Monkey Superior Colliculus Research Articles

Loss of relative-motion sensitivity in the monkey superior colliculus after lesions of cortical area MT.

Many cells in the superficial layers of the monkey superior colliculus are sensitive to relative motion. The response to a small stimulus moving through a cell's receptive field is strongly modulated by the relative motion between the stimulus and a textured pattern moving through the surrounding visual field; modulation is independent of absolute direction and speed of the stimulus. To determine whether cortical visual area MT is essential for this type of relative-motion sensitivity, colliculus cells were studied in the anesthetized, immobilized preparation after ablation of area MT. Unilateral MT lesions were made by either aspiration, kainic acid injection, or a combination of both methods. Data from the lesioned animals were compared with those from intact animals. Ipsilateral to the lesions, colliculus cells showed an almost total loss of sensitivity to relative motion. This loss was related neither to inadvertent injury of cortical areas neighboring MT nor to incidental optic radiation damage. Two other forms of motion-dependent, center-surround interactions were still present in the colliculus after the cortical lesions. These were a rudimentary sensitivity to differential motion between stimulus and background, which occurs for only one direction of stimulus movement, and a nonselective center-surround suppression, which is induced by movement of a background stimulus in any direction. Visual responsiveness, ocular dominance, and flash-evoked responses were also unaffected by the cortical lesions. We conclude that input from area MT is crucial for relative-motion sensitivity, but not for other response properties, in the superficial layers of the monkey colliculus.

Monkey superior colliculus activity during short-term saccadic adaptation.

This article concerns the neural mechanisms that underlie short-term saccadic adaptation in the rhesus monkey. By means of a consistent intrasaccadic target displacement, the relation between visual input and motor output was gradually changed in three monkeys, such that they made hypometric saccades. During this process, the activity of saccade-related burst neurons in the intermediate and deep layers of the Superior Colliculus (SC) was recorded in two of the monkeys. Our findings show that, like in humans, only saccades evoked within a restricted field around the adaptation target were adapted. However, unlike in humans, the kinematic properties of adapted saccades also changed systematically during the adaptation process. Typically, adapted saccades were slower and had a longer duration than would be expected on the basis of the main sequence for nonadapted visually guided movements. During adaptation, saccade-related activity of units in the SC remained appropriate for the saccade that was required to foveate the initial target, rather than for the saccade that was actually made. This means that adaptation caused a dissociation between SC activity and the ensuing saccade. Thus, the activity of the colliculus was better described in "required eye displacement coordinates" than in "actual eye displacement coordinates." Our data provide further evidence for the hypothesis that short-term saccadic adaptation acts at a level downstream from the SC, presumably at a stage that determines the kinematics of saccadic eye movements.

Functional dissociation within the cerebellum: motor execution and sensori-motor readiness

This paper reports on single-unit activity of saccade-related burst neurons (SRBNs) in the intermediate and deep layers of the monkey superior colliculus (SC), evoked by bimodal sensory stimulation. Monkeys were trained to generate saccadic eye movements towards visual stimuli, in either a unimodal visual saccade task, or in a bimodal visual-auditory task. In the latter task, the monkeys were required to make an accurate saccade towards a visual target, while ignoring an auditory stimulus. The presentation of an auditory stimulus in temporal and spatial proximity of the visual target influenced neither the accuracy nor the kinematic properties of the evoked saccades. However, it had a significant effect on the activity of 90% (45/50) of the SRBNs. The motor-related burst increased significantly in some neurons, but was suppressed in others. In visual-movement cells, comparable bimodal interactions were observed in both the visually evoked burst and the movement-related burst. The large differences observed in the movement-related activity of SRBNs for identical saccades under different sensory conditions do not support the hypothesis that such cells encode dynamic motor error. The only behavioral parameter that was affected by the presentation of the auditory stimulus was saccade latency. Auditory stimulation caused saccade latency changes in the majority of the experiments. Meanwhile, the timing of peak collicular motor activity and saccade onset remained tightly coupled for all stimulus configurations. In addition, saccade latency varied as function of the distance between the stimuli in 36% of the recordings. Interestingly, the occurrence of a spatial latency effect covaried significantly with a similar spatial influence on the SRBNs firing rate. These cells were always most active in the bimodal task when both stimuli were in spatial register, but activity decreased with increasing stimulus separation.

