Role of the Primate Superior Colliculus in the Control of Head Movements

doi:10.1152/jn.00258.2007

Role of the Primate Superior Colliculus in the Control of Head Movements

Mark M. G. Walton¹, Bernard Bechara³ and Neeraj J. Gandhi¹^,2^,3^,4

¹Departments of Otolaryngology, ²Neuroscience, and ³Bioengineering and ⁴the Center for the Neural Basis of Cognition, University of Pittsburgh, Eye and Ear Institute, Pittsburgh, Pennsylvania

Submitted 7 March 2007; accepted in final form 18 June 2007

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

One important behavioral role for head movements is to assistin the redirection of gaze. However, primates also frequentlymake head movements that do not involve changes in the lineof sight. Virtually nothing is known about the neural basisof these head-only movements. In the present study, single-unitextracellular activity was recorded from the superior colliculuswhile monkeys performed behavioral tasks that permit the temporaldissociation of gaze shifts and head movements. We sought todetermine whether superior colliculus contains neurons thatmodulate their activity in association with head movements inthe absence of gaze shifts and whether classic gaze-relatedburst neurons also discharge for head-only movements. For 26%of the neurons in our sample, significant changes in averagefiring rate could be attributed to head-only movements. Mostof these increased their firing rate immediately prior to theonset of a head movement and continued to discharge at elevatedfrequency until the offset of the movement. Others dischargedat a tonic rate when the head was stable and decreased theiractivity, or paused, during head movements. For many putativehead cells, average firing rate was found to be predictive ofhead displacement. Some neurons exhibited significant changesin activity associated with gaze, eye-only, and head-only movements,although none of the gaze-related burst neurons significantlymodulated its activity in association with head-only movements.These results suggest the possibility that the superior colliculusplays a role in the control of head movements independent ofgaze shifts.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Over the last several decades, much neurophysiological workhas been done to clarify the role of the superior colliculus(SC) in the generation of saccadic eye movements. This structureis also known to be involved in coordinated eye-head gaze shifts.For example, numerous studies have shown that microstimulationof SC evokes movements of both the eyes and head in both cats(Guillaume and Pelisson 2001, 2006; Munoz et al. 1991; Pareet al. 1994; Roucoux et al. 1980) and monkeys (Freedman et al.1996; Klier et al. 2001). In addition, the activity of singleSC neurons, particularly of the classic gaze-related burst cells(sometimes referred to as "burst neurons" in this report), iswell correlated with gaze amplitude (Freedman and Sparks 1997a;Munoz et al. 1991). Data from a variety of species have ledto the idea that the role of this structure in the control ofgaze is part of a more general role in the control of orientingmovements. Stein and Clamann (1981) stimulated the SC in catand found a topographic map of pinna movements in register withthe map of saccadic eye movements. Stimulation of the optictectum in goldfish evokes not only eye movements but also movementsof the tail (Herrero et al. 1998). In rodents, stimulation ofSC evokes a whole-body circling response (Tehovnik 1989; Tehovnikand Yeomans 1986). In the bat, stimulation of SC not only evokesmovements of the pinnae and head but also sonar vocalizations(Valentine et al. 2002). In the primate SC, a number of studieshave reported neural activity that is correlated with arm movements(Kutz et al. 1997; Stuphorn et al. 1999, 2000; Werner 1993;Werner et al. 1997). Stimulation of the cat SC during ongoingreach movements induces perturbations in mid-flight (Courjonet al. 2004).

Data also exist to support the notion that the SC has accessto head movement control circuitry. Anatomical studies havedemonstrated tecto- and tectoreticulospinal projections (Cowieet al. 1994; Huerta and Harting 1982; May and Porter 1992; Robinsonet al. 1994). In terms of electrophysiological evidence, Corneilet al. (2002) reported that when SC was stimulated at currentlevels below the threshold to evoke gaze shifts, head movementswere sometimes evoked in the absence of a gaze shift [i.e.,vestibuloocular reflex (VOR) gain of one]. These authors alsoreported that subthreshold stimulation evokes neck muscle electromyographicactivity (Corneil et al. 2002, 2007). The onset of this activityis time-locked to the visual response of SC during the performanceof a gap task (Corneil et al. 2004). Petit and Beauchamp (2003)used fMRI to study head movements in humans. These authors reportedthat head-only movements were associated with activation ofa number of areas, including frontal eye fields, supplementaryeye fields, intraparietal sulcus, precuneus, MT, basal ganglia,thalamus, and SC, suggesting that head-only movements may besubserved by many of the same areas that control saccades. Althoughthese studies do not convincingly establish a role for SC inthe control of head movements independent of gaze shifts, theydo at least suggest the possibility.

Humans and monkeys do sometimes make head movements withoutgaze shifts. Humans do this frequently, such as when shakingthe head to indicate "no" or nodding the head to indicate "yes"while speaking to another person. Monkeys may make head movementswithout gaze shifts as part of displays of aggression and/orwhen biting off a chunk of food while fixating on a distanttarget. When the eyes are at somewhat eccentric orbital positions,such head movements could be used to more favorably orient thepinnae toward the current target of visual fixation and restorethe eyes to a more optimal, central orbital position. It ispossible that SC might play a role in the generation of suchmovements.

Although none of the available data demonstrates unambiguouslythat SC is involved in the generation of head movements independentof gaze shifts, this possibility is worth investigating. Theissue, unfortunately, is difficult to address using standardbehavioral tasks that elicit coordinated eye-head gaze shifts.The problem is that the eyes and head are temporally coupled,which makes it difficult to demonstrate that single-unit activityis truly related to head movements and not eye or gaze. Thisproblem is particularly difficult to address because the relationshipbetween eye and head movements during gaze shifts is highlylawful and consistent (Freedman and Sparks 1997b).

With these considerations in mind, we have devised a seriesof behavioral tasks that dissociate movements of the eyes andhead. Monkeys were trained to make eye movements without headmovements, head movements without gaze shifts, and coordinatedeye-head gaze shifts. Using these tasks, we sought to determinewhether the SC contains neurons that discharge in associationwith head movements in the absence of gaze and whether saccade-relatedburst neurons also fire for head movements.

Portions of these results have been published previously inpreliminary form (Gandhi and Walton 2006).

METHODS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Two male macaque monkeys (Macaca mulatta) were used. Approvalfor this study was granted by the Institutional Animal Careand Use Committee for the University of Pittsburgh, and allprocedures were in compliance with guidelines of the PublicHealth Service Policy on Humane Care and Use of Laboratory Animals.Each monkey initially underwent sterile surgery to implant aTeflon-coated coil of wire underneath the conjunctiva of oneeye to monitor gaze position using the magnetic search coiltechnique (Fuchs and Robinson 1966; Judge et al. 1980) and toaffix a stainless steel post to the skull to permit head restraint.This head post was also used as a base to which a miniaturelaser module (Edmund Optics, Model No. P57-100) was mountedduring experiments (Gandhi and Sparks 2001). This laser wasused to provide the animal with visual feedback regarding hishead position during some of the behavioral tasks (see followingtext). A second coil of wire was then implanted in the bonecement to monitor head position. After these procedures, theanimals were trained for 4–6 mo on the tasks describedin the following text. After the animals had attained proficiencyon these tasks, a second surgery was performed to prepare forneurophysiological recording. A single stainless steel chamberwas positioned over a 15-mm hole trephined in the skull. Ineach animal, the chamber was roughly centered on the midlineand tilted 38° with respect to the coronal plane, such thatthe electrode penetrations were approximately orthogonal tothe SC surface.

