Role of Primate Superior Colliculus in Preparation and Execution of Anti-Saccades and Pro-Saccades

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The Journal of Neuroscience, April 1, 1999, 19(7):2740-2754

Role of Primate Superior Colliculus in Preparation and Execution of Anti-Saccades and Pro-Saccades
Stefan Everling¹, Michael C. Dorris¹, Raymond M. Klein², and Douglas P. Munoz¹
¹ Medical Research Council Group in Sensory-Motor Neuroscience, Department of Physiology, Queen's University, Kingston, Ontario, Canada, K7L 3N6, and ² Department of Psychology, Dalhousie University, Halifax, Nova Scotia, Canada, B3H 4J1

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
REFERENCES

We investigated how the brain switches between the preparation of a movement where a stimulus is the target of the movement,and a movement where a stimulus serves as a landmark for an instructedmovement elsewhere. Monkeys were trained on a pro-/anti-saccadeparadigm in which they either had to generate a pro-saccade towarda visual stimulus or an anti-saccade away from the stimulus toits mirror position, depending on the color of an initial fixationpoint. Neural activity was recorded in the superior colliculus(SC), a structure that is known to be involved in the generationof fast saccades, to determine whether it was also involved inthe generation of anti-saccades. On anti-saccade trials, fixationduring the instruction period was associated with an increasedactivity of collicular fixation-related neurons and a decreasedactivity of saccade-related neurons. Stimulus-related and saccade-relatedactivity was reduced on anti-saccade trials. Our results demonstratethat the anti-saccade task involves (and may require) the attenuationof preparatory and stimulus-related activity in the SC to avoidunwanted pro-saccades. Because the attenuated pre-saccade activitythat we found in the SC may be insufficient by itself to elicitcorrect anti-saccades, additional movement signals from otherbrain areas are presumablyrequired.

Key words: superior colliculus; eye movement; anti-saccade; stimulus-response mapping; sensorimotor transformation; oculomotor; motor preparation; saccade; visual fixation

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
REFERENCES

Rapid saccadic eye movements are used to move the eyes to objects of interest. It is well known that the superior colliculus(SC) in the midbrain is an important structure for the generationof these fast saccades in which the stimulus is also the targetof the movement (Wurtz and Goldberg, 1972; Schiller et al., 1987;Edelman and Keller, 1996; Dorris et al., 1997). The movement repertoireof primates, however, is not constrained to spatially congruentmovements. Primates can acquire arbitrary stimulus-response mappings,where a stimulus can serve as a landmark for an instructed incongruentmovement (for review, see Wise et al., 1996).

The frontal eye field (FEF), supplementary eye field (SEF), and dorsolateral prefrontal cortex (DPC) are considered to bethe predominate brain regions involved in the generation of incongruentsaccades. Patients with frontal cortex lesions (Guitton et al.,1985; Pierrot-Deseilligny et al., 1991) have difficulty correctlyperforming the anti-saccade task (Hallett 1978; Hallett and Adams,1980; for review, see Everling and Fischer, 1998), in which theyare instructed to suppress a saccade toward a suddenly appearingperipheral visual stimulus (pro-saccade) and to generate a saccadeto its mirror position (anti-saccade). Recently, neurophysiologicalstudies have also shown that SEF (Schlag-Rey et al., 1997) andDPC (Funahashi et al., 1993) neurons are active for anti-saccades.To date, the contribution of the SC to the generation of anti-saccadesisunknown.

The primate SC receives direct projections from many cortical areas, including FEF, SEF, and DPC (Leichnetz et al., 1981;Fries, 1984; Stanton et al., 1988; Shook et al., 1990), and projectsdirectly to preoculomotor neurons in the brain stem (for review,see Moschovakis et al., 1996). However, FEF and SEF also havedirect projections to the preoculomotor region in the brain stemthat bypass the SC (for review, see Schall, 1997). The combinationof serial and parallel pathways in the saccadic system has ledto two extreme hypotheses for the generation of anti-saccades.Guitton (1991) hypothesized that the anti-saccade movement signalgenerated in the FEF or SEF is relayed to the SC, which in turnsends the motor command to the brain stem saccade generator ("serialhypothesis"). In contrast, Forbes and Klein (1996) hypothesizedthat the cortical motor command for the anti-saccade is sent directlyby the cortex to the brain stem ("bypass hypothesis").

These two hypotheses predict different neural activity in the SC during the anti-saccade task: The serial hypothesis predictssimilar activity of saccade-related neurons in the SC before pro-saccadesand anti-saccades, whereas the bypass hypothesis predicts thatsaccade-related neurons in the SC are inactive for anti-saccades.To distinguish between these two hypotheses, we recorded singleneuron activity in the SC of awake behaving rhesus monkeys trainedto perform saccades in a task with randomly interleaved pro-saccadeand anti-saccadetrials.

Preliminary reports of some of these data have been published previously (Everling et al., 1998a,b)

  MATERIALS AND METHODS

Preparation of experimental animals. Two adult male rhesus monkeys (Macaca mulatta), weighing 6 and 10 kg, were used in thisstudy. All procedures were approved by the Queen's UniversityAnimal Care Committee and were in compliance with the CanadianCouncil on Animal Care policy for the care and use of laboratoryanimals. Animals were prepared for chronic experiments in a singlesurgery. Eye movements were monitored by the magnetic search coiltechnique (Fuchs and Robinson, 1966; Judge et al., 1980). Scleralsearch coils, a head restraint, and a stainless steel recordingchamber were implanted under ketamine/isoflurane anesthesia andaseptic conditions (for details, see Munoz and Istvan, 1998).The recording chamber was centered on the midline and tilted 38°posterior of vertical to allow recordings of bothSCs.

