基于脑电的多模态神经功能成像新技术研究进展

doi:10.3969/j.issn.0258-8021.2020.05.010

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摘要神经功能成像能够实现活体脑结构与功能变化的无创(微创)检测。鉴于头皮脑电具有高时间分辨、便于操作、能直接反映大脑神经生理活动等优点,近年已逐步整合形成脑电-功能磁共振成像(EEG-fMRI)、脑电-近红外光谱(EEG-NIRS)、脑电-经颅聚焦超声(EEG-tFUS)等兼具高时空分辨优势的多模态神经功能成像新技术。从技术原理、技术特征及其在神经功能研究中的最新进展等方面,综述3种新模式的研究现状,论述存在问题与发展趋势,突出多模态神经功能成像新技术在促进脑科学发展中的意义。

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	周伊婕
	宋西姊
	何峰
	万柏坤
	明东

关键词 ：脑电, 神经功能成像, 功能磁共振成像, 功能近红外光谱, 经颅聚焦超声

Abstract：Functional neural imaging is able to non-invasively detect the changes in structure and function of living brain. The scalp electroencephalogram has the advantages of high time resolution,easy operation and direct reflection of the brain's neurophysiological activities. It has been integrated into the new multimodal functional neural imaging technology with both high temporal and spatial resolution. In this paper,electroencephalogram functional magnetic resonance imaging (EEG-fMRI),electroencephaloelectric near-infrared spectroscopy (EEG-NIRS) and brain electric transcranial focused ultrasound (EEG-tFUS) were taken as examples to reflect the current state of the development. The main contents included technical principles,technical characteristics and the latest progress in neural function research. In addition,the shortcomings and development trend of the three new models were discussed in detail to promote the research and application of multimodal functional neural imaging technology in brain science.

Key words： electroencephalogram functional neural imaging functional magnetic resonance imaging functional nearinfrared spectroscopy transcranial focused ultrasound

收稿日期: 2019-12-30

PACS:

R318

基金资助:国家重点研发计划(2017YFB1300302);国家自然科学基金重点项目(81630051);国家自然科学基金青年科学基金(81801787)

通讯作者: ^*E-mail:richardming@tju.edu.cn

引用本文:

周伊婕, 宋西姊, 何峰, 万柏坤, 明东. 基于脑电的多模态神经功能成像新技术研究进展[J]. 中国生物医学工程学报, 2020, 39(5): 595-602.
Zhou Yijie, Song Xizi, He Feng, Wan Baikun, Ming Dong. Research Progress of Multimodal Functional Neural ImagingTechnology Based on EEG. Chinese Journal of Biomedical Engineering, 2020, 39(5): 595-602.

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http://cjbme.csbme.org/CN/10.3969/j.issn.0258-8021.2020.05.010 或 http://cjbme.csbme.org/CN/Y2020/V39/I5/595

