Segregation of Nociceptive and Non-Nociceptive Networks in the Squirrel Monkey Somatosensory Thalamus

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Segregation of Nociceptive and Non-Nociceptive Networks in the Squirrel Monkey Somatosensory Thalamus

A. Vania Apkarian,¹ Ting Shi,¹ Johannes Brüggemann,¹ and Levon R. Airapetian²

¹Department of Neurosurgery, SUNY Upstate Medical University, Syracuse, New York 13210; and ²Yerevan Physics Institute, Yerevan 375049, Republic of Armenia

Apkarian, A. Vania, Ting Shi, Johannes Brüggemann, and Levon R. Airapetian. Segregation of Nociceptive and Non-Nociceptive Networks in the Squirrel Monkey Somatosensory Thalamus. J. Neurophysiol. 84: 484-494, 2000. The somatosensory thalamus (here we examine neurons in the caudal cutaneous portion of ventral posterior lateral nucleus,VPL) is composed of a somatotopic arrangement of anteroposteriorlyoriented rods. Each rod is a collection of neurons with homogeneousproperties that relay sensory information to specific corticalcolumns. We developed a multi-electrode recording technique, usingfixed-geometry four-tip electrodes that allow simultaneous recordingsfrom small populations of neurons (4-11), in a ~150 × 150 × 150µm³ volume of brain tissue (i.e., the approximate diameter of rods)and study of their spatiotemporal interactions. Due to the fixedgeometry of the four-tip electrodes, the relative locations ofthese neurons can be determined, and due to the simultaneity ofthe recordings, their spike-timing coordination can be calculated.With this method, we demonstrate the existence of two distinctfunctional networks: nociceptive and non-nociceptive networks.The population dynamics of these two types of networks are different:cross-correlations in each type of network were different in directionand strength, were a function of the distance between neurons,had an opponent organization for nociceptive networks and a non-opponentorganization for non-nociceptive networks, and rapidly changedunder different stimulus conditions independent of changes infiring rates. A simple neural network model mimicked these physiologicalfindings, demonstrating the necessity of inhibitory interneuronsand different amounts of afferent input synchronization. Basedon these results, we conclude that the somatosensory thalamusis composed of two modules, nociceptive and non-nociceptive rods,and that the response dynamics differences between these modulesare due to spatiotemporal differences of their afferentinputs.

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