Behavioral paradigms. The monkeys were trained to perform a pro-/anti-saccade paradigm (Fig. 1). The experiments were conductedin a dark, sound-attenuated room. The monkeys were seated comfortablyin a primate chair (Crist Instruments) with their head restrained.They faced a screen 86 cm in front of them that spanned 70° ×70° of the visual field. Isoluminant light-emitting diodes (greenand red, 0.3 cd/m²) were back-projected onto the screen to generate visual stimuli.During the intertrial intervals, the screen was illuminated diffusely(1.0 cd/m²) to prevent the animals from becoming dark-adapted. Each trialstarted with the removal of the background light, and after aperiod of 250 msec, a fixation point (FP) appeared at the centerof the screen. The monkeys were required to look at the FP andmaintain fixation for 700 to 900 msec. A red FP was used to signala pro-saccade trial (Fig. 1A) and a green FP was used to signalan anti-saccade trial (Fig. 1B). For half of the trials, the FPwas extinguished 200 msec (gap period) before stimulus presentation(Fig. 1C, Gap-Condition). For the other half of the trials, theFP remained illuminated throughout the whole trial (Fig. 1D, Overlap-Condition).Then, within a block of trials, a red visual stimulus was projectedpseudorandomly with equal probability at one of two possible positionson opposite sides of the horizontal and vertical meridians. Forsaccade-related and visual-related neurons, one position was setto the location that yielded the optimal saccade-related or visual-relatedactivity, respectively (contralateral to the side of recording).The other position was set to the mirror location on the oppositeside of the horizontal and vertical meridians (ipsilateral side).The optimal response location of a saccade-related neuron anda visual-related neuron was identified in a block of gap pro-saccadetrials in which the location of stimulus presentation was changedsystematically. Saccade-related neurons in the SC can exhibitpreparatory activity and visual activity in addition to theirmotor-related activity (Munoz and Wurtz, 1995a). Therefore, werefer in the following text to the optimal response location ofa neuron as the neuron's "response field," instead of using theterms "receptive field" or "motor field." For neurons with fixation-relatedactivity, the stimulus was presented pseudorandomly 10° to theleft and 10° to the right of the FP. Monkeys received a liquidreward if they maintained central fixation throughout the visualfixation and gap periods and then generated a saccade within 500msec after stimulus presentation to the stimulus location on pro-saccadetrials (as indicated by red FP) or to its mirror location on anti-saccadetrials (as indicated by green FP), and then maintained fixationthere for at least 200 msec.

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Figure 1. Schematic representation of the pro-/anti-saccade paradigm. FP, Fixation point; RF, response field; S, stimulus. See Materials and Methods for details.

The on-line accuracy criterion for the saccades consisted of a window of ±60% of the length of the vector of the stimulus.This large window was necessary, because the endpoints of anti-saccadesdisplay great variability (Hallett, 1978; Smit et al., 1987).The accuracy criterion was more stringent off-line for the quantificationof saccade-related activity (see below). On anti-saccade trials,a green stimulus was presented 600 msec after and at the mirrorlocation of the red stimulus to provide the monkey with post-trialinformation about the correct location for the anti-saccade. Duringthe recording of one neuron, between 12 and 20 trials of eachof the eight conditions were presented in a pseudorandom orderby combining the two types of mapping conditions (pro-saccadeand anti-saccade) with the two fixation conditions (gap and overlap)and the two stimulus locations. The monkeys received water untilsatiation, after which they were returned to their home cages.Daily records were kept of the weight and health status of themonkeys, and additional water and fruit was provided asneeded.

Recording techniques. Single neuron activity was recorded extracellularly in both SCs in the two monkeys with commerciallyavailable tungsten microelectrodes (Frederick Haer) with impedancesof 0.5-5 M $Omega$ at 1 kHz. Electrodes were driven by a hydraulic microdrive(Narishige, Tokyo, Japan) through stainless steel guide tubesthat were held in position firmly by a Delrin grid inside therecording chamber (Crist et al., 1988). Single-neuron activitywas sampled at 1 kHz after passing through a window discriminator(Bak Electronics), which excluded action potentials that did notmeet both amplitude and timeconstraints.

A 486 personal computer running a real-time data acquisition system (REX) (Hays et al., 1982) was used to control the behavioralparadigms and visual displays and to store data. Horizontal andvertical eye positions were sampled at 500 Hz from oneeye.

Data analysis. The off-line data analysis was performed on a Sun Sparc2 workstation with the use of a computer program thatmarked the beginning and end of a saccade based on velocity andacceleration threshold criteria (Waitzman et al., 1991). The saccadesmarked on each trial were verified by an experimenter and correctedif necessary. Because saccades with saccadic reaction times (SRTs)below 80 msec had a 50% chance of being in the correct directionon pro-saccade trials, all such saccades were excluded as anticipation.Trials with SRTs above 500 msec were excluded as no responsetrials.

To evaluate the relationship between neuronal discharge and specific events (stimulus appearance, saccade initiation), rastersof neuronal discharge and continuous activation waveforms wereconstructed. The activation waveform was obtained by convolvingeach spike with an asymmetric function that resembled a postsynapticpotential (Hanes and Schall, 1996; Thompson et al., 1996; Dorrisand Munoz, 1998; Everling et al., 1998a):

(1)

where the activation level A as a function of t varies according to $tau$ _g, the time constant for the growth time that was setto 1 msec, and $tau$ _d, the time constant for the decay time that wasset to 20 msec. This asymmetric activation waveform, which isdesigned to mimic an excitatory postsynaptic potential, is physiologicallymore plausible than the plain Gaussian activation function (Richmondand Optican, 1987), because a spike exerts an influence only forwardand not backward intime.

For the quantification and comparison of neuronal activity between pro-saccade and anti-saccade trials on a single trial basis,each spike train was replaced with the postsynaptic activationfunction (Eq. 1) with a binwidth of 1 msec (Fig. 2). The meanactivity of a single neuron was calculated by averaging the singletrial activities.

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Figure 2. Quantification of neuronal activity on a single trial. A-E, Analysis epochs (see Materials and Methods for details). Eh, Horizontal eye position; FP, fixation point; S, stimulus; SRT, saccadic reaction time.

Neuronal activity was quantified in several epochs (Fig. 2). To quantify the neuronal activity during the instruction period(fixation of the red or green FP) on pro-saccade and anti-saccadetrials, the activity during the 400-200 msec interval before presentationof the stimulus was calculated for correct pro-saccade and anti-saccadetrials (Fig. 2, A). Overlap trials and gap trials were combined,because during this epoch the stimulus conditions and the instructionswere identical for overlap and gaptrials.

To quantify the gap-related changes in neuronal activity on pro-saccade and anti-saccade trials, the mean activity level inthe interval 40-50 msec after the appearance of the stimulus wasmeasured on gap trials (Fig. 2, B). All SC neurons with stimulus-relatedresponses had latencies >50 msec, as determined by the Poissonspike train analysis developed by Thompson et al. (1996). Thistechnique identified on individual trials the time at which theneural activity deviated significantly from that expected froma random Poisson distribution. We never found stimulus-relatedresponses <50 msec on any individual trials. Therefore, the activityduring the interval 40-50 msec after stimulus presentation reflectedthe activation level before stimulus presentation and was notinfluenced by any changes related to the appearance of the stimulus.To determine the change in neural activity from the activity duringthe instruction period, the average activity in the interval 400-200msec before stimulus presentation was subtracted from the averageactivity in the interval 40-50 msec after stimuluspresentation.

The activity of SC neurons during the gap period is correlated with SRT (Dorris and Munoz, 1995, 1998; Dorris et al., 1997).To examine further the relationship between SRT and prestimulusactivity, trial-by-trial correlations (Pearson product-momentcorrelation coefficient r) between SRT and prestimulus activitylevel in the interval 40-50 msec after stimulus presentation werecalculated for saccade-related neurons with a low-frequency prestimulusactivity (see "Neuron classification" below) on pro-saccade gaptrials and anti-saccade gaptrials.