1518 Functional dissociation within the cerebellum: motor execution and sensori-motor readiness

This paper reports on single-unit activity of saccade-related burst neurons (SRBNs) in the intermediate and deep layers of the monkey superior colliculus (SC), evoked by bimodal sensory stimulation. Monkeys were trained to generate saccadic eye movements towards visual stimuli, in either a unimodal visual saccade task, or in a bimodal visual-auditory task. In the latter task, the monkeys were required to make an accurate saccade towards a visual target, while ignoring an auditory stimulus. The presentation of an auditory stimulus in temporal and spatial proximity of the visual target influenced neither the accuracy nor the kinematic properties of the evoked saccades. However, it had a significant effect on the activity of 90% (45/50) of the SRBNs. The motor-related burst increased significantly in some neurons, but was suppressed in others. In visual-movement cells, comparable bimodal interactions were observed in both the visually evoked burst and the movement-related burst. The large differences observed in the movement-related activity of SRBNs for identical saccades under different sensory conditions do not support the hypothesis that such cells encode dynamic motor error. The only behavioral parameter that was affected by the presentation of the auditory stimulus was saccade latency. Auditory stimulation caused saccade latency changes in the majority of the experiments. Meanwhile, the timing of peak collicular motor activity and saccade onset remained tightly coupled for all stimulus configurations. In addition, saccade latency varied as function of the distance between the stimuli in 36% of the recordings. Interestingly, the occurrence of a spatial latency effect covaried significantly with a similar spatial influence on the SRBNs firing rate. These cells were always most active in the bimodal task when both stimuli were in spatial register, but activity decreased with increasing stimulus separation.

Visuomotor and motor type saccade related purkinje cells in the cerebellar hemisphere of the monkey

This paper reports on single-unit activity of saccade-related burst neurons (SRBNs) in the intermediate and deep layers of the monkey superior colliculus (SC), evoked by bimodal sensory stimulation. Monkeys were trained to generate saccadic eye movements towards visual stimuli, in either a unimodal visual saccade task, or in a bimodal visual-auditory task. In the latter task, the monkeys were required to make an accurate saccade towards a visual target, while ignoring an auditory stimulus. The presentation of an auditory stimulus in temporal and spatial proximity of the visual target influenced neither the accuracy nor the kinematic properties of the evoked saccades. However, it had a significant effect on the activity of 90% (45/50) of the SRBNs. The motor-related burst increased significantly in some neurons, but was suppressed in others. In visual-movement cells, comparable bimodal interactions were observed in both the visually evoked burst and the movement-related burst. The large differences observed in the movement-related activity of SRBNs for identical saccades under different sensory conditions do not support the hypothesis that such cells encode dynamic motor error. The only behavioral parameter that was affected by the presentation of the auditory stimulus was saccade latency. Auditory stimulation caused saccade latency changes in the majority of the experiments. Meanwhile, the timing of peak collicular motor activity and saccade onset remained tightly coupled for all stimulus configurations. In addition, saccade latency varied as function of the distance between the stimuli in 36% of the recordings. Interestingly, the occurrence of a spatial latency effect covaried significantly with a similar spatial influence on the SRBNs firing rate. These cells were always most active in the bimodal task when both stimuli were in spatial register, but activity decreased with increasing stimulus separation.

