Attention to One or Two Features in Left or Right Visual Field: A Positron Emission Tomography Study

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Volume 17, Number 10, Issue of May 15, 1997 pp. 3739-3750
Copyright ©1997 Society for Neuroscience

Attention to One or Two Features in Left or Right Visual Field: A Positron Emission Tomography Study

Rik Vandenberghe¹^,⁵, John Duncan², Patrick Dupont³, Robert Ward²^,⁶, Jean-Baptiste Poline⁵, Guy Bormans³, Johan Michiels⁴, Luc Mortelmans³, and Guy A. Orban¹
¹ Laboratorium voor Neuro- en Psychofysiologie, Katholieke Universiteit Leuven, Belgium, ² Medical Research Council Applied Psychology Unit, Cambridge CB2 2EF, United Kingdom, Departments of ³ Nuclear Medicine and ⁴ Radiology, University Hospital Gasthuisberg, Leuven, Belgium, ⁵ Wellcome Department of Cognitive Neurology, Institute of Neurology, London WC1N 3BG, United Kingdom, and ⁶ School of Psychology, University of Wales, Bangor, Gwynedd LL57 2DG, United Kingdom

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

In human vision, two features of the same object can be identified concurrently without loss of accuracy. Performance declines,however, when the features belong to different objects in oppositevisual fields. We hypothesized that different positron emissiontomography activation patterns would reflect these behavioralresults. We first delineated an attention network for single discriminationsin left or right visual field and then compared this with theactivation pattern when subjects divided attention over two featuresof a single object or over two objects in opposite hemifields.When subjects attended to a single feature, parietal, premotor,and anterior cingulate cortex were activated. These effects werestrongest in the right hemisphere and were, remarkably, unaffectedby the direction of attention. In contrast, direction of attentionaffected occipital and frontal activity: right occipital and leftlateral frontal activity were higher with attention to the left,whereas right lateral frontal activity was higher with attentionto the right. When subjects identified two features of the sameobject, parietal, premotor, and anterior cingulate activity wasenhanced further, predominantly this time in the left hemisphere.Again, there was no direction sensitivity. Direction-sensitiveactivation of lateral frontal cortex also was increased. Finally,when subjects divided their attention over opposite hemifields,activity in the direction-sensitive occipital and frontal regionsfell to a level midway between those seen during exclusively leftwardor rightward attention. Thus, the behavioral efficiency with whichwe attend to multiple features of a single peripheral object isparalleled by enhanced activity in structures generally activeduring peripheral selective attention as well as in structuresthat depend on the specific direction of attention, most notablylateral frontal cortex. In addition, in the direction-sensitiveregions, dividing attention over hemifields causes a compromisepattern between the extreme levels obtained during unilateralattention.
Key words: human brain mapping; direction of attention; covert attention; superior parietal; pulvinar; prefrontal

INTRODUCTION

Physiologically, visual attention has been conceptualized as a brain state during which activity in widely separated brainareas is organized to enhance processing of the different featuresof a selected object (Desimone and Duncan, 1995). The behavioralbenefit of focused attention on a single object has been demonstratedby comparing dual and single discriminations of features belongingto one or two objects (Duncan, 1993; Egly et al., 1994; Veceraand Farah, 1994). Subjects attend very efficiently to two attributeswhen they belong to one object (Duncan, 1984). When the attributesbelong to two different objects, however, accuracy decreases,especially for the discrimination reported second. This decreasehas been demonstrated for many pairs of features, including displacementand orientation (Duncan, 1993) and brightness and orientation(Duncan, 1984), and occurs when the locations of the objects overlap(Duncan, 1984) as well as when the objects are in opposite hemifields(Vecera and Farah, 1994). Using positron emission tomography (PET),we investigated the physiological changes underlying these behavioralresults for displacement and orientation discrimination concerningleft- or right-sided objects.

In an initial step, we determined which areas were involved in discriminations of the feature of a single object in the leftor in the right visual field. Event-related potentials (ERP) (Mangunet al., 1993; Heinze et al., 1994) and PET studies (Corbetta etal., 1993; Heinze et al., 1994; Woldorff et al., 1995) have demonstratedhigher activity in occipital areas when subjects attend selectivelyto events occurring in the contralateral hemifield. In addition,right superior parietal activation has been described during shiftsof attention in the left and right visual fields, whereas theleft intraparietal sulcus has been reported during right fieldshifts only (Corbetta et al., 1993). Other studies of lateralizedattention, however, have not revealed parietal differences withchanging direction of attention (Heinze et al., 1994; Woldorffet al., 1995).

In a second step, we related the activation pattern obtained for single discriminations to that obtained when subjects directtheir attention to more features of the same object. We consideredthree nonexclusive hypotheses. First, activations occurring generallyduring single-feature discriminations could be enhanced duringdiscrimination of two features. This enhancement would be especiallycompelling when it exceeds the summed responses obtained duringthe component single discriminations. Second, activations thatoccur during single discriminations specifically when attentionis either to the left or to the right could become even more activewhen subjects attend to two rather than one feature within thefavored hemifield. Dual discrimination indeed may require moreintense focusing of attention to the contralateral object locationthan single discrimination does. Third, areas that are specificallymore active during single discrimination of either displacementor orientation could be activated in parallel when the two typesof attribute are attended concurrently. Attention to displacementmight activate components of the occipitoparietal processing pathwayand attention to orientation components of the occipitotemporalpathway (Haxby et al., 1994). When one task required attentionto the two features, we expected to see integrated activationof these two functionally segregated processing streams.

Finally, we compared conditions in which attention is focused on one object or divided between different objects in oppositehemifields. We hypothesized that the performance decline duringdivided attention over two objects might be paralleled by weakerpatterns of lateralized brain activity (Van Voorhis and Hillyard,1977) or by recruitment of additional structures because of highertask demands.

MATERIALS AND METHODS
Subjects Fourteen men, aged between 18 and 29 years, participated in the first experiment and 10 men, aged between 20 and 25 years,in the second. All were strictly right-handed, drug-free, hadno neurological or psychiatric history, and had a normal brainmagnetic resonance image. They gave their written informed consentin accordance with the Declaration of Helsinki. The experimentwas approved by the Ethical Committee of the Medical School, CatholicUniversity of Leuven.
Stimulus characteristics Stimuli were displayed using a VISA MC 8521 monitor (width, 14.4°; height, 10.7°) at a viewing distance of 107 cm and mountedat an angle of 52° relative to the horizontal.

