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425 results on '"Yanagisawa, Takufumi"'

1. SplitSEE: A Splittable Self-supervised Framework for Single-Channel EEG Representation Learning

Author

Kotoge, Rikuto, Chen, Zheng, Kimura, Tasuku, Matsubara, Yasuko, Yanagisawa, Takufumi, Kishima, Haruhiko, and Sakurai, Yasushi

Subjects
Computer Science - Machine Learning, Computer Science - Artificial Intelligence
Abstract

While end-to-end multi-channel electroencephalography (EEG) learning approaches have shown significant promise, their applicability is often constrained in neurological diagnostics, such as intracranial EEG resources. When provided with a single-channel EEG, how can we learn representations that are robust to multi-channels and scalable across varied tasks, such as seizure prediction? In this paper, we present SplitSEE, a structurally splittable framework designed for effective temporal-frequency representation learning in single-channel EEG. The key concept of SplitSEE is a self-supervised framework incorporating a deep clustering task. Given an EEG, we argue that the time and frequency domains are two distinct perspectives, and hence, learned representations should share the same cluster assignment. To this end, we first propose two domain-specific modules that independently learn domain-specific representation and address the temporal-frequency tradeoff issue in conventional spectrogram-based methods. Then, we introduce a novel clustering loss to measure the information similarity. This encourages representations from both domains to coherently describe the same input by assigning them a consistent cluster. SplitSEE leverages a pre-training-to-fine-tuning framework within a splittable architecture and has following properties: (a) Effectiveness: it learns representations solely from single-channel EEG but has even outperformed multi-channel baselines. (b) Robustness: it shows the capacity to adapt across different channels with low performance variance. Superior performance is also achieved with our collected clinical dataset. (c) Scalability: With just one fine-tuning epoch, SplitSEE achieves high and stable performance using partial model layers., Comment: This paper has been accepted by ICDM2024

Published
2024

2. Brain-aligning of semantic vectors improves neural decoding of visual stimuli

Author

Vafaei, Shirin, Fukuma, Ryohei, Yanagisawa, Takufumi, Yang, Huixiang, Oshino, Satoru, Tani, Naoki, Khoo, Hui Ming, Sugano, Hidenori, Iimura, Yasushi, Suzuki, Hiroharu, Nakajima, Madoka, Tamura, Kentaro, and Kishima, Haruhiko

Subjects
Quantitative Biology - Neurons and Cognition, Computer Science - Artificial Intelligence
Abstract

The development of algorithms to accurately decode of neural information is a long-standing effort in the field of neuroscience. Brain decoding is typically employed by training machine learning models to map neural data onto a preestablished vector representation of stimulus features. These vectors are usually derived from image- and/or text-based feature spaces. Nonetheless, the intrinsic characteristics of these vectors might be fundamentally different than those encoded by the brain, limiting the ability of algorithms to accurately learn this mapping. To address this issue, here, we propose a representation learning framework, called brain-aligning of semantic vectors, that fine-tunes pretrained feature vectors to better align with the structure of neural representations of visual stimuli in the human brain. We trained this model with functional magnetic resonance imaging (fMRI) data representing 150 visual stimulus categories; then, we performed zero-shot brain decoding on 1) fMRI, 2) magnetoencephalography (MEG), and 3) electrocorticography (ECoG) data reflecting neural representations of visual stimuli. By using fMRI-based brain-aligned vectors, the zero-shot decoding accuracy all three neuroimaging datasets increased. This finding underscores the potential of leveraging a richer array of brainderived features to increase the performance of brain decoding algorithms., Comment: 40 pages, 5 figures

Published
2024

3. Fast, accurate, and interpretable decoding of electrocorticographic signals using dynamic mode decomposition

Author

Fukuma, Ryohei, Majima, Kei, Kawahara, Yoshinobu, Yamashita, Okito, Shiraishi, Yoshiyuki, Kishima, Haruhiko, and Yanagisawa, Takufumi

Subjects
Electrical Engineering and Systems Science - Signal Processing, Computer Science - Machine Learning
Abstract

Dynamic mode (DM) decomposition decomposes spatiotemporal signals into basic oscillatory components (DMs). DMs can improve the accuracy of neural decoding when used with the nonlinear Grassmann kernel, compared to conventional power features. However, such kernel-based machine learning algorithms have three limitations: large computational time preventing real-time application, incompatibility with non-kernel algorithms, and low interpretability. Here, we propose a mapping function corresponding to the Grassmann kernel that explicitly transforms DMs into spatial DM (sDM) features, which can be used in any machine learning algorithm. Using electrocorticographic signals recorded during various movement and visual perception tasks, the sDM features were shown to improve the decoding accuracy and computational time compared to conventional methods. Furthermore, the components of the sDM features informative for decoding showed similar characteristics to the high-$\gamma$ power of the signals, but with higher trial-to-trial reproducibility. The proposed sDM features enable fast, accurate, and interpretable neural decoding.

