Retinotopy and Functional Subdivision of Human Areas MT and MST

doi:20026661

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 ISI 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 ISI Web of Science (91)

Citing Articles via Google Scholar

Google Scholar

Articles by Huk, A. C.

Articles by Heeger, D. J.

Search for Related Content

PubMed

PubMed Citation

Articles by Huk, A. C.

Articles by Heeger, D. J.

Previous Article  |  Next Article

The Journal of Neuroscience, August 15, 2002, 22(16):7195-7205

Retinotopy and Functional Subdivision of Human Areas MT and MST
Alexander C. Huk, Robert F. Dougherty, and David J. Heeger
Department of Psychology, Stanford University, Stanford, California 94305-2130

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We performed a series of functional magnetic resonance imaging experiments to divide the human MT+ complex into subregionsthat may be identified as homologs to a pair of macaque motion-responsivevisual areas: the middle temporal area (MT) and the medial superiortemporal area (MST). Using stimuli designed to tease apart differencesin retinotopic organization and receptive field size, we establisheda double dissociation between two distinct MT+ subregions in 8of the 10 hemispheres studied. The first subregion exhibited retinotopicorganization but did not respond to peripheral ipsilateral stimulation,indicative of smaller receptive fields. Conversely, the secondsubregion within MT+ did not demonstrate retinotopic organizationbut did respond to peripheral stimuli in both the ipsilateraland contralateral visual hemifields, indicative of larger receptivefields. We tentatively identify these subregions as the humanhomologues of macaque MT and MST, respectively. Putative humanMT and MST were typically located on the posterior/ventral andanterior/dorsal banks of a dorsal/posterior limb of the inferiortemporal sulcus, similar to their relative positions in the macaquesuperior temporalsulcus.

Key words: area MT; area MST; area MT+; visual motion; direction-selectivity; retinotopy; homology

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Functional imaging studies in humans have identified a cortical region with particularly strong responses to moving stimuli.This region, referred to variously as human MT+ or V5, is typicallyfound on the lateral surface of the occipital lobe, often withina dorsal/posterior limb of the inferior temporal sulcus (ITS)(Zeki et al., 1991; Watson et al., 1993; Tootell et al., 1995;Dumoulin et al., 2000). On the basis of its sensitivity to movingstimuli, MT+ has been hypothesized to be homologous to motion-sensitivevisual areas in the macaque dorsal superior temporal sulcus (STS).The case for this homology rests on the general location of MT+with respect to other identified visual areas in both species,on its anatomical structure (Tootell and Taylor, 1995), on itsheightened sensitivity to low-contrast moving stimuli relativeto other visual areas (Tootell et al., 1995), and on evidencethat direction-selective signals underlie MT+ activity (Heegeret al., 1999; Huk et al., 2001; Huk and Heeger, 2002). The presentstudy assesses the retinotopic organization and receptive fieldsizes within human MT+, with the goal of subdividing it into distinctfunctional regions that may be identified as homologs of the macaquemiddle temporal (MT) and medial superior temporal (MST) visualareas.

The STS of the macaque monkey brain contains several areas that are selectively sensitive to visual motion. These includeMT, the lateral and dorsal subdivisions of MST (MSTl and MSTd),and the floor or fundus of the STS (FST) (Allman and Kaas, 1971;Dubner and Zeki, 1971; Maunsell and Van Essen, 1983; Albrightet al., 1984; Desimone and Ungerleider, 1986; Saito et al., 1986;Komatsu and Wurtz, 1988a). Most neurons in areas MT and MST arestrongly direction-selective, and several lines of evidence suggestthat these areas are important in processing neuronal signalsrelated to visual motion (Zeki, 1974; Van Essen et al., 1981;Newsome et al., 1983; Albright et al., 1984; Movshon et al., 1986;Saito et al., 1986; Tanaka and Saito, 1989; Duffy and Wurtz, 1991b),and that activity in these areas is linked to the perception ofmotion (Dursteler and Wurtz, 1988; Newsome and Pare, 1988; Salzmanet al., 1992; Celebrini and Newsome, 1995; Orban et al., 1995;Britten and van Wezel, 1998). Although contiguous, these areasare distinguishable based on anatomical location, functional properties,architecture, and connectivity (Van Essen et al., 1981; Saitoet al., 1986; Ungerleider and Desimone, 1986; Komatsu and Wurtz,1988a,b; Boussaoud et al., 1992).

The experiments described here aim to divide the human MT+ complex into regions that are homologous to the macaque STS motionareas MT and MST by exploiting two functional differences betweenthese areas. First, MT has a distinguishable retinotopic map,whereas MST exhibits a much coarser retinotopic organization (Gattassand Gross, 1981; Albright and Desimone, 1987; Maunsell and VanEssen, 1987). Second, at a given visual eccentricity, MST neuronshave much larger receptive fields than MT neurons. In particular,the receptive fields of MST neurons, but not MT neurons, oftenextend >10° into the ipsilateral hemifield (Desimone and Ungerleider,1986; Albright and Desimone, 1987; Komatsu and Wurtz, 1988a; Tanakaand Saito, 1989; Duffy and Wurtz, 1991a).

Using stimuli designed to assess retinotopic organization and receptive field size, we were able to "double-dissociate" twodistinct regions within human MT+. The first region exhibitedstrong response modulations to a rotating-wedge stimulus designedto measure retinotopic organization. This region often exhibiteda systematic map of the angular component of the visual fieldbut did not respond to peripheral ipsilateral stimulation. Conversely,the second region within MT+ did not demonstrate a strong responsemodulation to the rotating-wedge (retinotopy) stimulus but didrespond to peripheral stimuli in both the ipsilateral and contralateralvisual hemifields. We tentatively identify these two regions asthe human homologs of macaque MT and MST, respectively. Some ofthese results have been presented previously in abstract form(Dougherty et al., 1999; Khan et al., 1999).

Although previous experiments have assessed ipsilateral responses within human MT+ (Tootell et al., 1998; Dukelow et al.,2001), and hence offer some evidence for large receptive fieldswithin a region of MT+, our experiments are distinct in that theyprovide conclusive evidence for a double-dissociation of humanMT and MST. A previous study of MT+ subdivision defined putativearea MT as the part of MT+ that did not exhibit ipsilateral responses(Dukelow et al., 2001). Our experiments use two complementarymeasurements, one indicating relatively large receptive fieldsand the other indicating relatively small receptive fields. Inaddition to providing positive evidence for the existence of humanMT as well as MST, our measurements revealed retinotopic organizationin human MT that was similar to that previously documented inmacaque MT (Gattass and Gross, 1981; Albright and Desimone, 1987;Maunsell and Van Essen, 1987), further strengthening the casefor the homology between these cortical motion-processing structuresin humans andmacaques.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects
Five right-handed volunteers (four males, one female, aged 26-39) participated in the study. All subjects were experiencedpsychophysical observers, well practiced at maintaining fixation,and had participated previously in other functional magnetic resonanceimaging (fMRI) studies. Consent was obtained and all procedureswere in compliance with safety procedures for MR research. Eachsubject participated in five scanning sessions: one session toobtain high-resolution anatomical images of the brain, one toidentify MT+ and to measure the angular component of the retinotopicmap, two to measure contralateral versus ipsilateral responses(one for each visual hemifield), and one to measure the centralversus peripheral representations of the retinotopic map. In allsessions, subjects were instructed to attend to the motion ofthe dots while maintaining fixation on a 0.5°, full-contrast fixationpoint.