First experiment. A central fixation point, accompanied by four-dot "frames" in each visual quadrant, was presented continuouslythroughout each run, a run being defined as a sequence of consecutivetrials (Fig. 1). On each trial two circular grating patches (diameter2.23° visual arc, eccentricity 4.45°, spatial frequency 1.79 cycles/degree,phase-randomized) appeared for 495 msec, one in the top left andone in the bottom right frame. The left patch was displaced bya specified distance either above or below center within its frame.For any given trial run, the distance of displacement was fixed,while its direction (above or below) varied randomly. This patchalso was rotated by a specified angle either clockwise or counterclockwisefrom horizontal. For any given trial run, the angle of rotationwas fixed, while its direction (clockwise or counterclockwise)varied randomly. Similarly, the right patch was displaced by aspecified distance either left or right of center and was rotatedby a specified angle, either clockwise or counterclockwise fromthe vertical. An interval of 1656 msec (± random variation of150 msec) separated onsets of one display and the next.
Fig. 1. First experiment. Stimulus display, described in detail in the subsection Stimulus Characteristics.
[View Larger Version of this Image (48K GIF file)]

Choice of materials was based on a previous behavioral study by Duncan (1993). In that study, as here, patches of lines variedin orientation and displacement with respect to a frame. Resultsshowed a standard contrast between one- and two-object tasks.

Second experiment. Stimuli were similar to those of the first experiment. They were presented for 115 msec with an intervalof 2001 msec (± random variation of 150 msec) separating onsetof one display and the next. The left grating appeared randomlyin the top or bottom quadrant and the right grating in the diagonallyopposite quadrant so that left and right visual field stimulationwere matched entirely over each run.
Task characteristics First experiment. In the first experiment we determined the brain activity pattern during discriminations of single featuresof left and right objects and related that to the pattern duringdiscrimination of two features of a single object. Because ofthe limited number of conditions available (6), we could makethe latter comparison only for the left visual field.

In the five discrimination conditions, subjects reported, respectively, left displacement and left orientation (ldlo), leftorientation (lo), left displacement (ld), right orientation (ro),and right displacement (rd). Each response was a vocal two-alternativeforced choice concerning the direction of either displacementor rotation: "boven" (above) versus "onder" (below) for left displacement,"stijgen" (go up) versus "dalen" (go down) for left orientation,"links" (left) versus "rechts" (right) for right displacement,and "stijgen" (go up) versus "dalen" (go down) for right orientation.In ldlo, both displacement and orientation responses were madeon each trial, in that order. In single discrimination conditions,a fixed, irrelevant word was spoken after each response, equatingtotal vocal output across conditions. Subjects were trained torespond between the onset of one stimulus and the next. In thecontrol condition (det), the onset of each display was acknowledgedsimply by a fixed, two-word response. Two days of practice (96trials/condition per day) were used to train subjects and adaptstimulus parameters (distances of displacement and angles of rotationin each condition) to each individual's performance. PET and behavioraldata were gathered on a third day. Mean angle and displacementparameters on this third day are listed in Table 1.

Table 1. First experiment: behavioral parameters

Stimulus parameters
% correct responses

ldlo lo ld ro rd ldlo lo ld ro rd

angle disp angle disp angle disp lo ld

± 1.71 ± 0.23 ± 1.64 ± 0.21 ± 1.69 ± 0.24 85.3 89.3 89.2 88.2 85.8 84.5

0.47 0.06 0.34 0.06 0.45 0.07 7.5 4.0 5.9 6.2 7.2 7.5

Angle parameters expressed as degrees rotation from horizontal or vertical, displacement (abbreviated disp) parameters asdegrees visual arc from frame center, and accuracies in percentageof correct responses. Top row, group averages; bottom row, SD.

Second experiment. In the second experiment all active tasks required concurrent discrimination of orientation as well asdisplacement. We compared conditions requiring focused attentionto left or right and conditions requiring divided attention betweensides.

All four active conditions shared the same type and number of attended attributes. In one experimental condition (ldlo), subjectsreported displacement and orientation of the grating on the left,in that order. In a second condition (rdro), subjects reporteddisplacement and orientation of the grating on the right, in thatorder. In a third condition (ldro), they reported displacementof the left grating and orientation of the right grating, in thatorder, and in a fourth condition (lord), the orientation of theleft grating and the displacement of the right, in that order.Two baseline conditions consisted of passive viewing (pv; no response)and detection (det; fixed two-word response on each trial). Subjectswere trained in the same way as during the first experiment. Thistime, angle and displacement parameters were fixed for a givensubject across all conditions; mean values are listed in Table2.

Table 2. Second experiment: behavioral parameters

Stimulus parameters
% correct responses

Angle Disp One object Two objects

Left Right Left Right

lo ld ro rd lo ld ro rd

± 5.35 ± 0.28 95.7 73.5 93.0 83.5 93.6 71.9 84.2 77.2

1.86 0 4.5 15.9 11.8 8.8 12.6 14.6 5.4 12.9

Stimulus parameters and performances expressed as in Table 1. In contrast with the first experiment, the angle and displacementparameters were fixed for a given subject across all conditions.First and second columns of performance data come from conditionldlo, third and fourth from rdro, fifth and eighth from lord,and sixth and seventh from ldro. Top row, group averages; bottomrow, SD.

Recording of eye movements Horizontal eye movements were monitored with contact electrodes placed on the outer ocular canthi, with a grounding electrodeplaced between the eyes. To ensure detection of gaze shifts atthe onset or the end of the task, we required subjects to readaloud a digit appearing at the fixation point just before andjust after the trial run. Electro-oculographical recordings (EOG)were stored on disk. The EOG was calibrated for fixation and forhorizontal visually guided saccades of 2 and 4° amplitude. TheEOG was inspected qualitatively for saccades or slow gaze driftoccurring during the tasks.
Data acquisition The brain was scanned in two-dimensional mode with a PET scanner of the type ECAT931-08-12 (CTI, Knoxville, TN) [voxel size,x = 1.878 mm, y = 1.878 mm, z = 6.75 mm; transaxial spatial resolution,8.5 mm full-width of half-maximum (FWHM); axial spatial resolution,6.75 mm FWHM; axial field of view, 10.0 cm] (Spinks et al., 1988).

Preparatory phase. Contact electrodes were placed and earphones installed. The subject's head was immobilized with a thermallymolded head holder and positioned parallel to the infero-orbitomeatalline by using laser alignment beams. A rectilinear scan was takenfor positioning.

