Metabolic Mapping of Suppression Scotomas in Striate Cortex of Macaques with Experimental Strabismus

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The Journal of Neuroscience, August 15, 1999, 19(16):7111-7129

Metabolic Mapping of Suppression Scotomas in Striate Cortex of Macaques with Experimental Strabismus
Jonathan C. Horton, Davina R. Hocking, and Daniel L. Adams
Beckman Vision Center, University of California, San Francisco, San Francisco, California 94143-0730

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Misalignment of the ocular axes induces double vision and rivalry. To prevent these unpleasant sensations, most subjects fixatepreferentially with one eye and suppress entirely the deviatingeye or else suppress portions of the visual field of either eye.To explore the mechanism of visual suppression, a divergent strabismus(exotropia) was induced in six normal, adult Macaca fascicularisby disinserting the medial rectus muscles. After 4-8 weeks, eachanimal was chaired to measure its exotropia and to determine itsocular fixation preference. Five of the monkeys developed a clearlydominant eye. It was injected with [³H]proline. Alternate sections from flat-mounts of striate cortexwere then processed either for autoradiography to label the oculardominance columns or for cytochrome oxidase (CO) to assess localmetabolic activity. Two CO patterns were seen, often in the samecortex. The first consisted of thin dark columns alternating withwide pale columns. This pattern arose from reduced CO activityin the suppressed eye's monocular core zones and both eyes' binocularborder strips. The second pattern consisted of thin pale bandsfrom reduced metabolic activity in both eyes' border strips. Thethin dark-wide pale CO pattern was more widespread in the threeanimals with a strong fixation preference. The dark CO columnsusually fit in register with the ocular dominance columns of thefixating eye, suggesting that perception was suppressed in thedeviating eye. In most animals, however, the correlation switchedin peripheral cortex contralateral to the deviating eye, implyinglocal suppression of the fixating eye's temporal retina (beyond10°), as reported in humans with divergent strabismus. In thetwo animals with a weak fixation preference, pale border stripswere found within the central visual field representation in bothhemispheres. This CO pattern was consistent with alternating visualsuppression. These experiments provide the first anatomical evidencefor changes in cortical metabolism that can be correlated withsuppression scotomas in subjects withstrabismus.

Key words: strabismus; scotoma; suppression; cytochrome oxidase; ocular dominance column; visual cortex; exotropia; border strip; core zone; stereopsis; binocular; diplopia

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Understanding the phenomenon of visual suppression is one of the keys to solving the vexing problem of strabismus. Childrenwho acquire strabismus rarely complain of diplopia (double vision),because they quickly adapt to misalignment of the ocular axesby suppressing vision from the deviating eye (von Noorden, 1996).Thus, visual suppression plays a critical role in the advent ofstrabismus by eliminating the drive to fuse disparate images.In addition, suppression often leads to amblyopia, if it becomesconstant in one eye, rather than alternating between theeyes.

The mechanism of visual suppression in strabismus is unknown. It is not even clear whether visual suppression originates inprimary visual cortex (striate cortex, V1), in extrastriate cortex,or at a subcortical level. Since the original report of Hubeland Wiesel (1965), numerous investigators have confirmed thatstrabismus reduces the number of cells in striate cortex thatcan be driven by both eyes. More recently, electrophysiologicalstudies have uncovered the existence of inhibitory binocular interactionsin animals raised with strabismus (Freeman and Tsumoto, 1983;Crewther and Crewther, 1993; Chino et al., 1994; Sengpiel andBlakemore, 1994; Smith et al., 1997). In these animals, the responseof neurons to an optimal stimulus in one eye was suppressed bystimulation of the other eye. Such residual inhibitory interactionsmay contribute to strabismic suppression. Sengpiel and colleagues(1994) have suggested explicitly that strabismic suppression dependson inhibitory interactions between cells in neighboring oculardominancecolumns.

Few studies have used anatomical methods to probe how strabismus alters the visual cortex. Löwel (1994) has reported thatstrabismus increases the width of ocular dominance columns inkittens, presumably by reducing the correlation of activity betweeneyes (Goodhill, 1993). In addition, it has been shown by intracorticaltracer injections in strabismic animals that intrinsic tangentialclustered connections are lost between ocular dominance columnsserving opposite eyes (Löwel and Singer, 1992; Tychsen and Burkhalter,1995). This loss of connections presumably reflects the breakdownof cortical binocularity that occurs from strabismus. It doesnot, however, shed any light on the problem of strabismic suppression.If anything, a loss of projections between ocular dominance columnsserving the left eye and the right eye would reduce the substratefor interocular suppression, unless only facilitatory connectionswereattenuated.

The main objective of this study was to explore the phenomenon of strabismic suppression using the mitochondrial enzyme cytochromeoxidase (CO) as a functional anatomical label. CO levels fluctuatedynamically with neuronal activity (Wong-Riley, 1994; DeYoe etal., 1995), making it an ideal label for this purpose. Our interestin strabismic suppression was kindled by the discovery that macaquestriate cortex is subdivided into monocular core zones and binocularborder strips (Horton, 1984; Horton and Hocking, 1998a). In normalanimals, these compartments contain equal CO activity in layerIVc (Fig. 1). We reasoned that strabismus, by disrupting binocularfunction, might cause greater loss of CO in border strips thanin core zones. We also predicted that animals with a strong fixationpreference might lose CO activity in the core zones of their deviatedeye, as a result of suppression. Our goal was to compare the fixationbehavior of each animal with the pattern of CO activity in itsvisual cortex.

