Handedness refers to the preference for using right or left hand for various unimanual activities [
Handedness is known to be related to dominant hemisphere [
The issue of selection of behavioral indexes of brain lateralization is very complex. Eye, ears, and foot are important in the consideration of cerebral specialization. Although different experimental work has attempted to identify reliable behavioral predictor of cerebral lateralization, no such predictor has been found. Previous study demonstrated that footedness is a possible indicator of human laterality [
We aimed to assess the association between brain lateralization and cognition as handedness was used as an index of brain lateralization.
There is currently no data reflecting the prevalence of right- and left-handedness in Kuwait. In order to ensure adequate representation of both right- and left-handed subjects, an equal sample of both right- and left-handed subjects was sought.
We chose a young population as evidence suggesting that the prevalence of left-handedness declines with increasing age [
Subjects for the study were selected from each school by visiting classes from each grade. Left-handed students were identified by either asking the students to raise the hand which they use to write or asking them to write their names or draw a check mark to observe their hand of choice. All left-handed students identified by these methods were included in the study.
In order to ensure adequate representation of both right- and left-handed subjects, an equal sample of both right- and left-handed subjects was sought. We included right- and left-handed groups according to the values of laterality indexes.
All selected students were given informed consent and self-administered questionnaires to take home to their guardians and were instructed to return signed consent and the filled out questionnaires and leave them with the school social worker for safekeeping until our return to the school for data collection two days later. Children who returned completed questionnaires were assigned to one of two sets of serial numbers reflecting their writing hand preference; within each set, students had equal opportunity of having odd and even serial numbers which aided in further randomization. The questionnaire consisted of questions regarding the child’s personal information and information regarding the family’s sociodemographic status. It is possible that left-handed children have early been corrected to being right-handed, so the questionnaire included questions to parents to clarify which preferred hand is since birth and if being left-handed has been corrected to being right-handed.
Handedness was assessed by two tests: the Grooved Pegboard Test (GPT) and the WatHand Cabient Test (WBT) [
Cognition was assessed with The Cambridge Neuropsychological Test Automated Battery (CANTAB) which is a group of computer-based tests that assess visual memory, attention, and executive function [
CANTAB is a computerized neuropsychological assessment battery originally written and developed by Barbara Sahakian, Trevor Robbins, and colleagues at Cambridge University in 1986 [
Visual memory was assessed with the Delayed Matching to Sample (DMS) test, Pattern Recognition Memory (PRM) test, and Spatial Recognition Memory (SRM) test. In the DMS test, the subject must memorize a visual pattern and then recognize it from a group of similar patterns after various delay intervals. In the first phase of the PRM test, the subject is shown a series of 12 patterns. In the second phase, the subject must choose from two patterns presented at a time, one of which has already been shown and the other is a novel distractor. The SRM test assesses the subject’s spatial recognition by first displaying a series of white boxes in different locations. These boxes reappear one at a time along with a new box, and the subject is requested to recognize the familiar ones.
The executive function test used is the Spatial Span (SSP) that assesses working memory in addition to visuospatial ability. Nine white squares appear on the screen, some of which change color in a sequence, and the subject must choose these squares in the same order. The sequence of squares starts with two and increases to a maximum of nine squares with every correct answer.
The remaining two tests assess attention and require the use of a two-button press pad. In the (CRT) test, subjects are presented with a series of arrows located in either the right or left half of the screen and are required to press the corresponding right or left button on the press pad.
In the Reaction Time (RTI) test, the subject is required to press a button on the press pad with the index finger until a circle appears on the screen. The subject must then react by immediately touching that circle with the same finger. The test is divided into two phases; in the first phase, the circle always appears in the center of the screen, while in the second, it may appear in one of five predefined locations.
In order to exclude children who are unable to comprehend commands or have visual or movement difficulties, all subjects began their CANTAB testing with the Motor Screening Task (MOT), a test in which the subject is required to touch a flashing cross that appears in different locations on the screen.
All tests were carried out in school libraries that provided a quiet, distraction-free environment for the students. Additionally, all students wore noise canceling headphones for the duration of the CANTAB tests to enhance the audio component of the tests and facilitate the test in a friendly environment. Ethical approval for this study was obtained from the Ministry of Education that oversees all the public schools from which the students were sampled.
Statistical analysis was performed using the Statistical Package for Social Sciences (SPSS). Pearson Correlation Coefficient Test “
Out of 410 questionnaires that were distributed, 233 were completed and returned (57%). The remaining 43% represented those students who were absent or failed to deliver the questionnaires due to either negligence or refusal of the parents to participate.