Image acquisition. A transmission scan with a germanium-gallium source was taken to correct for attenuation. Each subjectwas scanned once in each of the six different conditions, eachconsisting of 64 trials (106 sec). ¹⁵O-labeled H₂O (50 mCi) was injected over a period of 12 sec in20 subjects (first and second experiment) and 40 mCi in the others(first experiment). The task was started at the same instant asthe injection. The acquisition began as soon as the intracranialradioactivity count rate rose sharply, i.e., on average 29 (SE2) sec after the onset of the task. The first 40 sec of imageacquisition were used for further analysis. The attenuation-correcteddata were reconstructed as 15 planes, using filtered back projectionwith a Hanning filter of cut-off frequency of 0.5 cycles/pixel.The brain tissue radiation count rate was used as a measure ofregional cerebral blood flow. The task order for the first experimentwas counterbalanced with constraints that the detection conditioncame either third or fourth and that rightward and leftward attentionconditions were blocked. The task order for the second experimentwas counterbalanced with the constraint that passive viewing anddetection came in the middle. An interval of at least 15 min separatedtwo successive injections. In the period between scans, subjectsreceived a 32-trial practice run of the condition to be scannednext.
Individual data All subsequent data analysis was performed with Statistical Parametric Mapping, version 1995 (SPM95) (Friston et al., 1995b).Images of all six conditions were available for each subject.The scans from each subject were realigned by using the firstimage as a reference. They were transformed stereotactically (Fristonet al., 1995a) to a standard template in the Talairach space (Talairachand Tournoux, 1988). Images were smoothed with a Gaussian filterof 20 × 20 × 12 mm³.
Group analysis First experiment. Data were analyzed using a randomized block design with global brain activity as a covariate of no interest,fixed at 50 ml/dl per minute (Friston et al., 1995b).

In the first and the second contrast, we delineated a general selective peripheral attention network involved in covert attentionacross variations in the type of attribute and in the attendedhemifield. We averaged the four single discrimination conditionsand compared detection with that average [ $-$ det and its inverse] (Table 3, Figs. 2A, 3A).

Table 3. General circuit for peripheral single discrimination: % rCBF increases

ldlo $-$ det lo $-$ det ld $-$ det ro $-$ det rd $-$ det $-$ det Z

R LPs 18, $-$ 68,44 5.49 3.10 4.05 2.83 4.09 3.91 5.08

BA7

R IPS 36, $-$ 42,36 4.39 1.43 3.88 3.21 3.55 3.01 4.39

BA40

R upper GPrC 34, $-$ 8,40 3.84 1.94 3.30 2.44 3.58 2.81 4.70

BA6

R lower PrCS 44,4,28 2.34 1.91 2.68 2.65 3.00 2.52 4.31

BA6/44

L pulvinar $-$ 18, $-$ 26,4 3.78 3.66 3.11 3.74 3.50 3.56 4.66

First experiment. Increases revealed by the subtraction of detection activity from mean activity over the discrimination conditions.Anatomical name, Talairach coordinates, percentage rCBF difference,and Z score. Threshold: corrected p < 0.05. All rCBF differencesbetween active conditions and detection (det) are expressed asa percentage of detection rCBF. refers to meanactivity in the four single discrimination conditions. The Z scorerefers to the -det comparison. LPs, Superior parietallobule; IPS, intraparietal sulcus; GPrC, precentral gyrus; PrCS,precentral sulcus.

Fig. 2. First experiment. Z-maps projected on the mean MRI image. A, Subtraction of detection from the mean of all single discriminationconditions. B, Subtraction of the right object from the left objectdiscrimination conditions. C, Subtraction of the mean of the left-sidedsingle discriminations from the dual discrimination condition.First, the subject's MRI image is coregistered with the mean ofhis realigned PET images. Subsequently, the subject's mean PETimage is transformed stereotactically, together with the subject'scoregistered MRI. Finally, the mean of the 14 normalized MRIsis calculated. Significance threshold, p < 0.2.
[View Larger Version of this Image (142K GIF file)]

Fig. 3. First experiment. All Z-maps are thresholded at p < 0.2. The right hemisphere is on the reader's right hand in the coronalviews. A, Subtraction of detection from the mean of all singlediscrimination conditions. Left top and bottom subquadrants, Coronaland sagittal see-through projections; right top subquadrant, coronalslice through y = $-$ 40 mm; left bottom subquadrant, sagittal slicethrough x = 36 mm. The crosshair marks the right intraparietalsulcus. B, Subtraction of the right object from the left objectsingle-feature discrimination conditions. Left top and bottomsubquadrants, Coronal and sagittal see-through projections; righttop subquadrant, coronal slice through y = 28 mm; left bottomsubquadrant, sagittal slice through x = $-$ 44 mm. The crosshairmarks the left lateral frontal activation. C, Subtraction of themean of the single discriminations from the dual discriminationcondition. Left top and bottom subquadrants, Coronal and sagittalsee-through projections; right top subquadrant, coronal slicethrough y = $-$ 56 mm; right bottom subquadrant, sagittal slice throughx = $-$ 26 mm. The crosshair marks the left superior parietal lobule.D, Subtraction of the left object from the right object single-featurediscriminations. Left top and bottom subquadrants, Coronal andsagittal see-through projections; right top subquadrant, coronalslice through y = 26 mm; right bottom subquadrant, sagittal slicethrough x = 32 mm. The crosshair marks the right lateral frontalactivation.
[View Larger Version of this Image (83K GIF file)]

The subsequent two contrasts allowed us to determine where activity depended on the direction of spatial attention. The meanof the single discriminations of the left grating was comparedwith the mean of single discriminations of the right grating [ $-$ and $-$ ] (Table 4, Figs.2B, 3B,D).

Table 4. Activations conditional on direction of attention: % rCBF difference

ldlo $-$ det lo $-$ det ld $-$ det ro $-$ det rd $-$ det Left-right Right-left

R GL 18, $-$ 78, $-$ 12 3.04 2.78 3.75 0.13 $-$ 0.21 3.31 -

BA18 Z = 6.05 -

R sca 16, $-$ 102, $-$ 8 1.85 3.74 3.79 0.09 0.11 3.66 -

BA17 Z = 4.67

L GFm:

$-$ L BA9 $-$ 42,18,40 2.89 $-$ 0.3 $-$ 0.44 $-$ 3.96 $-$ 3.40 3.14 -

Z = 4.63 -

L IFS:

$-$ L BA45/46 $-$ 46,28,20 4.27 $-$ 0.84 0.14 $-$ 2.49 $-$ 3.74 2.77 -

Z = 4.61 -

L GFi:

$-$ L BA47 $-$ 38,26, $-$ 12 0.20 $-$ 0.37 0.22 $-$ 4.99 $-$ 4.68 4.75 -

Z = 4.61 -

$-$ L BA47 $-$ 38,40, $-$ 8 1.93 $-$ 0.93 $-$ 1.06 $-$ 5.7 $-$ 5.66 4.69 -

Z = 4.44 -

L lower GPrC $-$ 50,14,24 6.63 2.60 2.16 $-$ 0.32 $-$ 0.50 2.79 -

BA6/44 Z = 4.49

R IFS:

$-$ R BA44/45 32,26,16 2.17 0.08 1.17 4.69 2.63 - 3.04

- Z = 4.45

L GTm $-$ 50, $-$ 12, $-$ 12 $-$ 1.24 0.58 $-$ 1.29 $-$ 2.87 $-$ 2.90 2.53 -

BA21 Z = 4.18 -

First experiment. Foci revealed by subtraction of mean activity in left-sided from right-sided attention conditions (or theinverse). Anatomical name, Talairach coordinates, rCBF differencesbetween conditions expressed as a percentage of detection rCBF,and Z scores. Bold, Corrected p < 0.05. GL, Lingual gyrus; sca,calcarine sulcus; GFm, middle frontal gyrus; GFi, inferior frontalgyrus; IFS, inferior frontal sulcus; GTm, middle temporal gyrus.See previous table for other abbreviations.

