Responses of Macaque V1 Neurons to Binocular Orientation Differences

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (13)

Citing Articles via Google Scholar

Google Scholar

Articles by Bridge, H.

Articles by Cumming, B. G.

Search for Related Content

PubMed

PubMed Citation

Articles by Bridge, H.

Articles by Cumming, B. G.

Previous Article  |  Next Article

The Journal of Neuroscience, September 15, 2001, 21(18):7293-7302

Responses of Macaque V1 Neurons to Binocular Orientation Differences
Holly Bridge¹ and Bruce G. Cumming²
¹ University Laboratory of Physiology, Oxford, OX1 3PT, United Kingdom, and ² Laboratory of Sensorimotor Research, National Eye Institute, National Institutes of Health, Bethesda, Maryland 20892-4435

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Interocular differences in orientation occur during binocular viewing of a surface slanted in depth. These orientation disparitiescould be exploited by the visual system to provide informationabout surface slant, but gradients of positional disparity providean equally effective means to the same end. We examined the encodingof orientation disparities in V1 neurons that were recorded fromtwo awake fixating monkeys. Monocular orientation selectivitywas measured separately in each eye. Although the preferred monocularorientation in the left and right eyes was highly correlated (r= 0.98), 19 of 61 cells showed a significant interocular differencein preferred orientation (IDPO). By itself, an IDPO does not implya specific binocular selectivity for orientation differences.We therefore examined the response to 25 binocular combinationsof orientations by pairing each of five orientations in one eyewith five in the other. Forty-four of 64 neurons showed responsesthat reflected the monocular orientation tuning selectivity; thepreferred orientation disparity changed when the monocular orientationwas changed in either eye. The remaining third (20 of 64) respondedto a consistent orientation disparity in a way that was not simplypredictable from monocular orientation selectivity. However, nearlyall of these neurons were selective for positional disparity,and several characteristics of the responses suggest that theapparent selectivity for orientation disparities was just a consequenceof the positional disparity sensitivity. Neither the data presentedhere nor previous data from the cat (Blakemore et al., 1972; Nelsonet al., 1977) support the idea that a population of neurons earlyin the visual system has a separate encoding scheme for orientationdisparities.

Key words: orientation disparity; positional disparity; energy model; cortical area V1; awake macaque; electrophysiology

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

When a frontoparallel plane is viewed with both eyes, lines on the plane project to images with the same orientation in botheyes. However, when the plane is tilted, the orientations of theelements are no longer matched in the two eyes; there is an interocularorientation difference (orientation disparity). Wheatstone (1838)found that, when observers were presented with lines of differentorientation in the two eyes, the three-dimensional percept wasa line slanted in depth. (Slant is used here to mean rotationout of the frontoparallel plane about a horizontal axis.) Thisobservation does not provide any insight into the underlying mechanismfor perceiving slant that might exploit the orientation disparityor the gradient of positional disparity along the extent of thelines in eacheye.

Several psychophysical studies have attempted to determine whether human observers use these orientation disparities ratherthan positional disparities to detect surface slant (von der Heydt,1978; Ninio, 1985; Mitchison and McKee, 1990; Cagenello and Rogers,1993). Three methods have been used to try to distinguish betweenpositional and orientation disparity mechanisms: (1) putting thetwo types of disparity into conflict (Ninio, 1985), (2) exploitingthe fact that line elements of different orientations containdifferent amounts of orientation disparity (Mitchison and McKee,1990; Cagenello and Rogers, 1993), and (3) attempting to introduceorientation disparities in the absence of consistent positionaldisparities (von der Heydt et al., 1980). No study has been ableto manipulate orientation and position disparities independently(the geometrical relationship between them makes this impossible).For this reason, these psychophysical studies have not led toany clear consensus concerning the role of orientation disparitiesin the perception ofslant.

Approaching the problem from a neurophysiological perspective allows a direct investigation of the underlying neural mechanism.Two distinct populations of neurons early in the visual system,one selective for positional differences and one selective fororientation disparities, would suggest that there are two differentmechanisms for detecting slant. Blakemore et al. (1972) demonstratedthat some binocular neurons in area 17 of the cat possess differentpreferred orientations in the two eyes. We refer to this neuronalproperty as an interocular difference in preferred orientation(IDPO), to distinguish it from orientation disparities, whichare a stimulus attribute. Blakemore et al. (1972) suggested thatneurons with IDPOs were selective for orientation disparities,and hence formed a "second neural mechanism for depth perception."Although Hubel and Wiesel (1973) disputed the experimental observations,they have subsequently been replicated both in area 17 (Nelsonet al., 1977) and area 21a (Wieniawa-Narkiewicz et al., 1992)of thecat.

All of the above studies were performed with anesthetized animals, in which it is possible that some of the results merelyreflected torsional rotation of the eyes under anesthetic. Wetherefore investigated orientation tuning of binocular neuronsin the awake, fixatingmonkey.

Even if IDPOs do occur, they are insufficient to encode orientation disparities. A binocular interaction that depends on theorientation disparity is also required. Consider a binocular neuronthat linearly sums activity from the input of the left and righteyes. Such a sum contains no information at all about the relationshipbetween left and right images, so it is of no more value for depthperception than purely monocular signals. As Wieniawa-Narkiewiczet al. (1992) pointed out, all of the existing data on IDPOs arecompatible with such an additive interaction; it is possible thatbinocular responses reflect the monocular orientation preferenceswithout encoding anydifferences.

Figure 1 illustrates this distinction. It shows idealized responses to many combinations of stimulus orientation in the twoeyes. The left panel is a simple summation of left and right responses,with no further binocular interaction. This produces a left-rightseparable response pattern (it can be separated into a functiondescribing the responses of the left eye and the right eye. Addingthese functions then describes the binocular responses.) The rightpanel shows an interaction that is specific to binocular orientationdifferences; the preferred orientation for one eye depends onthe stimulus orientation in the other eye, and so it is left-rightinseparable. Previous studies of binocular responses (Blakemoreet al., 1972; Nelson et al., 1977; Wieniawa-Narkiewicz et al.,1992) have only manipulated stimulus orientation for one eye,keeping the orientation in the other eye constant. Such data aresingle cross sections through the surfaces shown in Figure 1 andso cannot distinguish the two response patterns.

View larger version (46K):
[in this window]
[in a new window]
Figure 1. An illustration of the difference between separable and inseparable responses to orientation disparities. A shows a response that is possible to predict from the two monocular orientation tuning curves (here the binocular response is simply the linear sum of the two monocular responses). In this case the preferred orientation disparity changes as the monocular orientations are changed. In contrast, the preferred orientation disparity in B remains constant as the monocular orientations are changed. This is a response that cannot be separated into the left and right monocular tuning functions. Only such left-right inseparable responses yield tuning to orientation disparities that does not vary with monocular orientation.

