Can Left-Handedness be Switched? Insights from an Early Switch of Handwriting

Participants.

Sixteen converted left-handers (mean age, 36.4 years; range, 24–47 years; 9 males) were compared with 16 consistent age- and sex-matched right-handed subjects (mean age, 33.3 years; range, 24–57 years; 10 males) and 16 left-handed subjects (mean age, 35 years; range, 25–56 years; 10 males). Converted left-handers were recruited via advertisement in which we asked for volunteers who showed an early and consistent preference for left-handed movements at preschool age (4–6 years of age) but were forced to learn handwriting with their right nondominant hand. Accordingly, all converted left-handers included in the study reported a clear preference for the left hand on commencing school. They or their parents clearly recalled them starting writing with the left hand at school with a subsequent switch to the right. None of the converted left-handers were members of the cohort we examined in our previous PET study (Siebner et al., 2002). Data from 13 consistent right-handed and 14 left-handed subjects are reported from a previous study that used the same paradigm (Klöppel et al., 2007).

Handedness was determined with the Edinburgh handedness questionnaire (Oldfield, 1971). This results in a laterality quotient in which a score of −100 reflects extreme left-handedness and +100 reflects extreme right-handedness. Scores ranged from −80 to 0 (mean laterality quotient, −43.4) in the converted group (Fig. 1). The two groups with consistent handedness reported scores from 60 to 100 (mean, 94.2) and from −60 to −100 (mean, −83.8), respectively (supplemental Fig. S1, available at www.jneurosci.org as supplemental material). In addition, handedness was assessed by asking participants to pantomime six manual tasks [writing, throwing, holding a tennis racket, striking a match (hand holding match), holding a hammer, brushing teeth] as listed in Annett's handedness questionnaire (Annett, 1976). Participants were labeled as consistent right- or left-handers when all six items were pantomimed with the same (dominant) hand. Participants gave written informed consent to the study. Experimental procedures were approved by the local Ethics Committee and performed according to the ethical standards laid down in the Declaration of Helsinki.

Handwriting task outside the MR scanner.

Participants were asked to continuously write pairs of two lower case “l” letters (“ll”) for a 10 s period (see Fig. 2, left) at normal speed. All subjects performed the task with both right and left hands. The handwriting task was used to obtain a measure of manual dexterity and to check whether right-handed handwriting was matched between converted left-handers and consistent right-handers. We chose a relatively simple writing task because it could be performed with both the preferred and nonpreferred hands.

To obtain an objective measure of handwriting, writing was continuously recorded with a digitizing graphics tablet and an inking digitizing pen (UD-1212; WACOM Europe, Neuss, Germany). The position of the pen tip was stored on a personal computer at a sample frequency of 166 Hz. The spatial resolution was 0.05 mm. Kinematic analysis used a personal computer-based program (CS software; MedCom, Munich, Germany). Kinematic analyses were based on writing movements along the vertical axis because this is the axis along which writing movements predominantly occur (Marquardt and Mai, 1994). The written trace was automatically segmented into consecutive up-and-down strokes. Curves of vertical position and velocity were calculated and smoothed by nonparametric regression methods. The mean frequency of consecutive up-and-down strokes was calculated for handwriting with the right and left hand. This measure is a well established marker of the degree of automation of handwriting (Marquardt and Mai, 1994).

Choice reaction-time task during fMRI.