1516 Visuomotor and motor type saccade related purkinje cells in the cerebellar hemisphere of the monkey

This paper reports on single-unit activity of saccade-related burst neurons (SRBNs) in the intermediate and deep layers of the monkey superior colliculus (SC), evoked by bimodal sensory stimulation. Monkeys were trained to generate saccadic eye movements towards visual stimuli, in either a unimodal visual saccade task, or in a bimodal visual-auditory task. In the latter task, the monkeys were required to make an accurate saccade towards a visual target, while ignoring an auditory stimulus. The presentation of an auditory stimulus in temporal and spatial proximity of the visual target influenced neither the accuracy nor the kinematic properties of the evoked saccades. However, it had a significant effect on the activity of 90% (45/50) of the SRBNs. The motor-related burst increased significantly in some neurons, but was suppressed in others. In visual-movement cells, comparable bimodal interactions were observed in both the visually evoked burst and the movement-related burst. The large differences observed in the movement-related activity of SRBNs for identical saccades under different sensory conditions do not support the hypothesis that such cells encode dynamic motor error. The only behavioral parameter that was affected by the presentation of the auditory stimulus was saccade latency. Auditory stimulation caused saccade latency changes in the majority of the experiments. Meanwhile, the timing of peak collicular motor activity and saccade onset remained tightly coupled for all stimulus configurations. In addition, saccade latency varied as function of the distance between the stimuli in 36% of the recordings. Interestingly, the occurrence of a spatial latency effect covaried significantly with a similar spatial influence on the SRBNs firing rate. These cells were always most active in the bimodal task when both stimuli were in spatial register, but activity decreased with increasing stimulus separation.

Shared neural control of attentional shifts and eye movements.

We are able to move visual attention away from the direction of gaze, fixating on one object while attending to something else at a different location, within the region of peripheral vision. It has been widely assumed that the attentional neural systems are separate from the motor systems, but some studies challenge this idea. It has now been suggested that the attentional system is part of the premotor processing in the brain. This model proposes that attentional processes evolved as part of the motor systems, with isolated attentional shifts representing an artificial separation of a natural linkage. Here we test how attentional shifts might be linked to the preparations for making saccadic eye movements. We studied the superior colliculus in monkeys as they shifted their attention during different tasks, and found that each attentional shift is associated with eye-movement preparation.

Discharge of superior collicular neurons during saccades made to moving targets.

1. The discharge of neurons in the deeper layers of the monkey superior colliculus was recorded during saccades made to stationary and to smoothly moving visual targets. 2. All neurons that discharged for saccades made to stationary targets also discharged during saccades made to moving targets, but there was a systematic shift in the saccade vector yielding maximal activity (i.e. center of the movement field) of collicular neurons for the latter class of movements. The shift moved the center of the movement fields toward larger-amplitude pursuit saccades for target motion away from the fovea, in comparison with saccades made to stationary targets. However, the discharge at the center of the movement field for pursuit saccades was 14% lower when averaged over the sample of recorded cells. 3. The saccades made during pursuit tracking of moving visual stimuli have different dynamics than saccades made to stationary targets. At similar amplitudes pursuit saccades are slower, and their velocity profiles often show secondary velocity peaks or inflection points and have longer-duration decelerating phases. 4. The combined experimental observations of a change in saccade dynamics and the shift in movement fields in collicular neurons for pursuit saccades are compatible with the hypothesis that saccades made to moving targets are controlled by neural processing in two partially separate pathways. In this theory, one path is concerned with correction of a presaccadic retinal position error (a path that includes the colliculus) and another path is concerned with position extrapolations based on the velocity of the moving target (a path that does not include the colliculus).

Analysis of the step response of the saccadic feedback: system behavior.

We used prolonged stimulation of the monkey superior colliculus to elicit staircase eye movements. By changing the parameters of the stimulating current we were able to obtain movements with different dynamics. An increase in the current frequency resulted in the shortening of the intersaccadic interval and a decrease of the amplitudes in the staircase. In cases of high stimulation, after an initial saccade of fixed metrics, the eyes moved in an apparently smooth fashion. The movement was conjugate and in the same direction as the first saccade. By analyzing the velocity trace we found that the movement consisted of a chain of small saccades, each of which started before the previous one ended. We conducted a quantitative analysis of the staircase movements including the cases of apparently smooth movement of the eyes. We conclude that all of the movements elicited by prolonged SC stimulation were generated by the saccadic feedback circuitry. The dynamic profiles of the elicited movements changed continuously with the stimulating current parameters. On one end of the continuum we observed the classically, described staircase movements with individual movements separated in time. On the other end of the continuum we saw the apparent smooth movement as the limit case produced by high stimulation of the SC.

Effects of eye position on saccades evoked by stimulation of the monkey superior colliculus.