The fifth and sixth contrasts allowed us to identify feature-specific processing areas. We compared the mean of the singleorientation discriminations of the left and right grating withthe mean of the single displacement discriminations of the leftand right grating [ $-$ and $-$ ].

In the seventh contrast, we determined where concurrent discrimination of two features of a left object yielded higher activitythan the average of the equivalent single discriminations. Wecompared concurrent discrimination of orientation and displacementof the left grating with the mean of the single discriminationsof orientation and displacement of the left grating [ldlo $-$ ](Table 5, Figs. 2C, 3C).

Table 5. Activations conditional on number of attributes attended: % rCBF difference

ldlo $-$ det lo $-$ det ld $-$ det ro $-$ det rd $-$ det ldlo $-$

L LPs $-$ 24, $-$ 56,40 4.06 1.37 1.05 1.28 1.64 2.85

BA7 Z = 4.62

L IFS $-$ 46,30,24 5.72 $-$ 0.27 0.74 $-$ 1.72 $-$ 3.19 5.49

BA46 Z = 6.53

L lower GPrC $-$ 52,14,8 3.99 $-$ 0.63 0.13 $-$ 1.14 $-$ 1.23 4.25

BA6/44 Z = 4.70

L upper GPrC $-$ 44,0,44 4.66 0.99 1.85 $-$ 0.37 0.75 3.24

BA6 Z = 4.27

GC $-$ 10,20,32 4.80 0.79 1.83 1.22 1.14 3.49

BA32 Z = 4.65

L GTm $-$ 42, $-$ 46, $-$ 4 1.34 $-$ 1.44 $-$ 2.75 $-$ 1.18 $-$ 1.09 3.44

BA21/37 Z = 4.42

First experiment. Foci revealed by subtraction of mean activity in left object single-feature discriminations from dual discrimination.Anatomical name, Talairach coordinates, rCBF differences betweenconditions expressed as a percentage of detection rCBF, and Zscores. Bold, Corrected p < 0.05. GC, Cingulate gyrus. See previoustables for other abbreviations.

In each subtraction we used a significance threshold of p < 0.05 corrected for multiple comparisons by the standard procedureof SPM95 (Friston et al., 1995b). Activations at a corrected p< 0.2 also will be mentioned (Poline et al., 1996). Where we wantedto further evaluate negative findings and to determine whetherthey implied either absent or weak activation, we explored thedata at an uncorrected p < 0.01.

Second experiment. The first experiment provided us with an a priori anatomical hypothesis about the areas specifically involvedin concurrent discrimination and about the areas influenced bythe direction of attention during single discrimination. In thesecond experiment we examined how these a priori defined regionsresponded during concurrent discrimination when subjects focusedattention on a single object in the left or in the right hemifieldor when they divided their attention over objects appearing onthe left and the right.

Brain regions were defined on the basis of the results from the first experiment, using the subtractions ldlo $-$ , $-$ and $-$ .Voxels were included when they fulfilled two criteria. The firstcriterion was identical to that applied in any SPM analysis andexcluded all voxels in which, in the second experiment, rCBF waslower than 80% of the image maximum rCBF level or the F valuedid not reach p < 0.05 in a one-way ANOVA over all conditions.According to our second criterion, we only included voxels forfurther analysis when they had reached a corrected p value ofp < 0.1 in one of the three above contrasts during the first experiment.These voxels then were grouped in left and in right regions, dependingon their coordinates. Then the General Linear Model was appliedon the average radioactivity count rates in these regions in exactlythe same way as it usually is applied for voxels (Friston et al.,1995b). Data were analyzed using a randomized block design withglobal brain activity as a covariate of no interest, fixed at50 ml/dl per minute (Friston et al., 1995b). p values were correctedby dividing the uncorrected value by the number of regions examined(Bonferroni correction).

RESULTS
The final image smoothness estimate (FWHM) in the first experiment was x = 21.3, y = 24.4, z = 18.7 mm and in the second x= 20.5, y = 24.0, z = 17.5 mm. The analyzed brain volume in thefirst experiment extended from z = $-$ 24 to +54 mm anteriorly and $-$ 28 to +48 mm posteriorly; in the second experiment the volumeextended from z = $-$ 10 to +54 mm anteriorly and $-$ 32 to +48 mm posteriorly.

Behavioral parameters
One subject made several saccades in the scanning session during the orientation discrimination concerning the left grating.All other subjects fixated well in all scanning conditions.

In the first experiment accuracies did not differ significantly between conditions (repeated measures one-way ANOVA F_(5,12)= 1.13) (Table 1). A paired t test between the performances onthe orientation discriminations during ldlo and during lo, forthose subjects who performed both tasks with identical orientationangle parameters, showed no significant difference (p > 0.1).The same was true for the displacement discriminations duringldlo and ld (p > 0.4). The results of these t tests confirm thatsubjects perform two-feature and one-feature discriminations withequal accuracy when the two features belong to a single object(Duncan, 1984, 1993).

The accuracies in the second experiment (Table 2) were examined with a three-way ANOVA, with number of objects, attendedhemifield, and attended attribute as within-subject factors. Therewas a main effect of number of objects attended (higher accuracyfor one than for two objects, F_(1,9) = 69.8, p < 0.0000) and amain effect of attended attribute (higher accuracy for orientationthan for displacement, F_(1,9) = 17.6, p < 0.005). There was alsoa significant interaction between number of attended objects andhemifield (F_(1,9) = 5.76, p < 0.05). In agreement with earlierresults (Duncan, 1984, 1993), it was the right-sided object (reportedsecond) that suffered the greatest loss of accuracy in two-objectdiscrimination.

Attention to one feature of a peripheral object (first experiment)
We determined which areas are involved in discriminations of single features of single objects in the peripheral visual fieldby subtracting the detection task from the average of the foursingle discrimination tasks. As shown in Figures 2A and 3A, adistributed, mainly right-hemispheric circuit was activated. Activationpeaks, together with their rCBF profiles, are listed in Table3. Note that activations at p < 0.2 (corrected) are includedin the figures, whereas a threshold at p < 0.05 (corrected) isused for the tables.

This peripheral selective-attention circuit consisted of the right intraparietal sulcus (Figs. 2A, z = 32 mm; 3A), the rightsuperior parietal lobule (Fig. 2A, z = 44 mm), the right upperprecentral gyrus (Figs. 2A, z = 44 mm; 3A), and the right lowerprecentral sulcus (Fig. 2A, z = 32 mm), as well as the left pulvinar(Fig. 2A, z = 8 mm).

