Saccade-related activity in the fastigial oculomotor region of the macaque monkey during spontaneous eye movements in light and darkness

Saccade-related burst neurons were recorded in the caudal part of the fastigial nucleus (fastigial oculomotor region) during spontaneous eye movements and fast phases of optokinetic and vestibular nystagmus in light and darkness from three macaque monkeys. All neurons (n=47) were spontaneously active and exhibited a burst of activity with each saccade and fast phase of nystagmus. Most neurons (n=31) only exhibited a burst of activity, whereas those remaining also exhibited a pause in firing rate before or after the burst. Burst parameters varied considerably for similar saccades. For horizontal saccades all neurons, except for three, had a preferred direction with an earlier onset of burst activity to the contralateral side. For contralateral saccades the burst started on average 17.5 ms before saccade onset, whereas the average lead-time for ipsilateral saccades was only 6.5 ms. Three neurons were classified as isotropic with similar latencies and peak burst activity in all directions. None of the neurons had a preferred direction with an earlier onset of burst activity to the ipsilateral side. Burst duration increased with saccade amplitude, whereas peak burst activity was not correlated with amplitude. There was no relationship between peak burst activity and peak eye velocity. In the dark, neurons generally continued to burst with each saccade and fast phase of nystagmus. Burst for saccades in the dark was compared with burst for saccades of similar amplitude and direction in the light. Saccades in the dark had a longer duration and peak burst activity was reduced on average to 62% (range 36–105%). In three neurons a burst in the dark was no longer clearly distinguishable above the ongoing spontaneous activity. These data suggest that the saccade-related burst neurons in the FOR modify saccadic profiles by directly influencing acceleration and deceleration, respectively, of individual eye movements. This could be achieved by an input to the inhibitory and excitatory burst neurons of the saccadic burst generator in the brainstem. From neuroanatomical studies it is known that FOR neurons project directly to the brainstem regions containing the immediate premotor structures for saccade generation.     

Saccade-related burst neurons with torsional and vertical on-directions in the interstitial nucleus of Cajal of the alert monkey

The interstitial nucleus of Cajal (iC) is known to be the neural integrator for vertical and torsional eye movements. Burst-tonic neurons are thought to be the neural substrate for this function. Until now, the iC has not been specifically considered to play a part in saccade generation. The aim of this study was to characterize saccade-related burst neurons in the iC during torsional and vertical eye movements. Saccade-related burst neurons were recorded in the iC of macaque monkeys during fast phases of torsional and vertical vestibular nystagmus, spontaneous and visually guided eye movements, and in light and darkness. Burst neurons in the iC (n=85) were found intermingled between burst-tonic and tonic neurons. They were not spontaneously active, showed no eye position sensitivity, and responded during saccades and quick phases of nystagmus with a burst of activity whose duration was closely correlated with saccade amplitude and hence saccade duration (correlation coefficients up to 0.9). Latency in the on-direction was, on average, 10.4 ms (range 5–23 ms); it decreased with different saccade directions and became negative in the off-direction. In a horizontal-vertical coordinate system, on-direction of the majority of neurons was either upward (n=52) or downward (n=33). There was no horizontal on-direction. Burst neurons of different vertical on-directions were found intermingled throughout the iC. In the vertical-torsional plane, on-direction always showed an ipsiversive torsional component, i.e., a clockwise (positive) torsion for neurons in the right iC and a counterclockwise (negative) torsional component when recorded in the left iC. The findings indicate that saccade-related burst neurons in the iC control coordinate axes for vertical and torsional quick eye rotations. As in the rostral interstitial nucleus of the medial longitudinal fasciculus (riMLF), burst neurons in the iC encode vertical saccades with an ipsitorsional direction with similar burst characteristics. It is suggested that iC burst neurons play a part in the local feedback loop of the reciprocal iC-riMLF projections.     