Other properties of neuronal responses have been considered in an attempt to determine the usefulness of these signals forslant perception. Nelson et al. (1977) pointed out that the activityof most neurons was more strongly modulated by positional disparitiesthan by orientation differences and that the bandwidth for tuningto orientation disparities was no narrower than that for monocularorientation. Although these observations suggest that IDPOs maybe of limited value in encoding orientation disparities, theyare compatible with interactions that are either left-right separableor left-right inseparable. Thus, the possible contribution ofIDPOs to the physiological encoding of depth remains unclear.We therefore investigated the extent to which neurons in V1 ofawake fixating monkeys encode orientation disparities. First,orientation tuning was examined in each eye monocularly. Then,binocular responses to a range of combinations of left and rightorientations were measured to determine whether or not the binocularinteraction between them was left-rightseparable.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animal training. Neurons were recorded from three hemispheres of two adult monkeys (Macaca mulatta), one male (Hg) and onefemale (Rb). All of the procedures that were performed on theanimals complied with the United Kingdom Home Office regulationson animal experimentation. The animals were implanted with a headfixation post and scleral eye coils under general anesthetic (Judgeet al., 1980; Cumming and Parker, 1999) and trained to fixatea binocular target for fluidreward.

Stimulus presentation. Stimuli were generated on a Silicon Graphics Indigo workstation and displayed on two cathode ray tubemonitors. Both monitors were gamma corrected to produce a linearrelationship between luminance and the computer gray level settings.The mean luminance was 42 cd.m², contrast was 99%, and the frame rate was 72 Hz. The monitorswere viewed by the animal through two small mirrors (diameter,18 mm) ~2 cm away from the eyes in a Wheatstone stereoscope configuration.The viewing distance to the monitors was 85 cm, and at this distancea pixel on the screen corresponded to 1.0 arc min of visual angle.The red signal was used to present stimuli to the left monitor,and the blue signal to the right monitor, which ensured accuratesynchronization of the binocular images. The stimuli on both monitorswere rendered in black-white monochrome (there was no actual colordifference between the images presented to the twoeyes).

The initial step in plotting receptive fields for the neurons was to find the preferred orientation using a moving bar. Minimumresponse fields were plotted using a flashing, high-contrast barat this preferred orientation. The stimuli were centered on, butlarger than, the minimum response field. Thus, our stimuli willhave covered the receptive field even if our measures of minimumresponse field underestimatedthis.

The main stimulus used in these experiments was a circular patch of sine-wave grating that was drifted across the receptivefield. When measuring disparity tuning, we also used random dotstereograms (RDS). Both types of stimulus were presented againsta mid-gray background. The RDS consisted of equal numbers of blackand white dots. In all experiments, the stimulus was presentedin the receptive field for 2 sec, and spikes were counted overthe entire duration. See Cumming and Parker (1999) for moredetails.

Unit recording. Recording was performed using tungsten in glass microelectrodes (Merrill and Ainsworth, 1972). The electrodewas advanced through the dura and left to rest for a few minutes.Neurons were then found by first withdrawing the electrode untilgray matter was no longer heard and then advancing through thegray matter of primary visual cortex. We examined the relationshipbetween receptive field location and the location of our electrodepenetrations over a 10 × 10 mm² area. There was a clear systematic map that agreed with the knowntopography of macaque primary visualcortex.

Signals from the electrode were amplified (Bak Electronics, Mount Airy, MD) and filtered (200 Hz to 5 kHz) before being digitized(32 kHz) and stored to disk. A Datawave Discovery System was usedto store the spike waveforms and eye position signals, which werethen reanalyzed off-line using software designed in ourlaboratory.

After plotting receptive fields, we measured orientation tuning with a binocular grating at zero disparity. A circular patchof grating extending from 0.5 to 1° beyond the minimum responsefield was used. [Full field gratings were avoided to reduce anystimulus-driven torsional eye movements (Howard et al., 1994).]The preferred spatial frequency was measured at the preferredorientation, and this spatial frequency was used for measuringmonocular orientation tuning curves. The same set of seven orientationswas presented to each eye, centered about the binocular preferredorientation (in six cases, only five orientations were used).Stimuli presented to the left and right eyes were interleaved,and each stimulus was presented a minimum of fourtimes.

Once the monocular orientation preference had been established, binocular interactions were measured. A two-dimensional tuningcurve was constructed in which left and right orientations werealtered systematically and independently. Five orientations foreach eye were chosen to span the range of orientations to whichthe neuron responded. Each of the 25 combinations was presentedat least four times, and all conditions wereinterleaved.

Finally, selectivity for positional disparity was tested with one (or both) of two different techniques. First, a random dotstereogram was used in which disparity was added by shifting thehorizontal position of the dots in opposite directions in thetwo eyes. A minimum of five different disparities, centered aboutzero, was used, and more values were used if necessary to characterizethe tuning curve more thoroughly. Disparity tuning was also measuredwith sine-wave gratings, because this was the stimulus used inall of the other experiments. The position of the circular gratingpatch in both eyes was maintained, whereas the interocular phasedifference was manipulated. Neurons were classified as disparity-selectiveif they were significant at the 5% level on a one-way ANOVA offiring rate with respect to disparity. In addition to this testfor significance, a disparity discrimination index (DDI) was calculatedusing the following equation from Prince et al. (2001):

(1)

where R_max is the largest response rate on the curve, R_min is the minimum response, and RMS_error is square root of the residualvariance across the whole tuning curve. The square root of thefiring rate was used as the response measure in all of these tests(see nextsection).

Analysis. Regression analysis was used to fit equations to the data. However, spike count variance increases with the meancount, violating an important condition for regression analysis.Therefore, all fitting was performed on the square root of thefiring rates, which largely removes this dependence (Cumming andParker, 2000; Prince et al., 2001). (Because the interval overwhich spikes were counted was fixed, this has the same effectas taking the square root of the counts.) Only fits that accountedfor at least 75% of the variance in the square root firing ratewere used for subsequent analysis. Tuning curves for both orientationand disparity were considered to have "significant tuning" ifthe neuronal firing rate was consistently modulated by the changingstimulus parameter. Such modulation was quantified by performinga one-way ANOVA of firing rate with respect to the changingparameter.

Monocular orientation tuning curves were tested for significant tuning with two different tests: first, using a one-way ANOVA;and second, using a test to ensure that a significant componentof the modulated data is smooth. The latter test exploited a sequentialF test (described below) to test that the Gaussian curve was abetter fit to the data than a horizontal straight line throughthe mean spike rate (averaged across all trials). Neurons wereonly included if they were significant at the 5% level on boththe ANOVA and the sequential F test. The analysis of monocularorientation differences required that the tuning in both eyesmeet this criterion. Binocular interactions were examined in neuronsthat met the criterion for at least oneeye.

