Isolated effective coherence analysis of epileptogenic networks in temporal lobe epilepsy using stereo-electroencephalography_Journal of Biomedical Engineering

Authors：

LI Zunyu ¹ , YUAN Guanqian ² , HUANG Ping ² , WANG Huijie ² , YAO Meiheng ¹ ,  LI Chunsheng ¹

1. Department of Biomedical Engineering, School of Electrical Engineering, Shenyang University of Technology, Shenyang 110870, P.R.China;
2. Department of Neurosurgery, Northern Theater General Hospital, Shenyang 110016, P.R.China;

Corresponding author：

LI Chunsheng, Email: lichunsheng@sut.edu.cn

Keywords：

stereo-electroencephalography; temporal lobe epilepsy; epileptic network; isolated effective coherence; out-degree

DOI：

10.7507/1001-5515.201806003

Video：

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Abstract Full text Figures/Tables Video References Cited by

Stereo-electroencephalography (SEEG) is widely used to record the electrical activity of patients' brain in clinical. The SEEG-based epileptogenic network can better describe the origin and the spreading of seizures, which makes it an important measure to localize epileptogenic zone (EZ). SEEG data from six patients with refractory epilepsy are used in this study. Five of them are with temporal lobe epilepsy, and the other is with extratemporal lobe epilepsy. The node outflow (out-degree) and inflow (in-degree) of information are calculated in each node of epileptic network, and the overlay between selected nodes and resected nodes is analyzed. In this study, SEEG data is transformed to bipolar montage, and then the epileptic network is established by using independent effective coherence (iCoh) method. The SEEG segments at onset, middle and termination of seizures in Delta, Theta, Alpha, Beta, and Gamma rhythms are used respectively. Finally, the K-means clustering algorithm is applied on the node values of out-degree and in-degree respectively. The nodes in the cluster with high value are compared with the resected regions. The final results show that the accuracy of selected nodes in resected region in the Delta, Alpha and Beta rhythm are 0.90, 0.88 and 0.89 based on out-degree values in temporal lobe epilepsy patients respectively, while the in-degree values cannot differentiate them. In contrast, the out-degree values are higher outside the temporal lobe in the patient with extratemporal lobe epilepsy. Based on the out-degree feature in low-frequency epileptic network, this study provides a potential quantitative measure for identifying patients with temporal lobe epilepsy in clinical.

Citation： LI Zunyu, YUAN Guanqian, HUANG Ping, WANG Huijie, YAO Meiheng, LI Chunsheng. Isolated effective coherence analysis of epileptogenic networks in temporal lobe epilepsy using stereo-electroencephalography. Journal of Biomedical Engineering, 2019, 36(4): 541-547. doi: 10.7507/1001-5515.201806003 Copy

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3.	Bartolomei F, Lagarde S, Wendling F, et al. Defining epileptogenic networks: contribution of SEEG and signal analysis. Epilepsia, 2017, 58(7): 1131-1147.
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6.	裘志军, 陈旨娟, 田心. 基于 Granger 因果分析研究颞叶癫痫脑电的网络特性. 天津医科大学学报, 2014, 20(6): 437-440.
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8.	Li Fali, Chen Bei, Li He, et al. The time-varying networks in P300: a task-evoked EEG study. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 2016, 24(7): 725-733.
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10.	亢志强, 钱若兵, 魏祥品, 等. 难治性颞叶癫痫患者脑功能网络节点的度属性研究. 立体定向和功能性神经外科杂志, 2015, 28(1): 1-4.
11.	闫秀鹏, 王海祥, 周文静, 等. 基于高频颅内脑电的致痫区定位和网络分析. 北京生物医学工程, 2017, 3(3): 229-236.
12.	Pascual-Marqui R D, Biscay R J, Bosch-Bayard J, et al. Assessing direct paths of intracortical causal information flow of oscillatory activity with the isolated effective coherence (iCoh). Front Hum Neurosci, 2014, 8(448): 1-12.
13.	Qin Yun, Xu Peng, Yao Dezhong. A comparative study of different references for EEG default mode network: the use of the infinity reference. Clinical Neurophysiology, 2010, 121(12): 1981-1991.
14.	Li Chunsheng, Jacobs D, Hilton T, et al. Epileptogenic source imaging using cross-frequency coupled signals from scalp EEG. IEEE Trans Biomed Eng, 2016, 63(12): 2607-2618.
15.	Mirzaei P, Azemi G, Japaridze N, et al. Surrogate data test for nonlinearity of EEG signals: a newborn EEG burst suppression case study. Digit Signal Process, 2017, 70(10): 30-38.
16.	D'andrea G, Angelini A, Romano A, et al. Intraoperative DTI and brain mapping for surgery of neoplasm of the motor cortex and the corticospinal tract: our protocol and series in BrainSUITE. Neurosurg Rev, 2012, 35(3): 401-412.
17.	程学梅, 崔园. Freesurfer 在癫痫病人脑模型重建中的应用. 计算机与数字工程, 2016, 44(5): 936-940.
18.	Huang M X, Mosher J C, Leahy R M. A sensor-weighted overlapping-sphere head model and exhaustive head model comparison for MEG. Phys Med Biol, 1999, 44: 423-440.
19.	Pascual-Marqui R D, Biscay R J, Bosch-Bayard J, et al. Isolated effective coherence (iCoh): causal information flow excluding indirect paths. Stat Methodol, 2014, 1402(4887): 1-15.
20.	魏杰. 基于 K-means 聚类算法改进算法的研究. 信息通信, 2018, 5: 14-15.
21.	郑霄, 张丹, 石岩芳, 等. 基于发作间期颅内脑电高频振荡的癫痫病灶定位. 北京生物医学工程, 2014, 3(3): 253-257.
22.	Mao Junwei, Ye Xiaolai, Li Yonghua, et al. Dynamic network connectivity analysis to identify epileptogenic zones based on stereo-electroencephalography. Front Comput Neurosci, 2016, 10: 1-13.