Visual stimuli
Stimuli were presented on a flat-panel display (multisynch LCD 2000; NEC, Itasca, IL) placed in a Faraday box with an electricallyconductive glass front, positioned near the subjects' feet. Subjectslay on their backs in the bore of the MR scanner and viewed thedisplay through binoculars with a pair of angled mirrors attachedjust beyond the two objectivelenses.

MT+ localizer stimulus
Area MT+ was functionally identified based on responses to stimuli that alternated in time between moving and stationary dotpatterns (Fig. 1A), as per conventional methods (Zeki et al.,1991; Watson et al., 1993; Tootell et al., 1995). Moving dotstraveled toward and away from fixation (8°/sec) within a 21° diametercircular aperture, alternating direction once per second (whitedots on a black background; dot diameter of 0.25°). After 9 sec,the moving-dot field was replaced by 27 sec of a stationary-dotfield. This moving/stationary cycle was repeated seven times ineach fMRI scan. We used this uneven duty cycle (9 sec moving,27 sec stationary = 25% duty cycle) to match the duty cycle ofthe retinotopy stimulus (described below). This MT+ localizerscan was repeated four to six times for each subject.

View larger version (71K):
[in this window]
[in a new window]
Figure 1. Stimuli. A, Moving versus stationary, localizing MT+. Area MT+ was identified based on responses to stimuli that alternated in time between moving (radially inward and outward from fixation, alternating direction every second, for 9 sec) and stationary (27 sec) dot patterns, while subjects fixated a small, high-contrast square in the center of the dot field. B, Retinotopy rotating wedge, identifying MT. The angular component of retinotopic organization was measured by having subjects fixate the center of a dot field with one-quarter of the field (a 90° wedge) containing moving dots. Every 2 sec, the wedge containing the moving dots rotated 20°, completing a full rotation every 36 sec. C, Ipsilateral stimulation, identifying MST. Responses to ipsilateral stimulation were assessed by presenting a peripheral dot patch in either the left or right visual field. The 15° diameter field of dots alternated between moving (18 sec) and stationary (18 sec), while subjects maintained fixation on a small, high-contrast square 10° from the nearest edge of the dot patch. D, Central versus peripheral visual field. The radial component of retinotopic organization was assessed by alternating moving dots within the central (4° outer radius) and peripheral (4° inner radius; 16.5° outer radius) parts of the visual field while subjects maintained central fixation.

Retinotopy stimulus
We measured the polar angle component of the retinotopic map within MT+ using a motion-defined wedge that rotated slowly throughthe visual field, about a central fixation point (Fig. 1B). Similarto the MT+ localizer stimulus, the retinotopy stimulus was a 21°diameter circular aperture filled with white dots on a black background.At any given time, the dots within a 90° wedge of the aperturemoved toward and away from fixation as in the MT+ localizer stimulus,but unlike the MT+ localizer, the rest of the dots were stationary.This motion-defined wedge rotated 20° every 2 sec, completinga full rotation every 36 sec. Thus, the 21° diameter circularaperture was always filled with dots: dots falling within thecurrent position of the wedge moved inward/outward from fixation,dots falling outside the wedge were stationary. Each part of thevisual field contained moving dots for 25% of the time, matchingthe duty cycle of the MT+ localizer described above. During eachscan, the moving-dot wedge completed seven cycles of rotationwhile the subject held fixation in the center of the screen. Thisretinotopy scan was repeated the same number of times as the MT+localizer scans (four to six times) for each subject, in the samescanning session as the MT+localizer.
The rotating-wedge stimulus evokes a traveling wave of activity in retinotopically organized visual areas; similar contrast-and flicker-defined wedges are used routinely to identify theearlier retinotopic areas including V1, V2, V3, V3A, V3B, V7,and V4v (Engel et al., 1994; Sereno et al., 1995; DeYoe et al.,1996; Engel et al., 1997; Press et al., 2001). Because the wedgerotates through the angular component of the visual field, thetemporal phase of the fMRI signal corresponds to the corticalrepresentation of angular position. One can also interpret theamplitude of the fMRI response to this rotating-wedge stimulusas an indirect measurement of receptive field size. A neuron witha relatively small receptive field would be stimulated by thewedge only during a part of each rotation. A neuron with a largerreceptive field, in contrast, would be stimulated through mostof the cycle of the wedge. Thus, the rotating wedge would elicita strong modulation of neuronal activity in visual area MT, whichcontains neurons with relatively small receptive fields, but aweak modulation of activity in visual area MST, which containsneurons with relatively large receptivefields.

Ipsilateral stimulus
Ipsilateral stimulation is a complementary test to distinguish MST from MT. We tested for ipsilateral responses using stimulirestricted to either the left or right hemifield. The stimulialternated every 18 sec between a field of moving dots and a similarfield of static dots for seven cycles (Fig. 1C). The dots wererestricted to a peripheral circular aperture (15° diameter) withits closest edge 10° from fixation. These peripheral moving stimuliwould be expected to evoke neuronal activity in the contralateralhemisphere in both macaque MT and MST, but they would be expectedto evoke activity in the ipsilateral hemisphere only in MST, wherethe receptive fields are large enough to extend into the ipsilateralhemifield. The ipsilateral scans were repeated 6-12 times in eachhemifield for eachsubject.

Central versus peripheral stimulus
We also assessed the cortical representations of the central and peripheral visual field by presenting moving dots alternatelyin the center and periphery (Fig. 1D). The stimulus was a 33°diameter circular field of white dots on a black background. Dotswere stationary except for a region of moving dots that alternatedevery 18 sec between a central disc (4° radius) and a peripheralannulus (4° inner radius; 16.5° outer radius). This central/peripheralcycle was repeated seven times in each fMRI scan. This center-peripheryscan was repeated 8-12 times for eachsubject.