Single-unit recording

Tungsten microelectrodes (Microprobe) were used to record extracellularactivity from the intermediate and deep layers of SC. On-line,the SC was identified by the presence of distinctive burstingof background activity associated with flashes of room lightsand gaze shifts, stimulation-evoked gaze shifts, and recordingsof typical gaze-related burst neurons and buildup cells.

Behavioral tasks and visual display

Data acquisition was accomplished through the use of customsoftware written in LabView running the Real Time module (Bryantand Gandhi 2005). Targets were presented on a cylindrical, tri-statelight-emitting diode (LED) board spanning 96° horizontallyand 80° vertically. LEDs were spaced 2° apart.

Head-movement-related activity was primarily assessed usinga series of eye-head dissociation tasks (Fig. 1). These beganwith the appearance of a red LED to which the monkey was askedto align the laser spot within 3 s. Next, a green LED was illuminatedat a second location, and the animal was required to look tothe new target without allowing the laser spot to move >5–7°away from the red LED (hereafter referred to as an "eye-onlymovement"). For some trial-types (Fig. 1A), the red target wasextinguished and the green target changed to red. Because theanimal was required to continue looking at this target afterthe color change, completion of this stage required a head movementwithout a change in gaze (hereafter referred to as a "head-only"movement). Fixation of both head and eye was then required fora variable period (generally 800-1,200 ms). For the head-onlytask, the animal was then rewarded. On other trials, referredto as head-only-gaze trials, the animal was required to performan additional gaze shift to earn the reward. In this case, thered LED was extinguished simultaneously with the appearanceof a yellow target at a new location. Reward was contingentupon looking to the location of this target and maintenanceof fixation for a variable period. The monkey was permittedto use any combination of eye and head movements to fixate theyellow target. This step was implemented several months intothe project as an additional control to address the possibilitythat apparent head-only activity could, in fact, be relatedto anticipation of a reward (Ikeda and Hikosaka 2003). Randomlyinterleaving trials with and without the additional gaze stepprevented the animal from knowing when the reward was comingas he was making head-only movements. An additional advantageof this trial type is that it ensured that the eyes were centeredin the orbits at the time of the gaze shift. For the gaze dissociationtask, instead of the green target turning red and the originalred target disappearing (the signal to initiate a head-onlymovement), the green and red targets and the laser were extinguishedsimultaneously with the appearance of a yellow target at a newlocation. Reward was then contingent on the animal successfullylooking to the yellow target and maintaining fixation for 800-1,200ms. Note that the eye-in-head and head-in-space positions werealigned when the yellow target appeared after a head-only movementbut were dissociated when the yellow target appeared insteadof the cue to initiate a head-only movement.

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FIG. 1. Schematic representation of the "head-only" and "head-only-gaze" tasks (A) and the gaze task (B). In A, the arrows depict 2 different possibilities, a reward (depicted by the drop of water) or the appearance of a yellow target at a new location, resulting in the "head only" and "head-only-gaze" tasks, respectively. A miniature laser (yellow oval), mounted on the head, produces a red spot on a light-emitting diode (LED) board. Green lines indicate the animal's line of sight (gaze). The dashed red line indicates that the laser may be either on or off at this stage of the task. Below the schematic representations of the tasks, eye (blue), head (red), and gaze (green) position traces are shown as a function of time. In each trace, 100 ms are shown before the onset of the movement.

Standard oculomotor tasks performed with the head unrestrained(schematics not shown) were often incorporated with the eye-headdissociation tasks. On the target step task, a green LED wasfirst illuminated, and the monkey was required to fixate itwithin 500 ms. After a variable fixation interval (800-1,200ms), this target was extinguished at the same time that a secondgreen LED was illuminated at a new location. In this task, themonkey was rewarded for directing his gaze to each target whenit was visible. The delay task was similar except that the firstand second targets overlapped by a variable period (typically400-1,000 ms). In this case, the monkey had to maintain fixationon the first target until it was extinguished. In the gap task,the first green target was extinguished 200 ms before the illuminationof the second target. Reward was contingent upon the animallooking to the second target when it appeared. For the targetstep, delay, and gap tasks there were no constraints placedon head position. The animal was free to make any combinationof eye and head movements as long as he looked to each targetat the proper time. These standard oculomotor tasks were alwaysrun in equal proportions and were, collectively, not more than40% of the total trials. However, for two cells, the gap trialswere briefly run in blocks at 100%.

In early recordings, the head-only and gaze dissociation taskswere each run on 30% of the trials with the standard oculomotortasks comprising the other 40% of trials. When the head-only-gazetask was introduced, it was run on 50% of trials with the gazedissociation and standard oculomotor tasks run on 30 and 20%of trials, respectively.

For all trial types, a list of possible horizontal target locationswas randomly combined with a list of possible vertical locationsto yield a wide range of directions and amplitudes. For gazemovements, most target locations fell within the expected movementfield for burst neurons at the site. However, a small numberof trials involved target locations that were expected to beoutside the movement field. To limit anticipatory movements,20–30% of target locations were ipsilateral. For head-onlymovements, targets were chosen from across the ipsilateral andcontralateral visual fields. This was done to avoid making apriori assumptions about the tuning characteristics of putativehead cells. One consequence of this strategy is that we wereable to collect data for movements of many different amplitudesand directions but few repeated movements of the same vector.Note that the locations of eye-only targets were dictated bythe requirements of the head-only trials because, by necessity,eye- and head-only movements used the same target location foreach trial.

Data analysis

Gaze shifts and eye-only movements were identified using velocitythreshold criteria of 50 and 30°/s for onset and offset,respectively. Because head movements are longer, slower, andmore variable than gaze shifts, a more complex algorithm (Chenand Walton 2004) was used to identify head onset and offset.Briefly, onset and offset were determined when a certain percentageof A/D points within a sliding window were found to be above(onset) or below (offset) a 6°/s velocity threshold. Foronset, the optimal criterion was empirically determined to be72/100 A/D points. If, at any point during that window, threeconsecutive points were found to be below the 6°/s threshold,the "count" was reset. For example, consider a 100-ms windowin which the first 5 A/D points were above threshold, the next24 points were below threshold, and the final 71 points wereabove threshold. In this case, the criteria would not be satisfiedbecause the first five points would not count. When the 72/100criterion was satisfied, the onset was defined as the firstpoint within that window that was above threshold. For offset,a similar sliding window was used, except that the optimal criterionwas found to be 16/22 A/D points below threshold. Chen and Walton(2004) have found that this algorithm, in conjunction with appropriatefiltering, detects head movements as small as 1 or 2° withoutfalse positives.