Effects of different initial eye positions on saccades evoked by electrical stimulation of the superior colliculus (SC) were investigated in alert monkeys with the head restrained. The dependence of saccade vector on initial eye position was studied quantitatively by multiple regression analysis. Following stimulation at 240 of 367 sites in the SC, saccade vector was influenced by initial eye position. The magnitude of eye position effects on horizontal saccade component was similar to that for vertical component. These effects were mostly found with stimulation in the caudal SC. Results suggest that eye position signals may control excitability of neurones in the SC.

Tonic activity during visuo-oculomotor behavior in the monkey superior colliculus

Tonic activity during visuo-oculomotor behavior in the monkey superior colliculus

Short-term adaptation of electrically induced saccades in monkey superior colliculus.

1. This study focuses on the neural mechanisms underlying short-term adaptation of saccadic eye movements in the rhesus monkey. Involuntary saccades of various amplitudes and directions (E-saccades) were elicited in complete darkness by electrical stimulation (< or = 50 microA) in the deeper layers of the superior colliculus (SC) at 30 different sites in two monkeys. E-saccades at a given site could be adapted by presenting a visual target at a small distance from the expected end point immediately after their occurrence. The monkeys were trained to null the ensuing error signal by making the appropriate correction saccade to the visual target in many successive trials (E-adap paradigm). By properly adjusting the location of the visual target relative to the end point of the E-saccade, the latter could be modified in amplitude as well as in direction. 2. E-saccade modifications were highly significant, always in the intended direction, and occurred only if a postsaccadic visual error signal was created. These changes were plastic and required a subsequent E-adap series with an opposite error signal to cancel them. Their time course, both during the adaptation and the readaptation period, indicated that the modification was a slow and gradual process, as has been observed earlier in classical visual adaptation experiments. 3. Postadaptation tests, assessing whether the adaptation of E-saccades was also noticeable in normal visually guided saccades (V-saccades), showed incomplete adaptation transfer that was significant in most cases. A similar result, significant in all cases, was obtained with an extended version of the E-adap paradigm in which movement planning on the basis of target selection was possible. In this case, a presaccadic visual target was presented at the expected end point of the E-saccade, which was evoked just before the monkey would make a voluntary saccade itself (VE-adap). 4. In another series of experiments, V-saccades, which were matched to the optimal saccade vector of the particular collicular site under investigation, were adapted with the classical intrasaccadic target shift paradigm (V-adap). In agreement with earlier findings, this V-adaptation showed no transfer to the E-saccades. This result was obtained even in trials in which movement planning on the basis of target selection was possible (VE-test). 5. Our experiments have shown that saccades of collicular origin can be adapted and that presaccadic target selection is not crucial for this process. Both results are nicely in line with an existing model featuring a downstream adaptive corrector with access to SC inputs. This scheme, however, does not explain why the degree of saccadic adaptation, achieved by applying any of the three adaptation paradigms (E-adap, EV-adap, or V-adap), was never equally expressed in V- and E-saccades. Arguments for extending the model by adding a cortical input from the frontal eye fields to the adaptive corrector are discussed.

Tonic activity during visuo-oculomotor behavior in the monkey superior colliculus

The purpose of this study was to examine whether the superior colliculus is involved in intermediary cognitive processes such as memory, movement preparation, and peripheral attention. To answer this question, we recorded single cell activities in the superior colliculus of monkeys trained to perform a series of visuo-oculomotor tasks: delayed saccade task (SACD), saccade task with overlap target (SACO), and attention task (ATT). We recorded 141 neurons showing tonic activities related to the tasks. Depending on the predominance of the activities among the three tasks, we classified the tonic neurons into four types: (1) visuomotor (greater activity in SACO), (2) mnemonic motor (SACD dominant), (3) attention (ATT), and (4) nonspecific. Among 108 neurons recorded in the intermediate layer, 13 were of a visuomotor type, 15 were of a mnemonic motor type, and 13 were of an attention type. The other 67 neurons were of a non-specific type. Of the 33 neurons in the superficial layer, many neurons were of the non-specific type. These results suggested that the tonic activities in the superior colliculus are related to memory of the target location, preparation of saccades and peripheral attention.