At p < 0.2, the right middle frontal gyrus (BA46/10; 34, 38, 20; Z = 4.05) (Figs. 2A, z = 20 mm; 3A) and the cingulate sulcus(BA32; 8, 8, 44; Z = 4.01) (Fig. 2A, z = 32-44 mm) also were activated,together with the right fusiform gyrus (BA19; 50, $-$ 70, $-$ 12; Z= 4.03) (Fig. 2A, z = $-$ 16 mm) and the right middle occipital gyrus(BA19; 34, $-$ 82, 16; Z = 3.60), the left intraparietal sulcus (BA40; $-$ 26, $-$ 40, 32; Z = 3.76) (Figs. 2A, z = 32 mm; 3A), as well asthe right anterior pallidum (20, 16, 4; Z = 3.68) (Fig. 2A, z= 8 mm).

Nearly all of these activations are located in the right hemisphere (Fig. 3A). Does the left hemisphere, apart from the pulvinarand the intraparietal sulcus, contribute anything at all duringsingle discriminations of peripheral objects? To explore this,we lowered the threshold to uncorrected p < 0.01 for the lefthemisphere only. Several activations were found at approximatelysymmetrical locations to the right-hemispheric activations: inthe left middle occipital gyrus (BA18/19; $-$ 34, $-$ 88, 12; Z = 2.42),superior parietal cortex (BA7; $-$ 14, $-$ 68, 44; Z = 2.46), and precentralsulcus (BA6/44; $-$ 54, 6, 28; Z = 3.21). This indicates that singlediscriminations do not rely exclusively on right-hemispheric areasdespite a clear right-hemispheric dominance. Several additionallow-threshold activations did not correspond to any of the areasthat had been activated in the right hemisphere at a correctedp < 0.05.

Decreases over all active conditions compared with baseline occurred in left anterior fusiform gyrus ( $-$ 46, $-$ 14, $-$ 24; Z = 4.82),left anterior medial frontal gyrus ( $-$ 12, 58, 8; Z = 4.83), leftmiddle temporal gyrus ( $-$ 56, $-$ 40, $-$ 8; Z = 5.02), left superiortemporal sulcus ( $-$ 52, $-$ 60, 16; Z = 5.21), and left inferior parietallobule ( $-$ 42, $-$ 70, 32; Z = 4.95). This pattern of decreases inactive, as compared with more passive, conditions is consistentwith what has been described previously over a wide variety oftasks (Shulman et al., 1996).

Single discriminations: effect of direction of attention (first experiment)
Occipital cortex When subjects attended to the left instead of the right, the right lingual gyrus (Table 4, Fig. 2B, z = $-$ 16 to $-$ 4 mm) wassignificantly more active, together with the right calcarine (Table4). This effect extended into the right posterior fusiform sitedescribed under the general network (50, $-$ 70, $-$ 12; Z = 2.62).

No equivalent effect was observed on the left side during rightward attention, even when the threshold was lowered to an uncorrectedp < 0.01.
Parietal cortex Remarkably, the direction of attention had no significant influence on parietal activity. To explore this negative findingfurther, we used two strategies.

First, we probed the parietal voxels obtained in the subtraction of detection from the averaged single discriminations. Activityin the right superior parietal voxel at 18, $-$ 68, 44 (Table 3)or at the peak in the right intraparietal sulcus at 36, $-$ 42, 36(Table 3) did not differ between leftward and rightward attentioneven at an uncorrected p < 0.01. Certainly, Table 3 suggestsno trend toward higher activity during contralateral attention.

Second, we explored the brain activations in the parietal cortex at a threshold p < 0.01 (uncorrected). Attention to the leftinstead of the right produced higher activity at the junctionbetween occipital and parietal cortex (BA19/39), both in the lefthemisphere ( $-$ 34, $-$ 66, 20; Z = 3.33; percentage rCBF differencewith respect to baseline: ldlo $-$ 0.03%, lo 0.13%, ld $-$ 0.60%, ro $-$ 1.98%, rd $-$ 1.28%) and in the right (44, $-$ 66, 36; Z = 2.59; ldlo $-$ 3.13%, lo $-$ 1.12%, ld $-$ 0.51%, ro $-$ 2.66%, rd $-$ 1.65%). When attentionwas to the right instead of the left, activity increased in theright inferior parietal lobule (BA39/40) (40, $-$ 46, 28; Z = 2.53;ldlo 1.45%, lo 0.09%, ld 1.60%, ro 2.22%, rd 1.87%). No strongconclusions can be drawn from these nonsignificant activations.
Frontal cortex Substantial areas of left lateral frontal cortex were more active during attention to the left than during attention to theright (Figs. 2B, z = $-$ 16 to 44 mm; 3B, Table 4). Conversely,right inferior frontal sulcus (BA44/45) was more active when attentionwas directed to the right instead of the left (Fig. 3D, Table4). At p < 0.2, subtracting leftward from rightward attentionrevealed a further activation in the left orbital gyri ( $-$ 12, 36, $-$ 20; Z = 3.94).
Temporal cortex As shown in Table 4, a region in the left middle temporal gyrus (Figs. 2B, 3B) was more active during leftward than duringrightward attention. This area fell within an area of net deactivationin the general circuit.

Single discriminations: effect of type of attended attribute (first experiment)
We determined the areas specifically involved in selective attention to orientation or to displacement by contrasting theaverage of the orientation discriminations with the average ofthe displacement discriminations.
Occipital cortex The left anterior ventral occipital cortex ( $-$ 42, $-$ 44, $-$ 20, BA36/37; Z = 4.35), at the border between fusiform and parahippocampalgyrus, was more active when subjects attended to the orientationof the grating than when they attended to its displacement. Thisdifference resulted from both an increase during orientation discrimination,as compared with baseline, and a decrease during displacementdiscrimination, as compared with baseline. A corresponding contralateralactivation (36, $-$ 34, $-$ 12) fell just below the significance threshold(p = 0.06, Z = 4.02). Another result bordering on significancealso is worth noting: the right middle occipital gyrus (44, $-$ 76,4; BA19/37) was activated more strongly during displacement thanduring orientation discrimination (p = 0.05, Z = 4.06).

Dividing attention over two features of a single object (first experiment)
We determined which areas were more active during discrimination of two features, as compared with single discriminations,by contrasting the condition in which subjects attended concurrentlyto orientation and displacement with the averaged conditions inwhich subjects attended to either orientation or displacement.This comparison could be made for the left visual field only.

As mentioned above, the brain activation pattern during single discriminations (Fig. 2A), as compared with detection, waslateralized mainly to the right. Subtracting this pattern fromthe activation pattern during dual discrimination left us witha mainly left-hemispheric activation pattern (Figs. 2C, 3C).