To determine if a neuron exhibited activity associated withhead-only movements, two intervals were selected for comparison.The head-only movement interval was defined as the period beginning10 ms before the onset of the movement and ending at movementoffset. Average firing rate during this period was comparedwith the average firing rate during a 400 ms baseline intervalbeginning 600 ms before head onset. Examination of raw tracesshowed that during this period, the head, eye, and gaze positionswere generally stable. If, on a given trial, the eye or headwas already moving during this period, the trial was not consideredfor this analysis. Activity associated with gaze shifts andeye-only movements was assessed using a similar approach. Inthis case, the 400-ms baseline window started 700 ms beforethe onset of the gaze shift. This was done to exclude preludeactivity that would occasionally be included in the baselineperiod if the same window were used for all movement types.The eye-only and gaze intervals were defined as the period beginning8 ms before the onset of the movement and ending at movementoffset. For each movement (head-only, eye-only, or gaze), thecell's modulation was computed by subtracting the mean baselinefiring rate from the mean firing rate during the movement. Pairedgroups t-tests were used to determine if a cell significantlymodulated its activity in association with head-only movements,eye-only movements, and/or gaze shifts. For these statisticalcomparisons, only contraversive movements were used. Due tothe animals' tendency to make small head movements that wereunrelated to the task, statistical comparisons involving head-onlymovements were only conducted on movements >5° in amplitude.

For some analyses, it was necessary to measure the intervalbetween a sudden change in firing rate and the onset or offsetof a head movement. Burst onset was defined as the point intime at which instantaneous spike frequency first exceeded athreshold, and remained above this threshold for a minimum of100 ms. For most cells, a threshold of 20 spike/s was used.For some cells, however, this was inappropriate due to a higherbaseline firing rate. For these cells, a different thresholdwas empirically set such that burst onsets were never detectedin the absence of gaze or head movements. Burst lead was thencomputed as the number of milliseconds between the onset ofincreased discharge and the onset of the head movement. Positivevalues indicate that the increase in firing rate preceded thehead movement. Analyses involving burst lead and burst timewere only performed on cells that exhibited at least a 30-spike/sincrease in average firing rate associated with the head movementfor the 10% of trials with the largest modulation. Pause onsetwas defined as the point in time at which instantaneous spikefrequency dropped below 10 spike/s and remained below this thresholdfor a minimum of 100 ms. For a trial to be considered, the instantaneousfiring rate over the previous 200 ms had to be consistentlyin excess of 30 spike/s. Pause lead was defined as the numberof milliseconds between pause onset and head onset. Pause offsetwas defined as the point in time at which instantaneous spikefrequency rose to a threshold of 20 spike/s for $≥$ 50 ms.

An inverse distance interpolation algorithm (Sigmaplot 2004,Systat Software) was used to construct filled contour plotswith neuronal activity (number of spikes or average firing rate)plotted as a function of horizontal and vertical amplitude (heador gaze). These plots were used to gain insight into the generaltuning characteristics of each cell.

RESULTS

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

Sufficient data were obtained from 210 neurons to characterizetheir discharge properties with respect to head movements. Neuronswere identified as possible head cells if they significantlymodulated their activity in association with head-only movements,and this modulation could not be more parsimoniously explainedby variables other than head movements (n = 56; see "additionalcontrols" in the following text). In the subsections that follow,the basic discharge characteristics of head cells are firstdescribed followed by an evaluation of their tuning characteristicsduring head-only movements, eye-only movements, gaze shifts,and the head component of gaze shifts. The next section examinesthe discharge characteristics of high-frequency gaze-relatedburst neurons in association with head-only movements. Next,the modulation of all cells during gaze shifts, eye-only movements,and head-only movements are summarized and considered as a functionof their locations within the SC. Finally, potential alternativeexplanations for the present results are considered.

Modulation of collicular activity during head-only movements: basic characteristics

The majority (n = 39; 70%) of these 56 neurons were characterizedby increased discharge rate (typically 50–200 spike/s)during head movements and a lower firing rate (anywhere from0 to 100 spike/s) when the head was stable. After the end ofthe head movement, the activity returned toward baseline. Manywere completely quiescent when the head was not moving. Rasterplots, averaged spike density functions, and corresponding movementwaveforms are shown for one example neuron during head-onlymovements (Fig. 2A), coordinated eye-head movements (Fig. 2B),and eye-only movements (Fig. 2C). Head, eye, and gaze positionsare plotted as a function of time by red, blue, and green traces,respectively. Note that the increased discharge precedes headonset in A and B. Also in these panels, the cell can be seento discharge at a very low rate during the low-velocity headdrifts near the beginning of the plot, then activity ceaseswhen the head is completely stable. Finally, the firing ratedramatically increases in association with the higher velocity,visually guided head movement. After the offset of these headmovements, firing rate declines but does not always return tobaseline because the head often drifted at subthreshold velocitiesafter the end of the movement. For head-only movements (A),these often occurred as the monkey made small adjustments tohead position after the end of the primary head movement tomore precisely align the laser spot with the red LED.

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FIG. 2. Example data for 1 cell that increased its firing rate in association with head movements. Eye, head, and gaze position traces, raster plots, and averaged spike density functions are shown for head-only movements (A), gaze shifts (B), and eye-only movements (C). Data are aligned on movement onset, indicated by the vertical dashed lines. Note that the cell begins to discharge before the onset of the head movement in both A and B. Same color conventions used for Fig. 1.

For some of these cells, upward activity modulation was sometimesobserved in association with the gaze shift itself, in additionto the activity accompanying the head movement, although thegaze-related modulation was much weaker than the high-frequencybursts that characterize gaze-related burst neurons. This canbe seen from the spike density function in Fig. 2B. Activitywas also observed in association with eye-only movements (C),but this result is difficult to interpret because it is likelythat some head cells discharge in association with such movements.

Aligning the head-only data on head movement offset (Fig. 3A)or eye-only offset (Fig. 3C) had little effect other than ashift of the averaged spike density function because similarvector movements generally had highly similar durations. InFig. 2B, data are synchronized on gaze onset so that the readercan see the weak bursts that often accompanied gaze shifts.In Fig. 3B, data are synchronized on the offset of the headmovement associated with the gaze shift so that the reader cansee what this cell does after the end of the head movement.Surprisingly, the spike density function shows no obvious declineafter the offset of the movement. This is due to two factors.First, it should be remembered that there were no constraintson head position when the animals were making eye-head gazeshifts or after these movements. Thus low-velocity head driftsinevitably occurred on some trials after the coordinated eye-headgaze shifts were over. These drifts were not necessarily inthe same direction as the measured head movement and usuallyoccurred after a brief (50–200 ms) period of no movement.Second, the animals were rewarded 800-1,200 ms after the animalfixated the target. Thus the position traces in B include largegaze shifts the animals performed after the end of the trial.A close inspection of the rasters for individual trials in Breveals some trials in which discharge continued beyond themeasured head offset and then decreased and others in whichthe firing rate declined for several hundred milliseconds andthen increased again. The former correspond to trials in whichhead drifts occurred after the offset of the measured head movementand the latter represent increased discharge associated withthe large gaze shifts visible on the right side of the plot.

