SeisMote: A Multi-Sensor Wireless Platform for Cardiovascular Monitoring in Laboratory, Daily Life, and Telemedicine

This article presents a new wearable platform, SeisMote, for the monitoring of cardiovascular function in controlled conditions and daily life. It consists of a wireless network of sensorized nodes providing simultaneous multiple measures of electrocardiogram (ECG), acceleration, rotational velocity...

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Bibliographic Details
Published in:Sensors (Basel, Switzerland) Switzerland), 2020-01, Vol.20 (3), p.680
Main Authors: Di Rienzo, Marco, Rizzo, Giovannibattista, Işılay, Zeynep Melike, Lombardi, Prospero
Format: Article
Language:English
Subjects:
Acceleration
Activities of Daily Living
Batteries
Blood pressure
body sensor network
cardiac mechanics
Cardiovascular Diseases - diagnosis
Computer Communication Networks
Electric Power Supplies
electrocardiogram
Electrocardiography
Equipment Design
Heart Failure - rehabilitation
Hemodynamics
Humans
Investigations
Laboratories
Mechanics
Monitoring, Physiologic - instrumentation
Monitoring, Physiologic - methods
Nodes
photoplethysmogram
Photoplethysmography
Power supply
pulse transit time
Pulse Wave Analysis
Rehabilitation
Rotation
seismocardiogram
Sensors
Signal monitoring
Signal Processing, Computer-Assisted
Software
Telemedicine
Telemedicine - instrumentation
Telemedicine - methods
telerehabilitation
Time synchronization
Vibration
Wearable Electronic Devices
wearable sensor
Wireless networks
Wireless Technology - instrumentation
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Summary:This article presents a new wearable platform, SeisMote, for the monitoring of cardiovascular function in controlled conditions and daily life. It consists of a wireless network of sensorized nodes providing simultaneous multiple measures of electrocardiogram (ECG), acceleration, rotational velocity, and photoplethysmogram (PPG) from different body areas. A custom low-power transmission protocol was developed to allow the concomitant real-time monitoring of 32 signals (16 bit @200 Hz) from up to 12 nodes with a jitter in the among-node time synchronization lower than 0.2 ms. The BluetoothLE protocol may be used when only a single node is needed. Data can also be collected in the off-line mode. Seismocardiogram and pulse transit times can be derived from the collected data to obtain additional information on cardiac mechanics and vascular characteristics. The employment of the system in the field showed recordings without data gaps caused by transmission errors, and the duration of each battery charge exceeded 16 h. The system is currently used to investigate strategies of hemodynamic regulation in different vascular districts (through a multisite assessment of ECG and PPG) and to study the propagation of precordial vibrations along the thorax. The single-node version is presently exploited to monitor cardiac patients during telerehabilitation.
ISSN:1424-8220
1424-8220
DOI:10.3390/s20030680