Component stretching during oblique stimulation-evoked saccades: the role of the superior colliculus.

1. During oblique visually guided saccades, the peak velocity of each component is reduced from what it would be for a purely horizontal or vertical saccade of the same amplitude, and the durations of the components are prolonged. We tested predictions of two competing accounts of the neural basis of this "component stretching" phenomenon. Using a recent experimental approach, we electrically stimulated sites in the monkey superior colliculus (SC) immediately after either vertical or horizontal visually guided saccades. Under these conditions, the amplitude of one component (corresponding to the direction of the preceding movement, horizontal or vertical) of the stimulation-evoked saccade varies systematically, while the amplitude of the other component ("constant-amplitude component") remains essentially constant. These changes in saccade metrics occur even though both the locus and parameters of collicular stimulation are fixed. 2. As with visually guided saccades, the peak velocity of the constant-amplitude component in stimulation-evoked saccades decreased with increasing amplitude of the orthogonal component, while the duration of the constant-amplitude component increased with orthogonal amplitude. The component stretching effect in these stimulation-evoked saccades was qualitatively indistinguishable from component stretching in metrically matched, visually guided movements. Yet, unlike visually guided saccades, the locus of stimulation-induced activity was fixed from one stimulation-evoked saccade to the next. 3. Therefore component stretching in stimulation-evoked oblique saccades does not depend on the locus of activity in the collicular motor map. These results are inconsistent with the predictions of common source models of component stretching, but are consistent with cross-coupling models. We discuss the present results in the context of a new interpretation of collicular interaction with downstream saccadic controllers.

Activity of neurons in monkey superior colliculus during interrupted saccades.

1. Recent studies of the monkey superior colliculus (SC) have identified several types of cells in the intermediate layers (including burst, buildup, and fixation neurons) and the sequence of changes in their activity during the generation of saccadic eye movements. On the basis of these observations, several hypotheses about the organization of the SC leading to saccade generation have placed the SC in a feedback loop controlling the amplitude and direction of the impending saccade. We tested these hypotheses about the organization of the SC by perturbing the system while recording the activity of neurons within the SC. 2. We applied a brief high-frequency train of electrical stimulation among the fixation cells in the rostral pole of the SC. This momentarily interrupted the saccade in midflight: after the initial eye acceleration, the eye velocity decreased (frequently to 0) and then again accelerated. Despite the break in the saccade, these interrupted saccades were of about the same amplitude as normal saccades. The postinterruption saccades were usually initiated immediately after the termination of stimulation and occurred regardless of whether the saccade target was visible or not. The velocity-amplitude relationship of the preinterruption component of the saccade fell slightly above the main sequence for control saccades of that amplitude, whereas postinterruption saccades fell near the main sequence. 3. Collicular burst neurons are silent during fixation and discharge a robust burst of action potentials for saccades to a restricted region of the visual field that define a closed movement field. During the stimulation-induced saccadic interruption, these burst neurons all showed a pause in their high-frequency discharge. During an interrupted saccade to a visual target, the typical saccade-related burst was broken into two parts: the first part of the burst began before the initial preinterruption saccade; the second burst began before the postinterruption saccade. 4. We quantified three aspects of the resumption of activity of burst neurons following saccade interruption: 1) the total number of spikes in the pre- and postinterruption bursts, was very similar to the total number of spikes in the control saccade burst; 2) the increase in total duration of the burst (preinterruption period + interruption + postinterruption period) was highly correlated with the increase in total saccade duration (preinterruption saccade + interruption + postinterruption saccade); and 3) the time course of the postinterruption saccade and the resumed cell discharge both followed the same monotonic trajectory as the control saccade in most cells. 5. The same population of burst neurons was active for both the preinterruption and the postinterruption saccades, provided that the stimulation was brief enough to allow the postinterruption saccade to occur immediately. If the postinterruption saccade was delayed by > 100 ms, then burst neurons at a new and more rostral locus related to such smaller saccades became active in association with the smaller remaining saccade. We interpret this shift in active locations within the SC as a termination of the initial saccadic error command and the triggering of a new one. 6. Buildup neurons usually had two aspects to their discharge: a high-frequency burst for saccades of the optimal amplitude and direction (similar to burst neurons), and a low-frequency discharge for saccades of optimal direction whose amplitudes were equal to or greater than the optimal (different from burst neurons). The stimulation-induced interruption in saccade trajectory differentially affected these two components of buildup neuron discharge. The high-frequency burst component was affected in a manner very similar to the burst neurons.(ABSTRACT TRUNCATED)

Open-loop simulations of the primate saccadic system using burst cell discharge from the superior colliculus.