fMRI methods
fMRI data acquisition. MR imaging was performed using a 3 tesla MRI scanner (General Electric, Fairfield, CT) with a custom-designeddual surface coil (Nova Medical, Inc., Wakefield, MA). Subjectsviewed the stimuli while 14 fMRI slices were acquired at 2 secintervals using a T2*-sensitive, spiral-trajectory, gradient-echopulse sequence (Glover and Lai, 1998; Glover, 1999). For our particularscanner hardware, spiral fMRI pulse sequences compare favorablywith echo-planar imaging in terms of sensitivity and spatial andtemporal sampling resolution (Sawyer-Glover and Glover, 1998).Pulse sequence parameters were: 1000 msec repetition time (TR),40 msec echo time (TE), 55° flip angle, two interleaves, inplanevoxel size of 2 × 2 mm, slice thickness of 3 mm, and 14 slicesoriented parallel to the calcarine sulcus with the lowest slicenear the ventral surface of the occipitallobe.
To minimize head movements, the subject's head was stabilized with a bite bar. The time series of images from each scan werevisually inspected for head movements. No post hoc motion correctionwas applied, because there was no indication of head movementsin any of thescans.
Each MR scanning session began by acquiring a set of T1-weighted anatomical images using the same slice prescription as thefunctional images (spoiled gradient-recalled acquisition in thesteady state; field of view, 220 mm; TR, 68 msec; TE, 15 msec;echo-train length, 2). The inplane anatomical images were alignedto a high-resolution anatomical volume of each subject's brainso that all MR images (across multiple scanning sessions) froma given subject were coregistered with an accuracy of ~1 mm (Nestaresand Heeger, 2000). The high-resolution anatomical images werealso used to restrict the functional data analyses to gray-mattervoxels and to create flattened visualizations of cortex (seebelow).
fMRI data analysis. Data from the first cycle (36 sec) of each fMRI scan were discarded to avoid transient effects of magneticsaturation and to allow the hemodynamics to reach steady state(noting that the full duration of the hemodynamic impulse responseis well over 20 sec). During the remaining six cycles of eachscan, 108 functional images (one every 2 sec) were recorded foreach slice. For each voxel, the image intensity changed over timeand comprised a time series of data. The fMRI time series werepreprocessed by: (1) high-pass filtering the time series at eachvoxel to compensate for the slow signal drift typical in fMRIsignals (Smith et al., 1999), (2) dividing the time series ofeach voxel by its mean intensity to convert the data from arbitraryimage intensity units to units of percentage signal modulationand to compensate for the decrease in mean image intensity withdistance from the surface coil, and (3) averaging the time seriesof each voxel across repeated scans of the same stimuluscondition.
The resulting mean time series were analyzed to locate gray-matter regions that responded strongly to the periodic changesin the stimuli. We fit a (36 sec period) sinusoid to the timeseries at each voxel and computed: (1) the correlation betweenthe time series at each voxel and the corresponding best-fittingsinusoid and (2) the phase of the best-fitting sinusoid at eachvoxel. The correlation measures signal to noise (Engel et al.,1997), taking a value near 1 when the fMRI signal modulation atthe stimulus-alternation period (36 sec) is large relative tothe noise (at the other frequency components) and a value near0 when there is no signal modulation or when the signal is smallcompared with the noise. The phase measures the temporal delayof the fMRI signal relative to the beginning of the stimulus cycle.For the rotating-wedge retinotopy stimulus, the phase correspondsto angular position in the visual field. For the central versusperipheral stimulus, the phase corresponds to eccentricity inthe visualfield.
To better visualize the results, we rendered the fMRI data on a computationally flattened representation ("flat map") of relevantregions of each subject's brain (Fig. 2A). We segmented the gray-and white-matter voxels in the high-resolution anatomical imagesusing a Bayesian classification algorithm (Teo et al., 1997) andthen performed manual refinements of the segmentation in the anatomicalarea of interest to preserve the topography of the fMRI responsesas accurately as possible. Specifically, we inspected the lateraloccipital lobe and ensured that: (1) the tissue identified asgray matter extended completely into the fundus of each sulcus(to be sure that responses from voxels in the deepest part ofthe sulcus were not missed) and (2) gray matter on opposite banksof each sulcus did not touch (to avoid mixing the responses fromopposite sides of the sulcus). The gray matter in the vicinityof MT+ was computationally flattened using an algorithm designedto preserve distances within the folded gray-matter surface (Wandellet al., 2000). Because the data from all fMRI scans of a givensubject were coregistered with the high-resolution anatomicalimages of that subject's brain, all of that subject's data couldbe superimposed on a common flat map.

View larger version (83K):
[in this window]
[in a new window]
Figure 2. MT+ subdivision and retinotopy for subject A.R.W. (right hemisphere). A-D show fMRI responses on a 35-mm-radius flat map, centered within the fundus of the occipital continuation of the ITS. Green and cyan outlines indicate areas MT and MST. A, Response to MT+ localizer. A strong response is evident throughout MT+. Colors correspond to correlation values above threshold (r > 0.50). B, Response to retinotopy stimulus. The posterior subregion (MT) responded strongly to the rotating-wedge stimulus (green outline). Colors correspond to angular position in the visual field, given that responses are above the correlation threshold (r > 0.50). Note the smooth progression of phases from posterior-ventral to anterior-dorsal (cyan/blue, lower-left quadrant of visual field; magenta/red, upper-left quadrant). Responses corresponding to the ipsilateral visual field (which would be colored green-yellow-orange) were not observed at this correlation threshold, and thus are not evident on the flat map and have not been depicted in the color bar. C, Response to ipsilateral stimulus. The distinct, anterior subregion (MST) responded to ipsilateral stimulation (cyan outline). Colors correspond to correlation values above threshold (r > 0.60). D, Response to central versus peripheral stimulus. The ventral base of MT+ responded strongly to central stimulation, whereas the periphery was represented more dorsally. Colors correspond to the timing of response (phase), which corresponds to eccentric position (i.e., orange, central; blue, peripheral) in the visual field, given that responses are above the correlation threshold (r > 0.35). Representation of visual field eccentricity is indicated as central (Cen) or peripheral (Per). Scale bar, 10 mm.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The subdivision of MT+ for one subject is shown on the flat maps in Figure 2. The subdivisions for all subjects are shownin Figures 3 and 4. Area MT is indicated by the green boundariesdrawn on the flat maps. The adjacent cyan boundaries indicatearea MST. The colored pixels in Figures 2-4 correspond to gray-matterlocations where the responses were particularly strong (i.e.,exceeding a correlation threshold) (see Materials and Methods,fMRI data analysis). By varying the correlation thresholds andvisually inspecting the data on the flat maps, we confirmed thatour identifications of MT and MST did not depend strongly on theparticular values of the correlation threshold used to generateFigures 2-4.

View larger version (62K):
[in this window]
[in a new window]
Figure 3. MT+ subdivision and retinotopy for all five subjects (right hemisphere). A-C, Responses to MT+ localizer, retinotopy, and ipsilateral stimuli, respectively (in the same format as Fig. 2A-C). MT is evident in all subjects, and MST is evident in all subjects except R.F.D. Correlation thresholds for localizer and retinotopy scans were as follows: A.R.W., 0.50; A.A.B., 0.52; A.C.H., 0.43; D.J.H., 0.55; and R.F.D., 0.42. Correlation thresholds for ipsilateral scans were as follows: A.R.W., 0.60; A.A.B., 0.65; A.C.H., 0.47; D.J.H., 0.36; and R.F.D., 0.29. Exact values of correlation thresholds were chosen for display; other correlation thresholds yielded similar results.

