Role of the Supplementary Motor Area and the Right Premotor Cortex in the Coordination of Bimanual Finger Movements

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Volume 17, Number 24, Issue of December 15, 1997

Role of the Supplementary Motor Area and the Right Premotor Cortex in the Coordination of Bimanual Finger Movements

Norihiro Sadato¹, Yoshiharu Yonekura¹, Atsuo Waki¹, Hiroki Yamada², and Yasushi Ishii¹^,²
¹ Biomedical Imaging Research Center and ² Department of Radiology, Fukui Medical School, Fukui, 910-11 Japan

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

To obtain a better understanding of the cortical representation of bimanual coordination, we measured regional cerebral bloodflow (rCBF) with ¹⁵O-labeled water and positron emission tomography (PET). To detectareas with changes of rCBF during bimanual finger movements ofdifferent characteristics, we studied 12 right-handed normal volunteers.A complete session consisted of three rest scans and six scanswith acoustically paced (1 Hz) bimanual, mirror, or parallel sequentialfinger movements. Activation of the right dorsal premotor area(PMd) extending to the posterior supplementary motor area (SMA)was significantly stronger during the parallel movements thanduring the mirror sequential movements (p < 0.05, at cluster levelwith correction for multiple comparisons). To determine whetherthese cortical areas truly represented bimanual coordination,a different group of nine normal volunteers was studied with adifferent task. Subjects performed acoustically paced (2 Hz) abduction-adductionmovements of the index finger, making right only, left only, andbimanual mirror and parallel movements. Activation of the posteriorSMA and right PMd was significantly greater during the parallelmovements than during the bimanual mirror movements or the unimanualmovements of either hand (p < 0.01, with anatomical constraint).Thus, the posterior SMA and right PMd appear to be related tothe bimanual coordination of finger movements.
Key words: regional cerebral blood flow; sequential finger movements; positron emission tomography; supplementary motor area; premotor cortex; bimanual coordination

INTRODUCTION

The neuroanatomical basis of coupling of bimanual coordination is poorly understood. Because distal hand movement is controlledmainly by the contralateral hemisphere (Brinkman and Kuypers,1972, 1973), there needs to be interhemispheric coupling. Inter-and intrahemispheric interconnections among primary motor cortex,premotor cortex, and supplementary motor area (SMA) suggest thatinterhemispheric connections may be mediated primarily by theSMA (Rouiller et al., 1994). Lesions of the SMA disrupt bimanuallycoordinated movement (Brinkman, 1981, 1984; Freund, 1990), butwhether this is discoordination of the muscle activation patternor failure to program or execute movement strategies, which wouldbe more complex with bimanual interactions, remains unclear (Donoghueand Sanes, 1994). To depict the neuroanatomical substrate forbimanual coordination, we measured regional cerebral blood flow(rCBF) with ¹⁵O-labeled water and positron emission tomography (PET) duringbimanual, sequential finger movements. The comparison of bimanualand unimanual movements by the functional neuroimaging techniqueis made difficult by the overlap of the cortical regions representingthe right and left unimanual movements. Because it is well knownthat sequential finger movements activate the primary and nonprimarymotor cortex bilaterally (Rao et al., 1993; Shibasaki et al.,1993; Sadato et al., 1996), a simple subtraction method cannotbe applied. Instead, we used detection of changes in rCBF in accordancewith differences in characteristics of the bimanual movements.Because previous neurological and animal studies suggest thatthe "default" state for bimanual control produces mirror movements(Brinkman, 1981, 1984; Chan and Ross, 1988), the areas that showedthe greatest activation during the nonmirror bimanual movementsare likely to have some role in bimanual coordination. We alsoused simpler bimanual and unimanual movements to determine whetherthese particular areas were more activated during bimanual movementsthan during unimanual movements, and whether the activation wassequence-dependent.

MATERIALS AND METHODS
The experiment consisted of two tasks in a total of 21 subjects, all of whom were right-handed according to the Edinburghinventory (Oldfield, 1971). The protocol was approved by the InstitutionalReview Board, and all subjects gave their written informed consentfor the study. A small plastic catheter was placed in the cubitalvein of each subject's left arm for injection of the radioisotope.The subjects lay in a supine position with their eyes closed andpatched and their heads immobilized with an elastic band and spongecushions.

Experiment 1: bimanual movements with different characteristics. We studied 12 normal volunteers, all men, aged 19-25 years(mean, 22.3 years). Each subject had nine consecutive PET scans,with a 10 min interval between scans. A complete session consistedof three rest scans and six scans with acoustically paced, bimanual,sequential finger movements in mirror and parallel conditions(Table 1). Subjects were trained before the PET scans to performthe sequences without difficulty. For the rest scans, subjectslay quietly, listening to a metronome sounding at a frequencyof 1 Hz. No attempt was made to control the subjects' thoughtcontent or attention during rest. Both hands were placed in aprone position on a flat board. For the movement scans, subjectsbriskly and precisely tapped the board with the fingers of bothhands at a frequency of 1 Hz. The finger movements were pacedto the beat of the metronome, which began sounding 8 sec beforethe isotope injection and continued for 3 min. The whole sequencewas started at the same time and performed repeatedly for 45 timesin each condition. The finger movements were monitored and recordedby a video camera. Performance of the sequence was assessed bycalculating the percentage of correct sequences. No omission oftaps was observed. The three conditions (rest, mirror, and parallel)consisted of one trial block. Within each trial block, the orderof the three conditions was randomized across all subjects. Trialblocks (Trials 1, 2, 3) were repeated three times in each subject.

Table 1. Sequences of bimanual sequential finger movements

Group A (n = 6) Group B (n = 6)

Mirror

  Right 1,2,3,4 1,2,3,4

  Left 1,2,3,4 1,2,3,4

Parallel

  Right 4,3,2,1 1,2,3,4

  Left 1,2,3,4 4,3,2,1

Sequence: 1, index finger; 2, middle finger; 3, ring finger; 4, little finger.