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FIG. 3. Example data for the same cell shown in Fig. 2. Data are aligned on head movement offset (A and B) or eye-only offset (C). Same format as Fig. 2.

We also isolated neurons that were characterized by the followingproperties: tonic discharge when the head was not moving, anabrupt decrease in firing rate—often a complete cessationof discharge—that was temporally associated with head-onlymovements, and resumption (or increase) in firing rate aroundthe time of head-only movement offset. Low-velocity head driftswere generally associated with decreased firing rate or evencessation of discharge. Data are shown for one example neuronin Fig. 4. In A, the firing rate can be seen to increase asthe low-velocity head drifts slow down and end prior to thevisually guided head-only movement. Then the firing rate abruptlydecreases shortly before the visually guided head-only movementbegins. The averaged spike density function gives the impressionthat resumption was very gradual but a close inspection of therasters for individual trials shows that the cell often returnedto baseline firing rate over a period of 50–100 ms (lookedat over the longer time scales of head movements, this seems"abrupt," and this is what is meant by this term in this manuscript).These "head pauser" cells (n = 17; 30% of 56 neurons) also pausedin association with gaze shifts (Fig. 4B) and sometimes eye-onlymovements (C). However, only one such cell was recorded in therostral portion of SC and satisfied all of the criteria introducedby Munoz and Wurtz (1993)

for classification as a fixation cell.

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FIG. 4. Example data for 1 cell that decreased its firing rate in association with head movements. Data are aligned on movement onset. Same format as Fig. 2. Note that, prior to the head movement, the firing rate abruptly decreased to near 0.

As with Fig. 3, aligning the data on movement offset had littleeffect on the averaged spike density functions for head-only(Fig. 5A) and eye-only data (C). It is important to note, however,that there was only a loose temporal association between headmovement offset and pause end (A). This may be due, in part,to subthreshold drifts that occurred shortly after the end ofthe measured head movement. In A, these drifts are particularlyapparent in the vertical head position traces. In B, data arealigned on head movement offset. The firing rate remained ata low rate after the end of the measured head movement, evenwhen the head was stable.

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FIG. 5. Example data, aligned on movement offset. Same format as Fig. 3. At approximately the time of head offset, the firing rate abruptly returned to baseline. On gaze trials, the neuron did not always return to baseline after the end of the head movement associated with the gaze shift.

Spatial tuning of putative head cells

Most putative head cells modulated their discharge for a widerange of movements across the contralateral hemifield; few hadcircumscribed movement fields within the limit of head movementswe were able to measure. Figure 6A shows a movement field plotfor one typical cell. Although the trial-to-trial variabilityis high, the average firing rate for this cell is clearly higherfor down-right head-only movements than for movements in otherdirections. To reveal structure that may be obscured by thisvariability, raw movement field plots were converted into filledcontour plots using an inverse-distance based smoothing algorithmin Sigmaplot. Panel B shows an example, computed from the rawdata points shown in A.

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FIG. 6. Movement field plots for an example head cell. Each data point represents a single movement. A: average firing rate during the movement is plotted as a function of horizontal and vertical head-only amplitude. B: filled contour plot constructed from the raw data points shown in A. For this example cell, vectorial head displacement seems to be predictive of firing rate.

Cells that modulated their activity in association with head-onlymovements displayed a variety of tuning profiles. Most increasedtheir firing rate monotonically with amplitude, although thisrelation often saturated for larger head movements. However,varying degrees of directional biases were also observed, rangingfrom weak to quite strong. This can be appreciated from Fig. 7,which shows filled contour plots for three cells that displayedrobust increases in discharge associated with head-only movements.This heterogeneity meant that there was no single curve fittingapproach that was appropriate for every cell. Some cells (forexample, see A) were best described by fitting a quadratic equationrelating firing rate modulation to vectorial amplitude, regardlessof direction. The quadratic fits were used because this relationtended to saturate for large head movements in many cells. Otherneurons (B) were better described by fitting a plane to thehorizontal amplitude, vertical amplitude, and firing rate modulationdata. All 56 putative head cells were analyzed using both ofthese approaches. The results were not strongly affected bywhether the modulation was positive or negative for head movements.The quadratic fits produced significant correlations for 25/56cells (44.6%). Next, planar fits were performed with and withoutan interaction term, as follows: FRmod = y0 + aX + bY and FRmod= y0 + aX + bY + cXY. where FRmod is the predicted modulationof the cells firing rate, X is the horizontal head displacement,and Y is the vertical head displacement. The planar model significantlyaccounted for the firing rate modulation for 26/56 cells (46.4%).Eight cells showed significant correlations for the quadraticfits but not for the planar fits. Average R² values were 0.08± 0.07 (SD) and 0.10 ± 0.10 for the quadraticand planar fits, respectively. For the plane fits, average coefficientsfor horizontal and vertical amplitudes were 0.15 ± 0.50and 0.05 ± 0.06, respectively. Including an interactionterm improved the fit somewhat, yielding an average R² of 0.12± 0.10 but only 25/56 were significant. Average coefficientsfor horizontal amplitude, vertical amplitude, and the interactionterm were 0.06 ± 0.35, –0.16 ± 0.78, and0.001 ± 0.06, respectively.

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FIG. 7. Filled contour plot movement fields for 3 example head cells. Putative head cells had highly heterogeneous tuning profiles with some more sensitive to amplitude than direction (A), some more sensitive to direction (B), and some showing movement fields similar to those for gaze cells in superior colliculus (C).

These analyses were also conducted using the mean firing rateduring the head movement instead of the average modulation.This approach resulted in slightly worse fits for the quadraticequation (R² mean = 0.07 ± 0.06) but improved the planarfits. Average R² values were 0.13 ± 0.11 and 0.15 ±0.12 with and without the interaction term, respectively. Averagecoefficients for horizontal and vertical amplitudes were 0.05± 0.34 and –0.06 ± 0.65, respectively, withoutthe interaction term and 0.06 ± 0.35, –0.08 ±0.84, and 0.001 ± 0.06, respectively, when the interactionterm was used. Using this approach, the distribution of averagefiring rate was statistically accounted for in 34/56 neuronsby the planar model without the interaction term, in 33/56 bythe planar model with the interaction term, and in 25/56 bythe quadratic fit.