The monocular tuning data were fit using a nonlinear least square algorithm (numerical algorithms groups) in two differentways. First, two independent Gaussians were fit, one for the lefteye and one for the right eye:

(2)

(3)

where A_l and A_r are the amplitudes for the left and right eye, B_l and B_r are the baseline firing rates, $omega$ _l and $omega$ _r are thepreferred orientations in the left and right eyes, and $sigma$ and $sigma$ are the variances for theleft and right tuningfunctions.

Second, the two sets of data were fit such that they were constrained to have the same preferred orientation, $omega$ (i.e., $omega$ _land $omega$ _r are both replaced with $omega$ ). The fitted curves in this conditionhad one less parameter overall. To test whether there was a significantdifference in the preferred orientation in the two eyes, a sequentialF test was performed to see whether allowing the two preferredorientations to be independent led to a significantly betterfit.

Gaussian curves have been shown to be an adequate description of orientation tuning curves in primary visual cortex of boththe cat and the monkey (Henry et al., 1978; Parker and Hawken,1988). The majority of orientation tuning curves in this studycould be fit with a Gaussian function, although a minority showeddeviations from this consistent with those previously describedby DeValois et al. (1982).

Fitting orientation disparity curves measured binocularly. If the monocular orientation tuning curves are well described byGaussians and the responses to binocular combinations are left-rightseparable, these binocular responses can be described by the sumand product of two Gaussians:

(4)

where A_lr determines the amplitude of the multiplicative component and D is the baselineactivity.

A simple modification to this equation allows it to fit left-right inseparable responses, where this represents a consistentresponse to orientation disparities. This is done by adding arotation term so that the fitted response surface can be elongatedalong a diagonal. In achieving this, Equation 4 becomes:

(5)

where

(6)

(7)

A_u, A_v, A_uv, and D are constants, $sigma$ and $sigma$ are the variancesin the u and v directions, and $phi$ is the angle through which theaxes have been rotated about the point ( $theta$ _L, $theta$ _R). Because thisinvolves adding one parameter to Equation 4, a sequential F test(Draper and Smith, 1998) can be used to give a statistical measureof the need for the rotationterm.

Fitting binocular orientation disparity data with the energy equation. In some cases, we found that neurons responded to morethan one orientation disparity, and Equation 5 produced a poordescription of the data. The form of the responses looked verysimilar to those responses described previously in studies ofthe interaction between left and right stimulus positions (Ohzawaet al., 1997). This is not surprising if the underlying mechanismis like the energy model; the interaction depends only on theresults of convolving the stimulus with the receptive field ineach eye. If changes in orientation produced systematic changesin the value of this convolution in a way that is similar to thechanges elicited by position changes, then one would expect thepattern of binocular interaction to be similar. For this reason,we chose to describe these responses with an equation of the sameform as that used by Ohzawa et al. (1997):

(8)

where A_u, A_v, A_uv, k, and D are constants, $omega$ _l and $omega$ _r are the preferred orientations in the left and right eyes, f is thespatial frequency of the cosine term, and $phi$ is the phase of thecosine term. This cosine term is the main difference between thissurface and the one described in Equation 5, and it allows formultiple peaks or troughs in the surface, rather than the singlepeak afforded by the Gaussian. Both types of fitting to binocularorientation differences were fit using a Levenberg-Marquardt algorithmrun in Matlab (MathWorks Inc., Natick,MA).

Use of sequential F tests. Sequential F tests are used to test whether adding one or more parameters to a linear regressionsignificantly improves the fit of a curve to the data (Draperand Smith, 1998). The residuals from the two fits to be comparedare used to calculate the F ratio, which is of the following form:

(9)

where r₁ is the residual from the fit with a greater number of parameters (p₁), r₂ is the residual from the fit with fewerparameters (p₂), and n is the total number of trials. For eachsituation in which these were used, a Monte Carlo simulation wasperformed to ensure that the frequency with which the null hypothesiswas rejected was appropriate for the significancecriterion.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

A total of 141 V1 neurons were recorded in the two animals. One hundred seven of these were tested for orientation tuningin each eye. The remainder showed weak orientation selectivityto the binocular stimulus or were lost before the monocular datawere collected. One hundred three of 107 neurons showed significantorientation selectivity in at least one eye. Seventy-seven of103 showed significant tuning in both eyes and 26 of 103 weretuned only in oneeye.

To compare the preferred orientation of each eye, it was necessary to restrict the analysis to neurons that were tuned inboth eyes. Of these 77 neurons, 61 had tuning curves that wereadequately described by Gaussian curves in both eyes. Of thoseneurons that could not be described by a Gaussian curve, the majorityhad multiple, smaller peaks away from the preferred orientation,as described previously by DeValois et al. (1982). Figure 2 showsmonocular tuning curves for four neurons with the fitted Gaussianfunctions. The error bars show SEMs. A and B show IDPOs of 1.3and 1.6°, respectively (neither significantly different from 0).C and D show significant IDPOs of 7.9 and 5.6°, respectively.Figure 3 summarizes the comparison of left and right preferredmonocular orientations for all 61 neurons. Although the preferredorientation in the two eyes is highly correlated (r = 0.985),there is a scatter of IDPOs (SD = 9.22). Nineteen of 61 of thesecells have significantly different monocular orientations (sequentialF test; p < 0.05).

View larger version (25K):
[in this window]
[in a new window]
Figure 2. Sample monocular tuning curves for four cells. A and B show two cells in which the two eyes have almost identical tuning. In A, both eyes respond with almost exactly the same response rate, whereas in B the maximum firing rate of the right eye is ~75% of the maximum left eye firing rate. The left and right preferred orientations are significantly different in C and D. The monocularly measured IDPOs are 7.9 and 5.6°, respectively.

View larger version (20K):
[in this window]
[in a new window]
Figure 3. A scatterplot showing the very high correlation (0.985) between the left and right preferred orientations for the 61 V1 cells that are tuned to orientation in both eyes. Those cells showing a significant difference in their preferred orientation are shown with filled symbols, whereas those without any significant difference are shown with open symbols. The three cells in which one of the fitted Gaussian curves is inverted are shown with crosses. The range of differences in monocular preferred orientations (IDPOs) is summarized in the frequency histogram.