Experiment 2: simple abduction-adduction movements of the index finger. We studied nine different normal volunteers, men,aged 22-27 years (mean, 24.3 years). Each subject had 10 consecutivescans at 10 min intervals. Each subject performed acousticallypaced (2 Hz) abduction-adduction movements of the index finger:right only, left only, mirror, and parallel, each of which wasperformed twice, on the same board as in Experiment 1. The directionof the movement was alternated at each beat of the metronome.In the mirror movements, simultaneous abduction was alternatedwith adduction of both index fingers. In the parallel movements,the task was simultaneous adduction of the other index finger,with repeated alternation of the direction. The first and lastscans were performed under the rest conditions. The eight scansin between were for the task conditions. The order of the fourconditions (right only, left only, mirror, and parallel) was counterbalancedand randomized across the subjects. Other settings were identicalto Task 1.

PET scans. The PET scans were performed with General Electric Advance tomograph (GE/Yokogawa Medical System, Tokyo, Japan),with the interslice septa retracted. The physical characteristicsof this scanner have been described in detail by De Grado et al.(1994) and Lewellen et al. (1996). This scanner acquires 35 sliceswith an interslice spacing of 4.25 mm. In the three-dimensionalmode, the scanner acquires oblique sinograms with a maximum cross-coincidenceof ±11 rings. A 10 min transmission scan using two rotating Ge-68sources was performed for attenuation correction. Images of CBFwere obtained by summing the activity during the 60 sec periodafter the first detection of an increase in cerebral radioactivityafter the intravenous bolus injection of 10 mCi of ¹⁵O-labeled water (Sadato et al., 1995). The images were reconstructedwith the Kinahan-Rogers reconstruction algorithm (Kinahan andRogers, 1989). Hanning filters were used, giving transaxial andaxial resolutions of 6 and 10 mm [full width at half maximum (FWHM)],respectively. The field of view and pixel size of the reconstructedimages were 256 and 2 mm, respectively. No arterial blood samplingwas performed, and thus the images collected were those of tissueactivity. Tissue activity recorded by this method is nearly linearlyrelated to rCBF (Fox et al., 1984; Fox and Mintun, 1989).

Anatomical MRI. For anatomical reference, a high-resolution whole-brain magnetic resonance image (MRI) for each subject wasobtained separately. A regular head coil and a conventional T1-weighted,spoiled-Grass volume sequence with a flip angle of 30°, echo timeof 5 msec, repetition time of 33 msec, and field of view of 24cm were used. Matrix size was 256 × 256, slice thickness was 1.5mm, and pixel size was 0.937 × 0.937 mm. These volume data of124 sagittal slices were interpolated and resliced to transaxialimages with voxel size of 0.937 × 0.937 × 0.937 mm. Each high-resolutionimage was normalized to the template T1-weighted images with lineartransformation. Because mesial surface is variable in its gyralanatomy, the location of the activated areas in relation to thecingulate sulcus was examined on the normalized MRIs. The cingulatesulcus was identified on the contiguous sagittal images of eachanatomically normalized high-resolution MRI with the method proposedby Steinmetz et al. (1989). The distance along z axis betweenthe peak activation and the cingulate sulcus of each subject wasmeasured.

Data analysis. The data were analyzed with statistical parametric mapping (SPM95; Wellcome Department of Cognitive Neurology,London, UK) implemented in Matlab (Mathworks Inc., Sherborn, MA)(Friston et al., 1989, 1990, 1994, 1995a,b). The scans from eachsubject were realigned using the first image as a reference. Afterrealignment, all images were transformed into a standard stereotaxicspace (Talairach and Tournoux, 1988) and filtered with a Gaussiankernel of 10 mm FWHM in the x, y, and z axes. After the appropriatedesign matrix was specified, the condition, subject, and covariateeffects were estimated according to the general linear model ateach and every voxel. The design matrix included global activityas a confounding covariate, and this analysis can therefore beregarded as an ANCOVA (Friston et al., 1990). To test hypothesesabout regionally specific condition effects, the estimates werecompared using linear contrasts. The resulting set of voxel valuesfor each contrast constitute a statistical parametric map of thet statistic SPM(t). The SPM(t) was transformed to the unit normaldistribution [SPM(Z)]. The threshold of SPM(Z) was set at Z >2.3. The resulting foci were characterized in terms of spatialextent (k) and peak height (u). The significance of each regionwas estimated using distributional approximation from the theoryof Gaussian fields. This characterization is in terms of the probabilitythat a region of the observed number of voxels could have occurredby chance [p(n_max > k)], giving the corrected p values at clusterlevels for multiple comparisons over the entire volume analyzed,or that the peak height observed could have occurred by chance[p(Z_max > u)], giving the corrected p values at voxel levels.p < 0.05 of a corrected p value was used as a statistical threshold(Friston et al., 1994, 1995b). Because of generous threshold ofZ > 2.3, activated regions during bimanual movement conditionscompared with rest conditions constituted a large activated field.Hence significant activated foci were reported on the basis ofthe peak height: p < 0.05 with a correction for multiple comparisons(Friston et al., 1995b).

To identify the cortical areas related to the control of the bimanual finger movements, parallel and mirror sequential fingermovement conditions in Experiment 1 were compared. From Experiment1, we obtained a priori information for Experiment 2 as to whichregions would show increase in rCBF during parallel movementscompared with mirror movements. Because voxel-level significancehas strong control over the regional specificity of the activation(Friston et al., 1996), activated foci that reached voxel-levelsignificance (p < 0.05 with correction for multiple comparisonsover the entire brain) were used for anatomically constraininghypothesis for Experiment 2. As the basis of statistical inferenceof any activations that fall within the FWHM of the prespecifiedlocation in SPM(Z), we used the p value of voxel-level with aBonferroni correction for number of the prespecified locations(Friston et al., 1996). FWHM of SPM(Z), which indicates the extentof autocorrelation of the data or dependency of the Z value ofone voxel on its neighbors, was estimated by the variance of thefirst derivatives of SPM(Z) in three directions (Friston et al.,1991, 1995b).