View larger version (61K):
[in this window]
[in a new window]
Figure 4. MT+ subdivision and retinotopy for all five subjects (left hemisphere). Format is the same as in Figure 3. MT is evident in all subjects, and MST is evident in all subjects except R.F.D. Correlation thresholds for localizer and retinotopy scans were as follows: A.R.W., 0.62; A.A.B., 0.51; A.C.H., 0.46; D.J.H., 0.62; and R.F.D., 0.23. Correlation thresholds for ipsilateral scans were as follows: A.R.W., 0.61; A.A.B., 0.54; A.C.H., 0.56; D.J.H., 0.64; and R.F.D., 0.40.

Identifying MT+

MT+ was identified, separately for each subject, based on a combination of anatomical and functional criteria. Specifically,a contiguous region was marked by hand to include voxels on thelateral surface of the occipital lobe, where the fMRI time seriescorrelated strongly with the moving/stationary stimulus alternations(r > ~0.5, chosen separately for each subject). Figure 2A showsa flat-map representation of MT+ localizer responses in onehemisphere.

MT+ was similarly localized bilaterally in all hemispheres of all subjects (Figs. 3A, 4A). Its location was anterior to anddistinct from the retinotopically defined areas V1, V2, V3, V3A,and V4v, whose locations had been identified previously in allsubjects. It fell mostly or entirely within a single sulcus. Weoccasionally noticed (three hemispheres) a swath of activity slightlyposterior and/or ventral to MT+ on the flat maps. Despite itsclose proximity to MT+, we excluded this patch of activity fromMT+ for two reasons. First, this activity was often found in adifferent sulcus (or sulci), with MT+ clearly on the other sideof an intervening gyrus [a fact somewhat obscured on the flat-maprepresentation but more evident when the data are viewed in sagittalslices of the three-dimensional (3D) brain volume]. Second, theapplication of a high correlation threshold (higher than thatused in the figures) to the MT+ localizer responses revealed aclear distinction between MT+ and this posterior-ventral activity.In fact, the MT+ localizer stimulus elicited activity throughoutmuch of the occipital lobe; the responses were simply stronger(i.e., withstanding a higher correlation threshold) in MT+.

Identifying MT: angular component of retinotopy

Area MT was defined, separately for each subject, to include a contiguous subregion of MT+ that exhibited strong responsemodulations during the retinotopy scans. The same correlationthreshold was applied to the MT+ localizer (Fig. 2A) and the retinotopydata (Fig. 2B). Because we collected equal numbers of repeatsof both of these conditions, and because the duty cycles of bothof these stimuli were the same (see Materials and Methods, visualstimuli), applying the same correlation threshold allowed fora fair comparison of the spatial extent of the responses to thesetwo stimulusconditions.

A retinotopic subregion of MT+ is clearly visible in Figure 2B and is marked by the green curve drawn on the flat map. Thefact that this subregion of MT+ responded strongly to the rotating-wedgestimulus suggests that neurons within this area have relativelysmall receptive fields. In addition, the phase map varies smoothlyfrom magenta/red (upper-left quadrant of visual field) throughpurple [horizontal meridian (HM)] through blue/cyan (lower-leftquadrant), suggesting orderly retinotopicorganization.

Area MT was discernable based on strong responses to the rotating-wedge stimulus in both hemispheres of all subjects (Figs.3B, 4B). We were also able to discern a qualitatively clear andorderly retinotopic phase map in 5 of the 10 hemispheres. In allhemispheres for which the angular retinotopic map was easily discernable,the representation of the upper vertical meridian (UVM) was anteriorto the representation of the lower vertical meridian (LVM). Evenwhen the retinotopic map within the area did not include a smoothprogression of phases, we chose to define the area whenever therewas a contiguous subregion of MT+ that responded strongly to therotating-wedge stimulus. A strong response to the rotating-wedgestimulus implies that neurons within each fMRI voxel had relativelysmall receptive fields at the same or nearby locations in thevisual field. Thus, even when visual inspection did not revealan orderly retinotopic phase map, the presence of a strong responsemodulation provided evidence of relatively small receptive fieldsand local retinotopicorganization.

Identifying MST: ipsilateral stimulation

Area MST was defined, separately for each subject, to include a contiguous subregion of MT+, distinct from retinotopicallydefined MT, that responded strongly to peripheral, ipsilateralstimulation. Figure 2C shows the ipsilateral responses in theright hemisphere of one subject. Although ipsilateral responseswere relatively weak compared with contralateral responses, asubregion of ipsilateral activity was clearly identifiable, markedby the cyan curve drawn on the flat map. This same subregion didnot respond strongly to the retinotopy stimulus; this double dissociationis evident by contrasting Figure 2B,C.

Area MST, as defined by the dual criteria of a response to ipsilateral stimulation and lack of a strong response modulationto the retinotopy stimulus, was evident in both hemispheres offour of the five subjects (Figs. 3C, 4C). In defining MST, wefirst noted the subregion of MT+ that did not exhibit a strongmodulation of response to the retinotopy stimulus and then definedarea MST as a nonretinotopic region that did respond stronglyto the ipsilateral stimulus. Furthermore, we chose to identifyMST only if a strong ipsilateral response was not also presentin the retinotopic region. We note that these conservative criteriasometimes left some parts of MT+ unclassified (neither MT norMST). MST, in the eight hemispheres in which it was identified,was always anterior and often dorsal to MT, although there wassome degree of variability across subjects. In these eight hemispheres,MST typically abutted MT; when some degree of separation was apparent,the areas were still within ~5 mm of one another along the gray-mattersurface.

However, in the remaining subject (R.F.D., left and right hemispheres) we did not observe a clear double dissociation betweentwo subregions of MT+. Although we were able to identify a retinotopicMT subregion in both hemispheres of this subject, responses toipsilateral stimulation were either too weak or too diffuse toconfidently identify a distinct MST region. Ipsilateral responsesin both hemispheres of this subject were notably weaker than thoseobserved in the other subjects. Also, in both hemispheres of thissubject, the anatomical location of MT+ was less distinct anddid not fall primarily within a single sulcus, as it did in mostsubjects. Because the local cortical anatomy of this region isquite variable across individuals (Watson et al., 1993; Tootellet al., 1995; Dumoulin et al., 2000), our sample is too smallto determine where subject R.F.D.'s organization lies with respectto the normal range. Critically, the failure to identify MST inthis subject demonstrates that our procedure (first identifyinga retinotopic subregion and then looking for a distinct subregionthat responded to ipsilateral stimuli) did not logically guaranteethat we would observe the desired doubledissociation.

Central and peripheral retinotopic representations

We also measured the cortical representations of the central and peripheral portions of the visual field by alternating movingdots within central (4° outer radius) and peripheral (4° innerradius; 16.5° outer radius) parts of the visual field. The responseto the central versus peripheral stimulus for one subject is shownin Figure 2D. A large central representation is evident in theventral portions of both MT and MST, and a smaller peripheralrepresentation is evident in the more dorsal portions, particularlywithin areaMT.

