Research on electroencephalogram specifics in patients with schizophrenia under cognitive load_Journal of Biomedical Engineering

Authors：

DU Xin ^1,2 , LI Jiahui ^1,2 , XIONG Dongsheng ^1,2 , PAN Zhilin ^1,2 , WU Fengchun ^2,3 , NING Yuping ^2,3 , CHEN Jun ^4,5 ,  WU Kai ^1,2,3,4,5

1. Department of Biomedical Engineering, School of Material Science and Engineering, South China University of Technology, Guangzhou 510006, P.R.China;
2. Guangdong Engineering Technology Research Center for Translational Medicine of Mental Disorders, Guangzhou 510370, P.R.China;
3. Guangzhou Huiai Hospital, The Affiliated Brain Hospital of Guangzhou Medical University, Guangzhou 510370, P.R.China;
4. Guangdong Engineering Technology Research Center for Diagnosis and Rehabilitation of Dementia, Guangzhou 510500, P.R.China;
5. National Engineering Research Center for Healthcare Devices, Guangzhou 510500, P.R.China;

Corresponding author：

WU Kai, Email: kaiwu@scut.edu.cn

Keywords：

schizophrenia; cognitive impairment; electroencephalogram; functional brain network; machine learning

DOI：

10.7507/1001-5515.201810007

Video：

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Cognitive impairment is one of the three primary symptoms of schizophrenic patients and shows important value in early detection and warning for high-risk individuals. To study the specifics of electroencephalogram (EEG) in patients with schizophrenia under the cognitive load, we collected EEG signals from 17 schizophrenic patients and 19 healthy controls, extracted signals of each band based on wavelet transform, calculated the characteristics of nonlinear dynamic and functional brain networks, and automatically classified the two groups of people by using a machine learning algorithm. Experimental results indicated that the correlation dimension and sample entropy showed significant differences in α, β, θ, and γ rhythm of the Fp1 and Fp2 electrodes between groups under the cognitive load. These results implied that the functional disruptions in the frontal lobe might be the important factors of cognitive impairments in schizophrenic patients. Further results of the automatic classification analysis indicated that the combination of nonlinear dynamics and functional brain network properties as the input characteristics of the classifier showed the best performance, with the accuracy of 76.77%, sensitivity of 72.09%, and specificity of 80.36%. The results of this study demonstrated that the combination of nonlinear dynamics and function brain network properties may be potential biomarkers for early screening and auxiliary diagnosis of schizophrenia.

Citation： DU Xin, LI Jiahui, XIONG Dongsheng, PAN Zhilin, WU Fengchun, NING Yuping, CHEN Jun, WU Kai. Research on electroencephalogram specifics in patients with schizophrenia under cognitive load. Journal of Biomedical Engineering, 2020, 37(1): 45-53. doi: 10.7507/1001-5515.201810007 Copy

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1. Patel K R, Cherian J, Gohil K, et al. Schizophrenia: overview and treatment options. Pharmacy and Therapeutics, 2014, 39(9): 638-645.
2. Krivoy A, Fischel T, Weizman A. The cognitive deficit in schizophrenia. Harefuah, 2012, 151(151): 277-280.
3. Green M F. Impact of cognitive and social cognitive impairment on functional outcomes in patients with schizophrenia. J Clin Psychiatry, 2016, 77(Suppl 2): 8-11.
4. Lee T Y, Hong Sangbin, Shin N Y, et al. Social cognitive functioning in prodromal psychosis: a meta-analysis. Schizophr Res, 2015, 164(1/3): 28-34.
5. 朱俊敬, 郭素芹. 首发儿童精神分裂症患者病前行为特征与病后认知功能的关系. 新乡医学院学报, 2018, 35(11): 1005-1008.
6. Gold J M. Cognitive deficits as treatment targets in schizophrenia. Schizophr Res, 2004, 72(1): 21-28.
7. Topolov M K, Getova D P. Cognitive impairment in schizophrenia, neurotransmitters and the new atypical antipsychotic aripiprazole. Folia Med (Plovdiv), 2016, 58(1): 12-18.
8. Leicht G, Andreou C, Polomac N, et al. Reduced auditory evoked gamma band response and cognitive processing deficits in first episode schizophrenia. World J Biol Psychiatry, 2015, 16(6): 387-397.
9. Erdős P, Rényi A. On the strength of connectedness of a random graph. Acta Mathematica Academiae Scientiarum Hungarica, 1964, 12(1/2): 261-267.
10. Montez T, Linkenkaer-Hansen K, van Dijk B W, et al. Synchronization likelihood with explicit time-frequency priors. Neuroimage, 2006, 33(4): 1117-1125.
11. Stam C J. Nonlinear brain dynamics, US: Nova Science Pub, 2006: 1-248.
12. Johannesen J K, Bi Jinbo, Jiang Ruhua, et al. Machine learning identification of EEG features predicting working memory performance in schizophrenia and healthy adults. Neuropsychiatric electrophysiology, 2016, 2(1): 3.
13. Chi Minyue, Guo Shengwen, Ning Yuping, et al. Discriminative analysis of major depressive disorder and anxious depression using support vector machine. J Comput Theor Nanosci, 2015, 12(7): 1395-1401.
14. Lu Xiaobing, Yang Yongzhe, Wu Fengchun, et al. Discriminative analysis of schizophrenia using support vector machine and recursive feature elimination on structural MRI images. Medicine, 2016, 95(30): e3973.
15. Chang C C, Lin C J. LIBSVM: A library for support vector machines. ACM Transactions on Intelligent Systems and Technology, 2011, 2(3): 1-27.
16. Wagenmakers J, Wetzels R, Borsboom D, et al. Online appendix for"why psychologists must change the way they analyze their data: the case of Psi": a robustness analysis. Journal of Personality & Social Psychology, 2011, 100(3): 426-432.

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