Three neurons showed an unusual pattern of results in which the orientations that were excitatory in one eye were suppressivewhen presented to the other eye. An example is shown in Figure4A, along with its disparity tuning curve (B). Note that thisshows suppression for near-zero disparities. This was true forthe disparity tuning curves of all three neurons. This combinationof response patterns suggests that the result of stimulation inone eye is inhibitory, whereas stimulation of the other eye isexcitatory, but that the underlying orientation of the receptivefield is in fact similar in the two eyes. For this reason, thefitted Gaussian was allowed to be inverted, and the cell shownin Figure 4 was deemed to have a small orientation difference.

View larger version (15K):
[in this window]
[in a new window]
Figure 4. A, One of the three cases in which the left and right eyes showed opposite orientation tuning. The orientation that produced maximum excitation in one eye produced maximum suppression in the other eye. In these cases, Gaussian curves have been fitted to both eyes, but an inversion of the curve has been permitted to best describe the data. B, The disparity tuning curve measured using a sine-wave grating for this cell. The minimum response occurs at zero disparity because cell firing is suppressed when both eyes receive the same stimulus.

Bandwidths were calculated by taking half width at half height of the fitted Gaussian curves. The average bandwidth for leftand right eyes is 21.64 ± 13.09° and 19.92 ± 10.84°, respectively.As shown in Figure 5, bandwidths in the left and right eyes aresignificantly correlated (r = 0.33; p < 0.05), although not ashighly correlated as left and right preferred orientation. Thethree neurons that were fit with an inverted Gaussian in one eyewere excluded from this analysis, because the meaning of bandwidthin this case is not clear.

View larger version (18K):
[in this window]
[in a new window]
Figure 5. Left and right eye orientation bandwidths are significantly correlated (r = 0.33; p < 0.05). Neurons with a significant IDPO are represented with filled circles, and those with no IDPO are shown as open circles. The average bandwidths for the left and right eyes are 21.64 ± 13.09° and 19.92 ± 10.84°, respectively.

The determination of complex or simple receptive field types in the awake monkey is complicated by small eye movements. Thereis no consensus as to how best to make this distinction, and nomethod has yet been subject to the close scrutiny that has beenapplied to work using anesthetized animals (Skottun et al., 1991).We used the method of Cumming et al. (1999); responses to driftinggratings were analyzed, but stimulus cycles during which a saccadewas made were discarded. Cells in which the F1:F0 harmonic ratiothat was estimated using this method was greater than one wereclassified as simple, following Skottun et al. (1991). However,cells with an F1:F0 harmonic ratio less than one could be eithercomplex cells or simple cells in which the response has been confoundedby a residual eye movement. Using this method, the mean bandwidthfor the 15 simple cells was 17.94 ± 6.98° for the left eye and19.04 ± 7.18° for the right eye. The corresponding values forthe 43 complex cells were 21.33 ± 9.17° and 18.20 ± 8.13°.

It is worth noting that there was no significant correlation between the measured magnitude of the IDPO and the orientationbandwidth (r = 0.14; p > 0.05). This suggests that the IDPO measuresdo not simply reflect measurement error (which would produce largerdifferences when the bandwidth islarger).

Binocular responses to orientation disparities

The results in the preceding section confirm that interocular differences in receptive field (RF) orientation are presentin monkey V1, as they are in the cat. This does not demonstratethat these IDPOs yield a useful binocular signal about orientationdisparities. We examined this question with binocular stimulicontaining orientation disparities. Binocular responses were examinedin 81 of the 103 cells that showed significant monocular orientationtuning. The other 22 cells were lost after the monocular orientationtuning curves were measured in each eye, but before the binocularexperiment could be completed. The analysis of binocular orientationdisparity encoding depends on fitting the data with one of Equations4, 5, or 8 (see Materials and Methods). For 17 of 81 cells, allof these fits were poor (<75% of variance explained by fit), sothe analysis could not be applied to these cells. Many neuronsfor which the fits to binocular data were poor also showed irregulartuning to monocular stimuli; in 11 of the 17 cases, at least oneof the monocular tuning curves was poorly fit by a Gaussian (<75%of variance explained by the fit). After exclusion of these 17cells, there were 64 cells with adequate data that were well describedby ourequations.

The most common pattern of results is illustrated in Figure 6, A and C. In these surface plots, the neuronal firing rate isrepresented by brightness; low firing rates are shown as darkpatches, and the highest firing rate is shown as white. The responsesare left-right separable. Although the response rate depends onthe stimulus orientation in both eyes, the orientation that elicitsthe maximum response in one eye is independent of the stimulusorientation in the other eye. All of the neurons showing thispattern of results can be fit by a sum and product of Gaussians(Eq. 4). Adding the extra rotation term of Equation 5 did notproduce a significant improvement (p > 0.05) in these neurons.Figure 6D shows an example in which there is an inhibitory binocularinteraction, but the response is still left-right separable, sothis is not specific to the orientation difference. Such a patternwas found in four cells. The three cells for which disparity tuningcurves were available all showed a "tuned inhibitory" patternof responses (Poggio and Fischer, 1977) to positional disparity(like that illustrated in Fig. 4B). Both of these patterns canbe well fit by Equation 4. The fit to Figure 6A is shown in B.

View larger version (51K):
[in this window]
[in a new window]
Figure 6. Three different types of left-right separable response patterns to binocular orientation differences. The level of brightness represents the rate of firing of the neuron; white areas represent high firing rates, whereas dark areas correspond to low firing rates. The most common type of response was that shown in A, with a central peak representing zero orientation disparity. B shows the surface that is fitted to the data. The neuron has the same orientation preference for stimulation of either eye in A. In C, the monocular preferred orientations are different, and the maximum response occurs when the two eyes are receiving different orientations. The pattern shown in D occurred in four neurons and is still left-right separable. The cell is activated when either eye receives its preferred orientation, but it is suppressed when both eyes receive the preferred orientation. Positional disparity tuning data were available in three of these cases, and they all exhibited tuned inhibitory disparity tuning.

This common type of response that is left-right separable does not represent a consistent response to orientation disparities.This is highlighted in Figure 7B, which shows two cross sectionsthrough the two-dimensional surface plot in A and the fit to thissurface using Equation 4. It is obvious that the maximum responsedepends on the monocular orientation tuning, not the orientationdisparity. The maximum response occurs when the right eye receives80° regardless of whether the left eye stimulus is at 90°, whereit represents an orientation disparity of $-$ 10°, or 30°, an orientationdisparity of +50°.