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Figure 1. Schematic diagram of macaque striate cortex, drawn as if one were looking down through the cortical layers from the pial surface. On the left, brackets mark the actual boundaries of the ocular dominance columns in layer IVc (L, = left; R = right). Each ocular dominance column contains a central, monocular core zone, with a row of CO patches (also known as "blobs" or "puffs") running down the middle. The CO patches are visible in all layers except IVc and IVa. Each monocular core zone is flanked by a thin binocular border strip. The border strips at the boundaries between ocular dominance columns create a single binocular region. Therefore, the existence of core zones and border strips gives rise to a regular system of alternating monocular and binocular compartments in striate cortex, at least within the representation of the central 12° (beyond this eccentricity, the ocular dominance columns serving the ipsilateral eye become fragmented, and binocular function is reduced). Although sharp boundaries are shown, the transition between core zones and border strips is gradual. Our goal in this study was to test the effects of strabismus on CO activity in the core zones and the border strips serving each eye.

To avoid diplopia and confusion, many subjects with strabismus appear to suppress information emanating from only part ofthe retina, instead of turning off the eye altogether. This phenomenongives rise to local suppression scotomas, revealed when the visualfields are plotted dichoptically (Graefe, 1896). By unfoldingstriate cortex and stripping it from the white matter, one canprepare flattened sections containing the representation of thecontralateral visual hemifield in a single piece of tissue (Hortonand Hocking, 1996c). We hoped that by examining such flat-mountedsections from each hemisphere, we might find anatomical evidencefor local suppression scotomas by correlating each animal's predominantfixation pattern with (1) the pattern of CO activity in its cortex,(2) the ocular dominance columns, and (3) the cortical map ofthe visualfield.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experimental animals. We used six normal Macaca fascicularis imported from Mauritius in 1995. Their ages were unknown becausethey were feral animals. All were male, fully adult, weighing5-6 kg, and in prime condition. Before use, each animal receiveda complete eye examination to exclude any preexisting disease.The pupil responses, eye movements, ocular alignment, ocular media,and fundus were normal in every case. All procedures used in theseexperiments were approved by the Committee on Animal Researchat University of California, SanFrancisco.

Strabismus can be induced experimentally at any age. We chose to begin this avenue of research on strabismic suppression bytesting adult animals. Our ultimate goal is to understand thephenomenon of suppression in children. However, before investingthe effort required to raise infant monkeys with strabismus, itseemed best to see whether promising results could be obtainedfirst in strabismic adults. In Discussion we consider this issuefurther and compare the mechanisms of suppression in adults andchildren.

We induced strabismus by tenotomy of the medial rectus muscle in both eyes. The procedure was performed under general anesthesiawith ketamine HCl (15 mg/kg, i.m.) and topical proparacaine HCl.After the muscle was released, the insertion site was examinedcarefully to ensure that the tendon was severed completely. Afterward,topical antibiotic ointment was applied liberally to the eyes.The animals were checked every day after the operation to verifyrapid healing and to observe ocularalignment.

Once each animal had developed a stable, divergent strabismus, it was fasted for 12 hr and placed in a restraining chair tomeasure ocular alignment in primary gaze. Two methods were usedto gauge the magnitude of the exotropia. The first relied on decentrationof the corneal light reflex in one eye (Hirschberg test), estimatedwhile the monkey fixated a small, handheld point light sourceheld 60 cm away. Grapes were used to attract the animal's attentionand to win its cooperation. Each millimeter of light reflex decentrationwas equivalent to 14° of ocular deviation (Quick and Boothe, 1989).For the second method, we determined the magnitude of a base-inprism required to center the corneal light reflex in each eye(Krimsky test). The Hirshberg and Krimsky tests were done by severalexaminers to arrive at a consensus regarding the magnitude ofeach animal's primary exodeviation. For documentation, photographswere also taken at a distance of 60 cm with a ring-flash mountedon the end of a 100 mm macrolens.

Fixation preference was judged independently by each author, as well as by two pediatric ophthalmologists. Assessments weremade by watching each animal's spontaneous behavior and by testingits fixation preference while reaching for food treats. Frequentobservations of unrestrained animals in their home cages wererecorded by each examiner over several weeks. Examiners were askedto decide whether the animal had a fixation preference for oneeye. If so, the examiner rated the preference as strong or weak.An animal with a strong fixation pattern spent >80% of the timefoveating with its preferred eye. An animal with a weak fixationpattern spent only 60-80% of the time looking with its preferredeye. Estimates were verified by reviewing videotapes of the animals.Observational assessment of fixation preference is simple andquite accurate when done by experienced strabismologists (Choiand Kushner, 1998).

Between 4-8 weeks after inducing strabismus, we labeled the ocular dominance columns in each monkey by [³H]proline transneuronal autoradiography. The tracer injectionwas always made into the eye that the monkey used preferentiallyfor fixation. It was prepared by reconstituting 2 mCi of L-[2,3,4,5-³H]proline (specific activity, 102-106 Ci/mmol; Amersham, ArlingtonHeights, IL) in 20 µl of sterile balanced salt solution. The pupilwas dilated pharmacologically, and the eye was massaged gentlyto lower the intraocular pressure below 12 mmHg. The tracer wasthen injected through the pars plana into the midvitreous of theeye under anesthesia with ketamine HCl (10 mg/kg i.m.) and topicalproparacaine HCl. Immediately afterward, the fundus was checkedwith an indirect ophthalmoscope for any sign of injury. The survivaltime for transport of the label was 7-9 d. Just before perfusion,the eye was examined again with an indirect ophthalmoscope. Ineach animal, the eye appeared unscathed by injection of theradioisotope.

Histological procedures. After receiving a lethal injection of sodium pentobarbital into the peritoneal cavity, each monkeywas perfused through the left ventricle with 1 l of normal salinefollowed by 1 l of 2% paraformaldehyde in 0.1 M phosphate buffer.Flat-mounts of striate cortex were prepared from each hemisphere(Horton and Hocking, 1996c), cut with a freezing microtome, mountedon slides, and air-dried. Alternating sections were reacted forCO (Wong-Riley, 1979) or dipped into NTB-2 emulsion (Eastman Kodak,Rochester, NY) for autoradiography. The autoradiographs were exposedfor 10 weeks and developed with D19 developer (Kodak) (Wieselet al., 1974). In three animals the lateral geniculate bodieswere sectioned and reacted forCO.