Saccadic burst neurons in the oculomotor region of the fastigial nucleus of macaque monkeys

1. The discharge of 255 neurons in the fastigial nuclei of three trained macaque monkeys was investigated during visually guided saccades. Responses of these neurons were examined also during horizontal head rotation and during microstimulation of the oculomotor vermis (lobules VIc and VII). 2. One hundred and two units were characterized by bursts of firing in response to visually guided saccades. Ninety-eight of these (96.1%) were located within the anatomic confines of the fastigial oculomotor region (FOR), on the basis of reconstruction of recording sites. During contralateral saccades, these neurons showed bursts that preceded the onset of saccades (presaccadic burst), whereas, during ipsilateral saccades, they showed bursts associated with the end of saccades (late saccadic burst). They were hence named saccadic burst neurons. Sixty-one saccadic burst neurons (62.2%) were inhibited during microstimulation of the oculomotor vermis with currents less than 10 microA. 3. All saccadic burst neurons were spontaneously active, and the resting firing rate varied considerably among units, ranging from 10 to 50 imp/s. The tonic levels of activity did not correlate significantly with eye position. 4. The presaccadic burst started 18.5 +/- 4.7 (SD) ms (n = 45) before the onset of saccades in the optimal direction (the direction associated with the maximum values of burst lead time, number of spikes per burst, and burst duration). Optimal directions covered the entire contralateral hemifield, although there was a slightly higher incidence in both horizontal and upper-oblique directions in the present sample. The duration of the presaccadic burst was highly correlated with the duration of saccade (0.85 less than or equal to r less than or equal to 0.97). 5. The late saccadic burst was most robust in the direction opposite to the optimal in each unit (the nonoptimal direction). Its onset preceded the completion of ipsilateral saccade by 30.4 +/- 5.9 ms. The lead time to the end of saccade was consistent among different units and was constant also for saccades of various sizes. Thus the late saccadic burst started even before the saccade onset when the saccade duration was less than 30 ms. Unlike the presaccadic burst, its duration was not related to the duration of saccade. 6. Discharge rates of saccadic burst neurons were correlated neither to eye positions during fixation nor to the initial eye positions before saccades. 7. Eye-position units and horizontal head-velocity units were located rostral to the FOR.(ABSTRACT TRUNCATED AT 400 WORDS)     

Contribution of pedunculopontine tegmental nucleus neurons to performance of visually guided saccade tasks in monkeys

The cholinergic pedunculopontine tegmental nucleus (PPTN) is one of the major ascending arousal systems in the brain stem and is linked to motor, limbic, and sensory systems. Based on previous studies, we hypothesized that PPTN would be related to the integrative control of movement, reinforcement, and performance of tasks in behaving animals. To investigate how PPTN contributes to the behavioral control, we analyzed the activity of PPTN neurons during visually guided saccade tasks in three monkeys in relation to saccade preparation, execution, reward, and performance of the task. During visually guided saccades, we observed saccade-related burst (26/70) and pause neurons (19/70), indicating that a subset of PPTN neurons are related to both saccade execution and fixation. Burst neurons exhibited greater selectivity for saccade direction than pause neurons. The preferred directions for both burst and pause neurons were not aligned with either horizontal or vertical axes, nor biased strongly in either the ipsilateral or the contralateral direction. The spatial representation of the saccade-related activity of PPTN neurons is different from other brain stem saccade systems and may therefore relay saccade-related activity from different areas. Increasing discharges were observed around reward onset in a subset of neurons (22/70). These neurons responded to the freely delivered rewards within ~140 ms. However, during the saccade task, the latencies of the responses around reward onset ranged between 100 ms before and 200 ms after the reward onset. These results suggest that the activity observed after appropriate saccade during the task may include response associated with reward. We found that the reaction time to the appearance of the fixation point (FP) was longer when the animal tended to fail in the ensuring task. This reaction time to FP appearance (RTFP) served as an index of motivation. The RTFP could be predicted by the neuronal activity of a subset of PPTN neurons (13/70) that varied their activity levels with task performance, discharging at a higher rate in successful versus error trials. A combination of responses related to saccade execution, reward delivery, and task performance was observed in PPTN neurons. We conclude from the multimodality of responses in PPTN neurons that PPTN may serve as an integrative interface between the various signals required for performing purposive behaviors.     

