Notes: Summary The present experiments were designed to characterize the discharge patterns of single cortical neurones within the cutaneous representation of the hand in postcentral cortex (areas 3b and 1) in awake monkeys during the performance of an active tactile discrimination task. The task consisted of making a single scanning movement over a surface (first half smooth; second half smooth or rough); the texture encountered over the second half of the surface was indicated by the animal, respectively, pushing or pulling a lever. Unitary discharge was recorded from 118 cells receiving input from the hand or distal forearm of two monkeys. Units with cutaneous fields on the digit tips in contact with the surfaces to be discriminated showed an increase in discharge (58%), a decrease in discharge (11%) or no change (31%) during the task. Units with cutaneous fields not in contact with the discriminanda were much more likely to show decreased discharge during the task (25%), suggesting that there is some selection of cutaneous inputs in this task. Cutaneous units in areas 3b and 1 were equally likely to signal differences in texture (respectively, 18% and 26% of those with digital receptive fields (RFs)) and most of the texture-related units (78%) had a large RF, spanning several digits. The discharge patterns of single texture-related cells did not reliably signal whether or not the animal successfully discriminated the surfaces: unitary responses were occasionally absent even though the animal correctly identified the surface or they were present when an incorrect response was made. This observation suggested that information derived from a population of cells is required for the performance of the task, since no single cell's discharge contained sufficient information upon which the animal could base its behavioural response. A group of cells with digital RFs (24% of area 3b cells and 15 % of area 1 units) were classified as movement-related. Their discharge signalled precisely the onset and/or end of movement, and they were generally insensitive to the texture of the surfaces scanned. Such cells may serve as an independent source of information for primary somatosensory cortex related to the physical parameters of movement. Most cells with digital RFs were more responsive during active tactile discrimination than during passive movement of the digits over the surfaces (monkey no longer required to discriminate the surface texture). For area 3b units, peripheral factors (RF orientation, speed of movement) were likely responsible for this observation. For area 1 units, the situation was more complex: 26% of the area 1 units were only active during the active behavioural task, suggesting that such units may signal peripheral events, but in a context-dependent manner. This may be related to attention, although other factors were not ruled out in the present experiments. Finally, the depth of modulation in the task was almost always less than that produced by classical RF testing, suggesting that the tactile inputs generated during exploratory movements are subject to gating controls, as has been shown for other types of movements.

Notes: Summary The discharge patterns of 144 single cortical neurones, within the cutaneous representation of the hand in area 2 (primary somatosensory cortex, SI), were studied in two rhesus monkeys during the performance of an active tactile discrimination task. These were compared to those previously described for units within areas 3b and 1 recorded from the same animals. The task consisted of making a single scanning movement of the digit tips over a surface (first half smooth; second half either smooth or rough). The nature of the texture encountered over the second half of the surface was indicated by the monkey making a differential lever response (push or pull) with the opposite hand. During the task, area 2 units with cutaneous receptive fields (RFs) on the digit tips of interest (those scanned over the surfaces) generally showed an increase in their discharge (75%); patterns of decreased discharge or no modulation (respectively, 12 and 13%) were rarely observed. Units with digital cutaneous RFs not in contact with the stimuli were much more likely to show either a pattern of decreased discharge or no modulation whatsoever (47% in each case), suggesting that there is some selection of cutaneous inputs in this task in that non-active inputs are selectively gated. For units with a cutaneous RF, the sign of modulation changed significantly across SI, in a manner consistent with a pattern of increased convergence onto the more caudal regions of SI. Overall, the proportions of area 2 units with digital RFs on the tips of interest that were classified as either texturerelated (25%) or movement-related (26%) were similar to those reported previously for areas 3b and 1, suggesting that their presumed roles in, respectively, the analysis of surface texture and the representation of the physical parameters of movement are shared and distributed across the three cytoarchitectonic subdivisions of SI under consideration. In addition, the discharge patterns of single texture-related cells in areas 3b, 1 and 2 did not reliably signal whether or not the animal successfully discriminated the surfaces, suggesting that information from a population of cells is required for the performance of the task. Texture-related responses in area 2 were, however, unique in two ways. Firstly, 35% of the texture-related units had additional discharges related to the performance of the scanning movement (texture- and movement-related cells); no such units were found in area 3b, and only one was encountered in area 1. Secondly, the texture-related responses of a subgroup of area 2 units (25%) varied as a function of the order of presentation of the surfaces. As response time also varied with the order of presentation, it is suggested that such cells might represent an intermediate step in the transformation of the sensory input to a behavioural response. Although most units with digital RFs were more responsive during active tactile discrimination than during passive movements of the digits over the same surfaces, secondary factors (speed of movement) were often responsible for this observation. In this aspect, area 2 discharge properties seemed closer to those previously described for area 3b than to those described for area 1. In contrast to both areas 3b and 1, however, the extent of modulation in the task of one-third of the units with larger multi-digit RFs was similar to that produced by classical RF testing, instead of being less (as found for areas 3b and 1). The latter observation suggests that some tactile inputs from the digit tips of interest are transmitted to area 2 relatively unchanged during exploratory movements, and that gating controls in this task of active tactile discrimination may be directed more towards cutaneous inputs to areas 3b and 1 than to area 2.

Notes: Abstract We investigated the accuracy of sequential saccadic eye movements, executed without visual feedback. We found evidence that the final error of one saccade is corrected during the next, which supports the existence of extraretinal inputs to the saccadic generator. The corrections, however, were incomplete, which suggests that extraretinal signals are only partially effective.