Abstract
Functional connectivity (FC) is a potential candidate that can increase the performance of brain-computer interfaces (BCIs) in the elderly because of its compensatory role in neural circuits. However, it is difficult to decode FC by the current machine learning techniques because of a lack of physiological understanding. To investigate the suitability of FC in BCIs for the elderly, we propose the decoding of lower- and higher-order FC using a convolutional neural network (CNN) in six cognitive-motor tasks. The layer-wise relevance propagation (LRP) method describes how age-related changes in FCs impact BCI applications for the elderly compared to younger adults. A total of 17 young adults 24.5±2.7 years and 12 older 72.5±3.2 years adults were recruited to perform tasks related to hand-force control with or without mental calculation. The CNN yielded a six-class classification accuracy of 75.3% in the elderly, exceeding the 70.7% accuracy for the younger adults. In the elderly, the proposed method increased the classification accuracy by 88.3% compared to the filter-bank common spatial pattern. The LRP results revealed that both lower- and higher-order FCs were dominantly overactivated in the prefrontal lobe, depending on the task type. These findings suggest a promising application of multi-order FC with deep learning on BCI systems for the elderly.
Highlights
We found that the difference in LoFC and HiFC between young adults and elderly group within and across brain regions was depended on the task and frequency bands
We found that the layer-wise relevance propagation (LRP)-derived relevance values were higher in the elderly group than in the young adult group, which reflects the age-related Functional connectivity (FC) overactivation
The primary finding of this study is that age-related compensatory overactivation in multi-order FC results in higher accuracy in multi-class brain-computer interfaces (BCIs) for the elderly than for the young adult population
Summary
With advancements in science and medical technologies, the average life span of humans has gradually increased [1]. There is a growing need for brain-computer interface (BCI) systems for healthy elderly people going through nonpathological physical and cognitive declines [2,3]. BCI systems connect the brain to a computer, allowing the user to enhance their life [4,5]. As machine learning and intelligent robotic technology advance, the range of BCI applications is growing. The development of a hybrid BCI, such as the simultaneous use of near-infrared spectroscopy [6] and an electroencephalogram (EEG) system, further increases the potential of BCI applications to real-life situations [7,8,9]
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