View larger version (18K):
[in this window]
[in a new window]
Figure 7. This figure relates the surface plots to more conventional tuning curves. The monocular orientation tuning curves in A predict that the maximum binocular response to orientation differences should occur when both eyes receive 90°. The data in B is left-right separable because the preferred orientation in the right eye does not change when the orientation changes in the left eye. This is readily seen in the two cross sections through the surface shown in C. The cross section with the solid line shows the tuning to right eye orientation when the left eye orientation is kept constant at 90°. The maximum response occurs when the right eye receives a stimulus of ~80°, an orientation disparity of $-$ 10°. In the second cross section (dotted line), the left eye stimulus is at 30°, and the maximum response still occurs when the right eye stimulus is at 80°, despite the fact that this binocular stimulus has an orientation disparity (od) of 50°. Cells showing this left-right separable response do not show a consistent response to the same od, and the binocular response can be predicted from the monocular orientation tuning.

In addition to the cells described above, there is a further population that does appear to respond consistently to the sameorientation disparity, regardless of the absolute orientationof the left and right stimuli; these responses were left-rightinseparable. An example of such a cell is shown in Figure 8A.In this example, the maximum response occurs when both eyes receivethe same orientation; it appears to be selective for an orientationdisparity of zero. This pattern of response is left-right inseparable,and the fit to these data (Fig. 8B) is achieved by adding a rotationterm to Equation 4. The rotated Gaussian yields a significantlybetter fit (F test, p < 0.05) than the left-right separable Gaussian.The neuron response in Figure 8C was also better fit (C) witha rotated Gaussian, and the preferred IDPO is ~30°. A total of20 neurons showed left-right inseparable response profiles, whichfell into two groups. One group (10 neurons) were fit with theinseparable Gaussian model (Eq. 5, the rotated form of the separableresponse profile). These tended to respond maximally for orientationdisparities near zero, as illustrated in Figure 8A. The secondgroup of 10 cells tended to show a consistent response minimumfor orientation disparities of 0°, with two peaks either side,like the example in Figure 8E. Such response profiles cannot bewell described by the rotated Gaussian of Equation 5 (this modelaccounted for <75% of the response variance), and so Equation8 was used, which provided a much better fit. This fit accountedfor a substantially greater fraction of the response variancethan the inseparable model or the separable model described byEquation 5.

View larger version (62K):
[in this window]
[in a new window]
Figure 8. Three examples of cells that appear to respond consistently to orientation differences. In each pair, the left panel shows the raw data, and the right panel is the surface fitted to that data. The neuron in A responds maximally when both eyes are receiving the same orientation. C shows a neuron that consistently responded to a non-zero od. Both data sets were fitted using Equation 5. The multiple peaks and troughs in the data of E meant that Equation 5 was not adequate to describe the data, and Equation 8 was required.

To summarize, of the 64 neurons that could be well fit with one of the two surfaces, 44 showed the left-right separable responseshown in Figure 6, and 20 were left-right inseparable. These left-rightinseparable responses all indicate a tendency to respond consistentlyto a certain orientation disparity, regardless of the orientationof the stimulus in either eye alone. This suggests a specializationfor signaling orientation disparities. However, several observationsindicate that there may be an alternative explanation. If neuronsare selective for orientation disparity, one would expect thatthe preferred orientation disparity measured with binocular stimuliwould be similar to the difference in RF orientation determinedfrom monocular measures. Figure 9 shows that this is not the case.The monocular measure was calculated from the difference in thepeaks of the Gaussians fitted to monocular tuning curves. Thebinocular measure is simply the orientation disparity of the peakin the fitted response profile. These two measures were not significantlycorrelated (r = 0.26; p > 0.05; n = 45).

View larger version (20K):
[in this window]
[in a new window]
Figure 9. This figure illustrates the relationship between monocular and binocular measures of the IDPO for neurons that are significantly tuned to monocular orientation in both eyes. The histograms are the projection of the monocular and binocular differences. Cells that show separable and inseparable responses are represented as open and filled symbols, respectively. To enter this analysis, a good fit is required for both monocular orientation tuning curves and the binocular orientation disparity tuning, so the number of cells in the plot is reduced to 45. As in previous plots, neurons for monkeys Hg and Rb are shown with circles and squares, respectively.

The effect of tuning for positional disparity

One factor that could produce discrepancies between monocular and binocular measures is disparity tuning. This may influencethe shape of the binocular interaction, without affecting preferredorientation measured monocularly. Figure 10 therefore plots themagnitude of the discrepancy against the extent of disparity tuning.It is clear that the largest discrepancies occur in disparityselective neurons. To quantify this, we measured the varianceof the absolute value of the discrepancy between monocular andbinocular IDPO. This was calculated separately for the group ofdisparity selective neurons (determined by one-way ANOVA; p <0.05) and for disparity unselective neurons. This variance wassignificantly larger for the disparity-selective neurons (F test;p < 0.05).

View larger version (20K):
[in this window]
[in a new window]
Figure 10. The relationship between the disparity discrimination index and the discrepancy between monocular and binocular measures of IDPO. Neurons that showed a left-right inseparable response to orientation disparities are shown with filled symbols; those showing a left-right separable response are shown with open symbols. The largest discrepancies are associated with stronger disparity tuning.

This analysis is only possible in neurons that showed significant orientation tuning in both eyes. A similar analysis canbe extended to the whole population by comparing monocular andbinocular measures of the preferred stimulus orientation for eacheye. The binocular measure is taken from the left and right orientationsat the point of maximum binocular response, and the monocularmeasures are taken from the peaks of the Gaussian fit to the monoculartuning data. The relationship is examined in Figure 11, in whichagain it is clear that the largest discrepancies are associatedwith disparity selectivity. The correlation between the disparitydiscrimination index and the discrepancy in measures of preferredorientation is significant (r = 0.32; p < 0.05).

View larger version (23K):
[in this window]
[in a new window]
Figure 11. The discrepancy between monocular and binocular measures of preferred orientation, as a function of disparity selectivity. The preferred orientation is measured separately for the two eyes, so for all of those cells that are tuned for orientation in both eyes (n = 39), there are two points on the plot. The difference for the dominant eye is indicated by a circle, and the symbol for the difference of the nondominant eye is a square. In those cases where only one of the eyes is tuned for orientation (n = 16), a single point appears on the plot, also indicated by a circle. The discrepancy between the preferred orientation measured monocularly and binocularly is significantly correlated with the disparity discrimination index (r = 0.32; p < 0.05).

Figure 11 also shows that the neurons exhibiting inseparable interactions between left and right stimulus orientations (filledsymbols) tend to show large discrepancies. The mean discrepancybetween the monocular and binocular measures of preferred orientationis 4.8° in neurons that showed separable interactions and 15.6°in those that showed inseparableinteractions.