Participants performed a visually cued choice reaction-time task with their right, left, or both index fingers in response to a symbolic cue. Each trial started with the presentation of a cue in the center of the visual field. The cue was presented for 1.0 s, and the time between two consecutive cues was jittered between 2.0 and 2.3 s. By choosing symmetrical stimuli, avoiding any directional information, and by presenting stimuli sequentially in the center of the screen, we tried to minimize shifts in spatial attention. Symbols were light gray in color presented on a dark gray background (see Fig. 3 A). There were three symbolic cues, each instructing a different movement (pressing a button with the left, right, or both index fingers). Responses were made as quickly as possible with two buttons set beneath the right or left index fingers. For a bilateral motor response, participants pressed both buttons simultaneously. A fourth cue instructed participants to keep still (referred to as a no-go condition). The no-go condition was introduced to prevent response anticipation. The assignment of cues to tasks was counterbalanced across participants. Each of the four cues was presented 48 times per fMRI run. In addition, there were 48 null events without cue presentation. The order of cue presentation and null events was pseudo-randomized. Participants had no advance information about movements to be made in successive trials. The software package PRESENTATION (Neurobehavioral Systems, Albany, NY) was used for stimulus presentation, synchronization of stimuli, image pulse acquisition, and recordings of motor responses during fMRI. In each trial, stimulus onset and reaction time were extracted from the results file. Mean reaction time was calculated for correct responses of each trial type. For trials that required bilateral responses, we used the first button press to calculate mean reaction time. To correlate performance in the handwriting task with imaging data, a quotient (mean stroke frequency right hand/mean stroke frequency left hand) was computed. Values >1 indicate lateralization to the right. The visuomotor reaction-time task was suitable for probing effector-independent sensorimotor representations because the task required unilateral and bilateral responses with right and left hands. A second reason for choosing a relatively simple reaction-time task was to avoid any differential task performance related to individual expressions of handedness (Klöppel et al., 2007). We refrained from using a more skillful manual task because differential right–left performance is a usual finding in such tasks. We were concerned that such differences would confound the interpretation of task-related group differences in neuronal activity (Stucchi et al., 1993; Lutz et al., 2005).

fMRI.

MRI was performed on a 3T system (TRIO; Siemens, Erlangen, Germany). We used single-shot gradient-echo echo-planar imaging (EPI) [repetition time (TR), 2.12 s; echo time (TE), 25 ms; flip angle, 70°] to measure task-related blood oxygenation level-dependent (BOLD) signal changes (used as an index of regional brain activity). A single brain volume consisted of 37 transversally oriented slices (slice thickness, 3 mm; matrix, 192 × 192 mm; in-plane resolution, 3 × 3 mm). The field of view covered both cerebral hemispheres. Three hundred brain volumes were acquired in a single fMRI session lasting ∼10 min.

We excluded structural abnormalities in the brain with a T1-weighted FLASH three-dimensional whole-brain sequence (TR, 15 ms; TE, 4.92 ms; flip angle, 25°; 192 slices; slice thickness, 1 mm; matrix, 256 × 256 mm).

Behavioral data analysis.

Separate repeated-measures ANOVA were computed to examine the mean frequency of up-and-down strokes during handwriting and mean reaction times during the visually cued reaction-time motor task. Both measures were treated as dependent variables in a two-factorial ANOVA with a within-subject factor, “performing hand” (two levels: right and left), and a between-subjects factor, “handedness” (three levels: right-handers, left-handers, and converted left-handers). Conditional on significant F test results, we performed post hoc pairwise comparisons using the Scheffé's test. In the reaction-time task, we also assessed how often participants made first button presses with left and right hands, respectively. The significance level was set at p < 0.05. Nonparametric tests were used to compare sex, percentage of correct button presses, and percentage of button presses with each hand in the bilateral condition. Behavioral data are given as mean ± SD for parametric tests and as median ± range for nonparametric data.

Imaging data analysis.

Preprocessing and statistical analysis of the fMRI data were performed using SPM2 software (www.fil.ion.ucl.ac.uk/spm/). The first three volumes of each session were excluded from data analysis because of magnetization effects. The remaining volumes were realigned to the first volume and spatially normalized to a standard EPI template in Montreal Neurological Institute (MNI) space. The images were then spatially smoothed with an isotropic Gaussian kernel of 8 mm full-width at half-maximum to allow statistical inference using the Gaussian random-field theory and temporally filtered with a high-pass filter to remove baseline drifts.

