An anesthesia depth computing method study based on wavelet transform and artificial neural network_Journal of Biomedical Engineering

Authors：

YUAN Sinian ^1,3 ,  YE Jilun ^1,2,3 , ZHANG Xu ^1,2,3 , ZHOU Jingjing ^1,3 , TAN Xue ^1,3 , LI Ruowei ^1,3 , DENG Zhuqiang ⁴ , DING Yaomao ⁴

1. Biomedical Engineering Department, School of Medicine, Shenzhen University, Shenzhen, Guangdong 518060, P.R.China;
2. Guangdong Key Lab for Biomedical Measurements and Ultrasound Imaging, Shenzhen, Guangdong 518060, P.R.China;
3. Shenzhen Key Lab for Biomedical Engineering, Shenzhen, Guangdong 518060, P.R.China;
4. The People’s Hospital of Gaozhou, Gaozhou, Guangdong 525200, P.R.China;

Corresponding author：

YE Jilun, Email: Yejilun@126.com

Keywords：

electroencephalogram; depth of anesthesia; discrete wavelet transform; bispectral index; artificial neural network

DOI：

10.7507/1001-5515.202007003

Video：

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General anesthesia is an essential part of surgery to ensure the safety of patients. Electroencephalogram (EEG) has been widely used in anesthesia depth monitoring for abundant information and the ability of reflecting the brain activity. The paper proposes a method which combines wavelet transform and artificial neural network (ANN) to assess the depth of anesthesia. Discrete wavelet transform was used to decompose the EEG signal, and the approximation coefficients and detail coefficients were used to calculate the 9 characteristic parameters. Kruskal-Wallis statistical test was made to these characteristic parameters, and the test showed that the parameters were statistically significant for the differences of the four levels of anesthesia: awake, light anesthesia, moderate anesthesia and deep anesthesia (P < 0.001). The 9 characteristic parameters were used as the input of ANN, the bispectral index (BIS) was used as the reference output, and the method was evaluated by the data of 8 patients during general anesthesia. The accuracy of the method in the classification of the four anesthesia levels of the test set in the 7:3 set-out method was 85.98%, and the correlation coefficient with the BIS was 0.977 0. The results show that this method can better distinguish four different anesthesia levels and has broad application prospects for monitoring the depth of anesthesia.

Citation： YUAN Sinian, YE Jilun, ZHANG Xu, ZHOU Jingjing, TAN Xue, LI Ruowei, DENG Zhuqiang, DING Yaomao. An anesthesia depth computing method study based on wavelet transform and artificial neural network. Journal of Biomedical Engineering, 2021, 38(5): 838-847. doi: 10.7507/1001-5515.202007003 Copy

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3.	Li T N, Li Y. Depth of anaesthesia monitors and the latest algorithms. Asian Pac J Trop Med, 2014, 7(6): 429-437.
4.	Liu Q, Ma L, Fan S Z, et al. Sample entropy analysis for the estimating depth of anaesthesia through human EEG signal at different levels of unconsciousness during surgeries. PeerJ, 2018, 6: e4817.
5.	李小俚, 崔素媛. 基于希尔伯特黄熵的麻醉深度估计. 中国生物医学工程学报, 2008, 27(5): 689-694.
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10.	Benzy V K, Jasmin E A, Koshy R C, et al. Relative wave energy based adaptive neuro-fuzzy inference system model for the estimation of depth of anaesthesia. J Integrat Neurosci, 2018, 17(1): 69-82.
11.	Tai N K, Wen P, Yan L, et al. Measuring the hypnotic depth of anaesthesia based on the EEG signal using combined wavelet transform, eigenvector and normalisation techniques. Comput Biol Med, 2012, 42(6): 680-691.
12.	Zoughi T, Boostani R, Deypir M. A wavelet-based estimating depth of anesthesia. Eng Appl Artif Intell, 2012, 25(8): 1710-1722.
13.	Benzy V K, Jasmin E A. A combined wavelet and neural network based model for classifying depth of anaesthesia. Procedia Comput Sci, 2015, 46: 1610-1617.
14.	Liu Q, Chen Y F, Fan S Z, et al. EEG signals analysis using multiscale entropy for depth of anesthesia monitoring during surgery through artificial neural networks. Comput Math Methods Med, 2015, 2015: 1-16.
15.	王凡. 基于脑电的麻醉深度监测系统研制. 深圳: 深圳大学, 2015.
16.	Chan Y, Walmsley R P. Learning and understanding the kruskal-wallis one-way analysis-of-variance-by-ranks test for differences among three or more independent groups. Phys Ther, 1997, 77(12): 1755-1761.
17.	Boser B E, Guyon I M, Vapnik V N. A training algorithm for optimal margin classifiers// Proceedings of the Fifth Annual Workshop on Computational Learning Theory. Pittsburgh: Association for Computing Machinery, 1992: 144-152.
18.	Hayashi K, Sawa T. The fundamental contribution of the electromyogram to a high bispectral index: a postoperative observational study. J Clin Monit Comput, 2019, 33(6): 1097-1103.
19.	刘军, 周雅琪, 陈绍宾, 等. 基于样本熵与决策树的麻醉意识深度评价指数的研究. 生物医学工程学杂志, 2015, 32(2): 192-197.
20.	王锋, 李晓欧. 基于脑电信号的麻醉特征参数分析. 生物医学工程学杂志, 2015, 32(1): 13-18.

