Abstract
Monitoring pathological mechano-acoustic signals emanating from the lungs is critical for timely and cost-effective healthcare delivery. Adventitious lung sounds including crackles, wheezes, rhonchi, bronchial breath sounds, stridor or pleural rub and abnormal breathing patterns function as essential clinical biomarkers for the early identification, accurate diagnosis and monitoring of pulmonary disorders. Here, we present a wearable sensor module comprising of a hermetically encapsulated, high precision accelerometer contact microphone (ACM) which enables both episodic and longitudinal assessment of lung sounds, breathing patterns and respiratory rates using a single integrated sensor. This enhanced ACM sensor leverages a nano-gap transduction mechanism to achieve high sensitivity to weak high frequency vibrations occurring on the surface of the skin due to underlying lung pathologies. The performance of the ACM sensor was compared to recordings from a state-of-art digital stethoscope, and the efficacy of the developed system is demonstrated by conducting an exploratory research study aimed at recording pathological mechano-acoustic signals from hospitalized patients with a chronic obstructive pulmonary disease (COPD) exacerbation, pneumonia, and acute decompensated heart failure. This unobtrusive wearable system can enable both episodic and longitudinal evaluation of lung sounds that allow for the early detection and/or ongoing monitoring of pulmonary disease.
Highlights
Monitoring pathological mechano-acoustic signals emanating from the lungs is critical for timely and cost-effective healthcare delivery
“crackles” due to turbulent airflow arising from a bolus of gas passing through airways as they open and close intermittently can be suggestive of a developing pneumonia if acute or the presence of obstructive lung (COPD, bronchiectasis, asthma) if chronic
In patients with congestive heart failure, shallow breathing patterns are indicative of strenuous breathing, and can act as an early b iomarker[15,16]
Summary
Monitoring pathological mechano-acoustic signals emanating from the lungs is critical for timely and cost-effective healthcare delivery. The performance of the ACM sensor was compared to recordings from a state-ofart digital stethoscope, and the efficacy of the developed system is demonstrated by conducting an exploratory research study aimed at recording pathological mechano-acoustic signals from hospitalized patients with a chronic obstructive pulmonary disease (COPD) exacerbation, pneumonia, and acute decompensated heart failure This unobtrusive wearable system can enable both episodic and longitudinal evaluation of lung sounds that allow for the early detection and/or ongoing monitoring of pulmonary disease. Lung mechano-acoustic signals vary over a wide range of intensities and frequencies depending upon the origin of the pathology, and require extremely sensitive sensors that can non-invasively capture microvibrations occurring on the surface of the skin with high fidelity Packaging such sensors in a wearable platform can enable episodic and longitudinal monitoring of respiratory conditions and facilitate early detection and comprehensive diagnosis[7,20]. Miniature high precision accelerometer contact microphones (ACM) have been previously demonstrated to capture heart sounds, respiratory rate, lung sounds, and body motion of an individual simultaneously in a continuous and unobtrusive manner using a single integrated s ensor[24,25]
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