To quantify the magnitude of the stimulus-related activity of neurons with stimulus-related responses on pro-saccade trialsand anti-saccade trials, the largest peak of activity in the intervalbetween 60 and 120 msec after stimulus presentation was determined(Fig. 2, C). The average activation was measured in a 10 msecinterval extending from 5 msec before to 5 msec after the peak,and the prestimulus activation in the interval 40-50 msec afterstimulus presentation was subtracted as the baseline activityfrom this value. These analyses were performed on overlap trialswith the exclusion of all saccades with SRTs below 125 msec (expresssaccades) (Fischer and Boch, 1983; Edelman and Keller, 1996; Paréand Munoz, 1996) to avoid a contamination of the stimulus-relatedactivity with the saccade-related activity. Neurons that increasedtheir activity >50 spikes/sec above the prestimulus level in theinterval 60-120 msec after stimulus presentation were consideredto have a visualresponse.

To quantify the pre-saccade activity, the average level of activity was measured in the interval 10-20 msec before saccadeinitiation (Fig. 2, D). We consider this interval to encompassthe activity that triggers saccade initiation, because microstimulationexperiments have shown that stimulation of the SC evokes saccadeswith latencies of ~20 msec during visual fixation (Robinson, 1972).The latencies are reduced to ~8 msec when the stimulation occursduring a saccade in midflight (Miyashita and Hikosaka, 1996).We also tested the intervals 20-30 and 0-10 msec before saccadeinitiation and obtained similarresults.

The endpoints of anti-saccades display a much greater variability than the endpoints of visually guided pro-saccades in humans(Hallett, 1978; Smit et al., 1987). This imposed a potential confoundfor our analysis, because the magnitude of the saccade-relatedactivity of SC neurons depends greatly on the saccadic vector.Saccade-related neurons display a maximum discharge for saccadesinto the center of their response field, and the magnitude ofthe saccade-related response decreases when the vector of thesaccade deviates from this location (Sparks and Mays, 1980; Munozand Wurtz, 1995a). To minimize this confound, we considered forthis analysis only pro-saccades and anti-saccades that landedwithin a radius that deviated only ±20% of the optimal vectorof thesaccade.

To quantify the magnitude of the saccade-related activity of saccade-related neurons on pro-saccade trials and anti-saccadetrials, the largest peak of activity in the interval ±20 msecaround saccade initiation was determined for each neuron in theoverlap condition (Fig. 2, E). Then, the average activity wasmeasured in a 10 msec interval extending from 5 msec before to5 msec after the peak. Also for this analysis, we used only saccadesthat landed within a radius that deviated less than ±20% of theoptimal vector of the saccade (seeabove).

Only neurons with at least five correct anti-saccade trials and five correct pro-saccade trials were considered for theseanalyses. All of the data are expressed as mean ± SEM. For thesample of neurons, the neural activity on pro-saccade trials wascompared with the neural activity on anti-saccade trials witha paired Student's t test or, if a test of normal distributionfailed (Kolmogorov-Smirnov test), with the nonparametric Wilcoxonsigned-rank test. For individual neurons, the neural activityon pro-saccade trials was compared with the neural activity onanti-saccade trials with an unpaired Student's t test. Significancewas accepted at the p < 0.05level.

Neuron classification. Neurons in the SC were separated into four different classes (visual, fixation, buildup, and burst)on the basis of criteria described previously (Goldberg and Wurtz,1972; Munoz and Wurtz, 1993a, 1995a; Dorris et al., 1997). Thisclassification was based on the data obtained in the pro-saccadegap condition. The dorsal surface of the SC was determined asthe electrode depth where visual background activity was firstnoticed. To be classified as a visual neuron in the superficiallayers of the SC, neurons had to be located 0-1.5 mm below thedorsal surface of the SC and had to possess the following dischargecharacteristics: (1) an increase in stimulus-related activity50 spikes/sec above baseline for stimulus presentations into theneuron's response field and (2) no saccade-related activity. Tobe classified as a fixation neuron, neurons had to be locatedfrom 1 to 3 mm below the dorsal surface of the rostrolateral poleof the SC and had to possess the following discharge characteristics:(1) tonic activity >10 spikes/sec during both the visual fixationand the end of gap periods, i.e., while the monkey fixated theFP even when it was removed momentarily and the monkey was requiredto maintain the same eye position (this test excluded visual neuronswith a foveal receptive field); and (2) a pause in activity duringall ipsiversive and most contraversive saccades (Munoz and Wurtz,1993a). To be classified as a buildup neuron, a neuron had tobe located 1-3 mm below the dorsal surface of the SC and possessthe following discharge characteristics: (1) low-frequency prestimulusactivity during the end of the gap epoch (Munoz and Wurtz, 1995a;Dorris et al., 1997) that was significantly greater than duringthe visual fixation epoch (paired t test, p < 0.05); and (2) saccade-relatedactivity above 100 spikes/sec for pro-saccades into the neuron'sresponse field. To be classified as a burst neuron, a neuron hadto located 1-3 mm below the dorsal surface of the SC and to possessthe following discharge characteristics: (1) no significant increasein discharge during the gap period and (2) saccade-related activityabove 100 spikes/sec for pro-saccades into the neuron's responsefield. Both buildup and burst neurons may or may not exhibit visualresponses.

  RESULTS

Behavior

After completion of training in the pro-/anti-saccade paradigm, both monkeys had achieved a stable performance that was significantlyabove chance. Figure 3 shows the distribution of SRTs of bothmonkeys in the four task conditions obtained by pooling the saccadesgenerated during the recording of the neurons in this study. Table1 summarizes the mean SRTs and the percentage of errors in thedifferent task conditions for the two monkeys. As in human subjects(Fischer and Weber, 1992), the SRTs for monkeys were longer foranti-saccades than for pro-saccades. The monkeys generated pro-saccadesand anti-saccades with shorter SRTs in the gap condition thanin the overlap condition. Moreover, the monkeys made more errorsin the anti-saccade task in the gap condition compared with theoverlap condition. A large proportion of these errors occurredat very short SRTs, in the range of express saccades. These errorswere corrected on most of the trials. Incorrect responses in thepro-saccade task, i.e., saccades away from the stimulus, werevery rare.

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Figure 3. Distribution of saccadic reaction times for the two monkeys in the different conditions of the pro-/anti-saccade paradigm. The bin width is 10 msec. The white bars show correct responses, and the black bars show direction errors.


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Table 1. Mean saccadic reaction times and percentage of errors in the pro-/anti-saccade paradigm

Neuronal activity

Figure 4 shows the discharge of typical individual neurons. The activity of a single visual neuron recorded in the left SCin the pro-/anti-saccade paradigm is shown in Figure 4A-D. Ontrials in which the stimulus was presented in the neuron's responsefield, the neuron displayed several phasic stimulus-related burstsin discharge on pro-saccade trials (Fig. 4A,C, left panels) andanti-saccade trials (Fig. 4A,C, right panels). The magnitude ofthe stimulus-related response was reduced on anti-saccade trials.The neuron did not display any increase in discharge when thestimulus was presented ipsilateral to the neuron's response field,regardless of whether the saccade was generated ipsilateral tothe response field on pro-saccade trials (Fig. 4B,D, left panels)or in the response field on anti-saccade trials. (Fig. 4B,D, rightpanels).