Data Analysis. Cortical CO flat mounts were imaged at 600 dots per inch on an Agfa (Mortsel, Belgium) Arcus II flatbed scannerfitted with a transparency adapter. To compare regions at higherpower, CO sections and autoradiographs were photographed throughan Olympus (Tokyo, Japan) SZH10 microscope using Technical Panfilm (Kodak). Negatives were processed with D19 developer andscanned into the computer using a Microtek (Redondo Beach, CA)Scanmaker 35t scanner. Images were imported into Photoshop 5.0(Adobe Systems, San Jose, CA) to prepare illustrations. Measurementswere made using Scion Image PC (Scion Corp., Frederick,MD).

In a previous paper, we used a series of neutral density filters to calibrate the optical density of each CO section (Hortonand Hocking, 1998a). This approach allowed us to compare the absolutedensity of CO reaction product between sections and between animals.In this present study, the CO patterns were often quite subtle.To improve their visibility, we found it necessary to adjust thebrightness and contrast of each section. For this reason, theimages in this paper were not calibrated to optical densitystandards.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Induction of strabismus

The day after surgery, all the monkeys had a huge divergent strabismus measuring ~60°. In each case the exotropia showed markedspontaneous improvement in the first 2 weeks after surgery (Sireteanuet al., 1993). The mechanism was unclear, but the animals mayhave learned to reduce lateral rectus muscle tone in each eye.In addition, postmortem examination showed some adhesion of Tenon'scapsule and the intermuscular septum at the site of the medialrectus tendon insertion. Although the muscle itself did not reinsert,it may have exerted some tension through these capsularattachments.

After the first few weeks, reduction of the exotropia became more gradual. Some monkeys improved more than others, with finaldeviations ranging between 8 and 25°. Although convergent strabismusis more prevalent clinically, we deliberately made all our monkeysexotropic, because we were concerned that esotropic monkeys withsmall deviations might fuse near targets. With exotropia, evenif a monkey had only a small deviation, we were sure that itseyes were misaligned all the time. None of our exotropic monkeysappeared able to use accommodative convergence to fuseintermittently.

In five of six monkeys, a fixation preference emerged within a few days of surgery. Because the monkeys could not fully adducttheir eyes, they usually made a slight head turn to the oppositeside to fixate with each eye. To switch fixation, the monkeysbobbed their heads back and forth. This behavior became less strikingas the exotropia diminished and the ocular motility improved.Even when subtle, it made it easy to see when the animals switchedfixation. In one animal, observers did not agree on the eye fixationpreference. It did not seem worthwhile to study this animal, giventhat we were unsure of its eye preference. Therefore, it was donatedto another laboratory. The remaining five animals achieved a stableexotropia by 4-8 weeks after surgery, and observers agreed unanimouslyon their ocular fixation preference. Figure 2 shows each animalbefore [³H]proline injection into the preferred eye, ~10 d before perfusion.Intraocular injection of [³H]proline did not affect the magnitude of the exotropia or theeye fixation preference in any monkey.

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Figure 2. Photographs of the five macaques that developed a clear eye preference, showing decentration of the corneal light reflex (Hirshberg test) from a ring-flash mounted on a macro lens 60 cm away. Each millimeter of displacement corresponds to ~14°. The magnitude of each animal's exotropia in primary gaze was determined by combining estimates made by at least two examiners using the Hirshberg test and the Krimsky test. Although each animal underwent the same operation (bilateral medial rectus tenotomy), the final deviations varied considerably.

Monkey 1 (right exotropia, 8°)

This animal developed the smallest exodeviation, measuring only 8°, but all observers concurred that it had a strong preferencefor the left eye, fixating with it virtually all the time. [³H]Proline was injected into the left eye 4 weeks after eye musclesurgery, followed by perfusion 9 d later. Figure 3, A and C, showssingle CO-stained tangential sections cut through flat-mountsof the left and right striate cortex. The sections pass mostlythrough layer IVc, revealing the CO pattern in that layer overa wide expanse of cortex, representing most of the visual field.In animals with normal ocular alignment and visual acuity, nopattern of CO activity is seen in layer IVc (Horton, 1984). Inthis strabismic animal, a remarkable pattern of alternating darkand light CO columns was visible everywhere, following the generallayout of the ocular dominance columns (LeVay et al., 1985). Thecolumns were quite faint, resembling those seen after eyelid suture,rather than after enucleation (Horton and Hocking, 1998a).

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Figure 3. Monkey 1 (8° right exotropia). A, C, Single CO sections passing mostly through layer IVc, showing a faint pattern of alternating light and dark columns induced by strabismus. They resemble the columns seen after monocular eyelid suture. The visual field eccentricities marked below the section are based on the cortical maps of Daniel and Whitteridge (1961), Van Essen et al. (1984), and Tootell et al. (1988). The lateral half of each section, representing the central 8°, is exposed on the smooth, posterior surface of the occipital lobe and is referred to as "opercular cortex" or "the operculum." The boxed regions are shown at higher power in subsequent figures, as indicated. B, D, Autoradiographs of single sections immediately superficial to the CO sections above, showing the ocular dominance columns labeled by [³H]proline injection into the fixating left eye. In dark-field illumination, the labeled ocular dominance columns appear bright. In peripheral cortex, between the representations of the blind spot (*) and the monocular crescent (MC), the ocular dominance columns serving the ipsilateral eye become attenuated, reducing cortical binocularity.