For some cells, the timing of discharge was predictive of headdisplacement. To assess this relationship, burst lead was computedas the interval (in ms) between the onset of activity and theonset of the head movement. This analysis could only be performedon cells that strongly increased their activity in associationwith head movements and that displayed a fairly abrupt onsetof activity on a majority of trials (see METHODS for more detail).Ten cells met these criteria and, of these, burst lead was significantlyrelated to head displacement for 8/10 (80%). Two of these cellsshowed more complex effects. Figure 8 shows the relationshipbetween burst lead and head displacement for these two cells.The data were fit with a four-parameter Gaussian

Formula
For the cell shown in the top row (which is thesame cell shown in Figs. 2 and 3), burst lead was strongly predictiveof the amplitude of the vertical component (R² = 0.44) whenthe initial vertical head position was 10° up (A). Burstonset led head onset for horizontal movements and those thatwere slightly down. However, for upward movements, burst onsetgenerally lagged head onset. This relationship, however, disappearedwhen the same analysis was repeated for trials in which thevertical initial head position was 20° up (R² = 0.05; B).Similarly, for the cell shown in the bottom row, burst leadwas predictive of horizontal head displacement (R² = 0.24) whenthe vertical initial head position was 20° up (D), yet norelationship was found when the head started at 10° up (R²= 0.04; C).

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FIG. 8. Relationship between burst timing and head displacement. Data in all panels are fitted with 4 parameter Gaussian functions. Top and bottom: data from 2 different cells. Left and right: data from trials in which the vertical initial head position was 10° up or 20° up, respectively. A and B: vertical burst lead (see text) was highly predictive of vertical head displacement for this example neuron when the head started at 10° up (A) but not when it started at 20° up (B). C and D: for this cell, horizontal burst lead was highly predictive of horizontal head displacement when the initial head position was 20° up (D) but not when it was 10° up (C).

For putative head cells that decreased their firing rate forhead-only movements (n = 17), analyses involving pause durationor pause lead were only performed on cells with $≥$ 15 trials withclearly defined pauses (see METHODS). Seven putative head cellsmet these criteria. Pause duration was significantly correlatedwith head movement duration for 2/7 cells. No relationship wasfound between the timing of the resumption of activity and headdisplacement or the time of head offset. This negative resultmay have been due to slow, subthreshold drifts after the measuredend of the movement. These cells often discharged at a substantiallyreduced frequency or were quiescent during these slow drifts.For 4/7 cells, pause lead was significantly correlated withvertical and/or vectorial head displacement. Figure 9 showsthis relationship for these cells. Note that, for three of thefour cells, the correlation was negative with the cell pausingearlier for small head movements than for large ones.

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FIG. 9. The relationship between pause lead (see text) and head displacement is shown for 4 cells that paused in association with head-only movements. Left: pause lead is correlated with vectorial head displacement. Right: vertical pause lead is correlated with vertical head displacement.

Comparison of movement fields

Next, we compared each putative head cell's movement field responseduring head-only movements, gaze shifts, and the head componentof gaze shifts. Figure 10 illustrates this comparison for oneneuron, and it also demonstrates the difficulties encounteredin performing a robust quantitative analysis. The head-onlymovement field (A) shows, despite the considerable trial-to-trialvariability, clearly higher activity for downward head-onlymovements than for movements in other directions. B shows amovement field for head movements associated with gaze shifts.Activity may appear weaker than that shown in A, but this isdifficult to interpret because these movements were primarilyhorizontal. C shows modulation associated with gaze shifts (i.e.,the same movements used in B) and eye-only movements (not shownin B). Most of the gaze data recorded for this cell involvedlarge-amplitude movements because burst neurons recorded onthis track had movement fields centered near (40, –40).Eye-only data were therefore included in C to show how thiscell responded for small-amplitude movements (that would normallybe accomplished with eye-only movements anyway). This cell showedlittle modulation for gaze shifts, even when they were directeddownward, and no evidence of a gaze movement field.

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FIG. 10. Movement fields for 1 putative head cell. A: average firing rate plotted as a function of horizontal and vertical head-only amplitude. Although much trial to trial variability in firing rate is apparent, the cell clearly discharges at a higher rate for downward head movements. B: average firing rate plotted as a function of horizontal and vertical amplitude of head movements associated with gaze shifts. When contributing to a gaze shift, head movements were mostly horizontal, even if the gaze shift had a substantial vertical component. Nonetheless, the cell was clearly active for head movements of all directions that accompany gaze shifts (i.e., there are very few blue points in this panel). C: average firing rate plotted as a function of horizontal and vertical gaze amplitude. Although the cell does discharge at a low rate during gaze shifts, there was no indication of organization or tuning. Data points shown in this panel include trials from small amplitude eye-only movements and larger amplitude gaze shifts.

We sought to perform a comparison between head-only movementsand head movements associated with gaze shifts. Our monkeyswere trained to make head-only movements in all directions,up to an amplitude of $~$ 30°. Head movements associated withgaze shifts, however, tend to be mostly horizontal, even ifthe gaze shift itself has a strong vertical component (Fig. 10B)(Freedman and Sparks 1997b

). We considered restricting the comparisonto horizontal head movements but, given our current lack ofunderstanding of the neurophysiological basis of eye-head coordination,we couldn't assume that the head movement that accompanies agaze shift is the same as the one requested by SC, a reflectionof the neural uncertainty problem (Sparks 1999

). For these reasons,we did not pursue any statistical comparisons of firing ratebetween the two different types of head movements.

We also attempted to perform direct statistical comparison ofthe movement fields associated with head-only movements andgaze shifts. If a topographic map existed for head-only movements,and, furthermore, if it was in spatial register with the topographicmap known for gaze shifts, we could have compared the responsesfor movements of the same "hot-spot" vector. This approach,however, was quickly deemed futile as we found no topographyfor head movements and no hot-spot vector for head-only movements.In fact, the heterogenous head-only movement fields rarely resembledthe circumscribed movement fields associated with gaze shifts.In the end, we opted for a generalized comparison of modulationin activity for head-only movements and gaze shifts across contralateralmovements. This analysis is presented later, after the characterizationof classic gaze-related burst neurons for head-only movements.

Do classic gaze-related burst neurons modulate in association with head movements?