The activation pattern obtained from the subtraction of single from dual discriminations (Fig. 2C) partly consisted of enhancedactivity of areas active (p < 0.2) during single discriminations(Fig. 2A): the anterior cingulate (Fig. 2A, z = 32-44 mm), theright superior parietal cortex (Fig. 2A, z = 44 mm), and the leftintraparietal sulcus (Fig. 2A, z = 32 mm). This was combined withenhanced activation of specific direction-sensitive areas: leftlateral frontal cortex (Fig. 2B, z = 8-44 mm). Finally, activityin the left superior parietal lobule, which was weak during singlediscrimination (Z = 2.46, see above), was much enhanced duringdual discrimination (Fig. 2C, z = 44 mm).
Parietal cortex The left superior parietal activation during concurrent discrimination (Figs. 2C, z = 44 mm; 3C) substantially exceeded thesum of the weak rCBF increases observed during the component singlediscriminations (Table 5). This activation extended into theleft intraparietal sulcus (Fig. 2C, z = 32 mm).

At p < 0.2, we observed an additional activation peak in the right medial superior parietal lobule (12, $-$ 70, 40; Z = 3.84)(Fig. 2C).
Frontal cortex As detailed above, a substantial area of left lateral frontal cortex was more active during leftward than during rightwardattention (Figs. 2B, 3B). Activity in this area increased evenfurther with two concurrent left-field discriminations (Figs.2C, 3C, Table 5).
Temporal cortex An area in the left middle temporal gyrus was activated during concurrent discrimination with respect to single discrimination(Fig. 2C, z = $-$ 4 mm; Table 5). As the comparison between Figure2B (z = $-$ 16 mm) and Figure 2C (z = $-$ 4 mm) shows, this temporalarea lay posterior to the temporal activation obtained in thesubtraction of rightward attention from leftward attention. Again,this region fell within an area of net deactivation in the generalcircuit.

Second experiment: a priori definition of the regions
For analysis of the second experiment, we included only voxels that, in the first experiment, had revealed a significant (correctedp < 0.1) difference between dual and the averaged single discriminationsor between right and left object single discrimination. They weregrouped as six regions, using Talairach coordinates of the voxels:right ventral occipital (x > 0, y < $-$ 55, z < 0), left parietal(x < 0, y < $-$ 20, z > 18), left anterior cingulate (x < 0, x > $-$ 15, y > $-$ 5), left lateral frontal (x < 0, x < $-$ 20, y > $-$ 5), rightlateral frontal (x > 0, x < $-$ 20, y > $-$ 5), and left posterior temporal(x < 0, y < $-$ 20, y > $-$ 55, z < 0). The latter temporal region correspondsto the temporal activation revealed by the subtraction of singlefrom dual discrimination (Fig. 2C). The anterior temporal direction-sensitivevoxels shown in Figure 2B did not reach a significant F valuein the second experiment, and there was, therefore, no correspondingregion in the second study. This could be attributable to therestricted volume scanned at lower levels.

We also wanted to confirm the absence of any rCBF differences in the left ventral occipital and right parietal cortex whenconditions with rightward and leftward attention were compared.We obtained a left ventral occipital region by mirroring the rightventral occipital area to the other hemisphere and a parietalregion by mirroring the left parietal region. The eight resultingregions are displayed in Figure 4.
Fig. 4. Second experiment. Localization and extent of the a priori defined regions. A, Sagittal see-through projection. B, Transverseprojection. C, Coronal projection. The averaged coordinates ofthe voxels included in these regions follow. Left and right occipital:x = |19|, y = $-$ 84, z = $-$ 11; left and right parietal: x = |24|,y = $-$ 58, z = 41; anterior cingulate: x = $-$ 9, y = 15, z = 39; leftlateral frontal: x = $-$ 44, y = 22, z = 24; right lateral frontal:x = 31, y = 23, z = 18; left temporal: x = $-$ 42, y = $-$ 45, z = $-$ 3.
[View Larger Version of this Image (31K GIF file)]

Dual discrimination: effect of direction of attention (second experiment)
Occipital cortex As in the first experiment, right ventral occipital rCBF was highest when attention was toward the object on the left andat its lowest level when attention was toward the object on theright (Table 6). The difference between exclusively rightwardand exclusively leftward attention was highly significant (correctedp < 0.005).

Table 6. Second experiment: % rCBF increase

ldlo $-$ det rdro $-$ det ldro $-$ det lord $-$ det pv $-$ det $-$ ldlo $-$ rdro

L occipital 0.90 0.77 0.55 0.27 $-$ 0.92 0.43 0.13

Z = 1.81

R occipital 1.96 0.08 1.04 0.29 $-$ 0.53 0.27 2.05

Z = 3.65 Z = 2.05 Z = 3.73

L parietal 1.54 1.46 1.69 1.73 $-$ 0.68 $-$ 0.21 0.08

Z = 2.85 Z = 2.61 Z = 3.10 Z = 2.97

R parietal 1.67 1.11 0.81 1.11 $-$ 0.52 0.07 0.56

Z = 3.43 Z = 2.19 Z = 1.67 Z = 3.51

L ant. cingulate 1.70 1.34 0.52 1.41 $-$ 0.50 0.55 0.36

Z = 2.99 Z = 2.30 Z = 2.36

L lat. frontal 0.65 $-$ 0.64 $-$ 0.02 $-$ 0.17 $-$ 0.16 0.10 1.29

Z = 2.01 Z = 3.69

R lat. frontal 1.75 0.96 1.00 1.54 0.84 0.09 0.78

Z = 3.77 Z = 2.12 Z = 3.19 Z = 2.28 Z = 1.79 Z = 1.77

L temporal $-$ 1.35 $-$ 0.98 $-$ 0.84 $-$ 0.53 $-$ 1.39 $-$ 0.48 $-$ 0.37

Second experiment: average rCBF profiles for each of the a priori selected regions. Anatomical name, mean rCBF differencesbetween conditions within a priori selected regions expressedas percentages of detection rCBF, and Z scores. Bold, p< 0.05 corrected; italic, p < 0.05 uncorrected; Z not mentionedwhen p > 0.05 uncorrected or for decreases.

The mirrored left ventral occipital region again demonstrated no activation during rightward, as compared with leftward, attention(Table 6), and regional blood flow was even slightly higher duringleftward attention. In the first experiment the absence of leftventral occipital modulation could have been explained by theposition of the right stimulus in the bottom quadrant, as opposedto the position of the left stimulus in the top quadrant (Woldorffet al., 1996). For the second experiment this explanation is unsatisfactory,because stimuli on either side appeared with equal frequency inthe top or bottom quadrant.
Parietal cortex Neither left nor right superior parietal blood flow changed with varying direction of attention (Table 6).
Frontal cortex In left lateral frontal cortex, as compared with baseline conditions (pv and det), blood flow was increased during leftwardattention and decreased during rightward attention. Similar tothe findings in the first experiment, the difference between leftobject and right object discrimination was highly significant(corrected p < 0.005) (Table 6).

