Assessment of atrial fibrillation inducibility based on epicardial mapping signals_Journal of Biomedical Engineering

Authors：

HE Kaiyue ¹ ,  YANG Cuiwei ^1,2,3

1. Department of Electronic Engineering, Fudan University, Shanghai 200433, P.R.China;
2. Key Laboratory of Medical Imaging Computing and Computer Assisted Intervention of Shanghai, Shanghai 200093, P.R.China;
3. Shanghai Engineering Research Center of Cardiac Electrophysiology, Shanghai 201318, P.R.China;

Corresponding author：

YANG Cuiwei, Email: yangcw@fudan.edu.cn

Keywords：

atrial fibrillation; epicardial mapping; electrophysiology; binary logistic regression

DOI：

10.7507/1001-5515.201910005

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Atrial fibrillation (AF) is the most common arrhythmia in clinic, which can cause hemodynamic changes, heart failure and stroke, and seriously affect human life and health. As a self-promoting disease, the treatment of AF can become more and more difficult with the deterioration of the disease, and the early prediction and intervention of AF is the key to curbing the deterioration of the disease. Based on this, in this study, by controlling the dose of acetylcholine, we changed the AF vulnerability of five mongrel dogs and tried to assess it by analyzing the electrophysiology of atrial epicardium under different states of sinus rhythm. Here, indices from four aspects were proposed to study the atrial activation rule. They are the variability of atrial activation rhythm, the change of the earliest atrial activation, the change of atrial activation delay and the left-right atrial dyssynchrony. By using binary logistic regression analysis, multiple indices above were transformed into the AF inducibility, which were used to classify the signals during sinus rhythm. The sensitivity, specificity and accuracy of classification reached 85.7%, 95.8% and 91.7%, respectively. As the experimental results show, the proposed method has the ability to assess the AF vulnerability of atrium, which is of great clinical significance for the early prediction and intervention of AF.

Citation： HE Kaiyue, YANG Cuiwei. Assessment of atrial fibrillation inducibility based on epicardial mapping signals. Journal of Biomedical Engineering, 2020, 37(3): 487-495, 501. doi: 10.7507/1001-5515.201910005 Copy

1.	Yoshida Takuo, Uchino S, Yokota T, et al. The impact of sustained new-onset atrial fibrillation on mortality and stroke incidence in critically ill patients: A retrospective cohort study. Journal of critical care, 2018, 44: 267-272.
2.	Zhang S. Atrial fibrillation in mainland China: epidemiology and current management. Heart, 2009, 95(13): 1052-1055.
3.	Schnabel R B, Yin Xiaoyan, Gona P, et al. 50 year trends in atrial fibrillation prevalence, incidence, risk factors, and mortality in the Framingham Heart Study: a cohort study. Lancet, 2015, 386(9989): 154-162.
4.	Wolf P A, Mitchell J B, Baker C S, et al. Impact of atrial fibrillation on mortality, stroke, and medical costs. Arch Intern Med, 1998, 158(3): 229-234.
5.	Le Heuzey J Y, Paziaud O, Piot O, et al. Cost of care distribution in atrial fibrillation patients: the COCAF study. American Heart Journal, 2004, 147(1): 121-126.
6.	Kumar S, Teh A W, Medi C, et al. Atrial remodeling in varying clinical substrates within beating human hearts: relevance to atrial fibrillation. Prog Biophys Mol Biol, 2012, 110(2-3): 278-294.
7.	Yoshizawa T, Niwano S, Niwano H, et al. Prediction of new onset atrial fibrillation through P wave analysis in 12 Lead ECG. Int Heart J, 2014, 55(5): 422-427.
8.	Thong T, Mcnames J, Aboy M, et al. Prediction of paroxysmal atrial fibrillation by analysis of atrial premature complexes. IEEE Trans Biomed Eng, 2004, 51(4): 561-569.
9.	Maryam M, Ghassemian H. Prediction of paroxysmal atrial fibrillation using recurrence plot-based features of the RR-interval signal. Physiol Meas, 2011, 32(8): 1147-1162.
10.	Schuessler R B, Grayson T M, Bromberg B I, et al. Cholinergically mediated tachyarrhythmias induced by a single extrastimulus in the isolated canine right atrium. Circ Res, 1992, 71(5): 1254-1267.
11.	杨诏旭, 蔡振杰, 王跃民, 等. 乙酰胆碱诱发犬急性心房颤动模型的研究. 心脏杂志, 2002, 14(3): 195-198.
12.	Everett T H 4th, Kok L C, Vaughn R H, et al. Frequency domain algorithm for quantifying atrial fibrillation organization to increase defibrillation efficacy. IEEE Trans Biomed Eng, 2001, 48(9): 969-978.
13.	Ganesan A N, Kuklik P, Lau D H, et al. Bipolar electrogram Shannon entropy at sites of rotational activation implications for ablation of atrial fibrillation. Circulation Arrhythmia & Electrophysiology, 2013, 6(1): 48-57.
14.	Sun Liqian, Yang Cuiwei, Lin Zhang, et al. A preliminary study on atrial epicardial mapping signals based on graph theory. Med Eng Phys, 2014, 36(7): 875-881.
15.	Ouyang Gaoxiang, Zhu Xiangyang, Ju Zhaojie, et al. Dynamical characteristics of surface EMG signals of hand grasps via recurrence plot. IEEE J Biomed Health Inform, 2014, 18(1): 257-265.
16.	白宝丹. 基于递归复杂网络的房颤预测分析方法研究. 上海: 复旦大学, 2012.
17.	Chen Ying, Wu Zhong, Yang Cuiwei, et al. Investigation of atrial vulnerability by analysis of the sinus node EG from atrial fibrillation models using a phase synchronization method. IEEE Trans Biomed Eng, 2012, 59(9): 2668-2676.
18.	黄娟, 钱新, 王成林, 等. 小波滤波器的构造及其在环境研究中的应用. 南京大学学报: 自然科学版, 2007, 43(4): 389-396.
19.	吴广宁, 刘曦, 佟来生, 等. 提取PWM脉冲下局部放电信号的sym4小波滤波器的研究. 电工技术学报, 2006, 21(2): 35-38, 50.
20.	孙莉倩. 心房电标测信号的节律分析及空间关联初探. 上海: 复旦大学, 2013.
21.	杨翠微. 基于心外膜标测技术的房颤表征方法及电生理机制研究. 复旦大学, 2008.
22.	苗志博. 心外膜标测信号特征点检测. 上海: 复旦大学, 2014.
23.	王济川, 郭志刚. Logistic回归模型: 方法与应用. 北京: 高等教育出版社, 2001.