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Figure 4. Activity of superior colliculus neurons in the pro-/anti-saccade paradigm. A-D, Activity of a visual neuron that was located in the left SC, 0.4 mm below the dorsal surface, and the stimulus was presented 7° right and 7° up (A, C, stimulus contralateral) or 7° left and 7° down (B, D, stimulus ipsilateral). Each dot indicates the time of an action potential relative to stimulus presentation, and each row represents one trial. The trials are sorted according to saccadic reaction times (indicated by $open circle$ ). Superimposed on the rasters is the average activation waveform. The presentation of visual stimuli (FP, fixation point; S peripheral stimulus) is represented by black (gap and overlap condition) and gray (overlap condition) horizontal bars below the rasters. The time of stimulus presentation is indicated by dashed vertical lines. The activity is shown in overlap trials (A, B) and gap trials (C, D) for pro-saccades and anti-saccades. E-H, Activity of a buildup neuron that was located in the left SC, 1 mm below the dorsal surface, and the stimulus was presented 5° right (E, G, stimulus contralateral) or 5° left (F, H, stimulus ipsilateral). I-L, Activity of a burst neuron that was located in the left SC, 1.7 mm below the dorsal surface, and the stimulus was presented 8° right (I, K, stimulus contralateral) or 8° left (J, L, stimulus ipsilateral). M-P, Activity of a fixation neuron that was located in the right SC, 2.6 mm below the dorsal surface, and the stimulus was presented 10° left (M, O, stimulus contralateral) or 10° right (N, P, stimulus ipsilateral). Each time mark indicates 200 msec.

The activity of a single buildup neuron is shown in Figure 4E-H. The neuron had low-frequency activity during the instructionperiod on pro-saccade trials (Fig. 4E-H, left panels). This low-frequencyactivity was almost absent during the instruction period on anti-saccadetrials (Fig. 4E-H, right panels). During the gap period, the neuronincreased its discharge rate on pro-saccade trials (Fig. 4G,H,left panels) and on anti-saccade trials (Fig. 4G,H, right panels).The increase in low-frequency prestimulus activity, however, washigher on pro-saccade trials compared with anti-saccade trials.On trials when the stimulus was presented in the neuron's responsefield (Fig. 4E,G), the neuron displayed a stimulus-related burstin discharge (first peak) on pro-saccade trials (Fig. 4E,G, leftpanels) and anti-saccade trials (Fig. 4E,G, right panels); however,the magnitude of the stimulus-related response was reduced, andthe response decayed on anti-saccade trials. On pro-saccade trials(Fig. 4E,G, left panels), the neuron then discharged a high-frequencyburst of action potentials for saccades into its response field(second peak). On trials in which the stimulus was presented onthe ipsilateral side (Fig. 4F,H), the low-frequency prestimulusactivity was truncated at the time when the neuron showed thestimulus-related burst in discharge after presentation of thestimulus in the neuron's response field. The neuron then remainedsilent on pro-saccade trials (Fig. 4F,H, left panels), whereasthe activity increased on anti-saccade trials (Fig. 4F,H, rightpanels), and the neuron displayed a saccade-related motor burstfor anti-saccades into the response field. The magnitude of thesaccade-related activity, however, was weaker for anti-saccadescompared with pro-saccades (Fig. 4F,H, right panels vs Fig. 4E,G,left panels).

The activity of a single burst neuron is shown in Figure 4I-L. The activity of the burst neuron was very similar to the activityof the buildup neuron, except that the burst neuron by definitiondid not display a significant increase in low-frequency prestimulusactivity during the gap period (Fig. 4K,L). It had a stimulus-relatedburst in discharge on trials in which the stimulus was presentedinto the neuron's response field (Fig. 4I,K; first peak). Themagnitude of this response was significantly greater on pro-saccadetrials (Fig. 4I,K, left panels) than on anti-saccade trials (Fig.4I,K, right panels). The neuron then displayed a high-frequencyburst in discharge associated with pro-saccades into its responsefield (Fig. 4I,K, left panels; second peak), whereas the activitydecayed before saccade onset on anti-saccade trials (Fig. 4I,K,right panels). On trials in which the stimulus was presented ipsilateralto the neuron's response field, the neuron was silent on pro-saccadetrials (Fig. 4J,L, left panels), but it discharged a saccade-relatedburst of action potentials for anti-saccades into the responsefield (Fig. 4J,L, right panels). The saccade-related activitywas weaker for anti-saccades than for pro-saccades.

The activity of a single fixation neuron in the pro-/anti-saccade paradigm is shown in Figure 4M-P. The neuron was tonicallyactive during visual fixation of the FP in the instruction periodon pro-saccade trials (Fig. 4M-P, left panels) and on anti-saccadetrials (Fig. 4M-P, right panels), but this activity was higheron anti-saccade trials compared with pro-saccade trials. Duringthe gap period, the neuron decreased its activity on pro-saccadetrials (Fig. 4O,P, left panels) and on anti-saccade trials (Fig.4O,P, right panels). The neuron then displayed a discrete pausein discharge associated with pro-saccades (Fig. 4M-P, left panels)and anti-saccades (Fig. 4M-P, right panels).

We recorded sufficient data from 114 SC neurons (19 visual neurons, 22 fixation neurons, 40 buildup neurons, and 33 burstneurons) in two monkeys performing the pro-/anti-saccade paradigmfor quantitative analysis. In the subsequent sections, we contrastthe activity of neurons in the pro-/anti-saccade paradigm (1)during the instruction period (for visual, fixation, buildup,and burst neurons), (2) during the gap period (for fixation andbuildup neurons), (3) between prestimulus neural activity andSRTs (for buildup neurons), (4) in magnitude of stimulus-relatedactivity (for visual, burst, and buildup neurons), (5) in levelof pre-saccade activity (for burst and buildup neurons), and (6)in magnitude of saccade-related activity (for burst and buildupneurons). For each stage of analysis, at least five responseswere required in each category. Therefore the number of neuronstested in each analysisvaried.

Instruction period-related neuronal activity

Each trial started with the presentation of a central FP, whose color was the instruction to generate either a pro-saccadeor an anti-saccade on stimulus presentation. Therefore, the monkeysknew before stimulus presentation which type of motor response(pro-saccade or anti-saccade) was required on a given trial andcould potentially use this information to prepare their response,although the direction of the response was not specified at thattime.

