Automatic Annotation of Seismocardiogram With High-Frequency Precordial Accelerations

Seismocardiogram (SCG) is the low-frequency vibrations signal recorded from the chest using accelerometers. Peaks on dorsoventral and sternal SCG correspond to specific cardiac events. Prior research work has shown the potential of extracting such peaks for various types of monitoring and diagnosis applications. However, annotation of these peaks is not a trivial task and complicated in some subjects. In this paper, an automated method is proposed to annotate these peaks. The high-frequency accelerations obtained from the same accelerometer, used to record SCG with, were used to facilitate the annotation of the SCG. Algorithms were developed for detection of isovolumic moment (IM) and aortic valve closure (AC) points of SCG. Four different envelope calculation methods were used: cardiac sound characteristic waveform (CSCW), Shannon, absolute, and Hilbert. The algorithms were evaluated based on a dataset including 18 subjects undergoing lower body negative pressure and were further tested with another dataset, which included 67 subjects. These datasets had been previously manually annotated. The algorithm based on CSCW envelope calculation produced the highest detection accuracy for both IM and AC. The overall CSCW algorithm detection accuracy for the test dataset was 98.7% and 99.1% for the IM and AC points, respectively.

[1]  Bozena Kaminska,et al.  Estimation of hemodynamic parameters from seismocardiogram , 2010, 2010 Computing in Cardiology.

[2]  L. Senhadji,et al.  Analysis of cardiac micro-acceleration signals for the estimation of systolic and diastolic time intervals in cardiac resynchronization therapy , 2008, 2008 Computers in Cardiology.

[3]  James H. McClellan,et al.  A System for Seismocardiography-Based Identification of Quiescent Heart Phases: Implications for Cardiac Imaging , 2012, IEEE Transactions on Information Technology in Biomedicine.

[4]  K. Radermacher,et al.  Simplified detection of myocardial ischemia by seismocardiography , 2013, Herz.

[5]  Peter J. Hannan,et al.  Relationship between seismocardiogram and echocardiogram for events in the cardiac cycle , 1994 .

[6]  A. Weissler,et al.  Systolic Time Intervals in Heart Failure in Man , 1968, Circulation.

[7]  Zhongwei Jiang,et al.  Comparison of envelope extraction algorithms for cardiac sound signal segmentation , 2008, Expert Syst. Appl..

[8]  Kouhyar Tavakolian,et al.  Precordial Vibrations Provide Noninvasive Detection of Early-Stage Hemorrhage , 2014, Shock.

[9]  D. Salerno,et al.  Seismocardiography : a new technique for recording cardiac vibrations. Concept, method, and initial observations , 1990 .

[10]  C. Menon,et al.  Precordial acceleration signals improve the performance of diastolic timed vibrations. , 2013, Medical engineering & physics.

[11]  Kouhyar Tavakolian,et al.  Seismocardiography: Past, present and future , 2013, 2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC).

[12]  Willis J. Tompkins,et al.  A Real-Time QRS Detection Algorithm , 1985, IEEE Transactions on Biomedical Engineering.

[13]  D. Salerno,et al.  Seismocardiography for monitoring changes in left ventricular function during ischemia. , 1991, Chest.

[14]  Zhongwei Jiang,et al.  A cardiac sound characteristic waveform method for in-home heart disorder monitoring with electric stethoscope , 2006, Expert Syst. Appl..