Eyelid suture produces a low-contrast CO pattern of thin dark columns alternating with wide pale columns in layer IVc (Horton,1984; Hendry and Jones, 1986; Crawford et al., 1989; Trusk etal., 1990; Tigges et al., 1992). This pattern results from lossof CO activity in the sutured eye's monocular core zones and inboth eyes' binocular border strips (Horton and Hocking, 1998a).We wondered whether strabismus might have induced the same effectin striate cortex. On close inspection of the opercular cortexin Figure 3, the dark columns looked slightly thinner than thepale columns. This impression was confirmed by measuring the widthof 50 light columns and 50 dark columns, selected arbitrarilyfrom each opercular cortex. The average widths were 297 ± 51.3(SD) µm for the dark columns and 408 ± 73.7 µm for the light columns.Assuming that the dark columns represented the core zones of thefixating eye, a pair of border strips measured 55.5 µm, yieldingfor a single wide pale column 55.5 + 297 + 55.5 = 408 µm.

To interpret the CO pattern in Monkey 1, it was vital to know its relationship to the ocular dominance columns. Figure 3,B and D, shows autoradiographs prepared from adjacent sectionssuperficial to the CO sections illustrated in Figure 3, A andC. Ocular dominance columns were visible throughout the sectionin layer IVc. On the operculum the ocular dominance columns wereabout equal in width. In the periphery, beyond the blind spotrepresentation, the columns serving the ipsilateral eye becameshrunken and fragmented, a normal feature described by LeVay etal. (1985).

To compare CO patterns with autoradiographs, one must examine local regions at high power, so that blood vessel patterns canbe matched precisely to ensure accurate alignment of adjacentsections. Figure 4A shows the CO pattern in layer IVc from theleft operculum of Monkey 1, in a region between 5 and 8°, nearthe lower vertical meridian. Figure 4B shows the correspondingregion from the adjacent autoradiograph. The thin dark CO columnsmatch the proline-labeled ocular dominance columns, although theyare slightly thinner, because they represent core zones only.In this region of cortex, we concluded that CO activity was richerin the core zones of the fixating eye.

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Figure 4. Monkey 1 (8° right exotropia). A, Boxed region from layer IVc of the left operculum (Fig. 3A) showing the CO pattern at higher magnification. The arrows mark six thin dark columns. B, Corresponding region from Figure 3B, showing that the labeled ocular dominance columns (arrows) of the fixating left eye match the thin dark CO columns in A. The labeled ocular dominance columns are slightly thicker than the dark CO columns, but the difference is small, because it amounts only to the width of a pair of border strips (~50 µm in this animal). C, Section 330 µm superficial to A, showing that strabismus has induced bands in the normally continuous honeycomb lattice of layer IVa. Every other band (arrows) is slightly darker, in register with the dark core zones in A. D, Section 405 µm more superficial to A, showing rows of CO patches in layer III. They form more continuous rows than in normal monkeys, and the rows (arrows) in register with the dark core zones in A are slightly darker. Examination of serial alternate sections showed that CO activity was greater in the core zones of the fixating left eye in all cortical layers except layer I. Arrowheads mark blood vessels used for aligning sections. All frames are to identical scale.

This metabolic bias in layer IVc favoring the fixating eye was perpetuated through the full thickness of the cortex, implyingthat visual processing was affected in both afferent and efferentlayers. Figure 4C shows the CO pattern in layer IVa. Bands oflabel were present, with each band running down the middle ofan ocular dominance column. In normal animals, bands are neverfound in layer IVa (Horton, 1984). Instead, one sees a continuous"honeycomb" of CO activity. Bands emerged in Monkey 1 becausestrabismus reduced metabolic activity within the border strips,sparing activity in the core zones. In addition, CO staining appearedslightly darker in the core zones of the fixating eye (matchingthe dark core zones in layer IVc), giving rise to a pattern ofalternating dark and light core zones in layer IVa, separatedby pale gaps representing the borderstrips.

In layers II and III, the CO patches appeared almost to merge as they ran down the middle of the ocular dominance columns(Fig. 4D). This tendency for patches to form "pearls on a string"is seen in normal animals, but it was exaggerated in all our strabismicmonkeys. Again, we believe that loss of CO activity in borderstrips accentuated each row of CO patches by silhouetting it againsta paler CO background. Strabismus also caused the rows of patchesin register with the core zones of the fixating left eye to appearslightly darker than the rows serving the deviating right eye.This effect was subtle but definite and even visible in layersV and VI. Therefore, metabolic hegemony of the fixating eye wasevident in all cortical layers (except layer I). It is worth emphasizingthat although strabismus mimicked the pattern produced by eyelidsuture in layer IVc, outside layer IVc it yielded a lower-contrastpattern of light and dark rows of patches. Curiously, eyelid suturein adult monkeys induces a high-contrast pattern outside layerIVc, rivaling that seen after enucleation (Horton, 1984; Hortonand Hocking, 1998a).

In Figure 4, CO patterns are compared with ocular dominance columns in only a small region of cortex. To confirm the assignmentof the dark CO columns to the ocular dominance columns of thefixating left eye, we compared CO sections and autoradiographsthroughout each striate cortex. Everywhere, the dark CO columnsfit in register with the labeled ocular dominance columns. Figure5 shows examples of three other regions matched at high power.Note that in the periphery of the right cortex (Fig. 5E), theCO pattern appeared as wide dark columns alternating with thinpale columns. This reversal occurred because, beyond 15° (Fig.5F), the ocular dominance columns serving the ipsilateral eyebecome naturally shrunken, whereas those serving the contralateraleye become expanded (LeVay et al., 1985). As a result, in theright peripheral cortex, the usual pattern of thin dark-wide palecolumns was replaced by wide dark-thin pale columns (Fig. 5E).Parenthetically, it is worth noting that in peripheral cortex,the existence of well organized border strips is uncertain. Neuronswith tuned disparity selectivity are more common in the centralvisual field representation, where binocular input is closelybalanced (Poggio, 1995). In peripheral cortex, border strips maybe rudimentary, because disparity-tuned cells are sparse, andocular input is biased strongly in favor of the contralateraleye. If so, core zones may become nearly equivalent to oculardominance columns, and CO patterns from strabismus may correspondalmost exactly to the actual boundaries of ocular dominance columns.

