{"title":"使用具有现实头部传导模型的卷积神经网络对皮层下和皮层的 M/EEG 信号源进行定位。","authors":"Hikaru Yokoyama, Naotsugu Kaneko, Noboru Usuda, Tatsuya Kato, Hui Ming Khoo, Ryohei Fukuma, Satoru Oshino, Naoki Tani, Haruhiko Kishima, Takufumi Yanagisawa, Kimitaka Nakazawa","doi":"10.1063/5.0226457","DOIUrl":null,"url":null,"abstract":"<p><p>While electroencephalography (EEG) and magnetoencephalography (MEG) are well-established noninvasive methods in neuroscience and clinical medicine, they suffer from low spatial resolution. Electrophysiological source imaging (ESI) addresses this by noninvasively exploring the neuronal origins of M/EEG signals. Although subcortical structures are crucial to many brain functions and neuronal diseases, accurately localizing subcortical sources of M/EEG remains particularly challenging, and the feasibility is still a subject of debate. Traditional ESIs, which depend on explicitly defined regularization priors, have struggled to set optimal priors and accurately localize brain sources. To overcome this, we introduced a data-driven, deep learning-based ESI approach without the need for these priors. We proposed a four-layered convolutional neural network (4LCNN) designed to locate both subcortical and cortical sources underlying M/EEG signals. We also employed a sophisticated realistic head conductivity model using the state-of-the-art segmentation method of ten different head tissues from individual MRI data to generate realistic training data. This is the first attempt at deep learning-based ESI targeting subcortical regions. Our method showed excellent accuracy in source localization, particularly in subcortical areas compared to other methods. This was validated through M/EEG simulations, evoked responses, and invasive recordings. The potential for accurate source localization of the 4LCNNs demonstrated in this study suggests future contributions to various research endeavors such as the clinical diagnosis, understanding of the pathophysiology of various neuronal diseases, and basic brain functions.</p>","PeriodicalId":46288,"journal":{"name":"APL Bioengineering","volume":null,"pages":null},"PeriodicalIF":6.6000,"publicationDate":"2024-10-28","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11537707/pdf/","citationCount":"0","resultStr":"{\"title\":\"M/EEG source localization for both subcortical and cortical sources using a convolutional neural network with a realistic head conductivity model.\",\"authors\":\"Hikaru Yokoyama, Naotsugu Kaneko, Noboru Usuda, Tatsuya Kato, Hui Ming Khoo, Ryohei Fukuma, Satoru Oshino, Naoki Tani, Haruhiko Kishima, Takufumi Yanagisawa, Kimitaka Nakazawa\",\"doi\":\"10.1063/5.0226457\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>While electroencephalography (EEG) and magnetoencephalography (MEG) are well-established noninvasive methods in neuroscience and clinical medicine, they suffer from low spatial resolution. 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引用次数: 0
摘要
虽然脑电图(EEG)和脑磁图(MEG)是神经科学和临床医学中成熟的无创方法,但它们的空间分辨率较低。电生理源成像 (ESI) 通过无创探索 M/EEG 信号的神经元起源解决了这一问题。虽然皮层下结构对许多大脑功能和神经元疾病至关重要,但准确定位 M/EEG 的皮层下来源仍具有特别的挑战性,而且其可行性仍是一个争论的话题。传统的 ESI 依赖于明确定义的正则化先验,在设置最佳先验和准确定位脑源方面一直举步维艰。为了克服这一问题,我们引入了一种数据驱动、基于深度学习的 ESI 方法,无需这些先验条件。我们提出了一种四层卷积神经网络(4LCNN),旨在定位 M/EEG 信号底层的皮层下和皮层源。我们还采用了一个复杂的现实头部传导性模型,使用最先进的分割方法从单个核磁共振成像数据中分割出十种不同的头部组织,以生成现实的训练数据。这是基于深度学习的针对皮层下区域的 ESI 的首次尝试。与其他方法相比,我们的方法在信号源定位,尤其是皮层下区域的信号源定位方面表现出了极高的准确性。这一点通过 M/EEG 模拟、诱发反应和有创记录得到了验证。本研究中展示的 4LCNNs 精确信号源定位的潜力表明,它未来将为临床诊断、了解各种神经元疾病的病理生理学和大脑基本功能等各种研究工作做出贡献。
M/EEG source localization for both subcortical and cortical sources using a convolutional neural network with a realistic head conductivity model.
While electroencephalography (EEG) and magnetoencephalography (MEG) are well-established noninvasive methods in neuroscience and clinical medicine, they suffer from low spatial resolution. Electrophysiological source imaging (ESI) addresses this by noninvasively exploring the neuronal origins of M/EEG signals. Although subcortical structures are crucial to many brain functions and neuronal diseases, accurately localizing subcortical sources of M/EEG remains particularly challenging, and the feasibility is still a subject of debate. Traditional ESIs, which depend on explicitly defined regularization priors, have struggled to set optimal priors and accurately localize brain sources. To overcome this, we introduced a data-driven, deep learning-based ESI approach without the need for these priors. We proposed a four-layered convolutional neural network (4LCNN) designed to locate both subcortical and cortical sources underlying M/EEG signals. We also employed a sophisticated realistic head conductivity model using the state-of-the-art segmentation method of ten different head tissues from individual MRI data to generate realistic training data. This is the first attempt at deep learning-based ESI targeting subcortical regions. Our method showed excellent accuracy in source localization, particularly in subcortical areas compared to other methods. This was validated through M/EEG simulations, evoked responses, and invasive recordings. The potential for accurate source localization of the 4LCNNs demonstrated in this study suggests future contributions to various research endeavors such as the clinical diagnosis, understanding of the pathophysiology of various neuronal diseases, and basic brain functions.
期刊介绍:
APL Bioengineering is devoted to research at the intersection of biology, physics, and engineering. The journal publishes high-impact manuscripts specific to the understanding and advancement of physics and engineering of biological systems. APL Bioengineering is the new home for the bioengineering and biomedical research communities.
APL Bioengineering publishes original research articles, reviews, and perspectives. Topical coverage includes:
-Biofabrication and Bioprinting
-Biomedical Materials, Sensors, and Imaging
-Engineered Living Systems
-Cell and Tissue Engineering
-Regenerative Medicine
-Molecular, Cell, and Tissue Biomechanics
-Systems Biology and Computational Biology