Fifteen students were excluded on account of not meeting the age criteria at the time of the test. Ten patients were excluded because they were unable to comprehend commands or have visual or movement difficulties. The effective sample size was 217 students (110 right-handed and 107 left-handed) ranging from the ages of seven to ten. Males and females were equally distributed, 108 males versus 109 females. Students aged nine comprised 31.1% with the remaining ages each not exceeding one fourth of the sample. All age groups had a difference of less than 10% in terms of distribution among right- and left-handed students (according to preferred writing hand) except for those aged 8 years where the majority was left-handed (63%). The majority of the students (56.8%) were female with near equal representation of students writing with their left hand between both genders.
The three measures of direction of handedness were compared using two-tailed Spearman correlation. A statistically significant correlation was found between all three measures,
Correlation between measures of handedness and writing hand.
Variables | Writing hand |
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WBT |
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GPT |
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There was no statistically significant correlation between any of the three tests of handedness and the parameters of the CRT test. The DMS test was significantly correlated in the parameters of mean correct latency (in which the triggers were not hidden) with the WBT (
Handedness and confounders handedness and DMS
WatHand | GPT |
Writing hand | |
---|---|---|---|
Percent correct | |||
|
0.029 | −0.090 | 0.060 |
|
0.761 | 0.350 | 0.535 |
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Mean correct latency | |||
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−0.118 | −0.121 | −0.038 |
|
0.221 | 0.207 | 0.695 |
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Mean correct latency simultaneous | |||
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−0.271 | −0.120 | −0.161 |
|
0.004 | 0.214 | 0.094 |
|
|||
Errors correct color | |||
|
−0.067 | 0.081 | −0.050 |
|
0.484 | 0.401 | 0.604 |
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Errors correct shape | |||
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−0.022 | −0.030 | −0.057 |
|
0.817 | 0.758 | 0.556 |
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Errors novel distractor | |||
|
0.079 | 0.139 | 0.003 |
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0.412 | 0.147 | 0.971 |
With regards to the PRM test, there was a significant correlation in the percent of correct answers with both the GPT (
Handedness and confounders handedness and PRM
WatHand | GPT |
Writing hand | |
---|---|---|---|
Percent correct | |||
|
0.144 | 0.205 | 0.216 |
|
0.139 | 0.034 | 0.025 |
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Mean latency | |||
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−0.009 | −0.120 | −0.047 |
|
0.928 | 0.217 | 0.633 |
Correlation between handedness and RTI
WatHand | GPT |
Writing hand | |
---|---|---|---|
Mean simple reaction time | |||
|
−0.044 | 0.201 | −0.077 |
|
0.648 | 0.036 | 0.422 |
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Mean simple movement time | |||
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−0.052 | −0.002 | −0.026 |
|
0.590 | 0.986 | 0.789 |
Correlation between handedness and SSP
WatHand | GPT |
Writing hand | |
---|---|---|---|
Span length | |||
|
−0.081 | 0.253 | 0.124 |
|
0.421 | 0.011 | 0.215 |
|
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Total errors | |||
|
0.019 | 0.228 | 0.047 |
|
0.844 | 0.020 | 0.633 |
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Total usage errors | |||
|
−0.235 | −0.023 | −0.132 |
|
0.016 | 0.816 | 0.180 |
Factors that were not significantly associated with cognition include gender and parental marital status and their educational level.
Selection of behavioral indexes of brain lateralization is very complex. Preferred hand, eye, ears, and foot are important in the consideration of cerebral specialization. Preferred handedness has been studied in many previous studies [
Our study included 217 students of ages ranging from seven to ten. Males and females were equally distributed with near equal representation of students writing with their left hand between both genders.
Our results showed that right-handed children had significant superior visuospatial abilities, visual memory, and better scores in reaction time tests which incorporated elements of visual memory. On the other hand, we proved that left-handed children have better simple reaction times. A similar result was also found in a study conducted by Boulinguez et al., using the visual retention tests [
Our study showed that reaction time tests which incorporated elements of visual memory gave the edge to right-handed children, whereas left-handed children proved to have better simple reaction times. This finding is in accordance with the majority of literature; the theory that the left hand is faster at reaction times that involve spatial relationships has been supported by the previous results [
Our study has some limitations. There were four different operators testing the students, with both the CANTAB and tests of handedness. While they read a uniform script of instructions, subtle differences may have occurred in the methods of delivering the tests. The touch screen used for the CANTAB test was pressure-sensitive which caused variation in responsiveness depending on individual subjects’ strength. Finally, the cross-sectional nature of this study probably limited our ability to truly test the causality of the different factors associated with cognition.
To our knowledge, this is the first study to employ the CANTAB tool in assessing handedness and cognition in healthy children. There are some statistically significant though small differences in cognitive abilities between right- and left-handed individuals. Prospective studies are required to fully analyze the relationship between handedness and cognition. A larger sample size may have yielded more significant differences in cognition between right- and left-handed subjects. More in-depth investigation of the differences between right- and left-handed people can help lateralize certain cognitive functions, which can only serve to improve our understanding of the nature of handedness.
All the authors have no competing interests.