The subregion of MT corresponding to the central representation of the visual field typically (in 8 of 10 hemispheres) coveredthe ventral (and sometimes posterior) extreme of MT. Responsesto peripheral stimulation were typically found at the dorsal and/oranterior borders of MT, although responses to the peripheral stimuluscovered much less cortical area than responses to the centralstimulus. Responses in this experiment were rather noisy, particularlyin MST, consistent with larger receptive fields that might beexpected to cover both the central and peripheral stimuli. Despitethe noise, we did observe a clear response to the central stimulusin MST in five of the eight hemispheres in which we were ableto identify MST. The representation of the central part of thevisual field in both regions provides additional evidence thatMST reflects a distinct cortical area and not simply the peripheralretinotopic representation of a single, largerarea.

Position and size of MT+ subregions

To better evaluate the relative positions of these areas in the 3D cortical volume, we transformed the regions correspondingto MT and MST from the flat map to the corresponding gray matterin the high-resolution anatomy images of each subject's brain.In all of the eight hemispheres in which we were able to defineboth MT and MST, we observed that MT fell primarily on the posterior(-ventral) bank of a sulcus, whereas MST fell on an anterior (-dorsal)bank. This sulcus could usually be identified as a dorsal/posteriorlimb of the ITS (Dumoulin et al., 2000). Although this dorsal/posteriorcontinuation of the ITS was the clearest anatomical landmark,we also observed that MT+ sometimes continued posteriorly intothe lateral occipital sulcus and/or onto the lateral occipitalgyrus.

Viewing the fMRI responses in the high-resolution volume anatomy also reveals the relative positions of MT and MST and confirmsthat the geometrical distortion inherent in transforming the functionaldata to the flat maps did not introduce any systematic artifacts.Figure 5A shows the responses to the MT+ localizer, the retinotopystimulus, and the ipsilateral stimulus on an axial slice in onesubject. In the left panel, a strong response to the MT+ localizeris evident on both sides of the sulcus (the center of the sulcusis indicated by the arrow). In the center panel, a strong responseto the retinotopy stimulus is evident only on the posterior bankof the sulcus. Conversely, in the right panel, the region respondingto ipsilateral stimulation lies on the anterior bank of the sulcus.Similar organization is evident in Figure 5B,C, which shows coronaland sagittal slices, respectively, in two additional subjects.

View larger version (117K):
[in this window]
[in a new window]
Figure 5. Spatial separation of retinotopy and ipsilateral responses in the cortical volume. A, fMRI responses shown in axial slices through the cortical volume (subject A.R.W., right hemisphere). The arrow indicates the center of the sulcus. Note that localizer responses (MT+) fall on both sides of the sulcus (left panel), retinotopy responses (MT) fall primarily on the posterior bank (middle panel), and ipsilateral responses (MST) are primarily restricted to the anterior bank (right panel). B, Coronal slices (subject A.A.B., left hemisphere, same format as in A). C, Sagittal slices (subject D.J.H., left hemisphere, same format as in A). A, Anterior; L, lateral; D, dorsal; M, medial; P, posterior.

Table 1 reports the gray-matter surface area for MT, MST, and MT+. On average, MT subsumed ~243 mm² and MST subsumed ~83 mm². Sizes for MST are likely to be underestimates, because of theconservative criteria used in defining this area (see Results,Identifying MST: ipsilateral stimulation). Size can also be estimatedby visual inspection of the figures, because all flat maps hada 35 mm radius. Postmortem anatomical studies in a similar partof human cortex have identified a region of dense myelination,believed to correspond to MT, covering ~200 mm² (Tootell and Taylor, 1995).


View this table:
[in this window]
[in a new window]
Table 1. Visual area sizes

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Human area MT+ can be functionally subdivided into two distinct areas that we tentatively identify as MT and MST. The retinotopicorganization of area MT can be measured using a rotating-wedgestimulus, and this area responds primarily to stimuli in the contralateralvisual hemifield. Area MST does not exhibit clear retinotopicorganization but does respond to peripheral (>10° from the verticalmeridian) ipsilateral stimulation. Figure 6 shows representativelocations of areas MT and MST in the cortical volume and schematizesour proposed organization of MT+ on a flat map. Table 2 summarizesour results in each of the 10 hemispheres studied.

View larger version (45K):
[in this window]
[in a new window]
Figure 6. Proposed location of MT and MST in sagittal, 3D, and flattened views. A, Position of MT+ shown on a sagittal slice through the cortical volume. MT+ is indicated by a blue outline in the ascending occipital continuation of the ITS. The STS is indicated for reference. B, Position of MT and MST, viewed on a 3D cortical reconstruction, for subject A.A.B. (left hemisphere). MT (green) falls on the posterior bank of the occipital continuation of the ITS, whereas MST (cyan) falls on the anterior bank. The STS is indicated for reference. Other visual areas are shown for reference: V1, red; V2, magenta; V3, blue; V3a/b, yellow. The image is reversed left to right to parallel A and C. C, Flat-map schematic of MT and MST. MT+ is outlined in blue, MT is outlined in green, and MST is outlined in cyan. Axes drawn within MT schematize the retinotopic organization observed, with more posterior/ventral portions representing the lower visual field (LVM) and more anterior/dorsal transition representing the upper visual field (UVM). Representation of visual field eccentricity is indicated as central (Cen) or peripheral (Per). The dashed line indicates the fundus of a dorsal/posterior limb of the ITS.


View this table:
[in this window]
[in a new window]
Table 2. Summary of MT+ subdivision results

Inferences about neuronal receptive field sizes

We interpret the retinotopy and the ipsilateral measurements as evidence that receptive fields are larger in MST than MT.MT responses modulated strongly to the rotating-wedge stimulusbut were weak or absent to stimuli presented at least 10° intothe ipsilateral visual field, implying relatively small receptivefields. MST responded to the ipsilateral stimulus but exhibitedweak or absent response modulations to the retinotopy stimulus,implying larger receptivefields.

Our measurements of ipsilateral responses are in general agreement with those of Tootell et al. (1998), who measured activityin human visual cortex to ipsilateral stimulation and reportedipsilateral responses in a broad region of extrastriate visualcortex including MT+. However, Tootell et al. (1998) excludedonly the central 0.5° of the visual field, in contrast to ourexclusion of the central 10° of the visual field. Given that monkeyMT neurons representing the fovea have receptive fields severaldegrees in diameter and that many of them cross into the ipsilateralvisual field, it is likely that their stimuli, unlike ours, wouldhave evoked activity in both monkey MT and MST. Thus, our resultsare consistent with those of Tootell et al. (1998), but our useof farther-peripheral stimuli permit more reliable inferencesconcerning the relative receptive field sizes within MT+.

Our results are also in agreement with those of Dukelow et al. (2001), who reported ipsilateral responses in the anteriorportion of MT+. Our results extend their observations by demonstratingthat the more posterior region in MT+ (which did not exhibit ipsilateralresponses) often exhibits clear retinotopic maps. In addition,Dukelow et al. (2001) only presented data from the right hemispheresof subjects (because of their use of a specialized head coil).We acquired fMRI responses from both hemispheres and confirmedthat the organization of human MT and MST is similar in the twohemispheres.

