Abstract
The problem size effect is a well-established finding in arithmetic problem solving and is characterized by worse performance in problems with larger compared to smaller operand size. Solving small and large arithmetic problems has also been shown to involve different cognitive processes and distinct electroencephalography (EEG) oscillations over the left posterior parietal cortex (LPPC). In this study, we aimed to provide further evidence for these dissociations by using transcranial direct current stimulation (tDCS). Participants underwent anodal (30min, 1.5 mA, LPPC) and sham tDCS. After the stimulation, we recorded their neural activity using EEG while the participants solved small and large arithmetic problems. We found that the tDCS effects on performance and oscillatory activity critically depended on the problem size. While anodal tDCS improved response latencies in large arithmetic problems, it decreased solution rates in small arithmetic problems. Likewise, the lower-alpha desynchronization in large problems increased, whereas the theta synchronization in small problems decreased. These findings reveal that the LPPC is differentially involved in solving small and large arithmetic problems and demonstrate that the effects of brain stimulation strikingly differ depending on the involved neuro-cognitive processes.
Highlights
The development of mathematical competencies is a major goal of formal schooling and an important prerequisite for success in various areas of life [1]
Confirming the well-established problem size effect (PSE), we found that large problems took longer to solve (M = 2899 ms, SD = 751) than small problems (M = 997 ms, SD = 119; t(22) = 13.2, p < 0.01, Cohen’s d = 2.76)
We found an improvement in response latencies after anodal (M = 2809 ms, SD = 707) compared to sham stimulation (M = 2989 ms, SD = 842; t(22) = 2.14, p = 0.04, d = 0.45; Fig. 3 left panel)
Summary
The development of mathematical competencies is a major goal of formal schooling and an important prerequisite for success in various areas of life [1]. March 19, 2015 adherence to PLOS ONE Editorial policies and criteria. When Problem Size Matters: A tDCS-EEG Study development lies in the acquisition of arithmetic skills which has been in the focus of cognitive and educational research for several decades The presumably most robust and well-established finding in this domain is the problem size effect (PSE) [3,4]. It is reflected in longer response latencies and lower accuracies when solving arithmetic problems with larger operands (i.e. sums > 10; large problems) compared to problems with smaller operands (i.e. sums 10; small problems).
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