We found that fixation during the instruction period on anti-saccade trials was associated with a significant decreased activityof visual neurons in the superficial SC compared with fixationduring the instruction period on pro-saccade trials (Fig. 5A;Table 2). Fixation neurons in the intermediate SC had a significantincrease in activity on anti-saccade trials compared with pro-saccadetrials (Fig. 5B,C; Table 2), whereas buildup neurons showed theopposite discharge behavior (Fig. 5B,D; Table 2). No differencesin instruction period-related discharge were observed betweenpro-saccade and anti-saccade trials in burst neurons (Table 2).

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Figure 5. Activity during the instruction period for the sample of fixation neurons, buildup, and visual neurons. A, The mean discharge rate of individual visual neurons during the instruction period on pro-saccade trials is plotted against the mean activity during anti-saccade trials. Gap and overlap trials are combined. B, The thick solid lines represent the mean spike density on pro-saccade trials, and the dashed lines represent the mean spike density on anti-saccade trials; same as A for fixation (C) and buildup neurons (D). Dashed line, unity line (slope = 1). SE is the SEM discharge rate, averaged from the SEM computed in each bin (1 msec).


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Table 2. Comparison of discharge in pro-saccades versus anti-saccades

Gap period-related neuronal activity

Previous studies (Dorris and Munoz, 1995; Munoz and Wurtz, 1995a; Dorris et al., 1997; Everling et al., 1998c) have shownthat neurons in the SC change their activity during the gap periodon pro-saccade trials: fixation neurons decrease their activityand buildup neurons increase their activity. Half of the trialsin the pro-/anti-saccade paradigm contained a gap period in whichthe FP disappeared 200 msec before the stimulus waspresented.

Fixation neurons reduced their discharge rate during the gap period on pro-saccade trials and anti-saccade trials (Fig. 6A)after a transient increase in discharge after FP disappearancein some fixation neurons (Everling et al., 1998c). The activityof fixation neurons did not differ significantly in this intervalbetween pro-saccades and anti-saccades (Fig. 6B, $open circle$ ; Table 2).

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Figure 6. Activity during the gap period for fixation neurons and buildup neurons. A, The thick solid lines represent the mean spike density on pro-saccade trials, and the dashed lines represent the mean spike density on anti-saccade trials. The vertical dashed line indicates the time of stimulus presentation. B, The mean discharge rate of individual fixation and buildup neurons at the end of the gap period on pro-saccade trials is plotted against the mean activity at the end of the gap period on anti-saccade trials (shaded area in A). One additional buildup neuron (115 spikes/sec pro-saccade activity and 175 spikes/sec anti-saccade activity) was not plotted in B. C, Change in neuronal activity during the gap period for individual buildup neurons and (D) fixation neurons. Dashed line, unity line (slope = 1). SE is the SEM discharge rate, averaged from the SEM computed in each bin (1 msec).

Buildup neurons increased their activity during the gap period on pro-saccade trials and anti-saccade trials (Fig. 6A). Theactivity at the end of the gap period, however, was significantlydifferent between pro-saccade trials and anti-saccade trials (Fig.6B, $black-square$ ; Table 2).

No differences in the change in neuronal activity were found from the instruction period to the end of the gap period betweenpro-saccade and anti-saccade trials in buildup neurons (Fig. 6C;Table 2). Fixation neurons, however, had a significantly strongerdecrease in discharge during the gap period on anti-saccade trialscompared with pro-saccade trials (Fig. 6D; Table 2).

Relationship between SRT and neuronal activity

It was demonstrated previously that the prestimulus activity of buildup neurons predicts SRTs in pro-saccade gap tasks ona trial-by-trial basis (Dorris et al., 1997; Dorris and Munoz,1998). The correlation of prestimulus activity with SRT was significantlygreater for the condition when the stimulus was presented in theneuron's response field as compared with when it was presentedon the opposite side at the mirror position. This finding hasbeen taken as evidence that the prestimulus activity of buildupneurons reflects motor preparation (Dorris and Munoz, 1998). However,because stimulus location and response location are identicalin the pro-saccade task, it remained possible that the decreasein SRTs with an increase in prestimulus activity is the resultof faster stimulus processing and not increased motor preparation.The anti-saccade task allows the dissociation between those twoprocesses, because stimulus and response locations are differentin this task. A negative correlation of the prestimulus activityof neurons contralateral to the saccade with SRTs would supportthe motor preparation hypothesis, whereas a negative correlationbetween the prestimulus activity of neurons contralateral to thestimulus would support the stimulus-processing hypothesis. Ourresults support the motor preparation hypothesis. For anti-saccades,the mean correlation coefficient between SRT and prestimulus activityof buildup neurons in the SC contralateral to the saccade (Fig.7A) was $-$ 0.31 ± 0.05 (range $-$ 0.77 to +0.31), whereas the meancorrelation coefficient between SRT and prestimulus activity inthe SC contralateral to the stimulus (Fig. 7B) was 0.00 ± 0.05(range $-$ 0.63 to +0.76) (t test; t = 4.59, df = 62, p < 0.0001).We also calculated the mean correlation coefficients between prestimulusactivity of buildup neurons and SRT for pro-saccades. For pro-saccades,the mean correlation coefficient between SRT and prestimulus activityof buildup neurons contralateral to the stimulus and saccade (Fig.7C) was $-$ 0.28 ± 0.04 (range $-$ 0.77 to +0.48), and the mean correlationcoefficient between SRT and prestimulus activity in the SC ipsilateralto the stimulus and saccade (Fig. 7D) was 0.09 ± 0.05 (range $-$ 0.38to +0.82) (t test; t = 5.86, df = 70, p < 0.0001). These valuesare similar to those reported previously (Table 3). The correlationcoefficients for pro-saccades and anti-saccades into the neuron'sresponse field (t test; t = 0.47, df = 67, p = 0.64) and the correlationcoefficients for pro-saccades and anti-saccades to the mirrorposition of the neuron's response field did not differ (t test;t = 1.33, df = 65, p = 0.19). Thus, these findings support thehypothesis that an increased prestimulus activity of buildup neuronsin the SC shortens SRTs because of an increased motor preparationand not faster stimulus processing.

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Figure 7. Distribution of correlation coefficients for the relationship between prestimulus activity and SRT in the gap condition for anti-saccades into the neuron's response field (A), anti-saccades to the mirror position (B), pro-saccades into the response field (C), and pro-saccades to the mirror position (D). RF, Response field. The hatched bars represent statistically significant correlations (p < 0.05).