Inferences about retinotopic organization

Our results suggest that a subregion of MT+ exhibits retinotopic organization that can be assessed using fMRI. We observeda strong response to the rotating-wedge retinotopy stimulus inall hemispheres. Furthermore, in five hemispheres we observeda smooth map of the visual field, with the LVM represented moreventral and/or posterior and the UVM represented more dorsal and/oranterior.

We believe that the lack of a clear retinotopic map in some hemispheres may reflect methodological failures. The corticalsurface in the vicinity of MT+ is one of the most highly gyrifiedareas of the human cortex (Zilles et al., 1989; Dumoulin et al.,2000). Consequently, fMRI measurements in this region may sometimesbe blurred across opposite sides of a sulcus, mixing responsesfrom the posterior bank (putative MT) and the anterior bank (putativeMST). Precise segmentation and unfolding of the gray matter inthis convoluted part of the cortex is difficult, which could introduceadditional errors. In particular, we noted that manually refiningthe gray-matter segmentation in this region often yielded clearerretinotopic maps (see Materials and Methods), suggesting thatat least some of the variability in our data could result fromthese technical difficulties. We also note that the retinotopicallyorganized area that we have identified as MT is approximatelyan order of magnitude smaller than V1 (~240 vs ~2400 mm²), and corresponded to only ~5 × 12 fMRI voxels. In light of therelatively small size of this area, the ability to discern anyretinotopic organization isnotable.

In addition to these technical issues, electrophysiological measurements in the macaque have revealed that the MT retinotopicmap is not as orderly as in earlier visual areas like V1. Maunselland Van Essen (1987) observed that: (1) the lower visual fieldwas often over-represented in comparison with the upper visualfield; (2) the angular component exhibited local discontinuities;(3) the same angular position could be represented in multipledistinct regions; and (4) retinotopic maps were variable acrosshemispheres. Given this variability and local representationaldisarray observed in macaque MT, one might not expect to observean orderly retinotopic map in every humanMT.

Maps of visual field eccentricity in the macaque yield a clearer picture, with more lateral/ventral neurons exhibiting centralreceptive fields and more medial/dorsal neurons exhibiting moreperipheral receptive fields. We observed a similar organizationin the responses to our central versus peripheral stimuli, withthe response to central stimulation often lying at the ventraledge of MT or lying ventral to a region exhibiting a clear peripheralresponse.

The maps of visual field angle that we observed were consistent and reproducible within subjects. We observed similar retinotopicsubregions in subjects A.R.W., A.C.H., and R.F.D. in scanningsessions performed >1 year before the data reported in this paper(Dougherty et al., 1999). The locations, orientations, sizes,and shapes of the retinotopic regions were similar within subjectsacross the two data sets, and in the hemispheres in which theretinotopic map was most orderly in both of the data sets (A.R.W.,right and left), the precise organization of the angular map wasalso found to be in close correspondence. In these preliminarysessions, we used a conventional retinotopic mapping stimulus,a flickering checkerboard wedge, instead of the motion-definedwedge used in this study. The similarity of the maps we observedwhen using such different stimuli also demonstrates the robustnessof the MT retinotopic maps weidentified.

Possible homologies between human and macaque motion-sensitive areas

Our results are consistent with the existence of areas MT and MST in the human that are homologous to those in the macaque.This homology is supported by three main observations. First,macaque MT and MST are adjacent to one another, with MST lyinganterior to MT on the opposite bank of the dorsal STS. We foundhuman MT and MST to be immediately adjacent in seven of the eighthemispheres in which we confidently identified both areas. MTand MST typically lay on opposite sides of the same sulcus (theITS), with MST anterior and/or dorsal to MT. Second, macaque MTexhibits a clearer retinotopic organization than macaque MST.In human MT, we observed clear maps of the angular component ofthe visual in field in 5 of 10 hemispheres, and we observed evidencefor a distinction between central and peripheral parts of thevisual field in 7 of 10 hemispheres. Third, neurons in macaqueMST have larger receptive fields than corresponding neurons inMT representing the same eccentricity. We inferred that humanMST has larger receptive fields than MT, based on responses tothe rotating wedge (retinotopy) and ipsilateralstimuli.

Although our data are consistent with a proposed homology between human and macaque MT and MST, they are not conclusive. Thereare four adjacent, motion-sensitive areas in macaque STS (MT,MSTl, MSTd, and FST), whereas our measurements discerned onlytwo areas within human MT+. We chose to concentrate on distinguishingtwo regions based on differences in retinotopy and receptive fieldsize, because electrophysiologists often use receptive field sizeas a rule of thumb to distinguish macaque MT and MST. In addition,fMRI measurements of retinotopic organization are well establishedas a technique for subdividing larger regions of visual cortex(Engel et al., 1994, 1997; Sereno et al., 1995; DeYoe et al.,1996), including dorsal motion-responsive regions V3A, V3B, andV7 (Tootell et al., 1997; Smith et al., 1998; Press et al., 2001;Tootell and Hadjikhani, 2001).

Additional measurements of function within the macaque STS and the human ITS will shed further light on the proposed homologiesbetween the monkey and human motion-sensitive areas. For example,most neurons in macaque MT respond only according to the localdirection of translation of a moving stimulus (Dubner and Zeki,1971; Maunsell and Van Essen, 1983; Albright, 1984), whereas manyneurons in macaque MST also exhibit selectivity for particularcomponents of optic flow (e.g., expansion/contraction or rotation)(Saito et al., 1986; Duffy and Wurtz, 1991b). In a human fMRIexperiment, Morrone et al. (2000) compared MT+ responses to translation,expansion/contraction, and rotation. They observed stronger responsesto translation in a dorsal and/or posterior portion of MT+ andstronger responses to expansion/contraction and rotation in aventral and/or anterior part (although in two subjects this layoutwas reversed). However, their results do not appear to clearlyalign with the areas that we have identified as MT andMST.

In addition, neurons in macaque MST, but not in macaque MT, receive extraretinal eye movement signals, so that some MST neuronsrespond during smooth-pursuit eye movements in the absence ofretinal motion (Newsome et al., 1988). Dukelow et al. (2001) reportedactivity in the most anterior portion of human MT+ when subjectsperformed "nonvisual" pursuit of a self-generated somatosensorytarget (their own finger moving back and forth) in darkness, andsuggested that this region corresponded to the human homolog ofMSTl. However, it is not known whether self-guided pursuit ismediated by the same cortical mechanisms that control normal pursuiteyemovements.

The visual response properties of neurons in macaque FST have not been well studied. FST neurons are typically thought toexhibit weak and erratic visual responses (Komatsu and Wurtz,1988a), although one study did observe direction-selective responsesin some FST neurons (Erickson and Dow, 1989). If a human homologof FST exists, it is unclear as to whether this region would respondstrongly enough to visual motion to fall within our original definitionof MT+. fMRI measurements in monkeys (Dubowitz et al., 1998; Stefanacciet al., 1998; Disbrow et al., 1999; Logothetis et al., 1999, 2001)could provide a standard against which to evaluate the measurementsfrom human brains to further test the proposedhomologies.

