A Robust System for Longitudinal Knee Joint Edema and Blood Flow Assessment Based on Vector Bioimpedance Measurements

We present a robust vector bioimpedance measurement system for longitudinal knee joint health assessment, capable of acquiring high resolution static (slowly varying over the course of hours to days) and dynamic (rapidly varying on the order of milli-seconds) bioresistance and bioreactance signals....

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Bibliographic Details
Published in:IEEE transactions on biomedical circuits and systems 2016-06, Vol.10 (3), p.545-555
Main Authors: Hersek, Sinan, Toreyin, Hakan, Inan, Omer T.
Format: Article
Language:English
Subjects:
Algorithms
Bioimpedance
Biomedical measurement
Biosensing Techniques - instrumentation
Blood
Current measurement
Dynamical systems
Dynamics
Edema
Edema - physiopathology
Electric Impedance
Electrical bioimpedance
Feasibility studies
Hemodynamics
Humans
Impedance
Impedance measurement
impedance plethysmography
Injuries
joint physiology
Knee
Knee Joint - physiopathology
Knees
Surgical implants
wearable sensing
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Summary:We present a robust vector bioimpedance measurement system for longitudinal knee joint health assessment, capable of acquiring high resolution static (slowly varying over the course of hours to days) and dynamic (rapidly varying on the order of milli-seconds) bioresistance and bioreactance signals. Occupying an area of 78×90 mm 2 and consuming 0.25 W when supplied with ±5 V, the front-end achieves a dynamic range of 345 Ω and noise floor of 0.018 mΩ rms (resistive) and 0.055 mΩ rms (reactive) within a bandwidth of 0.1-20 Hz. A microcontroller allows real-time calibration to minimize errors due to environmental variability (e.g., temperature) that can be experienced outside of lab environments, and enables data storage on a micro secure digital card. The acquired signals are then processed using customized physiology-driven algorithms to extract musculoskeletal (edema) and cardiovascular (local blood volume pulse) features from the knee joint. In a feasibility study, we found statistically significant differences between the injured and contralateral static knee impedance measures for two subjects with recent unilateral knee injury compared to seven controls. Specifically, the impedance was lower for the injured knees, supporting the physiological expectations for increased edema and damaged cell membranes. In a second feasibility study, we demonstrate the sensitivity of the dynamic impedance measures with a cold-pressor test, with a 20 mΩ decrease in the pulsatile resistance associated with increased downstream peripheral vascular resistance. The proposed system will serve as a foundation for future efforts aimed at quantifying joint health status continuously during normal daily life.
ISSN:1932-4545
1940-9990
DOI:10.1109/TBCAS.2015.2487300