RESULTS

Experiment 1
The performance of the mirror movements was slightly but significantly better than that of the parallel movements, but therewas no significant difference between the mirror and the parallelmovements for trial effect or interaction between sequence andtrial effects (Table 2).

Table 2. Performance of bimanual sequential finger movements

Trial Mirror Parallel

1 100.0 ± 0.0 96.9 ± 4.1

2 99.4 ± 1.9 98.5 ± 2.2

3 99.4 ± 1.4 99.3 ± 2.0

Total 99.6 ± 1.4 98.2 ± 3.0^*

Values are mean ± SD for percentage of correct sequences [% = correct sequences/ total sequences (n = 45) × 100; n = 12 foreach trial]. ^* Sequence effect was significant (F_(1,66) = 7.05; p = 0.009). The difference in the percentage of correct sequences among thethree trials was not significant in either the mirror or parallelmovements (p > 0.05; two-way ANOVA).

Both mirror and parallel movements activated the primary sensorimotor cortex (SM1) extending to the premotor cortex (PM),inferior and superior parietal lobule (LPi and LPs), cerebellum,putamen, and thalamus bilaterally, and the posterior SMA. In addition,the midbrain and right prefrontal cortex were significantly activatedby the parallel movements, but not the mirror movements, comparedwith the rest condition. (Tables 3, 4).

Table 3. Activation by sequential finger movement (n = 12): mirror versus rest

Location Coordinates
Z % $Delta$ CBF Voxel-level corrected p

x y z

SM1

  Left $-$ 34 $-$ 20 56 8.3 9.7 <0.01

  Right 34 $-$ 20 56 10.1 10.5 <0.01

LPi

  Left $-$ 32 $-$ 34 44 8.8 8.5 <0.01

  Right 32 $-$ 34 44 8.0 8.4 <0.01

Cerebellum

  Left $-$ 20 $-$ 56 $-$ 28 8.6 8.6 <0.01

  Right 26 $-$ 54 $-$ 28 8.2 9.5 <0.01

Putamen

  Left $-$ 22 $-$ 8 4 6.3 5.6 <0.01

  Right 22 $-$ 8 4 5.5 5.0 <0.01

Thalamus

  Left $-$ 8 $-$ 30 8 5.8 5.0 <0.01

  Right 14 $-$ 24 8 6.2 5.2 <0.01

LPs

  Left $-$ 32 $-$ 40 56 4.5 4.3 0.03

  Right 32 $-$ 60 52 4.9 4.0 <0.01

SMA

  Right 6 $-$ 4 52 7.5 4.8 <0.01

LPi, Inferior parietal lobule; LPs, superior parietal lobule; SM1, primary sensorimotor area; SMA, supplementary motor area.

Table 4. Activation by sequential finger movement (n = 12): parallel versus rest

Location Coordinates
Z % $Delta$ CBF Voxel-level corrected p

x y z

SM1

  Left $-$ 36 $-$ 30 56 9.3 10.2 <0.01

  Right 32 $-$ 18 56 11.7 12.2 <0.01

LPi

  Left $-$ 32 $-$ 34 44 9.2 9.0 <0.01

  Right 32 $-$ 34 44 8.2 8.7 <0.01

Cerebellum

  Left $-$ 20 $-$ 56 $-$ 28 10.5 12.6 <0.01

  Right 12 $-$ 56 $-$ 20 8.9 9.4 <0.01

Putamen

  Left $-$ 22 $-$ 8 4 6.1 5.4 <0.01

  Right 22 $-$ 8 4 5.8 5.4 <0.01

Thalamus

  Left $-$ 18 $-$ 10 4 6.5 5.9 <0.01

  Right 14 $-$ 22 8 6.5 5.8 <0.01

LPs

  Left $-$ 30 $-$ 54 56 5.1 5.4 <0.01

  Right 14 $-$ 68 56 4.6 4.2 <0.01

SMA

  Right 4 $-$ 6 56 8.3 8.4 <0.01

Prefrontal cortex

  Right 54 2 24 6.5 4.7 <0.01

Midbrain

  Left $-$ 2 $-$ 24 $-$ 12 4.3 4.1 0.04

LPi, Inferior parietal lobule; LPs, superior parietal lobule; SM1, primary sensorimotor area; SMA, supplementary motor area.

The right dorsal premotor area (PMd) extending to the posterior SMA showed significantly greater activation during the parallelmovements compared with the mirror movements (corrected p < 0.05)(Fig. 1, Table 5). These areas showed significant but less prominentactivation during the mirror movements than during the parallelmovements compared with the rest condition (Table 5).
Fig. 1. Comparisons of adjusted mean rCBF between bimanual, sequential parallel movement and mirror finger movements, superimposedon typical magnetic resonance images unrelated to the study'ssubjects. Six transaxial images of 40, 44, 48, 52, 56, and 60mm above the anterior-posterior commissural line are shown. Thepixels show levels of statistical significance above p < 0.05for its spatial extension of activation after thresholding atZ > 2.3. Vertical red line indicates midsagittal plane, crossinghorizontal red line at the vertical anterior commissural line(VAC).
[View Larger Version of this Image (99K GIF file)]

Table 5. Activated foci by sequential finger movements: parallel versus mirror

Region size (k) Cluster-level corrected p Z Voxel-level corrected p^* Coordinates
% $Delta$ CBF Location Adjusted mean rCBF (mean ± SD)

x y z Rest Mirror^** Parallel^**

929 0.033 4.46 0.019 (<0.0001) 22 $-$ 10 52 3.9 PMd (right) 70.2 ± 2.3 72.5 ± 2.3 (3.9) 75.3 ± 2.4 (7.4)

4.28 0.040 (<0.0001) 20 $-$ 10 52 3.8 PMd (right) 67.0 ± 2.3 69.2 ± 2.2 (3.7) 71.8 ± 2.4 (7.2)

3.41 0.497 (<0.0001) 16 $-$ 20 64 2.6 SMA (right) 53.7 ± 1.8 55.1 ± 1.7 (3.3) 56.6 ± 1.1 (6.2)

3.35 0.558 (<0.0001) $-$ 12 $-$ 10 64 2.7 SMA (left) 55.2 ± 1.6 57.1 ± 1.7 (4.1) 58.6 ± 2.0 (6.8)

^* Uncorrected p value. ^** Z values for the comparison with rest condition. PMd, Dorsal premotor cortex; SMA, supplementary motor area.