The a priori defined right inferior frontal region was not influenced significantly by the direction of attention (Table 6).When we examined the data from the second experiment without apriori selection criteria, however, a weak right inferior frontalactivation (42, 32, $-$ 8; Z = 3.13), lying below the predefinedregion, was observed during attention to the right (% rCBF difference:ldlo $-$ det, $-$ 4.12%; rdro $-$ det, 0.35%; lord $-$ det, $-$ 1.91%; ldro $-$ det, $-$ 1.84%). Because the lowest anterior brain level scannedwas at z = $-$ 10 mm, we cannot exclude any direction effect occurringbelow that level.

As in the first experiment, anterior cingulate rCBF was higher during concurrent discrimination than during detection. Itwas not influenced by the direction of attention (Table 6).

Dividing attention over two hemifields (second experiment)
When we examined the data from the second experiment without any a priori selection and contrasted the average of single-with the average of dual-object conditions [subtraction (ldlo+ rdro) $-$ (ldro + lord)], we found no significant (corrected p< 0.2) differences.
Occipital and frontal cortex When subjects divided their attention between objects in the two visual hemifields, blood flow in the a priori defined rightoccipital and left lateral frontal regions lay in between themore extreme levels obtained during exclusively leftward or rightwardattention (Table 6). The classical subtraction (ldlo + rdro) $-$ (ldro + lord) had overlooked this effect as it failed to showthat the component conditions during focused attention (ldlo andrdro) yielded blood flow levels at extreme ends, whereas the levelsduring divided attention (ldro and lord) lay midway between theseextremes. Obviously, if such an effect were obtained in regionsdefined by the contrast between leftward and rightward conditionsin the second experiment, it might have been an artifact inducedby selection bias. Critically, the regions studied were defineda priori in an independent experiment, and, therefore, the averagerCBF level during divided attention most probably reflects a truephysiological substrate for divided attention.
Parietal cortex Dividing attention between two objects had no effect on superior parietal regions (Table 6).

DISCUSSION

Single discriminations: direction-insensitive regions
The activations during single peripheral discriminations (p < 0.2) that were not influenced by the direction of attentionwere the right superior parietal lobule, the intraparietal sulcusbilaterally, the right upper and lower premotor cortex, the anteriorcingulate, and the left pulvinar (Fig. 2A).

Earlier neuropsychological (Posner et al., 1987; Posner and Petersen, 1990) and PET experiments concerning shifting (Corbettaet al., 1993) or maintaining of peripheral attention (Vandenbergheet al., 1996) convincingly demonstrated that the parietal cortexfulfills a function in peripheral orienting of attention. Giventhe conventional role of parietal cortex in controlling the attentionalfocus (Posner and Petersen, 1990), a clear expectation might havebeen that parietal activity, in as far as it reflects peripheralorienting, would be modulated by direction of attention. Despitethe strong parietal activations observed in some of our othersubtractions, no such modulation was observed.

It is worth noting that two earlier PET studies of visuospatial attention also failed to reveal any parietal direction sensitivity(Heinze et al., 1994; Woldorff et al., 1996). In both of thesestudies the relevant stimulus was presented at a fixed peripherallocation with distractors present in the ignored hemifield, asin our experiment. In a third study there was some trend towardhigher parietal activation on the side opposite to the attendedhemifield (Corbetta et al., 1993). Even in this study, however,parietal activation was clearly bilateral, and, in fact, differencesbetween leftward and rightward attention conditions were not demonstrateddirectly in a statistical way. Furthermore, experimental differencescould account for the different results. For instance, the studyby Corbetta et al. (1993) required systematic attention shiftsamong many locations within the selected hemifield. One key featureof the hemineglect syndrome after parietal lesions is a disengagementdeficit that is restricted mainly to the contralateral visualhemifield (Posner et al., 1987; Posner and Petersen, 1990). Thisdeficit is manifest when attention has to be shifted but is lessobvious when attention remains on the cued location. One interpretationof all these results is that superior parietal activity dependson the attended hemifield only under certain shifting conditions,possibly depending on whether distractors are presented in theignored hemifield. Whether or not this hypothesis is confirmed,it seems clear that there is little lateralization during sustainedleftward or rightward attention in the presence of bilateral visualstimulation.

It remains to be seen what cognitive processes are associated with the direction-insensitive parietal activity we observed.In a previous study parietal activation was associated with attentionto peripheral targets rather than to central targets (Vandenbergheet al., 1996), arguing for a role in the attentive processingof peripheral events. On the other hand, activation of the sameor a nearby region with PET during nonspatial tasks indicatesthat parietal cortex also fulfills a more general role in maintainingcognitive readiness or alertness (Pardo et al., 1991; Coull etal., 1996). More work will be needed to discriminate such alternatives.

Other direction-insensitive components of the general peripheral selective-attention network (see Table 3) were left pulvinar,right upper and lower premotor cortex, and right anterior cingulate.Structures near or identical to the premotor activations describedhave been reported by others studying covert (Corbetta et al.,1993) or overt orienting (Anderson et al., 1994; Sweeney et al.,1996). In the absence of any modulation by our current (Table3) or previous (Vandenberghe et al., 1996) experimental manipulations,our data do not help us to specify further the precise contributionof these regions to covert peripheral attention.

Single discriminations: direction-sensitive regions
The left lateral frontal and right ventral occipital cortex were strongly influenced by the direction of attention: left frontalrCBF was higher when attention was directed ipsilaterally (Figs.2B, 3B, Tables 4, 6), and right ventral occipital rCBF was higherwhen attention was directed contralaterally (Fig. 2B, Tables 4,6). A complementary (Table 4) but less consistent (Table 6)effect was found during rightward attention in the right inferiorfrontal sulcus (Fig. 3D). The right occipital modulation is inagreement with earlier ERP (Mangun et al., 1993; Heinze et al.,1994) and PET reports (Heinze et al., 1994), although these studiesalso found complementary effects in the left occipital lobe. Left-sidedoccipital effects of direction of attention were entirely absentin our experiments.

