Abstract
Recent research has shown promising results for the detection of aortic stenosis (AS) using cardio-mechanical signals. However, they are limited by two main factors: lacking physical explanations for decision-making on the existence of AS, and the need for auxiliary signals. The main goal of this paper is to address these shortcomings through a wearable inertial measurement unit (IMU), where the physical causes of AS are determined from IMU readings. To this end, we develop a framework based on seismo-cardiogram (SCG) and gyro-cardiogram (GCG) morphologies, where highly-optimized algorithms are designed to extract features deemed potentially relevant to AS. Extracted features are then analyzed through machine learning techniques for AS diagnosis. It is demonstrated that AS could be detected with 95.49–100.00% confidence. Based on the ablation study on the feature space, the GCG time-domain feature space holds higher consistency, i.e., 95.19–100.00%, with the presence of AS than HRV parameters with a low contribution of 66.00–80.00%. Furthermore, the robustness of the proposed method is evaluated by conducting analyses on the classification of the AS severity level. These analyses are resulted in a high confidence of 92.29%, demonstrating the reliability of the proposed framework. Additionally, game theory-based approaches are employed to rank the top features, among which GCG time-domain features are found to be highly consistent with both the occurrence and severity level of AS. The proposed framework contributes to reliable, low-cost wearable cardiac monitoring due to accurate performance and usage of solitary inertial sensors.
Highlights
Recent research has shown promising results for the detection of aortic stenosis (AS) using cardiomechanical signals
5 frequency-domain heart rate variability (HRV) parameters were extracted for each channel axis (6 axes) per subject, amounting to 6Œ5=30 features
This paper reports on the design and development of a novel reference-less framework for the detection of aortic stenosis based on SCG and GCG morphological characteristics and HRV parameters
Summary
Recent research has shown promising results for the detection of aortic stenosis (AS) using cardiomechanical signals. The main goal of this paper is to address these shortcomings through a wearable inertial measurement unit (IMU), where the physical causes of AS are determined from IMU readings To this end, we develop a framework based on seismo-cardiogram (SCG) and gyro-cardiogram (GCG) morphologies, where highly-optimized algorithms are designed to extract features deemed potentially relevant to AS. Deploying machine learning (ML) algorithms, our research group has targeted AS detection based on the SCG/GCG technology[21,22] In these works, the time-frequency representation of all ten second SCG/GCG segments were generated, out of which features such as the energy of frequency bands were extracted. We propose a framework for the detection of AS by employing SCG and GCG time-domain and frequency-domain morphological features in two cases, i.e., subject-level and chunk-level analyses. The GCG time-domain features are proven to be excellent representatives of AS, which is a promising achievement for non-invasive monitoring of the cardiac system
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