Saccade-related burst neurons (SRBNs) in the monkey superior colliculus (SC) have been hypothesized to provide the brainstem saccadic burst generator with the dynamic error signal and the movement initiating trigger signal. To test this claim, we performed two sets of open-loop simulations on a burst generator model with the local feedback disconnected using experimentally obtained SRBN activity as both the driving and trigger signal inputs to the model. First, using neural data obtained from cells located near the middle of the rostral to caudal extent of the SC, the internal parameters of the model were optimized by means of a stochastic hill-climbing algorithm to produce an intermediate-sized saccade. The parameter values obtained from the optimization were then fixed and additional simulations were done using the experimental data from rostral collicular neurons (small saccades) and from more caudal neurons (large saccades); the model generated realistic saccades, matching both position and velocity profiles of real saccades to the centers of the movement fields of all these cells. Second, the model was driven by SRBN activity affiliated with interrupted saccades, the resumed eye movements observed following electrical stimulation of the omnipause region. Once again, the model produced eye movements that closely resembled the interrupted saccades produced by such simulations, but minor readjustment of parameters reflecting the weight of the projection of the trigger signal was required. Our study demonstrates that a model of the burst generator produces reasonably realistic saccades when driven with actual samples of SRBN discharges.

Influence of eye position on activity in monkey superior colliculus.

1. Most recording studies on the role of the monkey superior colliculus (SC) in eye movement generation have so far indicated that the code of the recruited population of cells is a fixed vector command representing the desired saccadic eye displacement vector, irrespective of the position of the eyes in the orbit. Experimental evidence from microstimulation, lesions, and neuroanatomy, however, suggests that the SC may have access to an eye position signal. 2. In this paper we have tested the hypothesis that SC activity is influenced by eye position, by recording from presaccadic burst neurons while monkeys made rapid eye movements in the light covering a large part of the oculomotor range. 3. In four alert rhesus monkeys, we obtained sufficient data from 57 SC single units. The activity of a substantial part of these cells (30/57) appeared to be significantly influenced by eye position. Although the tuning properties of these cells for saccade amplitude and direction remained invariant for changes in eye position, the peak firing rate of these units was systematically influenced by the position of the eyes in the head. 4. We have characterized this eye position dependence of a neuron's activity by a qualitative, model-independent, as well as by a quantitative model description (gain field), which takes into account both the tuning properties of the cell for eye displacement vectors and the dependence of eye position. 5. Although a majority of gain fields had their eye position sensitivity vector roughly aligned with the optimal saccade vector direction (colinear gain field, 17/30), a substantial part of the gain fields had their eye position sensitivity vectors in quite different directions, approximately homogeneously distributed with respect to the cell's ON direction. 6. We conclude that the SC has access to a signal related to the position of the eyes in the orbit. Several hypotheses on the possible functional role of this signal, in relation to the neural code of the motor map, are discussed.

A novel interpretation for the collicular role in saccade generation

Recently, we found evidence that the activity of neurons in the deep layers of the monkey superior colliculus (SC) is modulated by initial eye position (gain fields). In this paper, we propose a quantitative model of the motor SC which incorporates these new findings. Inputs to the motor map represent the desired eye displacement vector (motor error), as well as initial eye position. A unit's activity in the motor map is described by multiplying a weak linear eye position sensitivity with a gaussian tuning to motor error. The motor map projects to several sets of output neurons, representing the coordinates of the desired eye displacement vector, the desired eye position in the head, and the three-dimensional ocular rotation axis for saccades in Listing's plane, respectively. All these signals have been hypothesized in the literature to drive the saccade burst generator. We show that these signals can be extracted from the motor map by a linear weighting of the population activity. The saccadic system may employ all coding strategies in parallel to ensure high spatial accuracy in many complex sensorimotor tasks, such as orienting to multimodal stimuli.