Our two experiments demonstrate unequivocally that left lateral frontal blood flow is sensitive to the direction of attention;it is higher during leftward than during rightward attention.The contrasts revealing this effect are narrowly matched for allprocesses except for direction of attention. These results wereunexpected. The ipsilateral localization gives us a possible clueregarding the underlying spatial attentional process. Lateralfrontal lesions can give rise to an imbalance in unilateral orienting,and lateral frontal patients may show increased orienting to thecontralateral hemispace in covert attention (Mennemeier et al.,1994), oculomotor tasks (Guitton et al., 1985; Butter et al.,1988), and manual tasks (Kwong and Heilman, 1991), although contralateralneglect also has been described (Heilman and Valenstein, 1972).Lateral frontal lesions, including the frontal eye fields, alsocan lead to increased latencies of ipsilateral reflexive saccades(Henik et al., 1994). Several hypotheses have been put forward.Ipsilesional systems that orient attention to the contralesionalside may be released from tonic inhibition exerted by the frontalcortex (Kwong and Heilman, 1991). Alternatively, contralesionalsystems that orient attention to the ipsilesional side may bedeprived from the facilitation normally exerted by the frontalcortex on the lesioned side (Henik et al., 1994). These lesiondata and the current findings require us to postulate a modelin which covert orienting results from the balance among inhibitory,disinhibitory, and facilitatory influences within a distributedattentional system, including the lateral frontal cortex. Thecomplex interplay among different components of such a systemmay be reminiscent of much better known oculomotor (Wallace etal., 1989, 1990) and motor systems (Alexander et al., 1986). Withinsuch a model the absolute sign of the frontal blood flow differenceis hard to interpret and may reflect inhibitory, disinhibitory,and facilitatory influences. At the current state of knowledge,several of these mechanisms could account equally well for changesin the balance between leftward and rightward attentional biases.

Dual discrimination
Behavioral data confirmed the efficiency with which we divide attention over several features of a single object (see Table1) (Duncan, 1984, 1993). As a first underlying physiologicalmechanism, activations present during attention for single featuresof peripheral objects were enhanced during attention to two features.Second, activity in areas sensitive to the direction of spatialattention was enhanced when subjects attended to more featuresin the favored hemifield. The current experiments did not provideus with evidence in favor of our third a priori hypothesis, predictingparallel activation of feature-specific processing areas. Thismay be attributable mainly to the limited segregation of displacementand orientation processing, as revealed in the current rCBF data.
Dual discrimination: enhancement in direction-insensitive regions The components of the peripheral attention circuit that were sensitive to the number of attended attributes, but not to thedirection of attention, were the superior parietal lobules andthe intraparietal sulci and the anterior cingulate.

When subjects attended to two attributes concurrently, parietal activity was enhanced, most prominently so in the left superiorparietal lobule. This marked enhancement (Figs. 2, 3C) exceededthe summed responses obtained during the component single discriminations.It could reflect the higher demands that concurrent discriminationsput on peripheral attention resources in comparison with singlediscriminations, enabling the subjects to maintain unchanged performanceparameters. Although the right-hemispheric components of the peripheralselective-attention network are already involved even in lessdemanding peripheral selective-attention tasks (Fig. 2A), symmetricalleft-hemispheric areas become more active when the attentionalload increases (Fig. 2C).

Similarly, the anterior cingulate activation obtained during single discrimination was enhanced further during dual discrimination(see Table 5). The absence of any modulation by our other taskvariables in this region leaves open a number of possible interpretations.For instance, anterior cingulate activation could be attributedto divided attention (Corbetta et al., 1991), dual task performance(Fletcher et al., 1995) or differences in response selection requirements(Deiber et al., 1991).
Dual discrimination: enhancement in direction-sensitive regions The left lateral frontal region we describe shows a combined effect of the number of attended attributes (Figs. 2C, 3C, Table5) and direction of attention (Figs. 2B, 3B, Table 6). Thiscombined effect is observed in its prefrontal as well as its lowerpremotor component (Table 5).

If we considered the left lateral frontal activation during dual, as compared with single, discrimination in isolation fromthe strong effect of direction of spatial attention, we mightattribute it to linguistic or general cognitive (D'Esposito etal., 1995) differences between the dual and single discriminationtasks used. We cannot exclude that the extensive activation observedincludes subregions involved in these processes. These alternativehypotheses only fall short in explaining the effect of directionof attention observed in the overall region (Table 6) and inits most significant components (Table 5). The dual discriminationconditions with a left or with a right object were matched strictlyin linguistic and working memory aspects. The combined effectof the number of attended attributes and direction of attentioncan be explained most parsimoniously as indicative for a spatialattentional process and may reflect the higher intensity withwhich spatial attention is directed toward the attended hemifieldand away from the ignored hemifield during dual, as compared withsingle, discrimination.

Dividing attention over objects in opposite hemifields
When subjects perform two feature discriminations concurrently, accuracy declines when the two features belong to two differentobjects (Duncan, 1984, 1993). This was confirmed by the behavioralresults obtained in the second experiment (see Table 2). ThePET results suggest a physiological homolog of this behavioralcost. When subjects divided attention over the two hemifields,levels of blood flow in left lateral frontal and right ventraloccipital cortex were intermediate between the extreme valuesobtained during exclusively leftward or rightward attention (seeTable 6). The rCBF difference between divided and focused attentionis in agreement with the above interpretation that the frontaleffects could reflect the intensity with which attention is directedipsilaterally and away from the contralateral hemifield. The rightoccipital effects could reflect enhanced processing of the contralateralstimulus during focused, as compared with divided, attention.

Conclusion
In conclusion, these experiments provide us with a physiological expression of how the brain copes efficiently with dividingattention over features of single objects. First, left superiorparietal and anterior cingulate activation during single discriminationsare strongly enhanced during dual discrimination, regardless ofthe direction of attention. Second, a left lateral frontal regionthat is activated when attention is toward the ipsilateral fieldis even more active when more features are attended within theipsilateral visual field. We hypothesize that both activationsreflect the increased intensity with which attention is directedtoward a peripheral object.

On the other hand, the behavioral loss incurred when we divide our attention between objects in opposite hemifields is paralleledby a very specific occipitofrontal pattern (see Table 6): whereasactivity in this set of regions reaches its extreme levels whensubjects focus exclusively on the left or on the right object,their activity lies in between when the subjects divide theirattention. Whereas the two extreme brain states during focusedattention may relate to the behavioral gain of focusing attentionon one single object, the "compromise" state possibly could relateto the behavioral loss observed when we divide attention overmore objects.

FOOTNOTES

Received Nov. 19, 1996; revised Feb. 25, 1997; accepted Feb. 28, 1997.

This work was supported by a grant from the Human Frontier Science Program, from the Belgian National Research Council (Grants9.0007.88 and 3.0043.89), and from the Queen Elizabeth MedicalFoundation. R.V. is a research fellow and P.D. a postdoctoralfellow of the Belgian National Research Council. We are gratefulto R. S. J. Frackowiak and K. J. Friston for making the SPM softwareavailable. We appreciate the help of Chantal Fransen, who trainedthe subjects, and we thank the technical staff of the PositronEmission Tomography Unit in Leuven for their assistance.

Correspondence should be addressed to Dr. J. Duncan, MRC Applied Psychology Unit, 15 Chaucer Road, Cambridge CB2 2EF, UnitedKingdom.

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