[1] 王亚,李永欣,黄文华.人类脑计划的研究进展[J].中国医学物理学杂志,2016,33(2):109-112.
[2] Ip IB,Berrington A,Hess AT,et al.Combined fMRI-MRS acquires simultaneous glutamate and BOLD-fMRI signals in the human brain[J].Neuroimage,2017,155(1):113-119.
[3] Soltanlou M,Sitnikova MA,Nuerk HC,et al.Applications of functional near-Infrared spectroscopy (fNIRS) in studying cognitive development:the case of mathematics and language[J].Frontiers in Psychology,2018,9(1):277.
[4] Movahedi F,Coyle JL,Sejdic E.Deep belief networks for electroencephalography:A review of recent contributions and future outlooks[J].IEEE Journal of Biomedical and Health Informatics,2018,22(3):642-652.
[5] Baillet S.Magnetoencephalography for brain electrophysiology and imaging[J].Nature Neuroscience,2017,20(3):327-339.
[6] 雷旭,尧德中.同步脑电-功能磁共振(EEG-fMRI)原理与技术[M].北京:科学出版社,2014.
[7] Hermes D,Nguyen M,Winawer J.Neuronal synchrony and the relation between the blood-oxygen-level dependent response and the local field potential[J].PLoS Biology,2017,15(7):e2001461.
[8] Mathias E,Kenny A,Plank MJ,et al.Integrated models of neurovascular coupling and BOLD signals:responses for varying neural activations[J].Neuroimage,2018:174(1):69-86.
[9] Pan PL,Zhu L,Yu TT,et al.Aberrant spontaneous low-frequency brain activity in amnestic mild cognitive impairment:a meta-analysis of resting-state fMRI studies[J].Ageing Research Reviews,2017,35(1):12-21.
[10] Hao Y,Khoo HM,Von NE,et al.DeepIED:An epileptic discharge detector for EEG-fMRI based on deep learning[J].Neuroimage Clinical,2018,17(1):962-975.
[11] Dong L,Luo C,Zhu Y,et al.Complex discharge-affecting networks in juvenile myoclonic epilepsy:A simultaneous EEG-fMRI study[J].Human Brain Mapping,2016,37(10):3515-3529.
[12] Bagarinao E,Maesawa S,Ito Y,et al.Detecting sub-second changes in brain activation patterns during interictal epileptic spike using simultaneous EEG-fMRI[J].Clinical Neurophysiology,2017,129(2):377-389.
[13] Abreu R,Leal A,Silva FLD,et al.EEG synchronization measures predict epilepsy-related BOLD-fMRI fluctuations better than commonly used univariate metrics[J].Clinical Neurophysiology,2018,129(3):618-635.
[14] Allen EA,Damaraju E,Eichele T,et al.EEG signatures of dynamic functional network connectivity states[J].Brain Topography,2018,31(3):1-16.
[15] Murta T,Chaudhary UJ,Tierney T,et al.Phase-amplitude coupling and the BOLD signal:A simultaneous intracranial EEG (icEEG)-fMRI study in humans performing a finger-tapping task[J].Neuroimage,2017,146(1):438-451.
[16] Xu J,Sheng J,Qian T,et al.EEG/MEG source imaging using fMRI informed time-variant constraints[J].Human Brain Mapping,2018,39(4):1700-1711.
[17] Marino M,Liu Q,Koudelka V,et al.Adaptive optimal basis set for BCG artifact removal in simultaneous EEG-fMRI[J].Scientific Reports,2018,8(1):8902.
[18] Steyrl D,Krausz G,Koschutnig K,et al.Reference layer adaptive filtering (RLAF) for EEG artifact reduction in simultaneous EEG-fMRI[J].Journal of Neural Engineering,2016,14(2):026003.
[19] Wang K,Li W,Dong L.Clustering-constrained ICA for ballistocardiogram artifacts removal in simultaneous EEG-fMRI[J].Frontiers in Neuroscience,2018,12(1):1-13.
[20] Sawan M,Salam MT,Le LJ,et al.Wireless recording systems:From noninvasive EEG-NIRS to invasive EEG devices[J].IEEE Transactions on Biomedical Circuits &Systems,2013,7(2):186-195.
[21] Alexander VL,Wabnitz H,Sander T,et al.M3BA:A mobile,modular,multimodal biosignal acquisition architecture for miniaturized EEG-NIRS based hybrid BCI and monitoring[J].IEEE Transactions on Biomedical Engineering,2016,64(6):1199-1210.
[22] Kassab A,Le JL,Tremblay J,et al.Multichannel wearable fNIRS-EEG system for long-term clinical monitoring[J].Human Brain Mapping,2017,39(1):7-23.
[23] Chiarelli AM,Zappasodi F,Di PF,et al.Simultaneous functional near-infrared spectroscopy and electroencephalography for monitoring of human brain activity and oxygenation:a review[J].Neurophotonics,2017,4(4):041411.
[24] Wang Zhongpeng,Zhou Yijie,Chen Long,et al.BCI monitor enhances electroencephalographic and cerebral hemodynamic activations during motor training[J].IEEE Transactions on Neural Systems and Rehabilitation Engineering,2019,27(4):780-787.
[25] Khan MJ,Hong MJ,Hong KS.Decoding of four movement directions using hybrid NIRS-EEG brain-computer interface[J].Frontiers in Human Neuroscience,2014,8(1):244.
[26] Koo B,Lee HG,Nam Y,et al.A hybrid NIRS-EEG system for self-paced brain computer interface with online motor imagery[J].Journal of Neuroscience Methods,2015,244(1):26-32.
[27] Grinband J,Steffener J,Razlighi QR,et al.BOLD neurovascular coupling does not change significantly with normal aging[J].Human Brain Mapping,2017,38(7):3538-3551.
[28] Leistritz L,Schiecke K,Astolfi L,et al.Time-variant modeling of brain processes[J].Proceedings of the IEEE,2016,104(2):262-281.
[29] Keles HO,Barbour RL,Omurtag A.Hemodynamic correlates of spontaneous neural activity measured by human whole-head resting state EEG+Fnirs[J].Neuroimage,2016,138(1):76-87.
[30] Nikulin VV,Fedele T,Mehnert J,et al.Monochromatic ultra-slow (～0.1 Hz) oscillations in the human electroencephalogram and their relation to hemodynamics[J].Neuroimage,2014,97(1):71-80.
[31] Martin V,Fiederer LDJ,Berberich S,et al.The dynamics of error processing in the human brain as reflected by high-gamma activity in noninvasive and intracranial EEG[J].Neuroimage,2018,173(1):564-579.
[32] Miocinovic S,Miller A,Swann NC,et al.Chronic deep brain stimulation normalizes scalp EEG activity in isolated dystonia[J].Clinical Neurophysiology,2017,129(2):368-376.
[33] He B.Focused ultrasound help realize high spatiotemporal brain imaging?——A concept on acousto-electrophysiological neuro-imaging[J].IEEE Transactions on Biomedical Engineering,2016,63(12):2654-2656.
[34] Witte R,Olafsson R,Huang SW,et al.Imaging current flow in lobster nerve cord using the acoustoelectric effect[J].Applied Physics Letters,2007,90(16):163902.
[35] Qin Y,Li Q,Ingram P,et al.Ultrasound current source density imaging of the cardiac activation wave using a clinical cardiac catheter[J].IEEE Transactions on Biomedical Engineering,2015,62(1):241-247.
[36] Qin Y,Ingram P,Xu Z,et al.Performance of a transcranial US array designed for 4D acoustoelectric brain imaging in humans[C]//IEEE International Ultrasonics Symposium.Washington D C:IEEE,2017:1-4.
[37] Darvas F,Mehic′ E,Caler CJ,et al.Toward deep brain monitoring with superficial EEG sensors plus neuromodulatory focused ultrasound[J].Ultrasound in Medicine &Biology,2016,42(8):1834-1847.
[38] Yu K,Sohrabpour A,He B.Electrophysiological source imaging of brain networks perturbed by low-intensity transcranial focused ultrasound[J].IEEE Transactions on Biomedical Engineering,2016,63(9):1787-1794.
[39] Zhou Yijie,Song Xizi,Chen Xinrui,et al.A source signal modulation mechanism with pulse focused ultrasound for acoustoelectric brain imaging[C]//International IEEE EMBS Conference on Neural Engineering.San Francisco:IEEE,2019:766-769.
[40] Zhou Yijie,Song Xizi,Wang Zhongpeng,et al.Coding biological current source with pulsed ultrasound for acoustoelectric brain imaging:application to vivo rat brain[J].Access,2020,8(1):29586-29694.