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Figure 5. Monkey 1 (8° right exotropia). A, B, Adjacent CO and proline sections from the left peripheral cortex (Fig. 3A,B). The autoradiograph is 70 µm deeper than the section illustrated in Figure 3B. The dark CO columns correspond to the left eye's labeled ocular dominance columns (compare arrows). C, D, Adjacent CO and proline sections from the right operculum (Fig. 3C,D), showing that the dark CO columns belong to the left eye (compare arrows). E, F, Adjacent CO and proline sections, each 70 µm superficial to the sections shown in Figure 3, C and D, again showing a match between the dark CO columns and the left eye's ocular dominance columns, this time in the right peripheral cortex. In this animal, the dark CO columns were associated with the fixating left eye everywhere in striate cortex of both hemispheres.

To summarize the findings in Monkey 1, the fixating left eye had stronger metabolic activity throughout the left and rightstriate cortex. Even in the monocular crescent of the left cortex,where the deviating right eye did not have to compete with thefixating left eye, CO staining appeared pale. Metabolic activityin the deviating eye's ocular dominance columns was reduced globally,and the left eye was dominant everywhere in the cortex (and hencein the visualfield).

Monkey 2 (left exotropia, 25°)

This animal had the largest deviation, a left exotropia measuring 25°. All observers agreed that it had a strong right eyefixation preference. The right eye was injected with [³H]proline 6 weeks after induction of strabismus. As in Monkey1, there were faint columns of CO activity everywhere in layerIVc of the left (Fig. 6A) and the right striate cortex (Fig. 7A).On the opercula, the dark columns were slightly thinner than thepale columns, consistent with loss of CO activity in border strips,and in the core zones of the deviating left eye. To check theassignment of the dark CO columns, they were compared at highpower with adjacent autoradiographs. In the left cortex, the darkcolumns corresponded to the labeled ocular dominance columns ofthe fixating right eye, both on the operculum and in the periphery(Fig. 6B-E). In the right cortex, the same result was found onthe operculum (Fig. 7D,E). However, in peripheral cortex, theopposite was seen: the pale CO columns matched the labeled oculardominance columns of the right eye (Fig. 7B,C). The most straightforwardexplanation for this result would be that the deviating left eyewas suppressed everywhere, except in the peripheral right visualcortex (representing the left peripheral visual field). In thisregion it enjoyed perceptual dominance, and the right eye waslocally suppressed. Note that the switchover occurred at an eccentricityof 10-12° in the left visual cortex (Fig. 7A), which did not equalthe magnitude of the divergent strabismus (~25°). This means thatthe peripheral temporal retina of the fixating right eye was activelysuppressed in favor of the nasal retina of the deviating lefteye.

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Figure 6. Monkey 2 (25° left exotropia). A, A composite of two half-sections, 30 µm apart, is shown to give the best view of the CO pattern in layer IVc of this animal. The thin white line running down the middle shows the section boundaries. On the left operculum, alternating thin dark and wide pale CO columns are visible in layer IVc. In the periphery, the wide pale columns become thinner than the dark columns, because the ipsilateral (left) eye's ocular dominance columns become shrunken in this region. B, Boxed region from A, showing the CO pattern at higher power. C, Region corresponding to B, from an adjacent autoradiograph, showing that the dark CO core zones match the fixating, injected right eye's ocular dominance columns (compare arrows), although, of course, they are slightly narrower. D, Boxed region, from peripheral cortex, showing the CO pattern. E, Adjacent autoradiograph, showing that the dark CO columns match label from the right eye.

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Figure 7. Monkey 2 (25° left exotropia). A, Flat-mount composite of the right striate cortex, showing a faint pattern of CO columns in layer IVc. B, Boxed region from A, showing CO columns from 20 to 40°, near the lower vertical meridian. C, Matching region from an adjacent autoradiograph, showing that the pale CO columns correspond to the labeled ocular dominance columns of the right eye. In the right cortex, from the switchover zone to the monocular crescent, the deviating left eye was dominant metabolically. Everywhere else, the fixating right eye's ocular dominance columns had stronger CO activity. D, CO pattern in layer IVc of the right operculum. E, Matching region from an adjacent autoradiograph, showing that the dark CO columns correspond to the labeled ocular dominance columns of the right eye.

Monkey 3 (left exotropia, 20°)

This animal also had a left exotropia, but it was slightly smaller than the previous animal's exotropia. His fixation preferencefor the right eye was strong. [³H]Proline was injected into the right eye 4 weeks after the medialrectus tenotomies. On the operculum of the left visual cortex,there were alternating thin dark and wide pale CO columns in layerIVc, but they were quite faint (Fig. 8A). At high power, it wasverified that the thin dark CO columns matched the ocular dominancecolumns of the fixating right eye (Fig. 8, compare B, C). In theperiphery of the left cortex, the CO columns were higher in contrast.Again, the dark CO columns coincided with the ocular dominancecolumns of the dominant right eye (Fig. 8, compare D, E).

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Figure 8. Monkey 3 (20° left exotropia). A, Flat-mounts through layer IVc reveal alternating dark and light CO columns everywhere in the left striate cortex, which increase in contrast toward the representation of the periphery. B, Boxed region from the left operculum, showing faint pattern of thin dark core zones. C, Matching autoradiograph, showing that the dark CO core zones pictured above correspond to the labeled ocular dominance columns of the injected, fixating right eye. D, Boxed region from the left periphery, showing CO columns. E, Matching autoradiograph, demonstrating that the dark CO columns above correspond to the right eye.

In the right visual cortex, from the representation of the fovea to 10°, the pattern of CO staining in layer IVc was extremelysubtle (Fig. 9A). It appeared homogeneous, except for a faintpattern of parallel pale strips, ~50-70 µm wide, spaced aboutevery half-millimeter. Comparison with adjacent autoradiographsshowed that the pale strips ran right along the borders betweenocular dominance columns (Fig. 9, compare D, E). We concludedthat the pale strips corresponded to pairs of border strips. Theirmetabolic activity was reduced because binocularity was disruptedby strabismus. Only pale border strips were seen in the rightoperculum, because metabolic activity was equal in the core zonesserving each eye.