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Table 3. Means of correlation coefficients between SRT and prestimulus neuronal activity

Magnitude of stimulus-related responses

The stimulus-related response of many SC neurons in the superficial layers is enhanced in a pro-saccade task when the stimulusis the target for a saccade compared with a fixation task whenthe maintenance of fixation on the FP is required (Goldberg andWurtz, 1972; Mohler and Wurtz, 1976). In the anti-saccade task,the stimulus acts both as a landmark for the anti-saccade andas a distractor that can elicit an incorrect pro-saccade. To assessthe influence of these task demands on the stimulus-related activityof SC neurons, we compared the peak of the stimulus-related responseon pro-saccade trials and anti-saccade trials for visual neurons(Fig. 8A,B) and saccade-related neurons (buildup and burst neurons)(Fig. 8C,D). All visual neurons in the superficial layers of theSC increased discharge only when the stimulus was presented intotheir response field, regardless of the direction of the subsequentsaccade (for an example, see Fig. 4). The stimulus-related response,however, was higher on pro-saccade trials compared with anti-saccadetrials for the majority of the visual neurons (Fig. 8B; Table2).

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Figure 8. Stimulus-related activity for the sample of visual neurons (A, B) and saccade-related neurons with stimulus-related responses (C, D) in the overlap condition. A, C, The thick solid line represents the mean spike density on pro-saccade trials, and the dashed line represents the mean spike density on anti-saccade trials. B, D, The stimulus-related activity of individual neurons on pro-saccade trials is plotted against the stimulus-related activity on anti-saccade trials (shaded area in A, C). Dashed line, unity line (slope = 1). SE is the SEM discharge rate, averaged from the SEM computed in each bin (1 msec).

Significant stimulus-related activity was found in 56% (23/41) of the buildup neurons and in 48% (16/33) of the burst neurons.All saccade-related neurons with stimulus-related responses hadonly a transient increase in discharge when the stimulus was presentedinto their response field, regardless of whether the monkeys generatedpro-saccades to the stimulus or anti-saccades to the oppositeside (for examples, see Fig. 4). However, of those saccade-relatedneurons with visual responses, the majority had a stronger stimulus-relatedresponse on pro-saccade trials compared with anti-saccade trials(Fig. 8D; Table 2).

Pre-saccade activity

Two extreme hypotheses have been proposed for the contribution of the SC to the generation of anti-saccades: the serial hypothesis(Guitton, 1991) and the bypass hypothesis (Forbes and Klein, 1996).The bypass hypothesis predicts that saccade-related neurons inthe SC ipsilateral to the stimulus are inactive for anti-saccades.To test this prediction, we compared the level of pre-saccadeactivity in burst and buildup neurons in the SC ipsilateral tothe stimulus for pro-saccades and anti-saccades (Fig. 9A). Themajority of burst neurons (Fig. 9B, $triangle$ ; Table 2) and all buildupneurons (Fig. 9B, $black-square$ ; Table 2) had a higher discharge for anti-saccadesthan for pro-saccades in the SC ipsilateral to the stimulus. Thus,saccade-related neurons in the SC ipsilateral to the stimuluswere active for anti-saccades. This finding does not support thebypass hypothesis.

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Figure 9. Comparisons of pre-saccade activity of saccade-related neurons in the overlap condition. A, Mean spike density in the SC ipsilateral to the stimulus on pro-saccade trials (thick solid line) and on anti-saccade trials (dashed line). B, The pre-saccade activity of individual buildup and burst neurons in the SC ipsilateral to the stimulus on pro-saccade trials is plotted against the pre-saccade activity on anti-saccade trials (shaded area in A). C, Mean spike density in the SC contralateral to the movement direction, on pro-saccade trials (thick solid line) and anti-saccade trials (dashed line). D, The pre-saccade activity of individual buildup and burst neurons in the SC contralateral to the movement on pro-saccade trials is plotted against the pre-saccade activity on anti-saccade trials (shaded area in C). E, Mean spike density in the SC contralateral to the movement on anti-saccade trials (thick solid line) and mean spike density in the SC contralateral to the stimulus on anti-saccade trials (dashed line). F, The stimulus-related activity of individual buildup and burst neurons in the SC contralateral to the stimulus on anti-saccade trials is plotted against the pre-saccade activity contralateral to the saccade on anti-saccade trials (shaded area in E). Dashed line in B, D, and F, unity line (slope = 1). SE is the SEM discharge rate, averaged from the SEM computed in each bin (1 msec).

The serial hypothesis predicts similar pre-activity of saccade-related neurons in the SC before pro-saccades and anti-saccades.To test this prediction, we compared the level of pre-saccadeactivity before saccade initiation in burst and buildup neuronsin the SC contralateral to the saccade for pro-saccades and anti-saccades(Fig. 9C). Burst neurons and buildup neurons had a significantlyhigher level of pre-saccade activity on pro-saccade trials comparedwith anti-saccade trials (Fig. 9D; Table 2). This finding doesnot support the serialhypothesis.

Schall and Hanes (1996) demonstrated a fixed level of pre-saccade activity in individual FEF neurons for pro-saccades in acountermanding task. On the basis of this observation, they hypothesizedthat FEF neurons have fixed saccade thresholds and that saccadesare elicited only when this threshold activity level is surpassed.Our findings show that the threshold activity level is differentfor pro-saccades and anti-saccades in the SC. If a fixed saccadethreshold exists in individual SC saccade-related neurons in theanti-saccade task, then the level of pre-saccade activity beforeanti-saccades should never be reached by the stimulus-relatedactivity on correct anti-saccade trials. To test this hypothesis,we compared the stimulus-related activity (without subtractingthe baseline activity) in the SC contralateral to the stimuluswith the level of pre-saccade activity in the SC contralateralto the saccade on anti-saccade trials in burst and buildup neuronswith stimulus-related responses (Fig. 9E,F). All burst neurons(n = 3) and all buildup neurons (n = 18) in the sample had higherstimulus-related activities than pre-saccade activities on anti-saccadetrials (Fig. 9F). Significant differences were found in all threeburst neurons, and in 72% (13/18) of the buildup neurons (t test;p < 0.05). For burst neurons, the mean stimulus-related activitywas 104.7 ± 39.3 spikes/sec (range 37-173 spikes/sec), and thepre-saccade activity was 30.0 ± 15.6 spikes/sec (range 7-51 spikes/sec).For buildup neurons, the mean stimulus-related activity was 182.9± 18.4 spikes/sec (range 80-326 spikes/sec) and the pre-saccadeactivity was 75.9 ± 9.2 spikes/sec (range 13-151 spikes/sec) onanti-saccade trials (paired t test; t = 5.37, df = 17, p < 0.0001).Thus, the stimulus-related activity of SC neurons was higher thanthe pre-saccade activity on anti-saccade trials, although thestimulus-related activity did not elicit asaccade.

Taken together, these results show that neurons in the SC are active during the generation of anti-saccades. However, themarkedly weaker pre-saccade activity before anti-saccades andthe finding that the stimulus-related activity was higher thanthe saccade-related activity on anti-saccade trials suggest thatadditional signals from other brain areas bypass theSC.

Magnitude of saccade-related responses

The anti-saccade task requires the generation of a saccade away from the visual stimulus, to an unmarked spatial location,whereas a pro-saccade is directed toward a visual stimulus. Acommon finding in all saccade-related neurons was that they dischargedfor saccades into their response field, whether the stimulus waspresented in the response field (pro-saccades) or on the oppositeside (anti-saccade).

