Your search keyword '"Trobec R"' showing total 2 results

1. Medical-Grade ECG Sensor for Long-Term Monitoring.

Author

Rashkovska A, Depolli M, Tomašić I, Avbelj V, and Trobec R

Subjects

Animals, Biometric Identification instrumentation, Biometric Identification methods, Biosensing Techniques methods, Biosensing Techniques veterinary, Cardiotocography instrumentation, Electrocardiography methods, Electrocardiography veterinary, Electrodes veterinary, Equipment Design, Female, Horses, Humans, Mobile Applications, Monitoring, Ambulatory instrumentation, Monitoring, Ambulatory methods, Monitoring, Ambulatory veterinary, Monitoring, Physiologic methods, Monitoring, Physiologic veterinary, Predictive Value of Tests, Pregnancy, Prenatal Care methods, Signal Processing, Computer-Assisted instrumentation, Sports Medicine instrumentation, Sports Medicine methods, Telemetry instrumentation, Telemetry methods, Telemetry veterinary, Time Factors, Veterinary Medicine instrumentation, Veterinary Medicine methods, Wireless Technology instrumentation, Biosensing Techniques instrumentation, Electrocardiography instrumentation, Heart Rate physiology, Monitoring, Physiologic instrumentation, Telemedicine instrumentation, Telemedicine methods

Abstract

The recent trend in electrocardiogram (ECG) device development is towards wireless body sensors applied for patient monitoring. The ultimate goal is to develop a multi-functional body sensor that will provide synchronized vital bio-signs of the monitored user. In this paper, we present an ECG sensor for long-term monitoring, which measures the surface potential difference between proximal electrodes near the heart, called differential ECG lead or differential lead, in short. The sensor has been certified as a class IIa medical device and is available on the market under the trademark Savvy ECG. An improvement from the user's perspective-immediate access to the measured data-is also implemented into the design. With appropriate placement of the device on the chest, a very clear distinction of all electrocardiographic waves can be achieved, allowing for ECG recording of high quality, sufficient for medical analysis. Experimental results that elucidate the measurements from a differential lead regarding sensors' position, the impact of artifacts, and potential diagnostic value, are shown. We demonstrate the sensors' potential by presenting results from its various areas of application: medicine, sports, veterinary, and some new fields of investigation, like hearth rate variability biofeedback assessment and biometric authentication.

Published

2020

2. Two proximal skin electrodes--a respiration rate body sensor.

Author

Trobec R, Rashkovska A, and Avbelj V

Subjects

Electrocardiography instrumentation, Electrodes, Equipment Design, Galvanic Skin Response physiology, Humans, Skin Physiological Phenomena, Biosensing Techniques instrumentation, Monitoring, Physiologic instrumentation, Respiratory Rate physiology

Abstract

We propose a new body sensor for extracting the respiration rate based on the amplitude changes in the body surface potential differences between two proximal body electrodes. The sensor could be designed as a plaster-like reusable unit that can be easily fixed onto the surface of the body. It could be equipped either with a sufficiently large memory for storing the measured data or with a low-power radio system that can transmit the measured data to a gateway for further processing. We explore the influence of the sensor’s position on the quality of the extracted results using multi-channel ECG measurements and considering all the pairs of two neighboring electrodes as potential respiration-rate sensors. The analysis of the clinical measurements, which also include reference thermistor-based respiration signals, shows that the proposed approach is a viable option for monitoring the respiration frequency and for a rough classification of breathing types. The obtained results were evaluated on a wireless prototype of a respiration body sensor. We indicate the best positions for the respiration body sensor and prove that a single sensor for body surface potential difference on proximal skin electrodes can be used for combined measurements of respiratory and cardiac activities.

Published

2012