Modeling Consistent Dynamics of Cardiogenic Vibrations in Low-Dimensional Subspace

The seismocardiogram (SCG) measures the movement of the chest wall in response to underlying cardiovascular events. Though this signal contains clinically-relevant information, its morphology is both patient-specific and highly transient. In light of recent work suggesting the existence of populatio...

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Bibliographic Details
Published in:IEEE journal of biomedical and health informatics 2020-07, Vol.24 (7), p.1887-1898
Main Authors: Zia, Jonathan, Kimball, Jacob, Hersek, Sinan, Inan, Omer T.
Format: Article
Language:English
Subjects:
Adult
Algorithms
Aorta
Aorta - physiology
autoencoder
cardiac monitoring
Convolution
dimensionality reduction
Female
generative modeling
Genetic variability
Harnesses
Heart Function Tests - methods
Hemodynamics
Humans
Male
Mapping
Mathematical model
Models, Cardiovascular
Monitoring
Morphology
Physiology
Seismocardiogram
Sensors
Signal processing
Signal Processing, Computer-Assisted
Stochasticity
Subspaces
Trajectory
Vibration
Vibrations
Waveforms
Young Adult
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Summary:The seismocardiogram (SCG) measures the movement of the chest wall in response to underlying cardiovascular events. Though this signal contains clinically-relevant information, its morphology is both patient-specific and highly transient. In light of recent work suggesting the existence of population-level patterns in SCG signals, the objective of this study is to develop a method which harnesses these patterns to enable robust signal processing despite morphological variability. Specifically, we introduce seismocardiogram generative factor encoding (SGFE), which models the SCG waveform as a stochastic sample from a low-dimensional subspace defined by a unified set of generative factors. We then demonstrate that during dynamic processes such as exercise-recovery, learned factors correlate strongly with known generative factors including aortic opening (AO) and closing (AC), following consistent trajectories in subspace despite morphological differences. Furthermore, we found that changes in sensor location affect the perceived underlying dynamic process in predictable ways, thereby enabling algorithmic compensation for sensor misplacement during generative factor inference. Mapping these trajectories to AO and AC yielded R^2 values from 0.81-0.90 for AO and 0.72-0.83 for AC respectively across five sensor positions. Identification of consistent behavior of SCG signals in low dimensions corroborates the existence of population-level patterns in these signals; SGFE may also serve as a harbinger for processing methods that are abstracted from the time domain, which may ultimately improve the feasibility of SCG utilization in ambulatory and outpatient settings.
ISSN:2168-2194
2168-2208
DOI:10.1109/JBHI.2020.2980979