基于被动听觉ERP范式的慢性意识障碍患者个体评估研究

doi:10.3969/j.issn.0258-8021.2022.02.001

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摘要近年来,大脑功能检测技术逐渐应用于意识障碍(DoC)患者的意识水平评估,以期降低仅依靠临床主观行为量表评估的误诊率。其中,被动听觉事件相关电位(ERPs)范式下诱发的N1和失匹配负波(MMN)成分被认为是反应DoC患者意识水平的关键脑功能指标,但目前仍局限于组别层面的统计分析结果,其在DoC患者个体水平的评估效能尚待挖掘。根据N1和MMN成分的特性,提出了一种适用于被动听觉ERPs范式下DoC患者个体评估的深度学习算法。该方法引入了特征融合的数据扩增策略,即在单被试数据中随机抽取不同类型的试次进行空间级联形成新的融合样本,并结合EEGNET深度学习算法实现自动化特征提取和分类识别。在包含132名被试的单试次数据集上进行测试。对健康被试(38名),微意识状态(40名)和植物状态(54名)患者进行三分类评估。统计分析结果表明,该样本融合策略可显著提升模型分类表现,并在单被试融合样本数量扩增至1 000时模型取得样本水平75.14%的平均分类准确率,以及被试水平83.00%的平均分类准确率,83.79%的精确率和84.02%的召回率。所提出的深度学习框架可有效克服传统方法中存在的个体评估能力不强的问题,为DoC患者个体评估提供新的研究思路。

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	王小宇
	杨艺
	李凡
	陈雪玲
	高寒冰
	马兆楠
	何江弘
	丛丰裕

关键词 ：意识障碍, 事件相关电位, 失匹配负波, 深度学习, 数据扩增

Abstract：In recent years, there have been increased efforts to assess the levels of consciousness in patients with disorders of consciousness (DoC) using neuroimaging techniques, aiming to improve diagnosis and identification beyond current subjective behavioral assessments that suffer from high misdiagnosis rates. Previous evidence suggests that N1 and mismatch negativity (MMN) components elicited by passive auditory event-related potentials (ERPs) paradigms are critical neurophysiological markers of DoC. However, as such evidence is limited to group-level analysis, the extent to which they enable residual consciousness detection at the individual-level is unclear. Considering the characteristics of N1 and MMN components, we proposed a deep learning algorithm for the individual assessment of patients with DoC under a passive auditory ERPs paradigm. The algorithm proposed a data augmentation strategy, which randomly fused single-trials elicited by different types of stimuli in the spatial domain to form fusion samples, and a deep learning classifier, known as EEGNET, to achieve automatic feature extraction and classification. The proposed method was evaluated in a three-class classification task (38 healthy controls, 40 minimally conscious state, and 54 vegetative state patients) using a single-trial dataset including 132 subjects. Statistical results showed that the proposed data augmentation method significantly improved the classification performance in the current task, and it achieved the highest 75.14% mean classification accuracies in sample level as well as 83.00% mean classification accuracies, 83.79% precision rate, and 84.02% recall rate in subject level when the number of single-subject samples was augmented to 1000. In conclusion, the proposed method could overcome the drawbacks of poor assessment performance in the conventional individual-level assessment methods, providing a new strategy for individual-level assessment in patients with DoC.

Key words： disorders of consciousness (DoC) event-related potentials (ERP) mismatch negativity deep learning data augmentation

收稿日期: 2021-05-18

PACS:

R318

基金资助:国家自然科学基金(91748105);国家自然科学基金青年科学基金项目(81600919);北京市科技新星计划(Z181100006218050)

通讯作者: ^*E-mail: he_jianghong@sina.cn; cong@dlut.edu.cn

作者简介: ^&共同第一作者

引用本文:

王小宇, 杨艺, 李凡, 陈雪玲, 高寒冰, 马兆楠, 何江弘, 丛丰裕. 基于被动听觉ERP范式的慢性意识障碍患者个体评估研究[J]. 中国生物医学工程学报, 2022, 41(2): 129-139.
Wang Xiaoyu, Yang Yi, Li Fan, Chen Xueling, Gao Hanbing, Ma Zhaonan, He Jianghong, Cong Fengyu. Individual-Level Assessment in Patients with Disorders of Consciousness under Passive Auditory ERP Paradigm. Chinese Journal of Biomedical Engineering, 2022, 41(2): 129-139.