A quantitative analysis of the correlations between eye movements and neural activity in the pretectum

The study of the saccadic system has focused mainly on neurons active before the beginning of saccades, in order to determine their contribution in movement planning and execution. However, most oculomotor structures contain also neurons whose activity starts only after the onset of saccades, the maximum of their activity sometimes occurring near saccade end. Their characteristics are still largely unknown. We investigated pretectal neurons with saccade-related activity in the alert cat during eye movements towards a moving target. They emitted a high-frequency burst of action potentials after the onset of saccades, irrespective of their direction, and will be referred to as "pretectal saccade-related neurons". The delay between saccade onset and cell activity varied from 17 to 66 ms on average. We found that burst parameters were correlated with the parameters of saccades; the peak eye velocity was correlated with the peak of the spike density function, the saccade amplitude with the number of spikes in the burst, and burst duration increased with saccade duration. The activity of six pretectal saccade-related neurons was studied during smooth pursuit at different velocities. A correlation was found between smooth pursuit velocity and mean firing rate. A minority of these neurons (2/6) were also visually responsive. Their visual activity was proportional to the difference between eye and target velocity during smooth pursuit (retinal slip). These results indicate that the activity of pretectal saccade-related neurons is correlated with the characteristics of eye movements. This finding is in agreement with the known anatomical projections from premotor regions of the saccadic system to the pretectum.     

Presaccadic omnidirectional burst activity in the basal interstitial nucleus in the monkey cerebellum

We recorded saccade-related neurons in the vicinity of the dentate nucleus of the cerebellum in two monkeys trained to perform visually guided saccades and memory-guided saccades. Among 76 saccade-related neurons, 38 showed presaccadic bursts in all directions. More than 80% of such burst neurons were located in the area ventral to, not inside, the dentate nucleus, which corresponded to the basal interstitial nucleus (BIN as previously described). We found that the activity of the BIN neurons was correlated with saccade duration but not with saccade amplitude or velocity. Thus, when tested with visually guided saccades, the burst started about 16 ms before saccade onset and ended about 33 ms before saccade offset, regardless of saccade amplitude. The characteristic timing of the BIN cell activity was maintained for different types of saccades (visually guided, memory-guided and spontaneous saccades), which had different dynamics. Although the number of spikes in a burst for each neuron was linearly correlated with saccade amplitude for a given type of saccade, the slope varied depending on the type of saccade. Peak burst frequency was uncorrelated with saccadic peak velocity. In contrast, burst duration was highly correlated with saccade duration regardless of the type of saccade. These results suggest that BIN neurons may carry information to determine the timing of saccades. Received: 14 August 1997 / Accepted: 17 February 1998     

Cerebellar control of saccadic eye movements: its neural mechanisms and pathways

Microstimulation studies on monkeys have shown that the cerebellar cortex which is related to saccadic function is located in lobules VIc and VII of the vermis. This vermal area is designated as the oculomotor vermis and characterized by low thresholds (less than 10 microA) and by saccade-related neuronal activity. The saccade evoked by the vermal stimulation has been shown to be the result of activation of Purkinje-cell axons. On the other hand, an anterograde WGA-HRP transport study has indicated that the Purkinje-cell axons of the oculomotor vermis terminate almost exclusively in a fatigial region which is designated as the fastigial oculomotor region (FOR). Microstimulation of the oculomotor vermis and the ventromedial aspect of the FOR results in saccades which differ in their horizontal directions, with vermal stimulation resulting in ipsilateral and fastigial stimulation resulting in contralateral saccades. Since the ipsilateral saccades evoked from the caudal part of the FN were suppressed by bicuculline, they were the results of stimulation of the Purkinje axons. It has been also shown that stimulation of the oculomotor vermis causes inhibition of FOR neurons. Furthermore, fastigial neurons bursting with saccades can be recorded only within the anatomical confines of the FOR. These data are consistent with the concept that signals from the vermis are transmitted to the saccadic nuclei of the brainstem via the FOR. Neurons in the FOR have been shown to project to various saccade-related nuclei, including the riMLF and PPRF. Some neurons in the FOR have divergent axon collaterals which terminate in both the vertical and horizontal preoculomotor nuclei. When the initial eye position is changed by stimulating the FN prior to visually-guided saccades, monkeys cannot compensate for the stimulation-induced movement. When the stimulation is delived 75-130 ms after the target presentation, saccades are triggered prematurely. The visuomotor processing for saccades seems to be completed during this period, which is approximately half the latency of normal saccades. When saccades were triggered prematurely at an early stage of information processing, the eyes moved first in the direction of evoked saccade and then changed the direction toward the location of the target without any intervening period. The retinal error information sampled before the stimulation was not disturbed by the cerebellar stimulation. These observations suggest that cerebellar output impulses are projected downstream to saccade-programming circuits where visual information has already been converted into motor-command signals. The cerebellum is a domain for parallel processing of visuomotor information.     