Figure 10 shows the discharge of a typical burst neuron (A) and a typical buildup neuron (B) aligned on the onset of pro-saccades(left panel) and anti-saccades (right panel). Both neurons displayedstronger saccade-related responses for pro-saccades than for anti-saccades.It should be noted that although the metrics of pro-saccades andanti-saccades were matched for this comparison, the peak velocitieswere lower for anti-saccades than for pro-saccades (Fig. 10) [seealso Smit et al. (1987); Van Gelder et al. (1997); Amador et al.(1998)].

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Figure 10. Comparison of saccade-related activity in two individual SC neurons for pro-saccades and anti-saccades. A, Neural activity of a burst neuron aligned on the onset (vertical lines) of pro-saccades (left panel) and anti-saccades (right panel). Each dot indicates the time of an action potential relative to saccade onset, and each row represents one trial. Superimposed on the rasters is the average activation waveform. The horizontal (Eh) and vertical (Ev) eye positions and the radial velocities ( $E$ ) are shown below. Gray lines indicate individual trials and black lines indicate averages. B same as A, but for a buildup neuron.

To investigate the contribution of saccade-related neurons in the generation of anti-saccades, we compared the magnitude ofthe saccade-related responses of burst neurons and buildup neuronson pro-saccade trials with the magnitude of the saccade-relatedresponse on anti-saccade trials (Fig. 11A). All burst neurons andall buildup neurons in our sample had significantly stronger saccade-relatedresponses for pro-saccades compared with anti-saccades (Fig. 11B;Table 2). Thus, saccade-related neurons in the SC displayed amotor burst for anti-saccades into their response field, but themagnitude of this motor burst was significantly lower than forpro-saccades.

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Figure 11. Saccade-related activity for the sample of saccade-related neurons in the overlap condition. A, The thick solid line represents the mean spike density on pro-saccade trials, and the dashed line represents the mean spike density on anti-saccade trials. B, The saccade-related activity of individual buildup and burst neurons on pro-saccade trials is plotted against the saccade-related activity on anti-saccade trials (shaded area in A). Dashed line, unity line (slope = 1). SE is the SEM discharge rate, averaged from the SEM computed in each bin (1 msec).

  DISCUSSION

In this study, we have provided important new insights into how anti-saccades are prepared. By examining the activity of neuronsin the SC of monkeys performing a pro-/anti-saccade paradigm,we were able to show that anti-saccades were associated with decreasedpreparatory activity (Figs. 4, 5B,D) and increased fixation activity(Figs. 4, 5B,C) during the instruction period before stimuluspresentation. Furthermore, neurons with stimulus-related activityresponded to stimulus presentations into their response field(Figs. 4, 8), regardless of the direction of the impending movement.The magnitude of the stimulus-related response, however, was weakerbefore anti-saccades (Figs. 4, 8). The movement-related activityof SC neurons represented the motor signal for the eye movement(Fig. 4), regardless of the location of the visual stimulus. Themagnitude of the movement-related activity, however, was markedlyweaker for anti-saccades (Figs. 4, 9-11). Taken together, these resultsdemonstrate that the instructional set to generate an anti-saccademodulates the activity of SC neurons. The low pre-saccade activity(Fig. 9) and the weak motor burst for anti-saccades (Figs. 10,11) suggest that although the SC does participate in anti-saccadegeneration, additional movement signals are necessary that presumablybypass theSC.

Prestimulus activity in the SC is modulated by behavioral context

The importance of SC fixation neurons in the maintenance of fixation has been shown by pharmacological (Munoz and Wurtz, 1992,1993b) and microstimulation studies (Munoz and Wurtz, 1993b).An increased post-saccadic enhancement in neuronal activity hasalso been found in some fixation neurons, which has been interpretedas a correlate for the refractory state of the saccadic systemafter visually guided saccades (Munoz and Wurtz, 1993a; Everlinget al., 1998c). In the present study, we have demonstrated thatmany fixation neurons also modulate their activity depending onthe instruction to generate either a pro-saccade or an anti-saccade.The anti-saccade instruction was associated with an increasedactivity of many fixation neurons and with reduced low-frequencyactivity of virtually all buildup neurons. Enhanced fixation activityduring anti-saccade trials could lead to the reduced buildup activityvia intracollicular inhibition (Munoz and Istvan, 1998).

The disappearance of the FP in gap pro-saccade tasks is associated with a decrease in the activity of SC fixation neurons(Dorris and Munoz, 1995; Dorris et al., 1997; Everling et al.,1998c) and an increase in low-frequency activity in SC buildupneurons (Munoz and Wurtz, 1995a; Dorris et al., 1997; Dorris andMunoz, 1998), which may be partly mediated by intracollicularinhibitory connections (Munoz and Istvan, 1998). Our results showthat fixation neurons also decreased their activity on anti-saccadetrials during the gap period to an activity level that did notdiffer from the activity level on pro-saccade trials. Therefore,the activity of fixation neurons alone cannot account for theattenuated activity in buildup neurons at the end of the gap periodon anti-saccade trials compared with pro-saccadetrials.

The intermediate layers of the SC receive direct afferents from many cortical areas (for review, see Sparks and Hartwich-Young,1989). Moreover, cortical signals can reach the SC indirectlyby a pathway that includes the caudate nucleus and the substantianigra pars reticulata (SNpr) (for review, see Hikosaka and Wurtz,1989). It is likely that the modulation of prestimulus activityduring the instruction period and the gap period between pro-saccadetrials and anti-saccade trials are shaped by these projections.Brain imaging studies in humans (Paus et al., 1993; O'Driscollet al., 1995; Sweeney et al., 1996; Doricchi et al., 1997) haveshown that the performance of an anti-saccade compared with apro-saccade task is associated with an increased blood flow inmany cortical and subcortical areas, e.g., DPC, FEF, SEF, cingulate,posterior parietal cortex, thalamus, and basal ganglia. An importanttonic inhibitory input on SC neurons arises from the SNPr (Hikosakaand Wurtz, 1983, 1985), which in turn is phasically inhibitedby the caudate nucleus. An increased inhibition from the SNprcould account for the reduced activity of buildup neurons duringthe instruction and gap period. Interestingly, it has been shownthat Huntington's disease, which results from the loss of cholinergicneurons in the striatum, is associated with high rates of reflexivepro-saccades in the anti-saccade task (Lasker et al., 1987).

Recently, it has been demonstrated that a high prestimulus activity of buildup neurons at the site in the SC where the stimulusis represented is associated with reflexive saccades toward thestimulus in an anti-saccade task (Everling et al., 1998a). Itwas hypothesized that when a visual stimulus is presented in theresponse field of buildup neurons that already have a high levelof prestimulus activity, the visual burst may trigger a saccadedirectly (see below). Taken together, the increased prestimulusactivity of fixation neurons during the instruction period andthe decreased prestimulus activity of buildup neurons on anti-saccadetrials may reflect different preparatory sets (Evarts et al.,1984) that are necessary to preset the oculomotor system to allowfor the preparation of an anti-saccade saccade by reducing theprobability of an automatic pro-saccade.