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2022.02.001 或 http://cjbme.csbme.org/CN/Y2022/V41/I2/129

[1] Giacino JT, Katz DI, Schiff ND, et al. Practice guideline update recommendations summary: Disorders of consciousness [J]. Neurology, 2018, 91(10): 450-460.
[2] Kondziella D, Bender A, Diserens K, et al. European Academy of Neurology guideline on the diagnosis of coma and other disorders of consciousness [J]. European Journal of Neurology, 2020, 27(5): 741-756.
[3] 中国医师协会神经修复专业委员会意识障碍与促醒学组. 慢性意识障碍诊断与治疗中国专家共识 [J]. 中华神经医学杂志, 2020, 19(10): 977-982.
[4] Giacino JT, Kalmar K, Whyte J. The JFK Coma Recovery Scale-Revised: Measurement characteristics and diagnostic utility [J]. Archives of Physical Medicine and Rehabilitation, 2004, 85(12): 2020-2029.
[5] Owen AM. Improving diagnosis and prognosis in disorders of consciousness [J]. Brain, 2020, 143(4): 1050-1053.
[6] Comanducci A, Boly M, Claassen J, et al. Clinical and advanced neurophysiology in the prognostic and diagnostic evaluation of disorders of consciousness: review of an IFCN-endorsed expert group [J]. Clinical Neurophysiology, 2020, 131(11): 2736-2765.
[7] Owen AM, Coleman MR, Boly M, et al. Detecting awareness in the vegetative state [J]. Science, 2006, 313(5792): 1402-1402.
[8] Rupawala M, Dehghani H, Lucas SJE, et al. Shining a light on awareness: A Review of functional near-infrared spectroscopy for prolonged disorders of consciousness [J]. Frontiers in Neurology, 2018, 9: 350-350.
[9] Comanducci A, Boly M, Claassen J, et al. Clinical and advanced neurophysiology in the prognostic and diagnostic evaluation of disorders of consciousness: review of an IFCN-endorsed expert group [J]. Clinical Neurophysiology, 2020, 131(11): 2736-2765.
[10] Luck SJ. An introduction to the event-related potential technique [M]. 2nd ed. Cambridge: The MIT Press, 2014.
[11] Fischer C, Morlet D, Bouchet P, et al. Mismatch negativity and late auditory evoked potentials in comatose patients [J]. Clinical Neurophysiology, 1999, 110(9): 1601-1610.
[12] Squires NK, Squires KC, Hillyard SA. Two varieties of long-latency positive waves evoked by unpredictable auditory stimuli in man [J]. Electroencephalography and Clinical Neurophysiology, 1975, 38(4): 387-401.
[13] Morlet D, Fischer C. MMN and Novelty P3 in coma and other altered states of consciousness: A review [J]. Brain Topography, 2014, 27(4): 467-479.
[14] Kotchoubey B, Lang S, Mezger G, et al. Information processing in severe disorders of consciousness: vegetative state and minimally conscious state [J]. Clinical Neurophysiology, 2005, 116(10): 2441-2453.
[15] Wijnen VJM, van Boxtel GJM, Eilander HJ, et al. Mismatch negativity predicts recovery from the vegetative state [J]. Clinical Neurophysiology, 2007, 118(3): 597-605.
[16] Wang Xiaoyu, Fu Rao, Xia Xiaoyu, et al. Spatial properties of mismatch negativity in patients with disorders of consciousness [J]. Neuroscience Bulletin, 2018, 34(4): 700-708.
[17] Wang Xiaoyu, Guo Yongkun, Zhang Yunge, et al. Combined behavioral and mismatch negativity evidence for the effects of long-lasting high-definition tDCS in disorders of consciousness: a pilot study [J]. Frontiers in Neuroscience, 2020, 14: 381.
[18] Fischer C, Dailler F, Morlet D. Novelty P3 elicited by the subject's own name in comatose patients [J]. Clinical Neurophysiology, 2008, 119(10): 2224-2230.