Changes in cerebellar fastigial burst activity related to saccadic gain adaptation in the monkey

The accuracy of saccades is ensured by an adaptive mechanism that probably involves the cerebellum. We examined the discharge of saccade-related neurons in the fastigial oculomotor region (FOR) during adaptation. Using a conventional intrasaccadic step paradigm, we changed the gain of saccades elicited by a 10 degrees horizontal target step to the side of unit recording. As a measure of neural activity, we took the number of spikes occurring in a 30 or 40 ms time window starting at 30 ms before saccade onset, which corresponded roughly to the foot and rising phase of the burst. A gain decrease was accompanied by a significant increase in spike discharge (6/6), and a gain increase by a significant reduction in discharge (3/3). During the course of adaptation, the neural activity and gain exhibited changes with a similar course but in the opposite direction. Regression analysis indicated that the two variables were significantly correlated (7/8). The present study has shown that activity of FOR neurons is altered during adaptive modification of saccade size. Our data are consistent with the hypothesized suppressive action of the FOR on ipsiversive saccades and provide support on a single-neuron basis for the cerebellar involvement in short-term saccade adaptation.     

Premotor inhibitory neurons carry signals related to saccade adaptation in the monkey

Cerebellar output changes during motor learning. How these changes cause alterations of motoneuron activity and movement remains an unresolved question for voluntary movements. To answer this question, we examined premotor neurons for saccadic eye movement. Previous studies indicate that cells in the fastigial oculomotor region (FOR) within the cerebellar nuclei on one side exhibit a gradual increase in their saccade-related discharge as the amplitude of ipsiversive saccades adaptively decreases. This change in FOR activity could cause the adaptive change in saccade amplitude because neurons in the FOR project directly to the brain stem region containing premotor burst neurons (BNs). To test this possibility, we recorded the activity of saccade-related burst neurons in the area that houses premotor inhibitory burst neurons (IBNs) and examined their discharge during amplitude-reducing adaptation elicited by intrasaccadic target steps. We specifically analyzed their activity for off-direction (contraversive) saccades, in which the IBN activity would increase to reduce saccade size. Before adaptation, 29 of 42 BNs examined discharged, at least occasionally, for contraversive saccades. As the amplitude of contraversive saccades decreased adaptively, half of BNs with off-direction spike activity showed an increase in the number of spikes (14/29) or an earlier occurrence of spikes (7/14). BNs that were silent during off-direction saccades before adaptation remained silent after adaptation. These results indicate that the changes in the off-direction activity of BNs are closely related to adaptive changes in saccade size and are appropriate to cause these changes.     

Saccade-related neurons in the primate fastigial nucleus: what do they encode?

The cerebellar fastigial oculomotor region (FOR) and the overlying oculomotor vermis (OV) are involved in the control of saccadic eye movements, but nature and function of their saccade-related neuronal signals are not fully understood. There is controversy in at least two major aspects: first, lesion studies in OV/FOR reported eye-position-dependent dysmetria-with FOR lesions, centripetal saccades became more hypermetric than centrifugal saccades-suggesting that the cerebellum may compensate for orbital mechanics. However, single-unit studies failed to reveal corresponding eye-position dependencies in FOR saccade-related discharge patterns. Second, some single-unit studies reported precise correlation between burst and saccade duration in the FOR. However, others stated that FOR bursts were only weakly related to saccade properties. In an attempt to resolve these discrepancies, we recorded single FOR units in monkeys that made horizontal saccades (16 degrees ) from different starting positions. Sampling saccades of one fixed amplitude and application of an objective, computer-based burst-detection-routine allowed us to correlate burst parameters (onset latency, peak latency, peak amplitude, number of spikes, duration) and kinematic properties of individual saccades. FOR bursts were found to start and peak earlier and exhibit higher peak burst amplitudes for faster than for slower saccades of the same amplitude. While these correlations between FOR bursts and saccade properties were statistically significant for a minority of approximately 20-25% of individual units, the same effects were also predominant in the remainder of the neuronal sample and statistically significant on the population level. Neuronal activity was not significantly modulated by eye position itself. However, reflecting differences in saccade velocities but not an actual influence of eye position per se, FOR bursts for centripetal and centrifugal saccades exhibited subtle but systematic differences, which closely paralleled, and hence probably explain, the eye-position dependency of deficits observed after FOR inactivation. Our findings indicate that FOR signals reflect much of the kinematic properties of the saccade. Moreover, they are consistent with the idea that the FOR output is purposefully modified according to these kinematic properties to maintain saccadic accuracy.     

