Abstract
Many tasks in our daily life demand not only the use of different fingers of one hand in a serial fashion, but also to alternate from one hand to the other. Here, we investigated performance in a bimanual serial reaction time task (SRTT) with particular emphasis on learning-related changes in reaction time (RT) for consecutive button presses for homologous index- and middle fingers. The bimanual SRTT consisted of sequential button presses either with the left or right index- and middle-finger to a series of visual letters displayed on a computer screen. Each letter was assigned a specific button press with one of four fingers. Two outcome measures were investigated: (a) global sequence learning as defined by the time needed to complete a 15-letter SRTT sequence and (b) changes in hand switch costs across learning. We found that bimanual SRTT resulted in a global decrease in RT during the time course of learning that persisted for at least two weeks. Furthermore, RT to a button press showed an increase when the previous button press was associated with another hand as opposed to the same hand. This increase in RT was defined as switch costs. Hand switch costs significantly decreased during the time course of learning, and remained stable over a time of approximately two weeks. This study provides evidence for modulations of switch costs during bimanual sequence learning, a finding that might have important implications for theories of bimanual coordination and learning.
Highlights
Many tasks in our daily life demand to use different fingers of one hand in a serial fashion, and alternate from one hand to the other
We were interested in learning effects of a bimanual serial reaction time task (SRTT) with particular emphasis on modulations in reaction time (RT) associated with switches between hands
While the SRTT performance in the random sequences was significantly reduced from 7.8661.96 s (1st sequence) to 6.1362.03 s, the improvement for the random sequences (1.7361.78 s 1st random vs. last random sequence) was significantly less pronounced as compared to the learning sequences (4.4961.87 s 1st learning vs. last learning sequence, p,0.001, Bonferroni-corrected t-test)
Summary
Many tasks in our daily life demand to use different fingers of one hand in a serial fashion, and alternate from one hand to the other. Apart from the considerable knowledge regarding unilateral motor sequence learning, surprisingly little is known about the neurophysiological mechanisms of bilateral engagement of hands in a sequential manner. This is an important issue in daily life situations where we use our two hands together such as in typing on a keyboard or playing a piano. Performance in a SRTT depends on the number of nodes that have to be traversed According to this model, a transition between fingers from different hands would require at least one more node to be traversed than a transition between fingers from one hand. The present study investigates performance to visually presented stimuli
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