1. Yoshida Takuo, Uchino S, Yokota T, et al. The impact of sustained new-onset atrial fibrillation on mortality and stroke incidence in critically ill patients: A retrospective cohort study. Journal of critical care, 2018, 44: 267-272.
2. Zhang S. Atrial fibrillation in mainland China: epidemiology and current management. Heart, 2009, 95(13): 1052-1055.
3. Schnabel R B, Yin Xiaoyan, Gona P, et al. 50 year trends in atrial fibrillation prevalence, incidence, risk factors, and mortality in the Framingham Heart Study: a cohort study. Lancet, 2015, 386(9989): 154-162.
4. Wolf P A, Mitchell J B, Baker C S, et al. Impact of atrial fibrillation on mortality, stroke, and medical costs. Arch Intern Med, 1998, 158(3): 229-234.
5. Le Heuzey J Y, Paziaud O, Piot O, et al. Cost of care distribution in atrial fibrillation patients: the COCAF study. American Heart Journal, 2004, 147(1): 121-126.
6. Kumar S, Teh A W, Medi C, et al. Atrial remodeling in varying clinical substrates within beating human hearts: relevance to atrial fibrillation. Prog Biophys Mol Biol, 2012, 110(2-3): 278-294.
7. Yoshizawa T, Niwano S, Niwano H, et al. Prediction of new onset atrial fibrillation through P wave analysis in 12 Lead ECG. Int Heart J, 2014, 55(5): 422-427.
8. Thong T, Mcnames J, Aboy M, et al. Prediction of paroxysmal atrial fibrillation by analysis of atrial premature complexes. IEEE Trans Biomed Eng, 2004, 51(4): 561-569.
9. Maryam M, Ghassemian H. Prediction of paroxysmal atrial fibrillation using recurrence plot-based features of the RR-interval signal. Physiol Meas, 2011, 32(8): 1147-1162.
10. Schuessler R B, Grayson T M, Bromberg B I, et al. Cholinergically mediated tachyarrhythmias induced by a single extrastimulus in the isolated canine right atrium. Circ Res, 1992, 71(5): 1254-1267.
11. 杨诏旭, 蔡振杰, 王跃民, 等. 乙酰胆碱诱发犬急性心房颤动模型的研究. 心脏杂志, 2002, 14(3): 195-198.
12. Everett T H 4th, Kok L C, Vaughn R H, et al. Frequency domain algorithm for quantifying atrial fibrillation organization to increase defibrillation efficacy. IEEE Trans Biomed Eng, 2001, 48(9): 969-978.
13. Ganesan A N, Kuklik P, Lau D H, et al. Bipolar electrogram Shannon entropy at sites of rotational activation implications for ablation of atrial fibrillation. Circulation Arrhythmia & Electrophysiology, 2013, 6(1): 48-57.
14. Sun Liqian, Yang Cuiwei, Lin Zhang, et al. A preliminary study on atrial epicardial mapping signals based on graph theory. Med Eng Phys, 2014, 36(7): 875-881.
15. Ouyang Gaoxiang, Zhu Xiangyang, Ju Zhaojie, et al. Dynamical characteristics of surface EMG signals of hand grasps via recurrence plot. IEEE J Biomed Health Inform, 2014, 18(1): 257-265.
16. 白宝丹. 基于递归复杂网络的房颤预测分析方法研究. 上海: 复旦大学, 2012.
17. Chen Ying, Wu Zhong, Yang Cuiwei, et al. Investigation of atrial vulnerability by analysis of the sinus node EG from atrial fibrillation models using a phase synchronization method. IEEE Trans Biomed Eng, 2012, 59(9): 2668-2676.
18. 黄娟, 钱新, 王成林, 等. 小波滤波器的构造及其在环境研究中的应用. 南京大学学报: 自然科学版, 2007, 43(4): 389-396.
19. 吴广宁, 刘曦, 佟来生, 等. 提取PWM脉冲下局部放电信号的sym4小波滤波器的研究. 电工技术学报, 2006, 21(2): 35-38, 50.
20. 孙莉倩. 心房电标测信号的节律分析及空间关联初探. 上海: 复旦大学, 2013.
21. 杨翠微. 基于心外膜标测技术的房颤表征方法及电生理机制研究. 复旦大学, 2008.
22. 苗志博. 心外膜标测信号特征点检测. 上海: 复旦大学, 2014.
23. 王济川, 郭志刚. Logistic回归模型: 方法与应用. 北京: 高等教育出版社, 2001.

Journal of Biomedical Engineering

Assessment of atrial fibrillation inducibility based on epicardial mapping signals

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content