Stimulus-related activity in the SC is modulated by behavioral context

Recently, it was demonstrated that stimulus-related activity was independent of movement direction in the primary motor cortex(Requin and Riehle, 1995; Riehle et al., 1997). In these studies,monkeys had to move a pointer toward a peripheral visual stimulus(congruent movement) or in the opposite direction (incongruentmovement), depending on the color of the stimulus. These resultswere interpreted as evidence for an automatic activation of thecongruent response (Riehle et al., 1997), and as evidence fora partial transmission from visual to motor cortical areas beforethe incongruent movement was programmed (Requin and Riehle, 1995).

We suggest that the stimulus-related activity of burst and buildup neurons in the SC on anti-saccade trials also representsan automatically activated congruent response. This assumptionfollows the recently proposed hypothesis that the visual responseof SC neurons in the intermediate layers can be viewed as a motorburst that fails to elicit a saccade (Sommer, 1994; Edelman andKeller, 1996; Dorris et al., 1997). Although sensory in its origin,the visual burst and the motor burst of saccade-related neuronsare simply action potentials from the same neuron, which makesit impossible for the recipient neurons to differentiate betweena visual and a motor signal. The hypothesis is supported by twofindings: (1) the stimulus-related response is lower than thesaccade-related response in these neurons, and (2) express saccades,which have reaction times <125 msec, are preceded by only oneburst, which occurs at the same time as the visual burst, butwith a greater magnitude (Edelman and Keller, 1996; Dorris etal., 1997).

The weaker stimulus-related responses on anti-saccade trials than on pro-saccade trials could represent a mechanism that reducesthe risk of generating a pro-saccade with express-saccade latencybefore the anti-saccade is programmed. Further work is neededto understand the sources of the modulation of stimulus-relatedresponses in SC neurons. One possibility is that the responsesare weaker on anti-saccade trials because of an increased inhibitionof saccade-related neurons before stimulus presentation. Our findingsof differences in the prestimulus activity between pro-saccadeand anti-saccade trials support this possibility. Another possibilityis a reduced visual input on anti-saccade trials. Our findingof reduced stimulus-related responses in superficial SC neuronsmay indicate a reduced activity in the visual cortex on anti-saccadetrials, because the superficial SC receives afferent projectionsfrom the striate (Weyand et al., 1986) and extrastriate visualcortex (Huerta and Harting, 1984). Alternatively, the reducedstimulus-related response of SC neurons may be the result of increasedinhibition signals at the time of stimulus presentation on anti-saccadetrials. Schlag-Rey et al. (1997) reported that SEF neurons havestronger visual responses on anti-saccade trials compared withpro-saccade trials. They proposed that this could reflect a roleof the SEF in the inhibition of quick reflexivesaccades.

Role of the SC in the generation of anti-saccades

The serial hypothesis for anti-saccades (Guitton, 1991) proposed that SC neurons receive direct and indirect cortical inputsvia the basal ganglia and in turn send the motor command for theanti-saccade to the preoculomotor neurons in the brain stem. Incontrast, the bypass hypothesis (Forbes and Klein, 1996) proposedthat the SC is inhibited during the preparation and generationof anti-saccades and that the motor command for the anti-saccadebypasses the SC by direct projections from frontal cortex to thebrain stem. On the basis of our results, we can reject the bypasshypothesis. SC neurons provide a movement signal for anti-saccades.However, although SC saccade-related neurons are active for anti-saccades,their low level of pre-saccade activity before an anti-saccadeis presumed to be insufficient to trigger thesaccade.

The generation of a saccade requires the suppression of omnipause neurons (OPNs), which act as a tonic inhibitory gate forthe brain stem saccade generator (for review, see Moschovakiset al., 1996). OPNs are inhibited polysynaptically by SC saccade-relatedneurons (Raybourn and Keller, 1997). The low pre-saccade dischargebefore an anti-saccade may be insufficient by itself to suppressOPNs, and additional suppression signals are likely needed. Theseadditional signals may arise from FEF or SEF neurons that alsoproject to the brain stem saccade burst generator (for review,see Schall, 1997). A compensatory trigger input from SEF neuronsis supported by the higher level of pre-saccade activity in SEFneurons for anti-saccades compared with pro-saccades (Schlag-Reyet al., 1997).

If additional signals not only bypass the SC to trigger an anti-saccade but also during an anti-saccade, then these findingsare likely to have important implications for current models ofsaccade generation and control. Several recent models have placedthe SC within a feedback loop controlling saccade accuracy (Waitzmanet al., 1988, 1991; Droulez and Berthoz, 1991; Munoz et al., 1991,1996; Lefèvre and Galiana, 1992; Optican, 1994; Munoz and Wurtz,1995b). In these models, the SC sends a motor error signal tothe saccade generator in the pons, and a signal is fed back tothe SC to allow a comparison between current and desired eye positionto control the amplitude of the saccade. If movement signals bypassthe SC during saccade generation, it would suggest that eitherthe SC is located upstream of the feedback mechanism, or morelikely, the feedback control mechanisms may be distributed andinvolve multiple structures and parallel systems (Quaia et al.,1998). Further experimentation is required to test these hypothesesexplicitly.

In summary, we have shown that the instructional set to generate either a pro-saccade or an anti-saccade modulates the activityof SC neurons. The results further demonstrate that the SC generatesa motor signal for the anti-saccade as predicted by the serialhypothesis, but additional trigger signals, which bypass the SC,are also likely needed for the generation of correct anti-saccades.

  FOOTNOTES

Received Sept. 1, 1998; revised Nov. 11, 1998; accepted Jan. 17, 1999.

This work was supported by a Collaborative Research Grant from the National Sciences and Engineering Research Council of Canadato R.M.K. and D.P.M. S.E. was supported by a postdoctoral fellowshipfrom the Deutsche Forschungsgemeinschaft. M.C.D. was supportedby a Queen's Graduate Fellowship. D.P.M. is a research scholarof the EJLB foundation and a Medical Research Council of CanadaScientist. We thank A. Lablans for her outstanding assistancein monkey training, and K. Moore and D. Hamburger for computerassistance. I. T. Armstrong, B. D. Corneil, E. Olivier, and A.Spantekow commented on an earlier version of this manuscript.We gratefully acknowledge the helpful comments of the anonymousreferee.
Correspondence should be addressed to Dr. Douglas Munoz, Department of Physiology, Queen's University, Kingston, Ontario,Canada, K7L3N6.

Dr. Everling's present address: Department of Experimental Psychology, Oxford University, South Parks Road, Oxford OX1 3UD,UK.

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