It is also clear from Figures 10 and 11 that neurons exhibiting left-right inseparable responses tend to show disparity selectivity(significant at the 5% level on a one-way ANOVA for 15 of 17 cases).In contrast, only 22 of the 40 cells that show a left-right separableresponse to binocular orientation disparities are disparity tuned.Together, Figures 9-11 strongly suggest that left-right inseparableresponses like those illustrated in Figure 8 are in some way aresult of tuning for positional disparity. In a few neurons, weexplored this further by measuring binocular responses to orientationdisparities with different positional disparities. Figure 12 showsone example in which two complete binocular interaction profileswere measured. Changing the stimulus disparity had a dramaticeffect on the responses to orientation disparities, invertingthe interaction profile. When the stimulus is at the preferreddisparity of the neuron ( $-$ 0.38°), the optimal orientation disparityis 0°. When the stimulus is at the positional disparity to whichthe neuron responds least (0°, the null disparity), the preferredorientation disparity is neither at 0° nor is it predicted bythe monocularly measured IDPO. Instead, stimuli with zero orientationdisparity produce a minimum in the response.

View larger version (23K):
[in this window]
[in a new window]
Figure 12. These are two binocular orientation disparity tuning curves recorded from the same cell. In A, the stimulus was at the preferred disparity of the cell ( $-$ 0.38°), and in B, the stimulus was at a disparity to which the cell hardly responded (0°). If only A were considered, it would appear that this cell responded consistently to 0° orientation disparity. However, this excitation caused by 0° orientation difference becomes inhibition when the stimulus disparity is changed in B.

The phenomenon illustrated in Figure 12 appears to be general in disparity-tuned neurons. In all cases in which there was aninseparable response that was selective for zero orientation disparity(seven neurons), the stimulus disparity turned out to be nearto the preferred disparity of the neurons. In all cases in whichthere was a response minimum near 0° orientation disparity, thedisparity was near the null disparity of the neurons. We quantifiedthis effect by calculating a simple index of how close a stimulusdisparity (d_stim) fell to the preferred disparity (d_pref) as aproportion of the distance between preferred and null (d_null)disparities. This index, (disparity_stim $-$ disparity_pref)/(disparity_pref $-$ disparity_null , had a strong negative correlation with the magnitudeof preferred orientation disparity determined from our fits (r= $-$ 0.91; p 0.01). This correlation between preferred positionaldisparity and preferred orientation disparity suggests that thepositional disparity tuning determines the orientation disparityto which each neuron appearsselective.

The importance of where rotation is centered

All of these observations (binocular IDPO is poorly correlated with monocular IDPO; the discrepancies are largest in disparity-tunedneurons; and the preferred orientation disparity seems to dependon the positional disparity of the stimulus) suggest stronglythat the left-right inseparable response comes about because ofthe positional disparity sensitivity of the neurons. One possiblereason for this type of response is illustrated in Figure 13, whichshows the consequences of applying an orientation disparity arounda center of rotation that is not centered in the RF. The boxesrepresent vertically oriented receptive fields, the dotted lineis the stimulus to the left eye, and the solid line is the stimulusto the right eye. For illustrative purposes, lines are used ratherthan sine-wave gratings, and the orientation disparity is producedby rotating the stimulus shown to the right eye only. On the leftpanel of Figure 13, the rotation occurs about the center of thereceptive field. However, on the right, the rotation is abouta point at the bottom of the receptive field. This is equivalentto the on-center rotation plus a translation. Because this translationis only applied to one eye, it constitutes a change in horizontaldisparity. The magnitude of the horizontal disparity (illustratedby the arrow) will increase as the angle of stimulus rotationincreases. Thus, off-center rotation leads to a complex interactionbetween binocular phase and binocular orientation differences.

View larger version (10K):
[in this window]
[in a new window]
Figure 13. The schematic diagram in A shows the stimulus on the receptive field when the rotation is performed about the center of the receptive field. The dashed line indicates the orientation of the left eye stimulus, and the solid line shows the orientation of the right eye stimulus. When the stimulus is rotated about the point at the bottom of the receptive field rather than the center (B), there is a translation in the position of the right eye stimulus. Because this translation occurs only in the right eye, it is equivalent to a horizontal disparity. Arrow represents magnitude of horizontal disparity.

To evaluate the effects of this interaction on our binocular measures of IDPO, we ran a simulation using the energy modelof Ohzawa et al. (1990) (H. Bridge, B. G. Cumming, and A. J. Parker,unpublished observations). Our implementation extended the modelto two-dimensional monocular receptive fields, so that the effectsof both orientation differences and positional differences couldbe assessed. The results of this simulation are shown in Figure14, in which two important features emerge. First, the combinationof off-center rotation and disparity selectivity is sufficientto produce a response pattern that is left-right inseparable,in a way that closely resembles that of the single units. Second,the response pattern depends on the stimulus disparity. At thepreferred disparity (A), the maximum response occurs when thestimulus is at the preferred orientation in each eye. When thestimulus is at the null disparity, the same combination of orientationsproduces maximum inhibition (B).

View larger version (48K):
[in this window]
[in a new window]
Figure 14. Rotating the stimulus about a point off the center of the receptive field causes a left-right inseparable response in the output of the energy model. When the stimulus is placed at the preferred positional disparity of the model cell (A), there is excitation along the 0° orientation difference diagonal. This line of excitation becomes inhibition when the disparity of the stimulus is changed to the null disparity of the model cell (B).

In summary, off-center rotation can, in principle, explain the left-right inseparable responses to binocularly measured IDPOsthat we observed in V1 neurons. Furthermore, three specific characteristicsof the data can be explained in the same way. First, maximum excitationat 0° orientation disparity only occurs when the experiment hasbeen performed with the stimulus at the preferred positional disparity,and conversely, there is a trough at 0° orientation disparitywhen the stimulus is at the null disparity. Second, the discrepancybetween the monocular and binocular measures of IDPO is greatestif the neurons are sensitive to positional disparity. Finally,the nature of the binocular tuning to orientation disparity changeswith a change in the stimulus disparity as illustrated in Figures12 (neuronal data) and 14 (energymodel).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

These experiments establish the presence of IDPOs in macaque V1 neurons using a statistical criterion. The use of an awakeanimal avoids the complication of torsional eye movements inducedby anesthesia and paralysis. Nonetheless, we find a range of IDPOssimilar to that reported previously from area 17 of the anesthetizedcat (Blakemore et al., 1972; Nelson et al., 1977). Although doubtshave been raised about the accuracy of the previous measures,this study provides unambiguous evidence of the presence and distributionofIDPOs.

The previous studies investigated only a limited range of binocular conditions. Here we examined responses to all combinationsof left and right orientations, which enabled us to determinewhether there was a specific binocular interaction that encodedthe difference between the stimulus orientations in the two eyes.Previous studies (Blakemore et al., 1972; Nelson et al., 1977;Wieniawa-Narkiewicz et al., 1992) kept the stimulus orientationconstant in one eye. Those data are also compatible with a responsepattern that was produced simply from summing left and right responses,with no mutual binocular interaction. Consequently, these earlierstudies do not demonstrate a binocular mechanism for signalingorientation disparities or surfaceslant.