1. Kwan P, Brodie M J. Early identification of refractory epilepsy. N Engl J Med, 2000, 342(5): 314-319.
2. 阮静, 闫秀鹏, 王海祥, 等. 立体定向电极置入路径与术前规划路径的偏差分析. 临床神经外科杂志, 2017, 14(3): 178-181, 185.
3. Bartolomei F, Lagarde S, Wendling F, et al. Defining epileptogenic networks: contribution of SEEG and signal analysis. Epilepsia, 2017, 58(7): 1131-1147.
4. Dong Li, Luo Cheng, Zhu Yutian, et al. Complex discharge-affecting networks in juvenile myoclonic epilepsy: a simultaneous EEG-fMRI study. Hum Brain Mapp, 2016, 37(10): 3515-3529.
5. 薛开庆, 罗程, 田银, 等. 基于弥散张量成像的儿童失神癫痫认知控制网络的结构连接研究. 中国生物医学工程学报, 2013, 32(4): 426-432.
6. 裘志军, 陈旨娟, 田心. 基于 Granger 因果分析研究颞叶癫痫脑电的网络特性. 天津医科大学学报, 2014, 20(6): 437-440.
7. Wilke C, Worrell G, HE Bin. Graph analysis of epileptogenic networks in human partial epilepsy. Epilepsia, 2011, 52(1): 84-93.
8. Li Fali, Chen Bei, Li He, et al. The time-varying networks in P300: a task-evoked EEG study. IEEE Transactions on Neural Systems and Rehabilitation Engineering, 2016, 24(7): 725-733.
9. Li Yonghua, Ye Xiaolai, Liu Qiangqiang, et al. Localization of epileptogenic zone based on graph analysis of stereo-EEG. Epilepsy Research, 2016, 128: 149-157.
10. 亢志强, 钱若兵, 魏祥品, 等. 难治性颞叶癫痫患者脑功能网络节点的度属性研究. 立体定向和功能性神经外科杂志, 2015, 28(1): 1-4.
11. 闫秀鹏, 王海祥, 周文静, 等. 基于高频颅内脑电的致痫区定位和网络分析. 北京生物医学工程, 2017, 3(3): 229-236.
12. Pascual-Marqui R D, Biscay R J, Bosch-Bayard J, et al. Assessing direct paths of intracortical causal information flow of oscillatory activity with the isolated effective coherence (iCoh). Front Hum Neurosci, 2014, 8(448): 1-12.
13. Qin Yun, Xu Peng, Yao Dezhong. A comparative study of different references for EEG default mode network: the use of the infinity reference. Clinical Neurophysiology, 2010, 121(12): 1981-1991.
14. Li Chunsheng, Jacobs D, Hilton T, et al. Epileptogenic source imaging using cross-frequency coupled signals from scalp EEG. IEEE Trans Biomed Eng, 2016, 63(12): 2607-2618.
15. Mirzaei P, Azemi G, Japaridze N, et al. Surrogate data test for nonlinearity of EEG signals: a newborn EEG burst suppression case study. Digit Signal Process, 2017, 70(10): 30-38.
16. D'andrea G, Angelini A, Romano A, et al. Intraoperative DTI and brain mapping for surgery of neoplasm of the motor cortex and the corticospinal tract: our protocol and series in BrainSUITE. Neurosurg Rev, 2012, 35(3): 401-412.
17. 程学梅, 崔园. Freesurfer 在癫痫病人脑模型重建中的应用. 计算机与数字工程, 2016, 44(5): 936-940.
18. Huang M X, Mosher J C, Leahy R M. A sensor-weighted overlapping-sphere head model and exhaustive head model comparison for MEG. Phys Med Biol, 1999, 44: 423-440.
19. Pascual-Marqui R D, Biscay R J, Bosch-Bayard J, et al. Isolated effective coherence (iCoh): causal information flow excluding indirect paths. Stat Methodol, 2014, 1402(4887): 1-15.
20. 魏杰. 基于 K-means 聚类算法改进算法的研究. 信息通信, 2018, 5: 14-15.
21. 郑霄, 张丹, 石岩芳, 等. 基于发作间期颅内脑电高频振荡的癫痫病灶定位. 北京生物医学工程, 2014, 3(3): 253-257.
22. Mao Junwei, Ye Xiaolai, Li Yonghua, et al. Dynamic network connectivity analysis to identify epileptogenic zones based on stereo-electroencephalography. Front Comput Neurosci, 2016, 10: 1-13.

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