Experiment 2
There were no erroneous movements in any of the tasks (right only, left only, mirror, or parallel movements of the index fingers)in all subjects in all trials.

Abduction-adduction movements of the right index finger activated the left SM1 extending to the posterior SMA, and the rightcerebellum. Left index finger movements activated the right SM1and a region extending from the anterior cingulate gyrus (ACG)to the posterior SMA, left ventral premotor cortex, and the leftcerebellum. Bimanual movements activated the SM1 and a regionextending from ACG to the posterior SMA, LPi, basal ganglia, andthalamus bilaterally, and the right prefrontal cortex (Tables6, 7).

Table 6. Activation by abduction-adduction movements of the index finger: unimanual versus rest

Location Coordinates
Z % $Delta$ CBF Voxel-level corrected p

x y z

Right index finger

  SM1

    Left $-$ 32 $-$ 26 56 7.3 12.4 <0.01

  SMA

    Left $-$ 4 $-$ 8 44 5.0 5.6 <0.01

  Cerebellum

    Right 18 $-$ 62 $-$ 20 5.1 7.2 <0.01

Left index finger

  SM1

    Right 40 $-$ 20 52 7.5 10.5 <0.01

  ACG

    Right 2 $-$ 8 40 5.1 4.6 <0.01

  Cerebellum

    Left $-$ 6 $-$ 64 $-$ 16 5.7 9.0 <0.01

    Right 8 $-$ 90 $-$ 28 4.5 6.8 0.02

  LPi

    Right 30 $-$ 26 40 6.7 9.5 <0.01

  PMv

    Left $-$ 54 $-$ 10 32 5.3 4.7 <0.01

ACG, Anterior cingulate gyrus; LPi, inferior parietal lobule; PMv, ventral premotor cortex; SM1, primary sensorimotor area;SMA, supplementary motor area.

Table 7. Activation by bimanual abduction-adduction movements of the index finger

Location Coordinates
Z % $Delta$ CBF Voxel-level corrected p

x y z

Mirror versus rest

  SM1

    Left $-$ 34 $-$ 22 52 7.6 13.1 <0.01

    Right 40 $-$ 20 52 7.4 10.3 <0.01

  ACG

    Right 10 $-$ 2 36 5.1 6.9 <0.01

  Cerebellum

    Left $-$ 4 $-$ 64 $-$ 16 6.3 10.1 <0.01

    Right 8 $-$ 60 $-$ 24 5.2 8.0 <0.01

  LPi

    Left $-$ 28 $-$ 38 40 5.7 7.1 <0.01

    Right 36 $-$ 38 44 4.3 6.6 0.04

  PMd

    Left $-$ 16 $-$ 20 48 5.1 6.9 <0.01

    Right 24 $-$ 16 48 4.5 6.7 0.02

  Globus pallidus

    Left $-$ 22 $-$ 14 4 5.0 5.7 <0.01

  Prefrontal cortex

    Right 58 6 16 4.6 6.4 <0.01

  Thalamus 0 $-$ 24 12 4.4 5.5 0.04

Parallel versus rest

  SM1

    Left $-$ 36 $-$ 22 52 7.5 13.3 <0.01

    Right 40 $-$ 20 52 7.9 11.5 <0.01

  LPi

    Left $-$ 30 $-$ 26 40 5.5 8.2 <0.01

    Right 30 $-$ 26 40 7.5 11.2 <0.01

  PMd

    Left $-$ 16 $-$ 20 48 5.2 7.2 <0.01

    Right 24 $-$ 16 48 5.5 8.7 <0.01

  Cerebellum

    Left $-$ 16 $-$ 54 $-$ 20 5.9 9.5 <0.01

    Right 26 $-$ 56 $-$ 28 5.9 10.2 <0.01

  Thalamus

    Left $-$ 16 $-$ 18 8 5.7 6.3 <0.01

    Right 2 $-$ 24 12 5.0 6.7 <0.01

  Globus pallidus

    Left $-$ 20 $-$ 6 4 5.0 6.2 <0.01

  Putamen

    Right 24 $-$ 16 8 4.9 6.4 <0.01

  Prefrontal cortex

    Right 58 4 16 5.3 7.3 <0.01

ACG, Anterior cingulate gyrus; LPi, inferior parietal lobule; LPs, superior parietal lobule; PMd, dorsal premotor cortex;SM1, primary sensorimotor area; SMA, supplementary motor area.

The right PMd with Talairach's coordinates of x = 20 mm, y = $-$ 10 mm, and z = 52 mm, and x = 22 mm, y = $-$ 10 mm, and z = 52mm showed activation during parallel sequential movements comparedwith mirror movements with voxel-level significance correctedfor multiple comparisons (Table 5). Hence assessment of the activationduring parallel abduction-adduction movements compared with duringmirror movements was restricted to the regions that fall withinthe FWHM of this location. Estimated FWHM of SPM(Z) was 14.9 mmin x, 16.0 mm in y, and 19.4 mm in z axis. With this anatomicalconstraint, the areas of right PMd and right posterior SMA weresignificantly activated with a Bonferroni correction for two foci(p < 0.01) (Table 8, Fig. 2). Measured with the normalized MRI,the location with coordinates (14, $-$ 6, 48) was 8.0 ± 3.3 mm (n= 9; mean ± SD) above the cingulate sulcus, confirming that itis in the SMA region in this particular group. Measured in thetemplate MRI (shown in Figs. 1, 2), the location (14, $-$ 6, 48)is 9 mm above the cingulate sulcus.

