergence similar to that present on neck muscles. Thevertical-vertical canal convergence present on many neck muscles,however, was not present on medial vestibulospinal neurons. Spatialtransformations achieved by the vestibulocollic reflex may occurin part on secondary neurons but further combination of canalsignals must take place to generate compensatory muscle activity.

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