The data presented so far indicate that the SC contains cellsthat modulate their response in association with head-only movementsas well as during gaze shifts but that the discharge duringgaze shifts is not the classic high-frequency burst that characterizesmany SC neurons (quantitative details to be provided in thefollowing text). Thus the next question to be addressed waswhether neurons displaying high-frequency gaze-related burstsalso discharged in association with head movements. In general,cells displaying high-frequency bursts associated with gazeshifts fired weakly—usually not at all—for head-onlymovements. Rasters and averaged spike density functions areshown in Fig. 11 for one example neuron, along with eye, head,and gaze position traces. On head unrestrained gap trials (B),this cell displayed clear prelude activity and a high-frequencyburst of spikes associated with the gaze shift. The bottom insetshows the mean spike density for the same gap trials alignedon target onset and emphasizes the buildup response (arrow).On head-only trials (A), this cell discharged at low frequency,but this activity was nowhere near as robust as either the preludeor burst associated with gaze shifts. Many cells, particularlyclassic gaze-related burst neurons, did not discharge at allduring head-only movements. This can be seen in Fig. 12, whichshows movement field plots for one cell for gaze shifts (A)and head-only movements (B). This cell was recorded at a relativelyrostral site in the right SC and preferred small gaze shifts( $~$ 8, –5). There was little or no discharge associated withhead only movements. To emphasize this point, average firingrates for head-only movements are plotted on a different scale(Fig. 12B). Indeed, classic gaze-related burst neurons (i.e.,no prelude activity) never significantly modulated their activityin association with head-only movements (see following textfor more details).

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FIG. 11. Example data for a high-frequency gaze related burst cell. Same format as Fig. 2. On gap trials (B), the cell displays a classic buildup of activity prior to the gaze shift. Bottom inset: averaged spike density function for the same trials, aligned on target onset (gap duration = 200 ms). The x and y scales for the inset are the same as for the outer panel. The offset of the fixation target and the onset of the gaze target are denoted by vertical solid and dashed lines, respectively. The arrow shows buildup activity. On head-only trials (A), the cell discharged at a very low rate, but did not show the robust burst of activity that was characteristic of gaze shifts into its response field.

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FIG. 12. Movement field plots for a gaze related, high-frequency burst neuron. A: average firing rate during gaze shifts, plotted as a function of horizontal and vertical gaze amplitude. B: average firing rate during head-only movements, plotted as a function of horizontal and vertical head displacement. In general, this cell was completely quiescent during head-only trials. To emphasize this point, the average firing rate is plotted on a different scale in B.

Comparison of modulation for gaze and head-only movements

Two analyses were conducted across all neurons to compare thelevel of modulation for head-only movements and gaze shiftsand between head- and eye-only movements. The objectives wereto determine if the strength of modulation is different forthese movement types and whether different or overlapping populationsof SC neurons showed significant change in activity for eye-only/gazemovement and head-only movements.

In the first case, a modulation parameter was computed as thedifference in activity during the appropriate movement intervaland its baseline periods, yielding "gaze modulation" or "eye-onlymodulation" and/or "head-only modulation" values for each trial.A paired t-test was applied to the distribution of values inthe two intervals for each type of movement directed into thecontralateral field (see following text). This procedure determinedwhether a given neuron showed statistically significant modulationfor just head-only movements, eye movements (eye-only or gaze)only, both types of movements, or neither. Figure 13A plotseach neuron's mean modulation during gaze shifts against itsmean modulation during head-only movements. The outcome of thestatistical test was used to classify each cell as exhibitingsignificant sensitivity to gaze (red circles), head (blue squares),both (green diamonds), or neither (black stars). As mentionedpreviously, classic gaze-related burst neurons never significantlymodulated their discharge in association with head-only movementsand therefore consistently fell close to the horizontal dashedlines in this figure. In contrast, it was common to find cellsexhibiting gaze prelude activity and/or weak gaze-related burstsin the "both" category. Overall, the modulation associated withgaze shifts was greater than the modulation associated withhead-only movements for neurons in the "gaze" (naturally) and"both" categories (2-tailed t-test; Table 1). Similar resultswere obtained when comparing head-only to eye-only movements(C).

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FIG. 13. Comparison of modulation associated with gaze and eye-only movements to modulation associated with head-only movements. ${square}$ , ${circ}$ , and ${diamond}$ denote cells that significantly modulated their activity in association with movements of the head, gaze, or both, respectively. ${star}$ , cells that did not significantly modulate for either. A and B compare data for gaze and head-only movements. C and D compare data for eye-only and head-only movements. A and C: change in firing rate during the movement in spike/s. B and D: modulation index (see text). Values of 0 indicate no modulation at all; values of 1 or –1 indicate that the cell fired exclusively during or before the movement, respectively.

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TABLE 1. Summary of modulation analyses

In the second analysis, a modulation index was computed as (meanfiring rate during movement –baseline firing rate)/(meanfiring rate during movement + baseline firing rate) for eye-onlymovements, head-only movements, and gaze shifts. Again, a pairedt-test was performed as explained in the preceding text. Thisresulted in slightly different percentages of neurons in thefour categories. Figure 13B compares the modulation indicesof the neurons during gaze shifts and head-only movements, andD compares the modulation indices of neurons during eye-onlyand head-only movements.

In all panels of Fig. 13, the numbers of cells in the four categoriesdo not add up to 210 because cells that significantly modulatedtheir activity in association with head-only movements are shownonly if they were considered to be good head cell candidates(see Additional controls). Furthermore, it must be emphasizedthat these analyses were not restricted to trials that fellwithin the movement field of the cell (if any). For eye-onlyand gaze, all contraversive trials were included; for head-onlymovements, all contraversive movements over 5° in amplitudewere used. This was done because cells displaying head-movement-relatedactivity usually were active for all contraversive head movements.For head-movement-related activity, averaging across the entirecontralateral hemifield appeared to more accurately representthe apparent head movement activity of these cells. An undesirableconsequence was that the modulation associated with eye-onlyand gaze is underestimated in this figure due to the inclusionof trials outside of the movement field. However, because saccade/gazerelated activity in SC has been well described in many studies,we felt that it was more important to accurately represent neuralactivity potentially related to head movements. Restrictingthese analyses to the 10% of trials with the highest firingrate produced more accurate estimates of eye-only and gaze-relatedactivity, but the estimates for some head cells were misleadingbecause the mean was affected too strongly by outliers. Overall,however, the figures were highly similar using these two approaches(data not shown). This "top 10%" approach was also used to assessthe gaze-related activity for the 56 cells that showed significanthead-movement-related activity. When this was done, only 7/56had gaze-related firing rates in excess of 100 spike/s for the10% of trials with the highest gaze-related firing rates. Allseven of these cells displayed prelude activity that began >100ms before gaze onset, and all seven continued to discharge for $≥$ 100 ms after gaze offset. Spike density functions computed forthe peri-gaze period never exceeded 500 spike/s for any of theseseven cells. Thus classic gaze-related burst neurons and head-movementrelated cells represented two distinct, nonoverlapping populationsof cells.

We next examined whether the modulation was a function of thelocation of the neurons, in terms of both the SC map and thedepth from the SC surface. Cells displaying head-movement relatedactivity were found throughout the mediolateral and rostrocaudalextent of SC (Fig. 14A). Typically, they were found between1 and 4 mm below the collicular surface with the greatest concentrationbetween 1 and 2 mm (Fig. 14B). Thus these cells were found intermingledbetween gaze-related neurons. Indeed, we often isolated gaze-relatedburst neurons and head cells in the same penetration, <1mm from each other.