Another possibility, of course, is that not all of the macaque motion-sensitive areas are preserved in humans. For example,in the owl monkey, homologs to macaque MST and FST have not beenunambiguously defined (Rosa et al., 1993). Regardless, becausethe subregions we identified exhibit differences in retinotopicorganization and receptive field sizes, it would be prudent toanalyze data from future fMRI experiments separately for eachof these subregions rather than treating them as one largerarea.

  FOOTNOTES

Received Jan. 30, 2002; revised April 24, 2002; accepted May 3, 2002.

This research was supported by National Eye Institute Grant R01-EY12741. We thank W. Newsome, K. Britten, and B. Wandell formany helpful comments throughout the course of this work and A.Wade for software used for gray-matter segmentation and flattening(available at http://white.stanford.edu/~brian/mri/segmentunfold.htm).

Correspondence should be addressed to Alexander C. Huk at his present address: Department of Physiology and Biophysics, Universityof Washington, Box 357290, Health Sciences Building Room G-424,Seattle, WA 98195-7290. E-mail: huk{at}u.washington.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Albright TD (1984) Direction and orientation selectivity of neurons in visual area MT of the macaque. J Neurophysiol 52:1106-1130[Abstract/Free Full Text].
Albright TD, Desimone R (1987) Local precision of visuotopic organization in the middle temporal area (MT) of the macaque. Exp Brain Res 65:582-592[ISI][Medline].
Albright TD, Desimone R, Gross CG (1984) Columnar organization of directionally selective cells in visual area MT of the macaque. J Neurophysiol 51:16-31[Abstract/Free Full Text].
Allman JM, Kaas JH (1971) A representation of the visual field in the caudal third of the middle temporal gyrus of the owl monkey (Aotus trivirgatus). Brain Res 31:85-105[ISI][Medline].
Boussaoud D, Desimone R, Ungerleider LG (1992) Subcortical connections of visual areas MST and FST in macaques. Vis Neurosci 9:291-302[ISI][Medline].
Britten KH, van Wezel RJ (1998) Electrical microstimulation of cortical area MST biases heading perception in monkeys. Nat Neurosci 1:59-63[ISI][Medline].
Celebrini S, Newsome WT (1995) Microstimulation of extrastriate area MST influences performance on a direction discrimination task. J Neurophysiol 73:437-448[Abstract/Free Full Text].
Desimone R, Ungerleider LG (1986) Multiple visual areas in the caudal superior temporal sulcus of the macaque. J Comp Neurol 248:164-189[ISI][Medline].
DeYoe EA, Carman GJ, Bandettini P, Glickman S, Wieser J, Cox R, Miller D, Neitz J (1996) Mapping striate and extrastriate visual areas in human cerebral cortex. Proc Natl Acad Sci USA 93:2382-2386[Abstract/Free Full Text].
Disbrow E, Roberts TP, Slutsky D, Krubitzer L (1999) The use of fMRI for determining the topographic organization of cortical fields in human and nonhuman primates. Brain Res 829:167-173[ISI][Medline].
Dougherty RF, Khan RM, Press WA, Wade AR, Baseler HA, Heeger DJ, Wandell BA (1999) Retinotopy in the human MT complex. Soc Neurosci Abstr 25:274.
Dubner R, Zeki SM (1971) Response properties and receptive fields of cells in an anatomically defined region of the superior temporal sulcus in the monkey. Brain Res 35:528-532[ISI][Medline].
Dubowitz DJ, Chen DY, Atkinson DJ, Grieve KL, Gillikin B, Bradley Jr WG, Andersen RA (1998) Functional magnetic resonance imaging in macaque cortex. NeuroReport 9:2213-2218[ISI][Medline].
Duffy CJ, Wurtz RH (1991a) Sensitivity of MST neurons to optic flow stimuli. II. Mechanisms of response selectivity revealed by small-field stimuli. J Neurophysiol 65:1346-1359[Abstract/Free Full Text].
Duffy CJ, Wurtz RH (1991b) Sensitivity of MST neurons to optic flow stimuli. I. A continuum of response selectivity to large-field stimuli. J Neurophysiol 65:1329-1345[Abstract/Free Full Text].
Dukelow SP, DeSouza JF, Culham JC, van den Berg AV, Menon RS, Vilis T (2001) Distinguishing subregions of the human MT+ complex using visual fields and pursuit eye movements. J Neurophysiol 86:1991-2000[Abstract/Free Full Text].
Dumoulin SO, Bittar RG, Kabani NJ, Baker Jr CL, Le Goualher G, Bruce Pike G, Evans AC (2000) A new anatomical landmark for reliable identification of human area V5/MT: a quantitative analysis of sulcal patterning. Cereb Cortex 10:454-463[Abstract/Free Full Text].
Dursteler MR, Wurtz RH (1988) Pursuit and optokinetic deficits following chemical lesions of cortical areas MT and MST. J Neurophysiol 60:940-965[Abstract/Free Full Text].
Engel SA, Rumelhart DE, Wandell BA, Lee AT, Glover GH, Chichilnisky EJ, Shadlen MN (1994) fMRI of human visual cortex. Nature 369:525[Medline].
Engel SA, Glover GH, Wandell BA (1997) Retinotopic organization in human visual cortex and the spatial precision of functional MRI. Cereb Cortex 7:181-192[Abstract/Free Full Text].
Erickson RG, Dow BM (1989) Foveal tracking cells in the superior temporal sulcus of the macaque monkey. Exp Brain Res 78:113-131[ISI][Medline].
Gattass R, Gross CG (1981) Visual topography of striate projection zone (MT) in posterior superior temporal sulcus of the macaque. J Neurophysiol 46:621-638[Free Full Text].
Glover GH (1999) Deconvolution of impulse response in event-related BOLD fMRI. NeuroImage 9:416-429[ISI][Medline].
Glover GH, Lai S (1998) Self-navigated spiral fMRI: interleaved versus single-shot. Magn Reson Med 39:361-368[ISI][Medline].
Heeger DJ, Boynton GM, Demb JB, Seidemann E, Newsome WT (1999) Motion opponency in visual cortex. J Neurosci 19:7162-7174[Abstract/Free Full Text].
Huk AC, Heeger DJ (2002) Pattern-motion responses in human visual cortex. Nat Neurosci 5:72-75[ISI][Medline].
Huk AC, Ress D, Heeger DJ (2001) Neuronal basis of the motion aftereffect reconsidered. Neuron 32:161-172[ISI][Medline].
Khan RM, Dougherty RF, Wandell BA, Newsome WT, Heeger DJ (1999) Functionally distinct motion areas in human visual cortex. Soc Neurosci Abstr 25:274.
Komatsu H, Wurtz RH (1988a) Relation of cortical areas MT and MST to pursuit eye movements. I. Localization and visual properties of neurons. J Neurophysiol 60:580-603[Abstract/Free Full Text].
