Abstract
Visual working memory (WM) training and practice can result in improved task performance and increased P300 amplitude; however, only training can yield N160 enhancements. N160 amplitudes are related to the spatial attention, the detection of novelty and the inhibitory control, while P300 amplitudes are related to the selective attention. Therefore, it could be speculated that the mechanisms underlying N160 and P300 production may differ to accommodate to their functions. Based on the different N160 engagements and different functional roles of N160 and P300, we hypothesized that the effects of visual WM training and practice can be dissociated by their brain effective connectivity patterns. We compared different neural connectivity configurations for the main task-related brain activities including N160 and P300 during the visual three-back task in subjects after visual WM training (the WM group) and after repetitive task practice (the control group). The behavioral result shows significantly greater improvement in accuracy after training and suggests that visual WM training can boost the learning process of this simple task. The N160 peak amplitude increased significantly after training over the anterior and posterior brain areas but decreased after practice over the posterior areas, indicating different mechanisms for mediating the training and practice effects. In support of our hypothesis, we observed that visual WM training alters the frontal-parietal connections, which comprise the executive control network (ECN) and the dorsal attention network (DAN), whereas practice modulates the parietal-frontal connections underpinning P300 production for selective attention. It should be noted that the analytic results in this study are conditional on the plausible models being tested and the experimental settings. Studies that employ different tasks, devices and plausible models may lead to different results. Nevertheless, our findings provide a reference for distinguishing the visual WM training and practice effects by the underlying neuroplasticity.
Highlights
Working memory (WM) is a system that is required to maintain and manipulate information to perform complex reasoning or learning tasks (Baddeley, 2003)
Regarding the impact of session on accuracy, the WM group shows a significant improvement in accuracy between W0–W2 (p < 0.01), W1–W3(p = 0.04) and W0–W3 (p < 0.01) whereas the control group exhibits a significant improvement in accuracy between W0–W2 (p < 0.01), W1–W2 (p = 0.01) and W0–W3 (p < 0.01)
We examined the differences in the behavioral data and the neuronal signals during visual three-back task after visual WM training and repetitive task practice
Summary
Working memory (WM) is a system that is required to maintain and manipulate information to perform complex reasoning or learning tasks (Baddeley, 2003). Thompson et al (2016) further tested the functional anatomy after intensive WM training using fMRI They reported that WM training enhanced the functional connectivity within both the executive control network (ECN)—which comprises the dorsolateral frontal gyrus, dorsomedial frontal gyrus, and IPS—and the dorsal attention network (DAN)—which comprises the human frontal eye fields, SFG, and superior parietal lobe. Previous studies tested only the oscillatory activities measured with EEG and their coupling in the frontalparietal network during WM tasks (Sauseng et al, 2005; Astle et al, 2015; Ewerdwalbesloh et al, 2016) It remains unclear whether N160 and P300 changes after WM training are associated with the frontal-parietal network alternations
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