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FIG. 14. Cells with head-movement related activity were found intermingled with gaze-related neurons across the rostrocaudal and mediolateral extent of SC, and were usually found 0.5–2.5 mm below the surface of SC. A: locations of recordings on the SC map. Shape conventions are the same used for Fig. 13. Colors indicate the mediolateral location of each cell on the collicular map. B: estimated depth of each recording below the collicular surface. Color conventions are retained from A.

Additional controls

In our sample of neurons, we found that 87/210 (41%) significantlymodulated their activity in association with head-only movements.However, 19/87 cells were rejected as head cell candidates despitesignificant modulation because the modulation associated withhead-only movements was <10 spike/s for the 10% of trialswith the largest modulation. For example, some cells that wereusually silent during head only movements occasionally dischargedthree or four spikes during these movements. Such cells oftenexhibited a significant modulation only because they never dischargedduring the baseline period. It would be difficult to argue thatsuch neurons are head cells. In addition, 12/87 cells were rejectedas head cell candidates because the modulation was more parsimoniouslyexplained as microsaccade or eye position effects (see followingtext for details). Thus 56 neurons were regarded as putativehead cells.

It is possible that microsaccades may be more likely to occurduring head-only movements than when the head is stationary.If this is the case, a cell that bursts in association withmicrosaccades would show a significant modulation for head-onlymovements in our analysis. To test for this possibility, saccadeonset and offset velocity thresholds were modified (15°/sfor onset and offset) to detect saccades of 0.5–2°.For all but five cells, modulation of firing rate was confirmedin the absence of microsaccades. These five cells clearly dischargedin association with microsaccades and were therefore eliminatedas potential head cells.

Before interpreting the present results as evidence that SCcontains head-movement cells, it is necessary to verify thatthe modulation of activity in the present data are not due tocells carrying eye-in-head signals. During head-only movements,of course, the eyes counter-rotate in the orbits due to theVOR. A cell that encodes the positions of the eyes in the orbitswould therefore significantly modulate its activity in associationwith head-only movements. To test this possibility, we performedregression analyses on the eye-in-head position during the baselineperiod when the eyes and head were stable. The slope of a linearregression line was found to be significantly different fromzero for seven cells. These cells also were eliminated as potentialhead-movement cells.

One must consider the possibility that apparent head movementactivity might, in fact, be a vestibular signal. During ourhead-only movements, the VOR gain was approximately one. Thuschanges in firing rate would be expected for any vestibularcell. To test this possibility, for four cells that showed particularlyrobust modulation associated with head movements, the head wasrestrained and passive, whole-body rotations performed whilethe monkey fixated a target LED. Rotations were performed manuallyin the horizontal dimension at speeds approximating the speedof typical head-only movements. None of the four cells showedany modulation associated with whole-body rotations.

One must also consider the possibility that apparent head-movementrelated activity is a visual response. Potentially, visual responsesmight be observed in response to the laser spot sweeping acrossthe visual field during head-only movements. To test this possibility,the laser spot was turned off during the head only movementin some or all head-only trials once the monkeys had extensiveexperience with the tasks (generally after 3 or 4 mo). The laserwas turned back on when the head passed within 5° of thetarget. For all cells in which these laser-blank trials wereused, the presence or absence of the laser spot was found tohave no effect on firing rate.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
GRANTS
ACKNOWLEDGMENTS
REFERENCES

We have found 56 cells in SC that can be regarded as likelyhead cells. Some (n = 39) increased their firing rate in associationwith head movements, others (n = 17) decreased or even paused.Cells exhibiting high-frequency bursts for gaze shifts generallyshowed little or no modulation associated with head-only movements.However, many cells with significant head-movement-related activityalso exhibited lower-frequency bursts for gaze shifts. For manycells with significant head-movement activity, average firingrate was predictive of head displacement, and many showed biasesfor movements in a particular direction. Furthermore, burstlead was predictive of head displacement for 8/10 cells forwhich a detailed analysis was possible. For two of these cells,the presence of this relationship depended on the initial headposition. The fact that the timing and level of activity ofthese cells is predictive of head-movement parameters supportsthe contention that these cells carry information related tohead movements.

At least two previous studies have reported cells in the catSC that may have been head cells. Straschill and Schick (1977)reported 15 neurons in cat SC that discharged before and duringhead movements. The firing rate of these neurons was correlatedwith head velocity. Peck (1990) described five neurons in catSC that were characterized by bursts of spikes that were temporallyassociated with head movements. Neither of these studies, however,employed a head-only task; thus it is difficult to unequivocallystate that the activity was related to head movements and notgaze shifts. To our knowledge, the present work represents thefirst direct evidence for the existence of head-only signalsin the primate SC.

Potential alternative explanations

As mentioned in the preceding text, cells carrying vestibularsignals would be expected to alter their firing rate in associationwith head-only movements. However, this is unlikely to be thecase for the neurons in our sample for two reasons. First, increaseddischarge usually preceded the onset of the head movement. Second,passive whole body rotation performed on several putative headcells did not produce changes in firing rate.

One might suggest the possibility that increased activity duringhead movements might be a visual response to the moving laserspot. However, turning off the laser spot during head movementsdid not affect the activity of these cells during the movement.It should also be pointed out that the laser spot always sweptthrough the visual hemifield opposite to the direction of themovement. During contraversive head-only movements, for example,the laser spot swept through the ipsilateral hemifield. Thereforeif the present results were attributable to movement of thelaser spot, the firing rate should have been higher for ipsiversivemovements but the opposite pattern was found.

It is also conceivable that the activity could be associatedwith movement of the visual target across the retina duringthe head-only movement. This could occur in either of two ways.First, microsaccades might be more common during the head movement.Such microsaccades might tend to provoke increased activityfrom visual cells. Increased activity associated with microsaccadeshas, indeed, been reported in primary visual cortex and lateralgeniculate nucleus (Martinez-Conde et al. 2002). In the presentdata, however, there were many trials in which head-only movementsoccurred in the absence of detectable microsaccades and robustdischarge was often seen on these trials. Retinal slip wouldalso occur during head movements if the VOR gain is not one.This drift could, potentially, increase the activity of visualcells. However, if this was the explanation for our results,increased activity should have been observed in response topassive, whole body rotation, but this was not the case. Itshould also be pointed out that many of these cells were recordedfrom SC sites encoding large gaze shifts. Visual receptive fieldsat such sites would not be expected to involve the parafovealregion of the visual field. Finally, retinal slip hypotheseswould not explain why changes in discharge rate tended to precedethe head movement.