Komatsu H, Wurtz RH (1988b) Relation of cortical areas MT and MST to pursuit eye movements. III. Interaction with full-field visual stimulation. J Neurophysiol 60:621-644[Abstract/Free Full Text].
Logothetis NK, Guggenberger H, Peled S, Pauls J (1999) Functional imaging of the monkey brain. Nat Neurosci 2:555-562[ISI][Medline].
Logothetis NK, Pauls J, Augath M, Trinath T, Oeltermann A (2001) Neurophysiological investigation of the basis of the fMRI signal. Nature 412:150-157[Medline].
Maunsell JH, Van Essen DC (1983) Functional properties of neurons in middle temporal visual area of the macaque monkey. I. Selectivity for stimulus direction, speed, and orientation. J Neurophysiol 49:1127-1147[Abstract/Free Full Text].
Maunsell JH, Van Essen DC (1987) Topographic organization of the middle temporal visual area in the macaque monkey: representational biases and the relationship to callosal connections and myeloarchitectonic boundaries. J Comp Neurol 266:535-555[ISI][Medline].
Morrone MC, Tosetti M, Montanaro D, Fiorentini A, Cioni G, Burr DC (2000) A cortical area that responds specifically to optic flow, revealed by fMRI. Nat Neurosci 3:1322-1328[ISI][Medline].
Movshon JA, Adelson EH, Gizzi MS, Newsome WT (1986) The analysis of moving visual patterns. Exp Brain Res 11:117-152.
Nestares O, Heeger DJ (2000) Robust multiresolution alignment of MRI brain volumes. Magn Reson Med 43:705-715[ISI][Medline].
Newsome W, Gizzi M, Movshon J (1983) Spatial and temporal properties of neurons in macaque MT. Invest Ophthalmol Vis Sci [Suppl] 24:106[Abstract/Free Full Text].
Newsome WT, Pare EB (1988) A selective impairment of motion perception following lesions of the middle temporal visual area (MT). J Neurosci 8:2201-2211[Abstract].
Newsome WT, Wurtz RH, Komatsu H (1988) Relation of cortical areas MT and MST to pursuit eye movements. II. Differentiation of retinal from extraretinal inputs. J Neurophysiol 60:604-620[Abstract/Free Full Text].
Orban GA, Saunders RC, Vandenbussche E (1995) Lesions of the superior temporal cortical motion areas impair speed discrimination in the macaque monkey. Eur J Neurosci 7:2261-2276[ISI][Medline].
Press WA, Brewer AA, Dougherty RF, Wade A, Wandell BA (2001) Visual areas and spatial summation in human visual cortex. Vision Res 41:1321-1332[ISI][Medline].
Rosa MG, Soares JG, Fiorani Jr M, Gattass R (1993) Cortical afferents of visual area MT in the Cebus monkey: possible homologies between New and Old World monkeys. Vis Neurosci 10:827-855[ISI][Medline].
Saito H, Yukie M, Tanaka K, Hikosaka K, Fukada Y, Iwai E (1986) Integration of direction signals of image motion in the superior temporal sulcus of the macaque monkey. J Neurosci 6:145-157[Abstract].
Salzman CD, Murasugi CM, Britten KH, Newsome WT (1992) Microstimulation in visual area MT: effects on direction discrimination performance. J Neurosci 12:2331-2355[Abstract].
Sawyer-Glover AM, Glover GH (1998) fMRI of the motor cortex: comparison of EPI and spiral pulse sequences. Proceedings of the International Society for Magnetic Resonance in Medicine: Section for Magnetic Resonance Technologists. 6:69.
Sereno MI, Dale AM, Reppas JB, Kwong KK, Belliveau JW, Brady TJ, Rosen BR, Tootell RB (1995) Borders of multiple visual areas in humans revealed by functional magnetic resonance imaging. Science 268:889-893[Abstract/Free Full Text].
Smith AM, Lewis BK, Ruttimann UE, Ye FQ, Sinnwell TM, Yang Y, Duyn JH, Frank JA (1999) Investigation of low frequency drift in fMRI signal. NeuroImage 9:526-533[ISI][Medline].
Smith AT, Greenlee MW, Singh KD, Kraemer FM, Hennig J (1998) The processing of first- and second-order motion in human visual cortex assessed by functional magnetic resonance imaging (fMRI). J Neurosci 18:3816-3830[Abstract/Free Full Text].
Stefanacci L, Reber P, Costanza J, Wong E, Buxton R, Zola S, Squire L, Albright T (1998) fMRI of monkey visual cortex. Neuron 20:1051-1057[ISI][Medline].
Tanaka K, Saito H (1989) Analysis of motion of the visual field by direction, expansion/contraction, and rotation cells clustered in the dorsal part of the medial superior temporal area of the macaque monkey. J Neurophysiol 62:626-641[Abstract/Free Full Text].
Teo PC, Sapiro G, Wandell BA (1997) Creating connected representations of cortical gray matter for functional MRI visualization. IEEE Trans Med Imaging 16:852-863[ISI][Medline].
Tootell RB, Hadjikhani N (2001) Where is "dorsal V4" in human visual cortex? Retinotopic, topographic, and functional evidence. Cereb Cortex 11:298-311[Abstract/Free Full Text].
Tootell RB, Taylor JB (1995) Anatomical evidence for MT and additional cortical visual areas in humans. Cereb Cortex 5:39-55[Abstract/Free Full Text].
Tootell RB, Reppas JB, Kwong KK, Malach R, Born RT, Brady TJ, Rosen BR, Belliveau JW (1995) Functional analysis of human MT and related visual cortical areas using magnetic resonance imaging. J Neurosci 15:3215-3230[Abstract].
Tootell RB, Mendola JD, Hadjikhani NK, Ledden PJ, Liu AK, Reppas JB, Sereno MI, Dale AM (1997) Functional analysis of V3A and related areas in human visual cortex. J Neurosci 17:7060-7078[Abstract/Free Full Text].
Tootell RB, Mendola JD, Hadjikhani NK, Liu AK, Dale AM (1998) The representation of the ipsilateral visual field in human. Cereb Cortex. Proc Natl Acad Sci USA 95:818-824[Abstract/Free Full Text].
Ungerleider LG, Desimone R (1986) Cortical connections of visual area MT in the macaque. J Comp Neurol 248:190-222[ISI][Medline].
Van Essen DC, Maunsell JH, Bixby JL (1981) The middle temporal visual area in the macaque: myeloarchitecture, connections, functional properties, and topographic organization. J Comp Neurol 199:293-326[ISI][Medline].
Wandell BA, Chial S, Backus BT (2000) Visualization and measurement of the cortical surface. J Cogn Neurosci 12:739-752[Abstract/Free Full Text].
Watson JD, Myers R, Frackowiak RS, Hajnal JV, Woods RP, Mazziotta JC, Shipp S, Zeki S (1993) Area V5 of the human brain: evidence from a combined study using positron emission tomography and magnetic resonance imaging. Cereb Cortex 3:79-94[Abstract/Free Full Text].
Zeki S, Watson JD, Lueck CJ, Friston KJ, Kennard C, Frackowiak RS (1991) A direct demonstration of functional specialization in human visual cortex. J Neurosci 11:641-649[Abstract].
Zeki SM (1974) Func