A first-level analysis based on the general linear model (Friston et al., 1995) was performed for each subject individually. Task-related changes in BOLD signal were estimated at each voxel by modeling the onsets of each trial as δ functions convolved with a hemodynamic response function (HRF). Each of the four experimental conditions (right button press, left button press, bilateral button press, and “no-go” condition) and incorrect responses were modeled as separate regressors. In addition, we included six regressors obtained at the realignment step to account for movements (translations in three planes and rotations along three axes). Null events were not modeled and provided the baseline for condition-specific main effects. Condition-specific effects were tested using the appropriate linear contrasts of parameter estimates for the HRF regressors of all conditions. The resulting set of voxel values for each contrast constitutes a statistical parametric map.

For group inferences (second level), we performed a random-effects analysis treating subjects as a random variable. The individual parameter images corresponding to each movement condition, derived from the first-level analysis, were entered into separate between-group ANOVAs that used the condition-specific BOLD signal changes as a dependent measure. Thus, each ANOVA model contained the parameter images of only one movement condition (i.e., right, left, or bilateral button presses) and three groups (converted and consistent left-handers, consistent right-handers). Within each ANOVA model, we specified appropriately weighted linear contrasts to test for regional differences in movement-related activation between the three groups with an F test.

Our primary aim was to identify brain regions where converted left-handers show a consistent difference in task-related BOLD signal changes independent of the effector, and therefore across all movement conditions, relative to individuals with consistent right- and left-handedness. To this end, we performed a stepwise masking approach. This procedure enabled us to use fully orthogonal contrasts to effectively reduce the search volume and thereby increase sensitivity. The statistical images containing the F values (F-maps) obtained in two separate ANOVAs were combined to define a region of interest for the F-map obtained in the third ANOVA. F-maps that were used to generate the masks were thresholded at p < 0.01 (uncorrected). For instance, the F-map showing voxels with differential activity for unilateral button presses between all three groups was used to generate an inclusive mask for the F-map showing differential activity for bilateral button presses. The order of masking did not change the significance of results. To avoid any bias toward a positive finding, we report the results for the masking order that gave the lowest F score (for full details, see supplemental Table 1, available at www.jneurosci.org as supplemental material).

For peak voxels in regions, identified by F statistics, which showed effector-independent, differential, movement-related BOLD signals in the three groups, we performed post hoc t tests. Post hoc comparisons tested for significant differences in task-related BOLD signal changes between converted left-handers and consistent left-handers as well as converted left-handers and consistent right-handers. For completeness, we also report results of a comparison between the two groups with consistent handedness (supplemental Table S2, available at www.jneurosci.org as supplemental material).

In converted left-handers, we performed an additional within-group analysis to identify areas in which task-related neuronal activity correlated positively and linearly with degree of rightward shift in hand preference. This analysis was performed in the converted group only because the aim was to demonstrate a relationship between neuronal activation evoked by simple button presses and degree of switching. We performed two separate regressions. Individual laterality quotients derived from Edinburgh handedness scores and handwriting stroke frequencies were used as explanatory variables with the task-related change in BOLD signal as the dependent variable. We were interested to identify brain voxels that showed an effector-independent relationship between the degree of conversion and task-related activity across all three types of response. Therefore, we used a similar stepwise masking approach as for the categorical comparison described above. A separate simple regression model with a behavioral measure as explanatory variable (writing quotient or Edinburgh score) was tested separately for each movement type. Voxels correlating significantly in any two conditions (threshold: p < 0.01, uncorrected) generated a mask to constrain the search volume for a correlation with the third conditions. We report results with the masking order that gave the lowest T scores (for full details, see supplemental Table 3, available at www.jneurosci.org as supplemental material).

Results were corrected for multiple nonindependent comparisons within a volume of interest or for the entire brain if no mask was applied. We used the false discovery rate correction as implemented in SPM2 at p < 0.05. All imaging results are reported with corresponding significance levels at peak coordinates in MNI space.