Published
2023

6. Closed-Loop Control of Images Based on Electrocorticogram Decoding in Visual Semantic Space

Author

Fukuma, Ryohei, Yanagisawa, Takufumi, Nishimoto, Shinji, Sugano, Hidenori, Tamura, Kentaro, Yamamoto, Shota, Iimura, Yasushi, Fujita, Yuya, Oshino, Satoru, Tani, Naoki, Koide-Majima, Naoko, Kamitani, Yukiyasu, Kishima, Haruhiko, Gan, Woon-Seng, Series Editor, Kuo, C.-C. Jay, Series Editor, Zheng, Thomas Fang, Series Editor, Barni, Mauro, Series Editor, Guger, Christoph, editor, Allison, Brendan, editor, Rutkowski, Tomasz M., editor, and Korostenskaja, Milena, editor

Published
2024
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7. Voluntary control of semantic neural representations by imagery with conflicting visual stimulation

Author

Fukuma, Ryohei, Yanagisawa, Takufumi, Nishimoto, Shinji, Sugano, Hidenori, Tamura, Kentaro, Yamamoto, Shota, Iimura, Yasushi, Fujita, Yuya, Oshino, Satoru, Tani, Naoki, Koide-Majima, Naoko, Kamitani, Yukiyasu, and Kishima, Haruhiko

Subjects
Quantitative Biology - Neurons and Cognition
Abstract

Neural representations of visual perception are affected by mental imagery and attention. Although attention is known to modulate neural representations, it is unknown how imagery changes neural representations when imagined and perceived images semantically conflict. We hypothesized that imagining an image would activate a neural representation during its perception even while watching a conflicting image. To test this hypothesis, we developed a closed-loop system to show images inferred from electrocorticograms using a visual semantic space. The successful control of the feedback images demonstrated that the semantic vector inferred from electrocorticograms became closer to the vector of the imagined category, even while watching images from different categories. Moreover, modulation of the inferred vectors by mental imagery depended on both the image category and time from the initiation of imagery. The closed-loop control of the semantic vectors revealed an asymmetrical interaction between visual perception and imagery.

Published
2021

8. A deep learning model for the detection of various dementia and MCI pathologies based on resting-state electroencephalography data: A retrospective multicentre study

Author

Watanabe, Yusuke, Miyazaki, Yuki, Hata, Masahiro, Fukuma, Ryohei, Aoki, Yasunori, Kazui, Hiroaki, Araki, Toshihiko, Taomoto, Daiki, Satake, Yuto, Suehiro, Takashi, Sato, Shunsuke, Kanemoto, Hideki, Yoshiyama, Kenji, Ishii, Ryouhei, Harada, Tatsuya, Kishima, Haruhiko, Ikeda, Manabu, and Yanagisawa, Takufumi

Published
2024
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13. Beta-gamma phase-amplitude coupling of scalp electroencephalography during walking preparation in Parkinson's disease differs depending on the freezing of gait.

Author

Kimoto, Yuki, Tani, Naoki, Emura, Takuto, Matsuhashi, Takahiro, Yamamoto, Takuto, Fujita, Yuya, Oshino, Satoru, Hosomi, Koichi, Khoo, Hui Ming, Miura, Shimpei, Fujinaga, Takahiro, Yanagisawa, Takufumi, and Kishima, Haruhiko

Subjects
PEARSON correlation (Statistics), PARKINSON'S disease, GAIT disorders, SUPPORT vector machines, MOVEMENT disorders, SUBTHALAMIC nucleus
Abstract

Introduction: Despite using beta oscillations within the subthalamic nucleus as a biomarker of akinesia or rigidity in Parkinson's disease, a specific biomarker for freezing of gait (FOG) remains unclear. Recently, scalp phase-amplitude coupling (PAC) measured through scalp electroencephalography (EEG) has emerged as a promising tool for analyzing brain function. In this study, we examined whether PAC could be a biomarker for FOG. Methods: We enrolled 11 patients with Parkinson's disease and recorded scalp EEG in preparation for and during gait while simultaneously assessing motor function, including FOG. We investigated changes in cortical PAC during walking with and without FOG and examined its correlation with the postural instability and gait difficulty (PIGD) score. Results: Patient characteristics were as follows: mean age 59.1 ± 6.9 years, disease duration 13.9 ± 4.1 years, and seven men. Four trials were excluded from the analysis owing to artifacts. In the trials without FOG (n = 18), beta-gamma PAC in the sensorimotor area decreased during gait preparation (p = 0.011; linear mixed-effects model), which was not the case in trials with FOG (n = 6) (p = 0.64; linear mixed-effects model). Using a support vector machine, machine learning of PAC during preparation for walking predicted the presence of FOG with an accuracy of 71.2%. Conversely, PAC increased during walking in trials with FOG (p = 0.0042; linear mixed-effects model), and PAC 20 s after the start of walking was positively correlated with the PIGD score (correlation coefficient = 0.406, p = 0.032; Pearson's rank correlation). Conclusion: Beta-gamma PAC in the sensorimotor area during preparation for walking differs depending on the emergence of FOG. As gait symptoms worsened, beta-gamma PAC in the sensorimotor area during walking gradually increased. Cortical PAC may be a biomarker for FOG in Parkinson's disease and may lead to the development of strategies to prevent falls in the future. [ABSTRACT FROM AUTHOR]