The effect of microstimulation of the oculomotor vermis on discharges of fastigial neurons and visually-directed saccades in macaques

The present study confirmed our previous reports that neurons in the fastigial oculomotor region (FOR) of the macaque show presaccadic bursts during contralateral saccades and that the burst duration is closely related to the duration of the accompanying saccade. Furthermore, when the burst duration was reduced by subthreshold electrical stimulation applied to the oculomotor vermis prior to the onset of the burst, the impending visually-directed saccade became hypometric. The reduction in the burst duration was closely related to the degree of the hypometria. Since saccadic burst neurons in the FOR constitute the sole output channel for saccadic signals of the oculomotor vermis, the findings support the hypothesis that the cerebellum can regulate the amplitude of eye movements.     

Glycinergic inputs cause the pause of pontine omnipause neurons during saccades

Pontine omnipause neurons (OPNs) are inhibitory neurons projecting to saccade-related premotor burst neurons. OPNs exhibit sustained discharge during fixations and cease firing before and during saccades. The pause in OPN discharge releases the burst neurons from tonic inhibition, resulting in generation of saccadic eye movements. OPNs are thought to receive two major inhibitory inputs during saccades: an early component that determines the pause onset and a late component that controls the pause duration. Although there is evidence that numerous glycinergic and GABAergic terminals contact OPNs, their physiological roles remain unclear. To reveal functions of glycinergic and GABAergic inputs, we investigated effects of iontophoretic application of strychnine, a glycine receptor antagonist, and bicuculline, a GABAA receptor antagonist, on discharge patterns of OPNs in alert cats. Application of strychnine reduced the ratio of pause duration to saccade duration. Analysis of the timing of pause relative to saccades showed that pause onset was delayed and pause end was advanced. These effects were observed for saccades in all directions. Application of bicuculline, in contrast, had no effect on the OPN pause duration or timing. Both strychnine and bicuculline increased tonic firing rate during intersaccadic intervals. These results suggest that glycinergic, but not GABAergic, afferents convey inhibitory signals that determine the onset as well as duration of pause in OPN activity during saccades.     

Effects of initial eye position on saccade-related behavior of abducens nucleus neurons in the primate

Previous work suggests that when the eye starts at different orbital initial positions (IPs), the saccade control system is faced with significant nonlinearities. Here we studied the effects of IP on saccade-related firing of monkey abducens neurons by either isolating saccade variables behaviorally or applying a multiple linear regression analysis. Over a 50 degrees range of IPs, we could select 10 degrees horizontal saccades with identical velocity profiles, which would require identical control signals in a linear system. The bursts accompanying ipsiversive saccades for IPs above the threshold for steady firing were quite similar. The excess burst rate above steady firing was either constant or decreased with ipsiversive IP, and both the number of excess spikes in the burst and burst duration were nearly constant. However, for ipsiversive saccades from IPs below threshold, both peak burst rate (6.82 +/- 1.38 spikes.s(-1).deg(-1)) and burst duration (0.67 +/- 0.28 ms/deg) increased substantially with ipsiversive IPs. Moreover, the pause associated with contraversive saccades shortened considerably with ipsiversive IPs (mean 1.2 ms/deg). This pattern of results for pauses and for bursts below threshold suggests the presence of a significant nonlinearity. Abducting saccades are produced by the net force of agonist lateral rectus (LR) and antagonist medial rectus (MR) muscles. We suggest that the decreasing force in the MR muscle with IPs in the abducting direction requires a more vigorous burst in LR motoneurons, which appears to be generated by a combination of saturating and nonsaturating burst commands and the recruitment of additional abducens neurons.     