Table 8. Activated foci by the abduction-adduction movement in the SMA-premotor regions: parallel-mirror (n = 9)

Location Z p^* Coordinates
% $Delta$ CBF Adjusted rCBF (mean ± SD)

x y z Rest Right index Left index Mirror Parallel

SMA (right) 3.16 0.0016 14 $-$ 6 48 4.3 62.5 ± 3.0 63.3 ± 1.6 64.7 ± 2.3 64.7 ± 2.2 67.5 ± 2.4

PMd (right) 2.73 0.0064 22 $-$ 10 44 3.8 60.3 ± 3.1 61.5 ± 1.9 61.9 ± 2.5 61.9 ± 1.9 64.3 ± 2.1

^* With a priori an anatomical constraint that the right PMd with Talairach's coordinates of x = 20, y = $-$ 10, z = 52, and x =22, y = $-$ 10, z = 52, specified by the (parallel-mirror) comparisonof bimanual sequential finger movements in Experiment 1, and itssurrounding regions, which fall within the FWHM of the SPM(Z),are the regions of interest. A Bonferroni correction for the twolocations was applied.

Fig. 2. Comparisons of adjusted mean rCBF between bimanual, abduction-adduction, parallel, and mirror movements of the index fingers.Three transaxial images of 40, 44, and 48 mm above the anterior-posteriorcommissural line are shown. The pixels show Z > 2.3. The activatedfoci are corresponding to that of sequential finger movements,with lesser significance.
[View Larger Version of this Image (89K GIF file)]

The parallel abduction-adduction movements activated these areas more prominently than unimanual movements of the index fingers,whereas no significant difference was observed between mirrorbimanual movements and unimanual movements of either hand (Table8).

DISCUSSION

Bimanual movements of different characteristics
Because both parallel and mirror are the characteristics of bimanual coordination, the difference between parallel and mirroris attributed to the difference of bimanual coordination. Henceareas showing increased rCBF during parallel rather than mirrorshould have a role in bimanual coordination. The right-sided largeractivation also suggests that more work is necessary in the parallelmovements than mirror movements in the right hemisphere, whereasleft-sided neural networks might be used equally in both conditions.The slight difference in performance of sequential movements andno difference in nonsequential movements may suggest that theperformance difference is related to sequence generation and notto bimanual coordination.

Supplementary motor area
Activation of the SMA is associated with the initiation of movement, motor programming (Roland et al., 1980), motor planning(Orgogozo and Larsen, 1979; Grafton et al., 1992; Rao et al.,1993), readiness to move (Fox et al., 1985), motor learning (Rolandet al., 1989; Seitz et al., 1990; Grafton et al., 1992), complexityof the movement (Shibasaki et al., 1993), and responsiveness tointernal cueing of movement (Halsband et al., 1993) or to theselection of movement (Deiber et al., 1991). The SMA is now arguedto have two distinct areas with different functions, that is,the anterior SMA or pre-SMA, and the posterior SMA, or SMA proper(Luppino et al., 1993). They are roughly divided by the verticalanterior commissural line (Deiber et al., 1991).

Previous studies suggest that the SMA has a role in bimanual coordination. Brinkman (1981, 1984) found that unilateral ablationof the SMA in monkeys produced a long-lasting deficit in bimanualcoordination, especially prominent when the SMA lesion was contralateralto the nonpreferred hand. Laplane et al. (1977) found that threepatients with unilateral SMA excision for control of epilepsyshowed an inability to perform alternating movements of the handthat required reciprocal coordination. Chan and Ross (1988) reporteda patient with an infarct of the right SMA who showed pathologicalleft-handed mirror writing and mirror movements during bimanualcoordination. They hypothesized that the SMA may be responsiblefor nonmirror transformation of motor programs originating inthe left hemisphere before execution by the primary motor areain the right hemisphere.

This hypothesis is supported by other studies. First, a leading role of the left hemisphere for bimanual movement is suggestedby the hypothesis that the left hemisphere is dominant for motorprograms. Studies involving brain lesions showed that the leftcerebral hemisphere can exert some ipsilateral motor control (Wyke,1966, 1967, 1968, 1971; Kimura and Archibald, 1974; Kimura, 1977;De Renzi et al., 1980; Jason, 1985). Concerning the effects oftask complexity on movement ipsilateral to lesions, Haaland etal. (1987) found that patients with left-sided cerebral strokesshowed greater impairment with a less complex movement than witha more complex movement, whereas patients with right-sided cerebralstrokes did not. They speculated that the less complex task wasperformed as a preprogrammed, open loop movement, whereas themore complex task was performed by visual guidance (closed loopmovement), concluding that the left hemisphere is dominant forpreprogrammed movements. These notions are consistent with thepresent study, because sequential finger movements were open loop,preprogrammed movements.

Second, cerebral dominance and asynchrony between bimanual movements have been reported. During a bimanual circular trackingtask, the right hand leads the left hand by ~25 msec (Stucchiand Viviani, 1993; Viviani et al., 1995). Because this delay iscompatible with intercallosal transmission, the mechanism responsiblefor setting and maintaining the rhythm may be located in the lefthemisphere, with the other hemisphere receiving time-keeping informationthrough an interhemispheric connection.

Third, a study in nonhuman primates showed that the SMA hand representations are strongly interconnected via the corpus callosum,whereas the transcallosal interconnections of the M1 or betweenthe SMA and the M1 are sparse (Rouiller et al., 1994).

Finally, using transcranial magnetic stimulation, which can demonstrate the contribution of a cortical area to a task by transientlydisrupting its function, Pascual-Leone et al. (1994) showed thatstimulation to the SMA disrupted the performance of parallel sequentialfinger movements and converted them to mirror movements. Theyconcluded that the SMA was required for the synchrony of bimanualmovements and for the bimanual coordination of parallel movements.