Saccade-related activity in monkey superior colliculus. I. Characteristics of burst and buildup cells.

1. In the monkey superior colliculus (SC), the activity of most saccade-related neurons studied so far consists of a burst of activity in a population of cells at one place on the SC movement map. In contrast, recent experiments in the cat have described saccade-related activity as a slow increase in discharge before saccades followed by a hill of activity moving across the SC map. In order to explore this striking difference in the distribution of activity across the SC, we recorded from all saccade-related neurons that we encountered in microelectrode penetrations through the monkey SC and placed them in categories according to their activity during the generation of saccades. 2. When we considered the activity preceding the onset of the saccade, we could divide the cells into two categories. Cells with burst activity had a high-frequency discharge just before saccade onset but little activity between the signal to make a saccade and saccade onset. About two thirds of the saccade-related cells had only a burst of activity. Cells with a buildup of activity began to discharge at a low frequency after the signal to make a saccade and the discharge continued until generation of the saccade. About one third of the saccade-related cells studied had a buildup of activity, and about three fourths of these cells also gave a burst of activity with the saccade in addition to the slow buildup of activity. 3. The buildup of activity seemed to be more closely related to preparation to make a saccade than to the generation of the saccade. The buildup developed even in cases when no saccade occurred. 4. The falling phase of the discharge of these saccade-related cells stopped with the end of the saccade (a clipped discharge), shortly after the end of the saccade (partially clipped), or long after the end of the saccade (unclipped). 5. Some cells had closed movement fields in which saccades that were substantially smaller or larger than the optimal amplitude were not associated with increased activity. Other cells tended to have open-ended movement fields without any peripheral border; they were active for all saccades of optimal direction whose amplitudes were equal to or greater than a given amplitude.(ABSTRACT TRUNCATED AT 400 WORDS)

Saccade-related activity in monkey superior colliculus. II. Spread of activity during saccades.

1. In the companion paper we described two classes of cells in the monkey superior colliculus (SC) that were related to saccade generation, buildup cells and burst cells, which fell into two functional sublayers within the intermediate layers of the SC. Fixation cells in the rostral SC were deemed to be part of the buildup cell layer. The buildup cells had several characteristics in common with cells in the cat described as having a "hill of activity" moving across the SC, but the burst cells had no such characteristics. In this paper we further investigate whether there is evidence for such a moving hill of activity in the monkey by analyzing the spatial and temporal activity of cells across the SC during the generation of visually guided saccades. 2. We recorded the activity of single cells while the monkey made saccades of different amplitudes (0.5-60 degrees). We recorded cells from locations extending from the rostral to caudal SC in order to sample cells whose optimal amplitudes ranged from small to large saccades. This allowed us to see any shift of activity across the SC before, during, and after saccades. It also allowed us to determine the fraction of the SC that was active during the successive phases of saccade generation. 3. During active visual fixation, the fixation cells in the rostral pole of the buildup layer showed an increased discharge rate. From the population reconstruction, we estimate that the zone of active cells spanned the most rostral 0.72 mm in each SC. Assuming the SC is 5 mm in length, approximately 15% of the cells lying along the horizontal meridian in the buildup layer would be active during fixation. 4. At least 100 ms before the initiation of a saccade, long-lead activity began to appear in the buildup layer at the site on the SC motor map related to the next saccade. Fixation activity in the rostral poles simultaneously began to diminish, but the cells in the burst layer remained relatively silent. 5. Approximately 25 ms before saccade onset, the fixation cells ceased firing and both burst and buildup cells began to burst. The active zone in the burst layer was estimated to be approximately 1.4 mm diam, occupying roughly 28% of the SC along a line running from the rostral pole through the center of the initially active zone. The size of this active area among the burst cells was independent of saccade amplitude.(ABSTRACT TRUNCATED AT 400 WORDS)