Topography of the oculomotor area of the cerebellar vermis in macaques as determined by microstimulation

1. Oculomotor responses to microstimulation of the cerebellar vermis of macaque monkeys were investigated by using a magnetic search-coil method. 2. The oculomotor responses were conjugate eye movements with an ipsilateral horizontal component. Analyses of amplitude-velocity and amplitude-duration relationships revealed that the peak eye velocities and the durations of the responses were comparable to those of saccadic eye movements. 3. Systematic mapping with microstimulation disclosed that the region in the cerebellar vermis that yielded saccades with weak stimulus currents was confined to lobule VII in five monkeys but included a part of folium VIc in the other four monkeys. This region coincided with the distribution of the saccade-related neural activity observed in the present study and also corresponded to the vermal folia from which we recorded the burst mossy-fiber units and the oculomotor Purkinje cell activity. 4. The oculomotor vermis was defined as that region of the cerebellar vermis that met the following criteria: 1) saccades were evoked with low-intensity microstimulation (with currents less than 10 microA); 2) vigorous saccade-related neural activity was present; and 3) Purkinje cell discharges were modulated with eye movements. The oculomotor vermis was more circumscribed and located more posteriorly than the vermal cortex explored in previous microstimulation experiments on monkeys. 5. Microstimulation of the oculomotor vermis evoked more or less curved saccades in oblique directions. The horizontal and vertical components were not simultaneous in some saccades: the shorter component started later or ended earlier than the other component and their peak velocities were not always synchronous. 6. The amplitude of the saccade depended on stimulus parameters; microstimulation with 10-12 pulses within a period of approximately 20 ms (500-600 Hz) was shown to be optimal. When the pulses were applied to the white matter or to the granular layer, a stimulus current of 10 microA was sufficient to evoke saccades. When the molecular layer was stimulated, evoked saccades were smaller and frequently curved, and an increase in the stimulus current changed either the initial direction or the trajectory of the saccade. 7. When the stimulus current was carefully controlled and maintained near the threshold, the direction of the saccade evoked from the oculomotor vermis was topographically organized.(ABSTRACT TRUNCATED AT 400 WORDS)     

Saccade-related Purkinje cells in the cerebellar hemispheres of the monkey

Summary Extracellular single unit discharges of cerebellar Purkinje cells (P-cells) were recorded from the cerebellar hemispheres of two Japanese monkeys (Macaca fuscata) during spontaneous and visually guided eye movements. We found that saccade-related P-cells, whose simple-spike (SS) discharge rates were modulated in close correlation with saccadic eye movements, were localized in fairly restricted areas in the hemisphere, mostly in Crus IIa with some in the deep folia of Crus I. P-cells located in simple lobules, superficial folia of Crus I or in Crus IIp did not change their discharge rate during voluntary eye movements. Fifty-five saccade-related P-cells recorded from Crus I and II showed modulation of SS discharge rate related to both spontaneous and visually triggered saccades, with the modulation closely time-locked to the saccades. Two thirds (37/55) of saccade-related P-cells began to change their SS discharge rate 20–100 ms prior to the onset of saccades. The remaining one third (18/55) changed their activity approximately at the same time as the saccade onset. These saccade-related P-cells did not show changes in activity during smooth pursuit eye movements, and we did not find any P-cells in the cerebellar hemisphere which showed changes of activity preferentially during smooth pursuit eye movements. In about half (26/55) of the saccade-related P-cells, the pattern of modulation prior to and during saccades was biphasic: increase-decrease or decrease-increase. The other half (29/55) showed monophasic increases or decreases. For a given P-cell, the discharge pattern during saccades was similar for saccades of all directions, though there was a preferred direction in the amount of discharge rate modulation. The present findings suggest that the cerebellar hemisphere (Crus I and IIa) plays an important role in the control of voluntary saccadic eye movements, in addition to other cerebellar cortical areas (flocculus and posterior vermis) which are known to participate in the control of saccades.     