Around two-thirds (44 of 64) of the V1 neurons recorded showed a left-right separable response to binocular orientation disparities,whereas the other third (20 of 64) showed an inseparable response.However, several characteristics of this latter group suggestedthat their inseparable responses are in fact a consequence ofpositional disparity selectivity: (1) there is a poor correlationbetween the IDPO determined from monocular and binocular measures;(2) these discrepancies were largest in disparity-tuned neurons;(3) neurons showing inseparable responses were disparity-selective;(4) the preferred orientation disparity depended on the positiondisparity of the stimulus, in relation to the preferred disparityof the neuron; and (5) a simple model of disparity-selective neuronsis able to reproduce all of these phenomena. The modeling suggeststhat the inseparable responses occur when the center of rotationfor the orientation disparities is not located exactly at thecenter of the RF. For these reasons, we conclude that even thesmall number of neurons that showed left-right inseparable responsesdo not represent a mechanism specialized for signaling orientationdisparities.

Another feature of the data that suggests that IDPOs are not important in signaling orientation disparities is the fact theyare not correlated with orientation bandwidth. Because orientationdisparities are usually small, cells with narrow orientation bandwidthsare best suited to signaling naturally occurring orientation disparities.Our modeling work suggests that V1 neurons are best able to signalslant through detection of positional disparities. Only neuronswith the narrowest orientation bandwidths could usefully exploitorientation disparities [although even these neurons signal slantmore reliably via positional disparity (H. Bridge, B. G. Cumming,and A. J. Parker, unpublished observations)]. It is very unlikelythat neurons with IDPOs and wide orientation bandwidths contributeto the detection of slant via orientation disparities. Becausewe find IDPOs are not limited to neurons with narrow orientationbandwidths, it is clear that the presence of an IDPO does not,by itself, suggest that a neuron is specialized for detectingorientationdisparities.

These findings also represent a useful test of the energy model of disparity-selective complex cells (Ohzawa et al., 1990).In a modeling study, we show that the energy model predicts aleft-right separable interaction between orientations, very similarto that illustrated in Figure 1A. In the energy model, an outputnonlinearity renders neurons sensitive to the results of multiplyingthe left and right images. By combining the outputs of severalsimple cells with different phase sensitivity, this model generatesresponses to left and right eye locations that are left-rightinseparable. Despite this, the interaction of different orientationsis left-right separable, just as we observe here for real neurons.It is possible that V1 neurons could have encoded orientationand position separately, allowing them to respond to orientationdisparities in ways quite different from those predicted by theenergy model. Indeed, the idea that position and orientation areencoded separately at the monocular stage is implicit in the suggestionthat orientation disparities represent a mechanism that is separatefrom position disparities. We found no evidence of this kind;all of the responses observed to both position and orientationdisparities can be explained by supposing that a single monocularcalculation is performed, which depends on both position and orientation.A simple convolution of the image with a fixed monocular RF, asin the energy model, is sufficient to account for the data. Thislends further support to the view that the energy model providesa good description of the mechanism of disparity tuning in V1(Cumming and DeAngelis, 2001).

The role of cyclovergence

Cyclovergence is the rotation of the two eyes in opposite directions about an axis from front to back through the center ofthe eye. If the stimuli used here elicited substantial cyclovergencemovements, it would complicate the interpretation of these data.There are several reasons to suppose that such movements did notoccur. Because the stimuli were matched in size and orientationto the RF, the orientation disparities applied did not producea rotation centered on the fovea. Thus, these rotations are nota stimulus to cyclovergence. Even when the rotation is centeredon the fovea, cyclovergence movements require large stimuli; Howardet al. (1994) found that decreasing stimulus size from 80 to 5°led to a fivefold decrease in the gain of cyclovergence. Furthermore,they found that the central visual field in which our stimuliwere placed made a small contribution tocyclovergence.

The relationship between orientation differences and slant

In considering the possible role of these neurons in signaling slant, it is important to recognize that on a real surfaceof fixed slant, the orientation difference is not uniform; itdepends on the orientation of feature elements (Cagenello andRogers, 1993). Vertical lines give rise to larger orientationdifferences than oblique lines. Nonetheless, a mechanism thatsignaled slant should still show left-right inseparability, withdiagonal structure in a plot of responses to all left and righteye combinations. If this structure reflected real world geometry,the diagonal would not always be at 45°.

Alternative ways of coding for slant

Several recent studies in extrastriate cortex have reported neurons that appear to signal surface slant. Shikata et al. (1996)reported visual neurons in the parietal cortex that were selectivefor surface orientation in three dimensions. This same group latershowed that cells in this area were selective not only for disparitygradient but also to texture gradient that corresponded to a similarsurface orientation (Tsutsui et al., 1999). In addition to thisdata for the parietal cortex, Janssen et al. (1999) have describedcells in the macaque inferior temporal cortex that are selectivefor the three-dimensional structure of surfaces. However, noneof these studies addresses whether the binocular responses arethe result of processing orientation disparities or the gradientof positional disparities. The neurophysiological data describedhere do not provide evidence for a mechanism that can signal orientationdisparities. Rather, they suggest that the initial processingof disparity depends on the orientation and position of featuresin both eyes, in the way predicted by the energy model of Ohzawaet al. (1990). The proposal that there are two separate neuralmechanisms early in visual processing (Blakemore et al., 1972),one that encodes orientation disparities and one that encodesposition disparities, therefore has no physiological evidenceto supportit.

  FOOTNOTES

Received Feb. 28, 2001; revised June 15, 2001; accepted June 20, 2001.