These findings, together with the present study, suggest that the posterior SMA is related to the nonmirror transformationof sequential finger movements.

Dorsal premotor area
The "premotor cortex" is a term originally applied to the lateral portion of the frontal agranular cortex rostral to the primarymotor cortex (Dum and Strick, 1991). Premotor lesions can be characterizedby the disintegration of the dynamics of the motor act and skilledmovements (Kleist, 1907, 1911; Luria, 1966). Although some typesof apraxia have been related mainly to left premotor lesions,a role for the right premotor area has occasionally been described(Halsband et al., 1993). The premotor cortex in the primate isheterogeneous and composed of multiple areas, including the PMdand the PMv (Dum and Strick, 1991; He et al., 1993). PMd is locatedaround the precentral dimple of the monkey, and PMv is in thepostarcuate region. The right premotor cortex, which showed moreactivation during parallel movements than during mirror movementsin the present study, may be equivalent to the PMd because ofits dorsal location.

Mushiake et al. (1991) showed that the motor set-related activity to perform a remembered sequential movement was more frequentin the PMd than in the PMv. In addition, sequence-specific neuronswere more numerous in the PMd. During hand movement with instructionof the direction and amplitude, Kurata (1993) showed that set-relatedactivity of the PMd was most active after instruction stimuli(ISs) were given for both amplitude and direction, not after ISfor either one alone was presented. Thus PMd set-related activitymay contribute to motor preparation by providing specified amplitudeand direction. A majority of set-related neurons after obtainingtwo ISs showed activity reflecting both amplitude and direction,suggesting that these two parameters were integrated in PMd set-relatedactivity. These findings suggest that the PMd may have a rolein preprogrammed processes linked to sequential motor actions(Kurata, 1993). The PMd has dense corticocortical input from theSMA (Kurata, 1991). The functional significance of the input maybe to provide the information necessary for motor set, so thatthe PMd could generate a program more closely reflecting motoraspects (Kurata, 1991). In nonhuman primates, the SMA and premotorcortex showed premovement activity. A portion of cells with movement-specificactivity were observed exclusively in relation to the bilateralkey press (Tanji et al., 1988). Hence the right PMd may integrateinformation such as the sequence of finger movements from theSMA to fit the left finger movements into that of the counterpart.

Abduction-adduction movement of index fingers
The present study showed that the activation of the posterior SMA and right PMd was significantly more prominent during parallelabduction-adduction finger movements than during mirror movements.The difference may originate from coordination of the muscularactivity rather than programming sequences or execution. In theseareas, there was no significant difference in activation betweenmirror abduction-adduction movements and unimanual movements,whereas the parallel movements were associated with greater activationthan the unimanual movements. This implies that mirror movementsdo not need additional involvement of the SMA and right premotorcortex. Involuntary mirror movements on one side of the body thatoccur as mirror reversal of an intended movement on the otherside of the body (Cohen et al., 1991) are common as normal phenomenain children and usually disappear after the first decade of life(Connolly and Stratton, 1968). The timing of this disappearancecoincides with the completion of myelination of the corpus callosum(Yakovlev and Lecours, 1967), implying the importance of interhemisphericconnections to generate nonmirror movement. These findings suggestthat the SMA and right PMd may suppress the "default" mirror movementsfor nonmirror, bimanual coordination.

Other areas of activation during bimanual movements
Bimanual movements activated well established parts of the motor system. Additional activation in the midbrain was noted duringsequential parallel movements, and in the right prefrontal cortexduring sequential parallel and abduction-adduction movements.Because no significant difference between parallel and mirrorwas noted, the role of these areas may not be specific to bimanualcoordination.

Jenkins et al. (1994) reported activation of the midbrain during the learning of a new sequence of finger tapping, whereasno significant activation occurred during performance of a prelearnedsequence. They speculated that this activation represented activationof cerebellorubral pathways, although the effect of increasedattention in learning a new sequence was another possibility.Because the tasks had a minimal learning component in the presentstudy and because the subjects had to attend to their fingersand the auditory cues to perform the bimanual movements, the activationof the midbrain may be related to increased attention (Kinomuraet al., 1996).

The right prefrontal cortex is also related to sustained attention (Pardo et al., 1991). To perform bimanual movement, on-linemonitoring of the position of the fingers is necessary. Becausethe right prefrontal cortex is involved in spatial working memory(Jonides et al., 1993), activation of the right prefrontal cortexduring bimanual movements may be related to increased spatialattention and spatial working memory.

FOOTNOTES

Received May 14, 1997; revised Sept. 24, 1997; accepted Sept. 26, 1997.

We thank Dr. Mark Hallett, National Institute of Neurological Disorders and Stroke, for helpful discussion.

Correspondence should be addressed to Dr. Norihiro Sadato, Biomedical Imaging Research Center, Fukui Medical School, 23 Shimoaizuki,Matsuoka, Yoshida, Fukui, 910-11 Japan.