Blink-perturbed saccades in monkey. II. Superior colliculus activity

Trigeminal reflex blinks evoked near the onset of a saccade cause profound spatial-temporal perturbations of the saccade that are typically compensated in mid-flight. This paper investigates the influence of reflex blinks on the discharge properties of saccade-related burst neurons (SRBNs) in intermediate and deep layers of the monkey superior colliculus (SC). Twenty-nine SRBNs, recorded in three monkeys, were tested in the blink-perturbation paradigm. We report that the air puff stimuli, used to elicit blinks, resulted in a short-latency ( approximately 10 ms) transient suppression of saccade-related SRBN activity. Shortly after this suppression (within 10-30 ms), all neurons resumed their activity, and their burst discharge then continued until the perturbed saccade ended near the extinguished target. This was found regardless whether the compensatory movement was into the cell's movement field or not. In the limited number of trials where no compensation occurred, the neurons typically stopped firing well before the end of the eye movement. Several aspects of the saccade-related activity could be further quantified for 25 SRBNs. It appeared that 1) the increase in duration of the high-frequency burst was well correlated with the (two- to threefold) increase in duration of the perturbed movement. 2) The number of spikes in the burst for control and perturbed saccades was quite similar. On average, the number of spikes increased only 14%, whereas the mean firing rate in the burst decreased by 52%. 3) An identical number of spikes were obtained between control and perturbed responses when burst and postsaccadic activity were both included in the spike count. 4) The decrease of the mean firing rate in the burst was well correlated with the decrease in the velocity of perturbed saccades. 5) Monotonic relations between instantaneous firing rate and dynamic motor error were obtained for control responses but not for perturbed responses. And 6) the high-frequency burst of SRBNs with short-lead and long-lead presaccadic activity (also referred to as burst and buildup neurons, respectively) showed very similar features. Our findings show that blinking interacts with the saccade premotor system already at the level of the SC. The data also indicate that a neural mechanism, rather than passive elastic restoring forces within the oculomotor plant, underlies the compensation for blink-related perturbations. We propose that these interactions occur downstream from the motor SC and that the latter may encode the desired displacement vector of the eyes by sending an approximately fixed number of spikes to the brainstem saccadic burst generator.     

Discharge patterns of neurons in the rostral superior colliculus of cat: activity related to fixation of visual and auditory targets

Neurons in the rostral superior colliculus (SC) of alert cats exhibit quasi-sustained discharge patterns related to the fixation of visual targets. Because some SC neurons also respond to auditory stimuli, we investigated whether there is a population of neurons in the rostral SC which is active in relation to fixation of both auditory and visual targets. We identified cells which were active with visual fixation and which continued to discharge if the fixation stimulus was briefly extinguished. The population of neurons exhibited similar discharge characteristics when the fixation stimulus was auditory. Few neurons were significantly more active during fixation of visual targets than during fixation of auditory targets. Most fixation neurons showed a diminished discharge rate during spontaneous (self-generated) saccadic eye movements away from a visual fixation stimulus, regardless of the direction of the saccade. this diminished discharge rate (or pause) typically began, on average, 12.2 ms before saccade onset and the duration of the pause was Ionger than the duration of the saccade. These observations are consistent with the hypothesis that increased discharge of these neurons is related to active fixation and that reductions in their activity are important for the generation of saccades. However, the lack of a precise relationship between pause duration and saccade duration implies that these neurons would be unlikely to project directly to the saccadic burst generator. The mean interval from the beginning of the pauses of fixation neurons to be beginning of the saccades away from fixation targets is also shorter than has been found in brainstem omnipause neurons. By analogy with the concept of a receptive field, agaze position error field depicts the range of gaze position error for which a cell is active. Although fixation neurons appear to encode the magnitude and direction of the error between visual targets and the visual axis, visual error fields at the end of fixating eye movements were significantly larger than those at stimulus onset. For auditory stimuli, this difference was not significant. These observations are compatible with a number of recent experiments indicating that neural signals of eye position are damped or delayed with respect to current eye position.     

Activity of the brain stem omnipause neurons during saccades perturbed by stimulation of the primate superior colliculus