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Figure 9. Monkey 3 (20° left exotropia). A, Layer IVc of the right operculum contains a faint CO pattern of thin pale bands. In the periphery, a strong pattern of light and dark columns emerges. B, CO section from the periphery above, showing CO columns. C, Matching autoradiograph shows that the pale CO columns correspond to the labeled ocular dominance columns of the right eye (compare arrows). D, Arrows denote faint thin pale bands, ~50-70 µm wide, visible on the right operculum. They are partly obscured by knife scratches, which slant in the other direction. E, Matching autoradiograph, showing that the pale CO bands fall on the borders between ocular dominance columns. Therefore, they represent pairs of border strips, whose metabolic activity is reduced by strabismus.

In the peripheral right cortex, a clear pattern of dark and light CO columns emerged from 10° to the monocular crescent representation(Fig. 9A). The more peripheral in the cortex, the greater thecontrast of the columns. At high power, we found that the paleCO columns matched the ocular dominance columns of the injected,dominant right eye (Fig. 9, compare B, C). To summarize: in thismonkey the fixating right eye was dominant throughout the leftvisual cortex; both eyes held equal sway on the right operculum;and the deviating left eye was supreme in the right peripheralcortex.

Monkey 4 (right exotropia, 10°)

This monkey preferred to fixate with the left eye, but he alternated fixation frequently. All five observers rated his fixationpreference as weak. A [³H]proline injection was made into the left eye 4 weeks after inductionof strabismus. Figure 10 shows the pattern of CO activity in theleft visual cortex. On the operculum, pale border strips werevisible throughout layer IVc. In the periphery, beginning at ~10°,alternating dark and pale columns emerged. Moving toward the monocularcrescent representation, their contrast increased steadily. Thepale CO columns matched the ocular dominance columns labeled bytracer from the preferred left eye.

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Figure 10. Monkey 4 (10° right exotropia). A, Pale border strips are present everywhere on the operculum, whereas alternating dark and light columns appear in the periphery. B, High-power view, showing the pale border strips marked by arrows. C, Matching autoradiograph, verifying that the pale bands in B straddle the borders of the ocular dominance columns. D, Close-up of the dark and light CO columns in the periphery. Note that CO staining is dark in the monocular crescent representation, which receives an exclusive projection from the nasal retina of the right eye. E, Matching autoradiograph, showing that the pale CO columns correspond to the injected left eye's ocular dominance columns. In the periphery of the left visual cortex, therefore, the right eye was metabolically dominant, which is logical in divergent strabismus, because it corresponds to perceptual dominance of the right eye in the right peripheral visual field.

In the right visual cortex the same pattern of CO activity was seen, but in reverse (Fig. 11). On the operculum, pale borderstrips were present. Beginning at 10°, a pattern of alternatingdark and light CO columns began to appear. On this side, it wasthe dark CO columns that matched the labeled ocular dominancecolumns of the left eye. In this animal, therefore, the eyes hadequal metabolic influence within the central field representation.Presumably the CO method was not sensitive enough to show a subtlebias in favor of the left eye, which one might have expected fromthe animal's weak fixation preference. The only sign of strabismuswas the loss of CO activity within border strips. In the peripheralfield representation, CO activity on each side was richer in oculardominance columns serving the contralateral eye. This patternof staining was consistent with suppression of the temporal retinain each eye, which, of course, would be expected in divergentstrabismus.

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Figure 11. Monkey 4 (10° right exotropia). A, As on the left side, pale border strips are visible throughout the right operculum. In the periphery, dark and light columns are present, although they are difficult to appreciate. B, High-power view of the right peripheral cortex, with arrows marking four dark CO columns. C, Autoradiograph, showing that the dark CO columns match the left eye's labeled ocular dominance columns. Thus, the left eye is dominant in the left peripheral visual field. D, High-power view of the opercular CO pattern, showing pale strips, which actually are seen best at lower power above. E, Autoradiograph, showing that the pale CO strips are border strips, because they are situated at the boundaries of ocular dominance columns (compare arrows).

Monkey 5 (right exotropia, 10°)

The findings in this monkey are not illustrated, because they resembled closely those described in Monkey 4. The animal hada right exotropia of similar magnitude and a weak fixation preferencefor the left eye. The [³H]proline injection was made into the left eye 8 weeks after eyemuscle surgery. On each operculum, a CO pattern of pale borderstrips was seen. In the periphery of each cortex, dark and paleCO columns were present. The dark columns coincided with the oculardominance columns of the contralateral eye on each side. Therefore,as illustrated for Monkey 4, the temporal retina appeared to besuppressed in each eye of thisanimal.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The main finding in this study was that induction of strabismus produced an abnormal pattern of metabolic activity in primaryvisual cortex of macaques. In each animal, for example, we couldidentify regions of cortex where CO activity was greater in thedominant, fixating eye's ocular dominance columns. In these regions,we infer that neurons were less active within ocular dominancecolumns serving the deviating eye. The most logical interpretationwould be that cortical activity driven by the deviating eye wassuppressed to avoid diplopia and confusion. In the paragraphsbelow we outline the evidence in favor of thisnotion.

The first issue is whether suppression even occurs in adult subjects. Classically, it is taught that adults with acquiredocular misalignment can learn to ignore a troublesome second imagebut never exhibit true strabismic suppression (von Noorden, 1996,page 215). There is evidence from evoked potentials, however,for true suppression of cortical activity in adults with acquiredstrabismus (Wright et al., 1990). Some investigators have suggestedthat strabismic suppression may harness the same innate corticalmechanism that prevents diplopia under normal conditions of binocularrivalry (Franceschetti and Burian, 1971; Harrad et al., 1996),although this idea is controversial (Smith et al., 1985). If correct,the difference between suppression in children and adults maybe simply that children can invoke suppression with greater facility.Until the mechanisms of strabismic suppression are better understoodin both children and adults, it is probably best to keep an openmind on these questions. It is certainly worth comparing corticalCO patterns induced by strabismus in adults and children. Examinationof young macaques raised with strabismus will be our nextstep.