One must also consider the possibility that apparent head-movementrelated activity is actually associated with covert saccadeplanning (Sparks 1999). During the head-only movement, however,the only target that is consistently visible is one that theanimal is currently fixating. Nonetheless, it is not impossiblethat the animals might be planning a saccade back to the rememberedlocation of the now-extinguished central target. However, thisis unlikely to be the explanation for our results. The headcells we recorded generally displayed stronger activity associatedwith contraversive head movements than ipsiversive movements.If apparent head-movement related activity were the result ofcovert planning of saccades to the remembered location of thecentral target, the opposite pattern of activity should havebeen observed. In fact, the covert planning hypothesis predictsthat "head movement fields" should have been found that closelyresemble gaze movement fields, only reversed (i.e., in the "ipsilateral"hemifield). However, this was not the case. Furthermore, robustmodulation of discharge was often observed during spontaneoushead movements (including head-only movements) during the intertrialinterval.

Cancellation of planned saccades is associated with sharp decreasesin activity in many SC neurons (Pare and Hanes 2003). In ourtasks, prior to the cue to initiate a head-only movement, theanimal does not know whether he is going to be asked to makea head-only movement or a gaze shift. Conceivably, during thisperiod, the monkey might be anticipating, and planning, a gazeshift that he then cancels when it becomes clear that it isa head-only trial. If this is the case, one might see neuralactivity during the dissociation period followed by a pause.Thus one must consider this as a possible alternative explanationfor decreases in activity that temporally coincide with headmovements. However, it must be pointed out that target directionand amplitude were randomized. Gaze targets were presented acrossa wide range of ipsi- and contralateral locations. In addition,the dissociation period was always more likely to be followedby a head-only movement than a gaze shift. For these reasons,we think it unlikely that the animals were planning gaze shiftsduring the dissociation period. It is also not clear why, ifpauses in discharge were due to cancellation of planned saccades,the cells often abruptly started firing again around the timethat the head movement ended. Finally, the fact that pause leadwas often significantly correlated with head displacement suggeststhat decreases in activity were related to the head movementitself.

Another possibility that must be considered is that apparenthead-movement-related activity is associated with microsaccades.It is conceivable that microsaccades might be more common duringhead-only movements and that SC neurons might participate inthe generation of these movements. (Note that this is not thesame as the above-mentioned possibility that microsaccades maylead to visual responses by inducing retinal slip. The questionhere is whether or not SC activity specifically related to microsaccadesmight give the false impression of head-movement activity.)Indeed, five neurons were rejected as head cell candidates forthis reason. These cells were easily identified because robustcorrelations (r > 0.9) were found between burst onset andmicrosaccade onset time. For most of the cells in our sample,robust changes in discharge were often observed during headmovements in the complete absence of detectable microsaccades.Microsaccades were also common during the dissociation periodbefore head-only movements, and no activity was observed forsuch movements for most head cells. The microsaccade hypothesisalso would not explain the relationships between neural activityand head-movement parameters.

It is also possible that SC cells with reward-related activity(Ikeda and Hikosaka 2003) might increase their firing rate duringhead-only movements if the animals come to expect a reward immediatelyafter these movements. However, for most of our cells, one ofour tasks required the animal to make a coordinated eye-headgaze shift after the head-only movement. Thus the animals shouldnot have been expecting a reward at this stage of the task.Even when the head-only movement was not followed by a requiredgaze shift, the animal still had to maintain fixation for 800-1,200ms to obtain the reward. In addition, one would not expect reward-relatedactivity to return to baseline after the head-only movementas it consistently did for our head cells.

Finally, one must consider the possibility that apparent head-movement-relatedactivity might be the result of a task-specific cognitive parameterrather than head movements per se. For example, it might besupposed that the head-only tasks are, in a sense, more demandingthan standard eye-movement tasks. If this is the case, thenchanges in discharge might be associated with increased attention.This seems unlikely because changes in firing rate were alsoobserved in association with coordinated eye-head gaze shifts,which, presumably, are not particularly difficult for the animal.Moreover, many of these cells were recorded in animals thathad many months of experience with these tasks. Finally, formany of our putative head cells, robust changes in activitywere observed in association with head movements during theintertrial interval when the monkeys were, of course, completelyoff task (data not shown).

Possible functional roles of head cells in SC

What role might SC cells play in head-movement control? In viewof the broad tuning of neurons in our sample, one must be cautiousabout assigning an important functional role to these cells.Nonetheless, it is well known that populations of broadly tunedneurons can carry far more information than the activity ofany single neuron. It should also be emphasized that, althoughthe correlation coefficients reported in the present study wouldbe quite low by the standards of most research involving theoculomotor system, they are comparable to those commonly foundin the skeletal motor literature (e.g., Churchland et al. 2006;Werner et al. 1997).

There are many possible roles that head cells in SC might play.At least two studies, (Corneil et al. 2002; Cowie and Robinson1994) have reported that low-frequency, long-duration stimulationevoked head-only movements from some SC sites. The authors ofboth of these studies suggested that SC may carry a parallel"head-only" drive. It is possible that the head-only movementsthat these authors reported might be mediated, at least in part,by cells of the same type reported in the present study. Thusit is possible that SC plays a role in the control of head movementsindependent of gaze shifts.

It is also possible that these cells might carry a corollarydischarge signal from SC to other structures (Sommer and Wurtz2004a,b). For example, accurate eye-head coordination may requireinformation regarding the initial positions of the eyes in theorbits. Head-only movements clearly result in a change in eye-in-headposition. It is not unreasonable to suppose that circuits controlling"head-only" movements might also relay information to the saccadic/gazesystem to update a representation of eye position in head andthat these circuits might involve SC.

With regard to potential functions, the head-pause cells warrantsome discussion. It should be pointed out that there was oftena negative correlation between pause lead and head displacement,a result that seems to argue against a simple "inhibitory gate"role analogous to the role that pontine omnipause neurons playin the saccadic system. Given the more complex musculature ofthe head, however, this should not be surprising. It is alsoworth discussing the observation that the cells resumed dischargeafter head-only movements but often did not after the end ofhead movements associated with gaze shifts. This was true evenwhen the head came to a complete stop. This also suggests thatthese cells should not be thought of as "head omnipause neurons."It is possible that this difference between head-only and head-with-gazemovements is related to the fact that the animal was requiredto maintain a fairly stable head position after the former typeof movement but not the latter.

The present data also may shed some light on the neural basisof head-movement control in general. Head-only movements andhead movements associated with gaze shifts serve entirely differentbehavioral roles. With this in mind, one might be led to hypothesizethat these different types of head movements may be subservedby separate circuits, analogous to the different subsystemsinvolved in the control of eye movements. It is worth pointingout that many of the cells in the present sample clearly modulatedtheir activity in association with both head-only movementsand gaze shifts. If these neurons are, indeed, head cells, thenthe present data would seem to suggest that head-only movementsand head movements associated with gaze shifts share some elementsat the level of the SC.

Gaze coding versus separate eye and head control

In recent years, many studies have explored eye-head coordinationin various brain regions with much disagreement about whetherparticular structures encode the eye and head components separatelyor as a gaze command (frontal eye fields: Bizzi and Schiller1970; Chen 2006