This work was supported by the Wellcome Trust. H.B. was a Christopher Welch Scholar. B.G.C. was a Royal Society UniversityResearch Fellow. We thank Andrew Parker for comments on thismanuscript.
Correspondence should be addressed to Dr. H. Bridge, University Laboratory of Physiology, Parks Road, Oxford, OX1 3PT, UK.E-mail: holly.bridge{at}physiol.ox.ac.uk.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Blakemore C, Fiorentini A, Maffei L (1972) A second neural mechanism of binocular depth discrimination. J Physiol (Lond) 226:725-749[Abstract/Free Full Text].
Cagenello R, Rogers B (1993) Anisotropies in the perception of stereoscopic surfaces: the role of orientation disparity. Vision Res 33:2189-2201[Web of Science][Medline].
Cumming B, Thomas O, Parker A, Hawken M (1999) Classification of simple and complex cells in (V1) of the awake monkey. Soc Neurosci Abstr 25:1548.
Cumming BG, DeAngelis GC (2001) The physiology of stereopsis. Annu Rev Neurosci 24:203-238[Web of Science][Medline].
Cumming BG, Parker AJ (1999) Binocular neurons in V1 of awake monkeys are selective for absolute, not relative, disparity. J Neurosci 19:1981-2088.
Cumming BG, Parker AJ (2000) Local disparity not perceived depth is signaled by binocular neurons in cortical area V1 of the macaque. J Neurosci 20:4758-4767[Abstract/Free Full Text].
DeValois RL, Yund EW, Hepler N (1982) The orientation and direction selectivity of cells in macaque visual cortex. Vision Res 22:531-544[Web of Science][Medline].
Draper NR, Smith HS (1998) Extra sums of squares and tests for several parameters being zero. In: Applied regression analysis, Ed 3, pp 149-165 New York: Wiley.
Henry GH, Goodwin AW, Bishop PO (1978) Spatial summation of responses in receptive fields of simple cells in cat striate cortex. Exp Brain Res 32:245-266[Web of Science][Medline].
Howard I, Sun L, Shen X (1994) Cycloversion and cyclovergence: the effects of the area and position of the visual display. Exp Brain Res 100:509-514[Web of Science][Medline].
Hubel D, Wiesel T (1973) A re-examination of stereoscopic mechanisms in area 17 of the cat. J Physiol (Lond) 232:29P-30P.
Janssen P, Vogels R, Orban G (1999) Macaque inferior temporal neurons are selective for disparity-defined three-dimensional shapes. Proc Natl Acad Sci USA 96:8217-8222[Abstract/Free Full Text].
Judge SJ, Richmond BJ, Chu FC (1980) Implantation of magnetic search coils for measurement of eye position: an improved method. Vision Res 30:535-538.
Merrill EG, Ainsworth A (1972) Glass-coated platinum-plated tungsten electrodes. Med Biol Eng 10:662-672[Web of Science][Medline].
Mitchison G, McKee S (1990) Mechanisms underlying the anisotropy of stereoscopic tilt perception. Vision Res 30:1781-1791[Medline].
Nelson J, Kato H, Bishop P (1977) Discrimination of orientation and position disparities by binocularly activated neurons in cat striate cortex. J Neurophysiol 40:260-283[Abstract/Free Full Text].
Ninio J (1985) Orientational versus horizontal disparity in the stereoscopic appreciation of slant. Perception 14:305-314[Web of Science][Medline].
Ohzawa I, DeAngelis GC, Freeman RD (1990) Stereoscopic depth discrimination in the visual cortex: neurons ideally suited as disparity detectors. Science 249:1037-1041[Abstract/Free Full Text].
Ohzawa I, DeAngelis GC, Freeman RD (1997) Encoding of binocular disparity by complex cells in the cat's visual cortex. J Neurophysiol 77:2879-2909[Abstract/Free Full Text].
Parker AJ, Hawken MJ (1988) Two-dimensional spatial structure of receptive fields in monkey striate cortex. J Opt Soc Am A 5:598-605[Web of Science][Medline].
Poggio GF, Fischer B (1977) Binocular interactions and depth sensitivity in striate and prestriate cortex of behaving rhesus monkey. J Neurophysiol 40:1392-1405[Free Full Text].
Prince SJD, Pointon AD, Cumming BG, Parker AJ (2001) Quantitative analysis of responses of V1 neurons to horizontal disparity in dynamic random dot stereograms. J Neurophysiol, In press.
Shikata E, Tanaka Y, Nakamura H, Taira M, Sakata H (1996) Selectivity of the parietal visual neurones in 3D orientation of surface of stereoscopic stimuli. NeuroReport 7:2389-2394[Web of Science][Medline].
Skottun B, DeValois R, Grosof D, Movshon J, Albrecht D, Bonds A (1991) Classifying simple and complex cells on the basis of response modulation. Vision Res 31:1079-1086[Web of Science][Medline].
Tsutsui K, Taira M, Min J, Sakata H (1999) Coding of surface orientation by the gradient of texture and disparity in the monkey caudal intraparietal area. Soc Neurosci Abstr 25:670.
von der Heydt R (1978) Stereoscopic perception of orientation disparity. Invest Ophthalmol Vis Sci ARVO Abst 17:286.
von der Heydt R, Hanny P, Dursteler M (1980) The role of orientation disparity in stereoscopic perception and the development of binocular correspondence. Adv Physiol Sci 16:461-469.
Wheatstone C (1838) Contributions to the physiology of vision. I. On some remarkable, and hitherto unobserved, phenomena of vision. Philos Trans R Soc Lond B Biol Sci 13:371-395.
Wieniawa-Narkiewicz E, Wimborne B, Michalski A, Henry G (1992) Area 21a in the cat and the detection of binocular orientation disparity. Ophthalmic Physiol Opt 12:269-272[Medline].

Copyright © 2001 Society for Neuroscience 0270-6474/01/21187293-10$05.00/0

This article has been cited by other articles:

T. M. Sanada and I. Ohzawa
Encoding of Three-Dimensional Surface Slant in Cat Visual Areas 17 and 18
J Neurophysiol, May 1, 2006; 95(5): 2768 - 2786.
[Abstract] [Full Text] [PDF]

J. C. A. Read and B. G. Cumming
Effect of Interocular Delay on Disparity-Selective V1 Neurons: Relationship to Stereoacuity and the Pulfrich Effect
J Neurophysiol, August 1, 2005; 94(2): 1541 - 1553.
[Abstract] [Full Text] [PDF]

H. Nienborg, H. Bridge, A. J. Parker, and B. G. Cumming
Receptive Field Size in V1 Neurons Limits Acuity for Perceiving Disparity Modulation
J. Neurosci., March 3, 2004; 24(9): 2065 - 2076.
[Abstract] [Full Text] [PDF]

J. C. A. Read and B. G. Cumming
Testing Quantitative Models of Binocular Disparity Selectivity in Primary Visual Cortex
J Neurophysiol, November 1, 2003; 90(5): 2795 - 2817.
[Abstract] [Full Text] [PDF]

I. Kagan, M. Gur, and D. M. Snodderly
Spatial Organization of Receptive Fields of V1 Neurons of Alert Monkeys: Comparison With Responses to Gratings
J Neurophysiol, November 1, 2002; 88(5): 2557 - 2574.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (13)

Citing Articles via Google Scholar

Google Scholar

Articles by Bridge, H.

Articles by Cumming, B. G.

Search for Related Content

PubMed

PubMed Citation

Articles by Bridge, H.

Articles by Cumming, B. G.