Strabismus induced two different patterns of CO activity in layer IVc of opercular cortex. The first pattern consisted ofslender pale bands, spaced every half-millimeter (Fig. 12A). Byalignment with ocular dominance columns labeled by [³H]proline in adjacent sections, we showed that these pale bandsrepresented pairs of border strips straddling the boundaries betweenocular dominance columns. Strabismus caused selective loss ofCO activity in the border strips because they are rich in binocularcells, which are generally excited maximally when driven by botheyes at a preferred disparity. A pattern of pale border strips,similar to that seen in strabismus, has also been found in newbornmacaques (Horton and Hocking, 1996a). It probably occurs becauseocular alignment and binocular function are immature in newborns(Chino et al., 1997). The pale border strips fade a few weeksafter birth, around the time when stereopsis begins to emerge(O'Dell and Boothe, 1997). Weak CO staining along border stripshas also been observed in a single adult macaque with mild amblyopia(Horton et al., 1997). This animal may have had a small anglestrabismus that reduced CO activity within border strips.

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Figure 12. Schematic diagrams showing the two patterns of CO activity induced by strabismus. A, Pale border strips prevailed in regions of cortex where CO activity was lost in the binocular border strips, from disruption of ocular alignment, but metabolic activity remained strong in the monocular core zones serving each eye. This pattern was seen only in cortex representing the central 15° and was most evident in the two monkeys with a weak fixation preference. B, Thin dark alternating with wide pale columns were seen in cortex where CO activity was reduced in both eyes' binocular border strips and one eye's monocular core zones. Presumably, CO was lowered in the suppressed eye's core zones. This pattern was seen throughout the cortex in animals with a strong fixation preference but only in the peripheral cortex of those with a weak fixation preference.

The second CO pattern in layer IVc consisted of thin dark columns alternating with wide pale columns (Fig. 12B). It was generatedby loss of CO activity in the border strips of both eyes and inthe core zones of one eye. We believe that CO was lost in thecore zones of the eye that was locally suppressed. The patterninduced by strabismus looked exactly like the pattern inducedby monocular eyelid suture. From the point of view of CO activity,therefore, strabismic suppression had an effect tantamount toclosure of one eye. It was, in metabolic terms, as if the brainachieved strabismic suppression by invoking a mechanism equivalentto local occlusion of oneretina.

The abnormal CO patterns seen in the strabismic monkeys were faint, compared with the vivid columns seen after monocular enucleation,TTX injection, or retinal laser lesions (Horton, 1984; Wong-Rileyand Carroll, 1984; Horton and Hocking, 1998a). These manipulationseliminate input from one eye, resulting in drastic reduction ofCO activity within geniculate cell bodies and axon terminals,accounting for the high-contrast pattern seen in layer IVc. Inthree strabismic monkeys we examined CO staining in the lateralgeniculate bodies. It was entirely normal. The CO patterns inducedby strabismus, therefore, arose within the cortex. Although theywere quite subtle (and difficult to illustrate), they were robust,in the sense that they were present everywhere in striate cortexof both hemispheres in all fiveanimals.

Figure 13 summarizes the patterns of abnormal CO activity induced by strabismus in each monkey. It is important to rememberthat CO levels fluctuate over a time scale of days, not minutesor hours. At any given moment, the actual pattern of neuronalactivity in any animal's cortex might have looked quite differentfrom the staining pattern depicted in Figure 13. The CO patternrepresents only the prevailing pattern of neuronal activity over24-48 hr and cannot capture momentary fluctuations that occurfrom switches in fixation or attention. Although it is valuableto know the predominant pattern of cortical activation, it wouldalso be exciting to explore the phenomenon of strabismic suppressionusing techniques with better time resolution. One could use electrophysiologicalrecordings (or optical imaging) in awake, behaving monkeys (Thieleet al., 1997) or functional magnetic resonance imaging (fMRI)in humans. fMRI has poorer spatial resolution than CO, but giventhe findings in this study, it should be quite easy to map regionalsuppression scotomas in striate cortex.

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Figure 13. Summary diagram showing the CO patterns seen in striate cortex of each animal. The raw data are illustrated in Figures 3 and 6-11, except for the last monkey. In cortex shaded green, the fixating eye was perceptually dominant most of the time in the visual field, and the chronically deviated eye was suppressed. In cortex shaded red, the reverse was true. This interpretation is based on the assumption that darker CO activity is present in ocular dominance columns serving the perceiving eye in any given region of cortex (whether or not that eye happens to be fixating). The patterns of suppression found in these animals are compatible with clinical data in human subjects with strabismus. These data show that in exotropes, the temporal retina is suppressed preferentially, as we found in four of five monkeys. In our monkeys, the pale border strip pattern, which occurred in cortex where both eyes perceived about equally, was always sandwiched between more peripheral cortex where opposite eyes dominated. This finding also supports our contention that these CO patterns are related to perceptual dominance of each eye in local portions of the visual field. The dark ovals are the blind spot "representations," which extend from 12 to 18° along the horizontal meridian.

The monkeys in this study all had divergent strabismus, but a range of CO patterns was seen. Each pattern made sense, in termsof the animal's fixation behavior, which strengthens our hypothesisthat it correlated with suppression in the visual field. Threemonkeys had a strong fixation preference (Monkeys 1-3). Monkey1 had darker CO staining in the fixating eye's ocular dominancecolumns everywhere in both cortices, implying complete suppressionof the exotropic eye. Monkey 2 also had darker CO staining inthe fixating eye's ocular dominance columns, except in the peripheralright cortex, where a switch took place in favor of the deviatingleft eye. This CO pattern signified perceptual dominance of thefixating right eye everywhere in the visual field, except in theleft periphery. This is a common pattern of suppression in humanexotropes (Melek et al., 1992). In Monkey 3, the CO pattern wassimilar, except that border strips were present on the right operculum.In this monkey, the temporal retina of the deviating left eyewas entirely suppressed. The temporal retina of the fixating righteye was also suppressed, except for the temporal macula, wheresuppression alternated with the nasal macula of the lefteye.