1. Gu Y, Liang Z, Hagihira S. Use of multiple EEG features and artificial neural network to monitor the depth of anesthesia. Sensors, 2019, 19(11): 2499.
2. Voss L, Sleigh J. Monitoring consciousness: the current status of EEG-based depth of anaesthesia monitors. Best Pract Res Clin Anaesthesiol, 2007, 21(3): 313-325.
3. Li T N, Li Y. Depth of anaesthesia monitors and the latest algorithms. Asian Pac J Trop Med, 2014, 7(6): 429-437.
4. Liu Q, Ma L, Fan S Z, et al. Sample entropy analysis for the estimating depth of anaesthesia through human EEG signal at different levels of unconsciousness during surgeries. PeerJ, 2018, 6: e4817.
5. 李小俚, 崔素媛. 基于希尔伯特黄熵的麻醉深度估计. 中国生物医学工程学报, 2008, 27(5): 689-694.
6. 封洲燕, 郑筱祥. 不同麻醉深度下大鼠脑电复杂度和功率谱的变化过程. 中国生物医学工程学报, 2004, 23(1): 87-91.
7. Jospin M, Caminal P, Jensen E W, et al. Detrended fluctuation analysis of EEG as a measure of depth of anesthesia. IEEE Trans Biomed Eng, 2007, 54(5): 840-846.
8. 田心. 脑电的非线性动力学研究中的问题和进展. 国际生物医学工程杂志, 1999, 22(4): 193-198.
9. Benzy V K, Jasmin E A, Koshy R C, et al. Wavelet entropy as a measure of depth of anaesthesia// 2016 3rd International Conference on Signal Processing and Integrated Networks (SPIN). Noida: IEEE, 2016: 616-619.
10. Benzy V K, Jasmin E A, Koshy R C, et al. Relative wave energy based adaptive neuro-fuzzy inference system model for the estimation of depth of anaesthesia. J Integrat Neurosci, 2018, 17(1): 69-82.
11. Tai N K, Wen P, Yan L, et al. Measuring the hypnotic depth of anaesthesia based on the EEG signal using combined wavelet transform, eigenvector and normalisation techniques. Comput Biol Med, 2012, 42(6): 680-691.
12. Zoughi T, Boostani R, Deypir M. A wavelet-based estimating depth of anesthesia. Eng Appl Artif Intell, 2012, 25(8): 1710-1722.
13. Benzy V K, Jasmin E A. A combined wavelet and neural network based model for classifying depth of anaesthesia. Procedia Comput Sci, 2015, 46: 1610-1617.
14. Liu Q, Chen Y F, Fan S Z, et al. EEG signals analysis using multiscale entropy for depth of anesthesia monitoring during surgery through artificial neural networks. Comput Math Methods Med, 2015, 2015: 1-16.
15. 王凡. 基于脑电的麻醉深度监测系统研制. 深圳: 深圳大学, 2015.
16. Chan Y, Walmsley R P. Learning and understanding the kruskal-wallis one-way analysis-of-variance-by-ranks test for differences among three or more independent groups. Phys Ther, 1997, 77(12): 1755-1761.
17. Boser B E, Guyon I M, Vapnik V N. A training algorithm for optimal margin classifiers// Proceedings of the Fifth Annual Workshop on Computational Learning Theory. Pittsburgh: Association for Computing Machinery, 1992: 144-152.
18. Hayashi K, Sawa T. The fundamental contribution of the electromyogram to a high bispectral index: a postoperative observational study. J Clin Monit Comput, 2019, 33(6): 1097-1103.
19. 刘军, 周雅琪, 陈绍宾, 等. 基于样本熵与决策树的麻醉意识深度评价指数的研究. 生物医学工程学杂志, 2015, 32(2): 192-197.
20. 王锋, 李晓欧. 基于脑电信号的麻醉特征参数分析. 生物医学工程学杂志, 2015, 32(1): 13-18.

Journal of Biomedical Engineering

An anesthesia depth computing method study based on wavelet transform and artificial neural network

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