Published
2024
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20. Brain-grounding of semantic vectors improves neural decoding of visual stimuli

Author

Vafaei, Shirin, Fukuma, Ryohei, Yang, Huixiang, Kishima, Haruhiko, Yanagisawa, Takufumi, Vafaei, Shirin, Fukuma, Ryohei, Yang, Huixiang, Kishima, Haruhiko, and Yanagisawa, Takufumi

Abstract

Developing algorithms for accurate and comprehensive neural decoding of mental contents is one of the long-cherished goals in the field of neuroscience and brain-machine interfaces. Previous studies have demonstrated the feasibility of neural decoding by training machine learning models to map brain activity patterns into a semantic vector representation of stimuli. These vectors, hereafter referred as pretrained feature vectors, are usually derived from semantic spaces based solely on image and/or text features and therefore they might have a totally different characteristics than how visual stimuli is represented in the human brain, resulting in limiting the capability of brain decoders to learn this mapping. To address this issue, we propose a representation learning framework, termed brain-grounding of semantic vectors, which fine-tunes pretrained feature vectors to better align with the neural representation of visual stimuli in the human brain. We trained this model this model with functional magnetic resonance imaging (fMRI) of 150 different visual stimuli categories, and then performed zero-shot brain decoding and identification analyses on 1) fMRI and 2) magnetoencephalography (MEG). Interestingly, we observed that by using the brain-grounded vectors, the brain decoding and identification accuracy on brain data from different neuroimaging modalities increases. These findings underscore the potential of incorporating a richer array of brain-derived features to enhance performance of brain decoding algorithms., Comment: 16 pages, 4 figures

Published
2024

21. Using a BCI Prosthetic Hand to Control Phantom Limb Pain

Author

Yanagisawa, Takufumi, Fukuma, Ryohei, Seymour, Ben, Hosomi, Koichi, Kishima, Haruhiko, Shimizu, Takeshi, Yokoi, Hiroshi, Hirata, Masayuki, Yoshimine, Toshiki, Kamitani, Yukiyasu, Saitoh, Youichi, Gan, Woon-Seng, Series Editor, Kuo, C.-C. Jay, Series Editor, Zheng, Thomas Fang, Series Editor, Barni, Mauro, Series Editor, Guger, Christoph, editor, Mrachacz-Kersting, Natalie, editor, and Allison, Brendan Z., editor

Published
2019
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30. Language-related cerebral oscillatory changes are influenced equally by genetic and environmental factors

Author

Iwatani, Yoshinori, Sakai, Norio, Kamide, Kei, Kihara, Shinji, Makimoto, Kiyoko, Watanabe, Hiroko, Hatazawa, Jun, Takahashi, Masanori, Watanabe, Mikio, Honda, Chika, Tomizawa, Rie, Araki, Toshihiko, Hirata, Masayuki, Yanagisawa, Takufumi, Sugata, Hisato, Onishi, Mai, Watanabe, Yoshiyuki, Ogata, Soshiro, Hayakawa, Kazuo, and Yorifuji, Shiro

Published
2016
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33. Prediction of IDH and TERT promoter mutations in low-grade glioma from magnetic resonance images using a convolutional neural network

Author

Fukuma, Ryohei, Yanagisawa, Takufumi, Kinoshita, Manabu, Shinozaki, Takashi, Arita, Hideyuki, Kawaguchi, Atsushi, Takahashi, Masamichi, Narita, Yoshitaka, Terakawa, Yuzo, Tsuyuguchi, Naohiro, Okita, Yoshiko, Nonaka, Masahiro, Moriuchi, Shusuke, Takagaki, Masatoshi, Fujimoto, Yasunori, Fukai, Junya, Izumoto, Shuichi, Ishibashi, Kenichi, Nakajima, Yoshikazu, Shofuda, Tomoko, Kanematsu, Daisuke, Yoshioka, Ema, Kodama, Yoshinori, Mano, Masayuki, Mori, Kanji, Ichimura, Koichi, Kanemura, Yonehiro, and Kishima, Haruhiko

Published
2019
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35. Precise Discrimination for Multiple Etiologies of Dementia Cases Based on Deep Learning with Electroencephalography