Stimulation of the rostral approximately 2 mm of the superior colliculus (SC) during a large, visual target-initiated saccade produces a spatial deviation of the ongoing saccade and then stops it in midflight. After the termination of the stimulation, the saccade resumes and ends near the location of the flashed target. The density of collicular projections to the omnipause neuron (OPN) region is greatest from the rostral SC and decreases gradually for the more caudal regions. It has been hypothesized that the microstimulation excites the OPNs through these direct connections, and the reactivation of OPNs, which are normally silent during saccades, stops the initial component in midflight by gating off the saccadic burst generator. Two predictions emerge from this hypothesis: 1) for microstimulation triggered on the onset of large saccades, the time from stimulation onset to resumption of OPN discharge should decrease as the stimulation site is moved rostral and 2) the lead time from reactivation of OPNs to the end of the initial saccade on stimulation trials should be equal to the lead time of pause end with respect to the end of control saccades. We tested this hypothesis by recording OPN activity during saccades perturbed by stimulation of the rostral approximately 2 mm of the SC. The distance of the stimulation site from the most rostral extent of the SC and the time of reactivation with respect to stimulation onset were not significantly correlated. The mean lead of reactivation of OPNs relative to the end of the initial component of perturbed saccades (6.5 ms) was significantly less than the mean lead with respect to the end of control (9.6 ms) and resumed saccades (10.4 ms). These results do not support the notion that the excitatory input from SC neurons-in particular, the fixation neurons in the rostral SC-provide the major signal to reactivate OPNs and end saccades. An alternative, conceptual model to explain the temporal sequence of events induced by stimulation of the SC during large saccades is presented. Other OPN activity parameters also were measured and compared for control and stimulation conditions. The onset of pause with respect to resumed saccade onset was larger and more variable than the onset of pause with respect to control saccades, whereas pause end with respect to the end of resumed and control saccades was similar. The reactivated discharge of OPNs during the period between the end of the initial and the onset of the resumed saccades was at least as strong as that following control movements. This latter observation is interpreted in terms of the resettable neural integrator hypothesis.     

Similarity of superior colliculus involvement in microsaccade and saccade generation

The characteristics of microsaccades, or small fixational saccades, and their influence on visual function have been studied extensively. However, the detailed mechanisms for generating these movements are less understood. We recently found that the superior colliculus (SC), a midbrain structure involved in saccade generation, also plays a role in microsaccade generation. Here we compared the dynamics of neuronal activity in the SC associated with microsaccades to those observed in this structure in association with larger voluntary saccades. We found that microsaccade-related activity in the SC is characterized by a gradual increase in firing rate starting ～100 ms prior to microsaccade onset, a peak of neuronal discharge just after movement onset, and a subsequent gradual decrease in firing rate until ～100 ms after movement onset. These properties were shared with saccade-related SC neurons, recorded from the same monkeys but preferring larger eye movements, suggesting that at the level of the SC the neuronal control of microsaccades is similar to that for larger voluntary saccades. We also found that neurons exhibiting microsaccade-related activity often also exhibited saccade-related activity for slightly larger movements of similar direction, suggesting a continuity of the spatial representation in the SC, in both amplitude and direction, down to the smallest movements. Our results indicate that the mechanisms controlling microsaccades may be fundamentally the same as those for larger saccades, and thus shed new light on the functional role of these eye movements and their possible influence on sensory and sensory-motor processes.     

Burst discharges of mossy fibers in the oculomotor vermis of macaque monkeys during saccadic eye movements.

Mossy fiber activity was recorded from the oculomotor vermis (lobules VIc and VII) during visually guided saccades. Saccade-related activities of 99 mossy fiber units were observed in two alert macaque monkeys. Ninety-six units were characterized by high-frequency bursts of firing in response to visually guided saccades (burst unit). These units were silent during all periods of fixation in any gaze position. Three units showed eye position-related tonic discharges with saccadic bursts. The lead time of saccadic bursts ranged from 2.6 to 80.5 ms (mean 27.9 ms, SD 16.6 ms). About 75% of the burst units exhibited a long lead burst characterized by a slow buildup, while the remaining units showed short lead bursts with a sharp onset. About 80% of the units showed burst in association with contralaterally directed saccades. The remaining units exhibited bursts in association with ipsilateral saccades. Preferred directions in this population covered the entire field including the vertical and the oblique. About 68% of long lead burst units exhibited the movement field which consists of a whole sector of the entire oculomotor range (directional type). About 32% of long lead burst units showed the movement field which is a closed area within the oculomotor range (vectorial type). On the other hand, peak frequency of short lead burst units increased in proportion to saccade amplitude. The end of the burst in all units always preceded the completion of saccade. The end of burst was time-locked to the completion of saccade, so that the lead time from the end of burst to the end of saccade was consistent among these units and, was constant regardless of saccadic amplitude. The duration between the peak and the offset of burst was correlated with the amplitude of saccade (0.63 < or = r < or = 0.83). Long lead burst of mossy fibers was almost comparable to burst activity in the nucleus reticularis tegmenti pontis (NRTP), while short lead burst of mossy fibers closely resembles activity of excitatory burst neurons in the paramedian pontine reticular formation (PPRF). These findings suggest that the cerebellum receives command signal from the superior colliculus via the NRTP and feedback signal from the PPRF.