[19] Tzovara A, Rossetti AO, Spierer L, et al. Progression of auditory discrimination based on neural decoding predicts awakening from coma [J]. Brain, 2013, 136(1): 81-89.
[20] Armanfard N, Komeili M, Reilly JP, et al. A machine learning framework for automatic and continuous MMN detection with preliminary results for coma outcome prediction [J]. IEEE Journal of Biomedical and Health Informatics, 2019, 23(4): 1794-1804.
[21] Parvar H, Sculthorpe-Petley L, Satel J, et al. Detection of event-related potentials in individual subjects using support vector machines [J]. Brain Informatics, 2015, 2(1): 1-12.
[22] Delorme A, Makeig S. EEGLAB: An open source toolbox for analysis of single-trial EEG dynamics including independent component analysis [J]. Journal of Neuroscience Methods, 2004, 134(1): 9-21.
[23] Perrin F, Pernier J, Bertrand O, et al. Spherical splines for scalp potential and current density mapping [J]. Electroencephalography and Clinical Neurophysiology, 1989, 72(2): 184-187.
[24] Lee T, Girolami M, Sejnowski T. Independent component analysis using an extended infomax algorithm for mixed subgaussian and supergaussian sources [J]. Neural Computation, 1999, 11(2): 417-441.
[25] Pion-Tonachini L, Kreutz-Delgado K, Makeig S. ICLabel: an automated electroencephalographic independent component classifier, dataset, and website [J]. NeuroImage, 2019, 198: 181-197.
[26] Lawhern VJ, Solon AJ, Waytowich NR, et al. EEGNet: a compact convolutional neural network for EEG-based brain-computer interfaces [J]. Journal of Neural Engineering, 2018, 15(5): 056013-056013.
[27] Simonyan K, Vedaldi A, Zisserman A. Deep inside convolutional networks: Visualising image classification models and saliency maps [DB/OL]. https://arxiv.org/abs/1312.6034arXiv, 2013/2021-05-18.
[28] Pan Jiahui, Xie Qiuyou, Qin Pengmin, et al. Prognosis for patients with cognitive motor dissociation identified by brain-computer interface [J]. Brain, 2020, 143(4): 1177-1189.
[29] Xiao Xiaolin, Xu Minpeng, Jin Jing, et al. Discriminative Canonical Pattern Matching for Single-Trial Classification of ERP Components [J]. IEEE Transactions on Biomedical Engineering, 2020, 67(8): 2266-2275.
[30] Shorten C, Khoshgoftaar TM. A survey on image data augmentation for deep learning [J]. Journal of Big Data, Springer, 2019, 6(1): 1-48.
[31] Lee M, Sehatpour P, Hoptman MJ, et al. Neural mechanisms of mismatch negativity dysfunction in schizophrenia [J]. Molecular Psychiatry, 2017, 22(11): 1585-1593.
[32] Volkmer S, Schulte-Koerne G. Cortical responses to tone and phoneme mismatch as a predictor of dyslexia? A systematic review [J]. Schizophrenia research, Elsevier, 2018, 191: 148-160.
[33] Gui Peng, Jiang Yuwei, Zang Di, et al. Assessing the depth of language processing in patients with disorders of consciousness [J]. Nature Neuroscience, 2020, 23(6): 761-770.
[34] Engemann DA, Raimondo F, King JR, et al. Robust EEG-based cross-site and cross-protocol classification of states of consciousness [J]. Brain, 2018, 141(11): 3179-3192.
[35] Cheng CH, Hsu WY, Lin YY. Effects of physiological aging on mismatch negativity: a meta-analysis [J]. International Journal of Psychophysiology, 2013, 90(2): 165-171.