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Exploring fNIRS-Based Brain State Recognition and Visualization through the use of Explainable Convolutional Neural Networks

Functional near infrared spectroscopy (fNIRS) is a neuroimaging technique that has grown vigorously in recent years. With noticeable attention, machine learning methods have also been applied to fNIRS. However, the current approach lacks interpretability of the results. In recent years, the utilizat...

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Main Authors:	Chen, Pin-Hua, Wei, Chun-Shu, Lan, Chen-Chia, Chen, Nai-Feng, Wang, Li-Chun
Format:	Conference Proceeding
Language:	English
Subjects:	Biological system modeling Brain - diagnostic imaging Brain modeling Cerebral Cortex Data visualization Feature extraction Hand Humans Neural Networks, Computer Physiology Predictive models Spectroscopy, Near-Infrared - methods Support vector machines
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creator	Chen, Pin-Hua Wei, Chun-Shu Lan, Chen-Chia Chen, Nai-Feng Wang, Li-Chun
description	Functional near infrared spectroscopy (fNIRS) is a neuroimaging technique that has grown vigorously in recent years. With noticeable attention, machine learning methods have also been applied to fNIRS. However, the current approach lacks interpretability of the results. In recent years, the utilization and investigation of fNIRS have experienced significant growth and are now being utilized in clinical research. However, the collection of clinical fNIRS data is limited in sample size. Therefore, our aim is to utilize the collected fNIRS data from all channels and achieve interpretable analysis results with minimal human manipulation, channel selection or feature extraction. We developed an fNIRS-based interpretable model and used class-specific gradient information to visualize the biomarkers captured by the model via locating the important region. The accuracy of our model's classification was 6% higher than that of the conventional SVM method under within-subject classification. The model focuses on signals from the left brain in the classification of right-hand finger tapping task, while in the task of classifying left-handed movements, the model relies on signals from the right brain. These results were consistent with current understanding of physiology.Clinical Relevance- The machine learning-based fNIRS model has the potential to be used for the diagnosis and prediction of therapeutic efficacy in clinical settings.
doi_str_mv	10.1109/EMBC40787.2023.10341196
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subjects	Biological system modeling Brain - diagnostic imaging Brain modeling Cerebral Cortex Data visualization Feature extraction Hand Humans Neural Networks, Computer Physiology Predictive models Spectroscopy, Near-Infrared - methods Support vector machines
title	Exploring fNIRS-Based Brain State Recognition and Visualization through the use of Explainable Convolutional Neural Networks
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