REFERENCES

Brinkman C (1981) Lesions in supplementary motor area interfere with a monkey's performance of a bimanual coordination task. Neurosci Lett 27:267-270[ISI][Medline].
Brinkman C (1984) Supplementary motor area of the monkey's cerebral cortex: short- and long-term deficits after unilateral ablation and the effects of subsequent callosal section. J Neurosci 4:918-929[Abstract].
Brinkman J, Kuypers HGJM (1972) Splitbrain monkeys: cerebral control of ipsilateral and contralateral arm, hand, and finger movements. Science 176:535-539[Abstract/Free Full Text].
Brinkman J, Kuypers HGJM (1973) Cerebral control of contralateral and ipsilateral arm, hand, and finger movements in the split-brain rhesus monkey. Brain 96:653-674[Free Full Text].
Chan J-L, Ross ED (1988) Left-handed mirror writing following right anterior cerebral artery infarction: evidence for nonmirror transformation of motor programs by right supplementary motor area. Neurology 38:59-63[Abstract/Free Full Text].
Cohen LG, Meer J, Tarkka I, Bierner S, Leiderman DB, Dubinsky RM, Sanes JN, Jabbari B, Branscum B, Hallett M (1991) Congenital mirror movements. Brain 114:381-403[Abstract/Free Full Text].
Connolly K, Stratton P (1968) Developmental changes in associated movements. Dev Med Child Neurol 10:49-56[ISI][Medline].
De Grado TR, Turkington TG, Williams JJ, Stearns CW, Hoffman JM (1994) Performance characteristics of a whole-body PET scanner. J Nucl Med 35:1398-1406[Abstract/Free Full Text].
Deiber M-P, Passingham RE, Colebatch JG, Friston KJ, Nixon PD, Frackowiak RSJ (1991) Cortical areas and the selection of movement: a study with positron emission tomography. Exp Brain Res 84:393-402[ISI][Medline].
De Renzi E, Motti F, Nichelli P (1980) Imitating gestures: a quantitative approach to ideomotor apraxia. Arch Neurol 37:6-10[Abstract].
Donoghue JP, Sanes JN (1994) Motor areas of the cerebral cortex. J Clin Neurophysiol 11:382-396[ISI][Medline].
Dum RP, Strick PL (1991) The origin of corticospinal projections from the premotor areas in the frontal lobe. J Neurosci 11:667-689[Abstract].
Fox PT, Mintun MA (1989) Noninvasive functional brain mapping by change-distribution analysis of averaged PET images of H₂¹⁵O tissue activity. J Nucl Med 30:141-149[Abstract/Free Full Text].
Fox PT, Mintun MA, Raichle ME, Herscovitch P (1984) A noninvasive approach to quantitative functional brain mapping with H₂¹⁵O and positron emission tomography. J Cereb Blood Flow Metab 4:329-333[ISI][Medline].
Fox PT, Fox JM, Raichle ME, Burde RM (1985) The role of cerebral cortex in the generation of voluntary saccades: a positron emission tomography study. J Neurophysiol 54:348-369[Abstract/Free Full Text].
Freund H-J (1990) Premotor area and preparation of movement. Rev Neurol 146:543-547[Medline].
Friston KJ, Passingham RE, Nutt JG, Heather JD, Sawle GV, Frackowiak RSJ (1989) Localisation in PET images: direct fitting of the intercommissural (AC-PC) line. J Cereb Blood Flow Metab 9:690-695[ISI][Medline].
Friston KJ, Frith CD, Liddle PF, Dolan RJ, Lammertsma AA, Frackowiak RSJ (1990) The relationship between global and local changes in PET scans. J Cereb Blood Flow Metab 10:458-466[ISI][Medline].
Friston KJ, Frith CD, Liddle PF, Frackowiak RSJ (1991) Comparing functional (PET) images: the assessment of significant change. J Cereb Blood Flow Metab 11:690-699[ISI][Medline].
Friston KJ, Worsley KJ, Frackowiak RSJ, Mazziotta JC, Evans AC (1994) Assessing the significance of focal activations using their spatial extent. Hum Brain Mapp 1:210-220.
Friston KJ, Ashburner J, Frith CD, Heather JD, Frackowiak RSJ (1995a) Spatial registration and normalization of images. Hum Brain Mapp 2:165-188.
Friston KJ, Holmes AP, Worsley KJ, Poline JB, Frith CD, Frackowiak RSJ (1995b) Statistical parametric maps in functional imaging: a general linear approach. Hum Brain Mapp 2:189-210.
Friston KJ, Holmes A, Poline J-B, Price CJ, Frith CD (1996) Detecting activations in PET and fMRI: levels of inference and power. NeuroImage 4:223-235.[ISI][Medline]
Grafton ST, Mazziotta JC, Presty S, Friston KJ, Frackowiak RSJ, Phelps ME (1992) Functional anatomy of human procedural learning determined with regional cerebral blood flow and PET. J Neurosci 12:2542-2548[Abstract].
Haaland KY, Harrington DL, Yeo R (1987) The effects of task complexity on motor performance in left and right CVA patients. Neuropsychologia 25:783-794[ISI][Medline].
Halsband U, Ito N, Tanji J, Freund H-J (1993) The role of premotor cortex and the supplementary motor area in the temporal control of movement in man. Brain 116:243-266[Abstract/Free Full Text].
He SQ, Dum RP, Strick PL (1993) Topographic organization of corticospinal projections from the frontal lobe: motor areas on the lateral surface of the hemisphere. J Neurosci 13:952-980[Abstract].
Jason GW (1985) Manual sequence learning after focal cortical lesions. Neuropsychologia 23:483-496[ISI][Medline].
Jenkins IH, Brooks DJ, Nixon PD, Frackowiak RSJ, Passingham RE (1994) Motor sequence learning: a study with positron emission tomography. J Neurosci 14:3775-3790[Abstract].
Jonides J, Smith EE, Koeppe RA, Awh E, Minoshima S, Mintun MA (1993) Spatial working memory in humans as revealed by PET. Nature 363:623-625[Medline].
Kimura D (1977) Acquisition of a motor skill after left-hemisphere damage. Brain 100:527-542[Free Full Text].
Kimura D, Archibald Y (1974) Motor functions of the left hemisphere. Brain 97:337-350[Free Full Text].
Kinahan PE, Rogers JG (1989) Analytic three dimensional image reconstruction using all detected events. IEEE Trans Nucl Sci 36:964-968.[ISI]
