Gaze shifts evoked by electrical stimulation of the superior colliculus inthe head-unrestrained cat. I. Effect of the locus and of the parameters ofthe stimulation

Several studies have suggested that the pattern of neuronal activity in the superior colliculus (SC) interacts with the well-known topographical codin g of saccades (motor map). To further describe this interaction, we recorde d gaze saccades evoked by electrical microstimulation of SC deeper layers i n the head-unrestrained cat and systematically varied the collicular locus (25 sites) and parameters (intensity, frequency) of the stimulation. Long s timulation trains were used to avoid saccade truncation. We found that the direction and amplitude of evoked gaze shifts were related to the stimulati on locus, describing a gaze shift map. For 18 out of 20 sites the amplitude , but not the direction, also strongly depended on stimulation strength. In deed, gaze amplitude continuously increased when raising current intensity up to several times the threshold value T (the largest intensity tested was 6 x T), whereas varying pulse frequency from 150 to 750 pulses per second (p.p.s.) revealed an optimal frequency range (300 and 500 p.p.s.) eliciting the largest gaze shifts. Moreover, the intensity effect on amplitude incre ased in an orderly fashion with the rostro-caudal stimulation locus. Gaze s hift amplitude was not related to the number of delivered stimulation pulse s. Concerning movement initiation, increasing either intensity or frequency led to an exponential decrease in gaze latency until minimal values near 3 0 ms were reached, but the number of pulses delivered during the correspond ing latency period remained constant within a 300-500 p.p.s. frequency rang e. These findings indicate that the pattern of collicular discharge evoked by electrical stimulation strongly interacts with the gaze shift map and pr ovide evidence for a summation of collicular activities by downstream premo tor neurons.