Monkeys 4 and 5 had weak fixation preferences. Not surprisingly, their cortical CO patterns revealed pale border strips inthe central field representations bilaterally. Border strips mayhave appeared because their fixation preferences were too weakto produce a strong CO pattern favoring the dominant eye (i.e.,thin dark-wide pale columns). Alternatively, the animals' centralsuppression scotomas may have shifted back and forth between thetwo eyes, without an actual change in fixation. Our methods couldnot distinguish between these two possibilities. Outside the maculae,the temporal retinas of both animals were suppressed, as one wouldexpect inexotropia.

Studies of the visual fields in subjects with strabismus have documented a confusing range of findings, depending on the techniqueused to map suppression scotomas (Jampolsky, 1955; Pratt-Johnsonand MacDonald, 1976; Sireteanu and Fronius, 1981; Sireteanu, 1982;Cooper and Record, 1986; Joosse et al., 1990, 1997; Melek et al.,1992). Mapping of the visual fields in strabismus is tricky, becauseone must dissociate the eyes enough to plot suppression scotomas,but not too much, or else they vanish. The conflicting resultsfrom various studies have been blamed on methodological differences(Mehdorn, 1989). It is also likely, judging from the range ofCO patterns seen in our monkeys, that suppression scotomas varywidely in size, depth, and location, depending on the degree ofocular misalignment and the strength of fixation preference displayedby the subject. In general, clinical studies agree that the temporalretina is suppressed in exotropia (von Noorden, 1996). This findingprevailed in ourmonkeys.

Two other reports have described CO patterns in strabismic monkeys. Tychsen and Burkhalter (1997) reported "spontaneous" oculardominance columns in an exotropic M. mulatta raised with dailyalternate occlusion of one eye. No second label was used, so theCO pattern was difficult to interpret. In a second animal, a M.nemestrina with naturally occurring esotropia, wheat germ agglutinin-horseradishperoxidase (WGA-HRP) was injected into one eye to label the oculardominance columns. Unfortunately, this tracer produces an intenseuveitis, factitiously reducing CO activity in the injected eye'socular dominance columns (Horton and Hocking, 1996b). Tychsenand Burkhalter reported that CO rich stripes corresponded to "nasalODCs" (i.e., ocular dominance columns serving the contralateraleye) in both V1s, a result that cannot be attributed to damagefrom WGA-HRP injection. Their finding was consistent with thetheory that functional dominance of the nasal retina contributesto esotropia (Tychsen and Lisberger, 1986) but was exactly oppositeto the pattern of CO activity one would expect from regional suppressionin convergent strabismus. Tychsen and Burkhalter (1997) did notillustrate both labels in the same region of cortex, so theirexperiment is difficult to assess, but it highlights the needfor further studies of CO patterns inesotropia.

In a second report, Fenstemaker et al. (1997) examined CO staining in three monkeys with strabismic amblyopia. They founda pattern of alternating thin dark and wide pale columns, butparadoxically, the thin dark columns were thought to match theamblyopic eye's ocular dominance columns. This assignment wasmade by stimulating the amblyopic eye for 2 hr, while the monkeywas still anesthetized at the end of a recording session, andthen immunostaining alternate sections for the transcription factorEGR-1 (Zif-268) (Chauduri et al., 1995). It is possible that 2hr of visual stimulation were not enough to erase a preexistingEGR-1 bias in favor of the fixating eye's ocular dominance columns.EGR-1 patterns can linger long after stimulus conditions change,mandating caution when using this approach to assign CO columnsto one eye or the other (Horton and Hocking, 1998a). That is whywe elected to use [³H]proline as a second label in our experiments. Recently, we haveused EGR-1 successfully, under different stimulus conditions,to show that darker CO staining is associated with the fixatingeye in most of striate cortex (Horton and Hocking, 1998b).

Induction of strabismus in adults creates binocular rivalry. Leopold and Logothetis (1996) have reported that ~20% of neuronsin V1 and V2 of normal, trained monkeys modulates responses accordingto which eye is perceiving during binocular rivalry. An even greaterpercentage of neurons modulates activity in downstream visualareas such as V4. To explore further the issues raised by ourfindings, the best approach would be to map the visual fieldsdichoptically in strabismic monkeys. One could then record fromsingle neurons to correlate changes in firing rates with switchesin fixation, suppression scotomas, and cortical patterns of COactivity. This strategy could provide direct evidence that theCO patterns we have described in this report arise from perceptualsuppression.

  FOOTNOTES

Received April 28, 1999; revised June 7, 1999; accepted June 7, 1999.

This work was supported by National Eye Institute Grant RO1 EY10217 and Core Grant EY02162, That Man May See, and Researchto Prevent Blindness. We thank Dr. Douglas R. Fredrick and Dr.Creig S. Hoyt for their help in evaluating the animals' ocularfixation preferences and Robin Troyer for assistance with animalcare and surgery. We also thank the California Regional PrimateResearch Center (especially Dr. Celia Valverde, Jenny Short, andDavid Robb). The California Primate Center is supported by NationalInstitutes of Health Base Grant RR00169. William T. Newsome, ArthurJ. Jampolsky, Nélida B. Melek, and Anne K. Churchland providedvaluable comments on thismanuscript.
Correspondence should be addressed to Dr. Jonathan C. Horton, Beckman Vision Center, 10 Kirkham Street, University of California,San Francisco, San Francisco, CA 94143-0730.

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MATERIALS AND METHODS
RESULTS
DISCUSSION
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