Kinomura S, Larsson J, Gulyas B, Roland PE (1996) Activation by attention of the human reticular formation and thalamic intralaminar nuclei. Science 271:512-515[Abstract].
Kleist K (1907) Corticale (innervatorische) apraxie. Jahrbuch Psychiatrie Neurologie 28:46-112.
Kleist K (1911) Der gang und der gegenwartige stand der apraxie-forschung. Ergebnisse Neurol Psychiatrie 1:342-452.
Kurata K (1991) Corticocortical inputs to the dorsal and ventral aspects of the premotor cortex of macaque monkeys. Neurosci Res 12:263-280[ISI][Medline].
Kurata K (1993) Premotor cortex of monkeys: set- and movement-related activity reflecting amplitude and direction of wrist movements. J Neurophysiol 69:187-200[Abstract/Free Full Text].
Laplane D, Talairach J, Meininger V, Bancaud J, Orgogozo JM (1977) Clinical consequences of corticectomies involving the supplementary motor area in man. J Neurol Sci 34:301-314[ISI][Medline].
Lewellen TK, Kohlmeyer SG, Miyaoka RS, Kaplan MS (1996) Investigation of the performance of the General Electric advance positron emission tomograph in 3D mode. IEEE Trans Nucl Sci 43:2199-2206.
Luppino G, Matelli M, Camarda R, Rizzolatti G (1993) Corticocortical connections of area F3 (SMA-proper) and area F6 (pre-SMA) in the macaque monkey. J Comp Neurol 338:114-140[ISI][Medline].
Luria AR (1966) In: Higher cortical functions in man. New York: Basic Books.
Mushiake H, Inase M, Tanji J (1991) Neuronal activity in the primate premotor, supplementary, and precentral motor cortex during visually guided and internally determined sequential movements. J Neurophysiol 66:705-718[Abstract/Free Full Text].
Oldfield RC (1971) The assessment and analysis of handedness: the Edinburgh inventory. Neuropsychologia 9:97-113[ISI][Medline].
Orgogozo JM, Larsen B (1979) Activation of the supplementary motor area during voluntary movement in man suggests it works as a supramotor area. Science 206:847-850[Abstract/Free Full Text].
Pardo JV, Fox PT, Raichle ME (1991) Localization of a human system for sustained attention by positron emission tomography. Nature 349:61-64[Medline].
Pascual-Leone A, Cohen L, Wassermann E, Hallett M (1994) The role of the supplementary motor area (SMA) in the coordination of bimanual movements. Neurology 44[Suppl 2]:A329.
Rao SM, Binder JR, Bandettini PA, Hammeke TA, Yetkin FZ, Jesmanowicz A, Lisk LM, Morris GL, Mueller WM, Estkowski LD, Wong EC, Haughton VM, Hyde JS (1993) Functional magnetic resonance imaging of complex human movements. Neurology 43:2311-2318[Abstract/Free Full Text].
Roland PE, Larsen B, Lassen NA, Skinhoj E (1980) Supplementary motor area and other cortical areas in organization of voluntary movements in man. J Neurophysiol 43:118-136[Abstract/Free Full Text].
Roland PE, Eriksson L, Widen L, Stone-Elander S (1989) Changes in regional cerebral oxidative metabolism induced by tactile learning and recognition in man. Eur J Neurosci 1:3-18[ISI][Medline].
Rouiller EM, Balalian A, Kazennikov O, Moret V, Yu X-H, Wiesendanger M (1994) Transcallosal connections of the distal forelimb representation of the primary and supplementary motor cortical areas in macaque monkeys. Exp Brain Res 102:227-243[ISI][Medline].
Sadato N, Carson RE, Daube-Witherspoon ME, Campbell G, Hallett M, Herscovitch P (1995) Optimization of non-invasive activation study with ¹⁵O water and 3D PET. J Nucl Med 36:82P.
Sadato N, Campbell G, Ibanez V, Deiber M-P, Hallett M (1996) Complexity affects regional cerebral blood flow change during sequential finger movements. J Neurosci 16:2693-2700.
Seitz RJ, Roland PE, Bohm C, Greitz T, Stone-Elander S (1990) Motor learning in man: a positron emission tomographic study. NeuroReport 1:57-60[Medline].
Shibasaki H, Sadato N, Lyshkow H, Yonekura Y, Honda M, Nagamine T, Suwazono S, Magata Y, Ikeda A, Miyazaki M, Fukuyama H, Asato R, Konishi J (1993) Both primary motor cortex and supplementary motor area play an important role in complex finger movement. Brain 116:1387-1398[Abstract/Free Full Text].
Steinmetz H, Furst G, Freund H-J (1989) Cerebral cortical localization: application and validation of the proportional grid system in MR imaging. J Comput Assist Tomogr 13:10-19[ISI][Medline].
Stucchi N, Viviani P (1993) Cerebral dominance and asynchrony between bimanual two-dimensional movements. J Exp Psychol Hum Percept Perform 19:1200-1220[ISI][Medline].
Talairach J, Tournoux P (1988) In: Co-planar stereotaxic atlas of the human brain. New York: Thieme.
Tanji J, Okano K, Sato KC (1988) Neuronal activity in cortical motor areas related to ipsilateral, contralateral and bilateral digit movements of the monkey. J Neurophysiol 60:325-343[Abstract/Free Full Text].
Viviani P, Perani D, Grassi F, Stucchi N, Todde S, Fazio F (1995) Hemispheric asymmetry in cerebral activity during rhythmic bimanual coordination. J Cereb Blood Flow Metab 15:S865.
Wyke M (1966) Postural arm drift associated with brain lesions in man. Arch Neurol 15:329-334[ISI][Medline].
Wyke M (1967) Effects of brain lesions on the rapidity of arm movements. Neurology 17:1113-1120[Free Full Text].
Wyke M (1968) The effects of brain lesions in the performance of an arm-hand precision task. Neuropsychologia 6:125-134.
Wyke M (1971) The effects of brain lesions on the performance of bilateral arm movements. Neuropsychologia 9:33-42[ISI][Medline].
Yakovlev PI, Lecours A-R (1967) The myelogenetic cycles of regional maturation of the brain. In: Regional development of the brain in early life (Minkowski A, ed), pp 3-70. Oxford: Blackwell.

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