Author

Hata, Masahiro, primary, Watanabe, Yusuke, additional, Tanaka, Takumi, additional, Awata, Kimihisa, additional, Miyazaki, Yuki, additional, Fukuma, Ryohei, additional, Taomoto, Daiki, additional, Satake, Yuto, additional, Suehiro, Takashi, additional, Kanemoto, Hideki, additional, Yoshiyama, Kenji, additional, Iwase, Masao, additional, Ikeda, Shunichiro, additional, Nishida, Keiichiro, additional, Takekita, Yoshiteru, additional, Yoshimura, Masafumi, additional, Ishii, Ryouhei, additional, Kazui, Hiroaki, additional, Harada, Tatsuya, additional, Kishima, Haruhiko, additional, Ikeda, Manabu, additional, and Yanagisawa, Takufumi, additional

Published
2023
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37. Tight adhesions after spinal cord stimulation observed during dorsal root entry zone lesioning for pain after spinal root avulsion: illustrative cases

Author

Kimoto, Yuki, primary, Hosomi, Koichi, additional, Ohnishi, Yuichiro, additional, Emura, Takuto, additional, Mori, Nobuhiko, additional, Nishi, Asaya, additional, Yanagisawa, Takufumi, additional, Tani, Naoki, additional, Oshino, Satoru, additional, Saitoh, Youichi, additional, and Kishima, Haruhiko, additional

Published
2022
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40. Evaluating the Safety of Simultaneous Intracranial Electroencephalography and Functional Magnetic Resonance Imaging Acquisition Using a 3 Tesla Magnetic Resonance Imaging Scanner

Author

Fujita, Yuya, primary, Khoo, Hui Ming, additional, Hirayama, Miki, additional, Kawahara, Masaaki, additional, Koyama, Yoshihiro, additional, Tarewaki, Hiroyuki, additional, Arisawa, Atsuko, additional, Yanagisawa, Takufumi, additional, Tani, Naoki, additional, Oshino, Satoru, additional, Lemieux, Louis, additional, and Kishima, Haruhiko, additional

Published
2022
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46. A Deep Learning Model for Detection of Dementia Diseases and Identification of Underlying Pathologies of Mild Cognitive Impairment Based on Resting-State Electroencephalography: A Retrospective, Multicenter Study

Author

Watanabe, Yusuke, primary, Miyazaki, Yuki, additional, Hata, Masahiro, additional, Fukuma, Ryohei, additional, Aoki, Yasunori, additional, Kazui, Hiroaki, additional, Araki, Toshihiko, additional, Taomoto, Daiki, additional, Satake, Yuto, additional, Suehiro, Takashi, additional, Sato, Shunsuke, additional, Kanemoto, Hideki, additional, Yoshiyama, Kenji, additional, Ishii, Ryouhei, additional, Harada, Tatsuya, additional, Kishima, Haruhiko, additional, Ikeda, Manabu, additional, and Yanagisawa, Takufumi, additional

Published
2022
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48. A framework for leveraging multi-rater data in brain decoding analysis: Prediction of evaluation drawn from population data using sparse probit regression

Author

Vafaei, Shirin, Yamane, Hiroaki, Fukuma, Ryohei, Noriaki, Yahata, Yanagisawa, Takufumi, and Kei, Majima

Abstract

Introduction: Using stimuli (e.g., images, videos, products) labeled by a number of raters has recently become common in brain decoding analysis, where subjective emotion/impression for stimuli felt by the population is predicted from brain responses. However, there remains no established method for constructing a decoder using such multi-rater labels. In previous studies, the variability across multiple raters was assumed to reflect noise, and the answers for a binary judgment were averaged across raters. Then, the average scores (i.e., empirical probabilities) for individual stimuli were predicted using standard regression methods. While this procedure is a simple and popular approach, it is not appropriate because most of these regression methods ignore the fact that probability is the variable to be predicted. To address this in an appropriate manner, we present a new framework in this study. Methods: Here, we assume that individual answers for a binary judgment about a stimulus follow a Bernoulli distribution. We then predicted the probability of positive answers from the human functional magnetic resonance imaging (fMRI) response to the stimulus using probit regression. We also introduced sparse regularization into probit regression (sparse probit regression) to prevent overfitting. Results: In both simulation and real fMRI data analysis, sparse probit regression more accurately predicted the probabilities of positive answers for individual stimuli than probit regression without sparse regularization, indicating that sparseness results in better decoding performance. Sparse probit regression also outperformed linear regression using the same type of sparse regularization, reflecting the advantage of our appropriate treatment of probability. Discussion & Conclusion: Our results suggest that our framework using sparse probit regression provides an effective method for the population prediction of emotion/impression assessment based on brain activity., 第5回ヒト脳イメージング研究会

Published
2021

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