The feasibility of using compression bioimpedance measurements to quantify peripheral edema

Koziol, Leo; Pitre, John J.; Bull, Joseph L.; Dodde, Robert E.; Kruger, Grant H.; Vollmer, Alan; Weitzel, William F.

doi:10.5617/jeb.929

Cited by 2 publications

(2 citation statements)

References 37 publications

(51 reference statements)

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“…The resistive path created by the ICF in biological cells to an electric signal ( Figure 4a) is represented as a resistive element called ICF resistance (RICF). Alternatively, the capacitance [74] offered by the protein-lipid-protein structure [62][63] of the cell membrane is modeled as cell membrane capacitance (C CM ) [5][6] ( Figure 4a).…”

Section: Equivalent Circuit Modeling Of Biological Tissuesmentioning

confidence: 99%

“…The electrical behavior of the tissues is usually quantified by its complex bioelectrical impedance [1][2][3][4], which is the physical quantity that we reconstruct from the experimental measurements. Because bioelectrical impedance depends on the physiological and physiochemical status of the probed tissue and because it also varies from subject to subject and with changes in the health status of the tissue [5][6], such as inflammation, infection and disease, studying how a tissue responds to frequency can provide valuable information about its anatomy and physiology. Many researchers [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23] have investigated electrical bioimpedance as an effective, noninvasive method to probe the pathological status of biological tissues.…”

Section: Introductionmentioning

confidence: 99%

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A LabVIEW-based electrical bioimpedance spectroscopic data interpreter (LEBISDI) for biological tissue impedance analysis and equivalent circuit modelling

Bera

Nagaraju

Lubineau

2016

Journal of Electrical Bioimpedance

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Under an alternating electrical signal, biological tissues produce a complex electrical bioimpedance that is a function of tissue composition and applied signal frequencies. By studying the bioimpedance spectra of biological tissues over a wide range of frequencies, we can noninvasively probe the physiological properties of these tissues to detect possible pathological conditions. Electrical impedance spectroscopy (EIS) can provide the spectra that are needed to calculate impedance parameters within a wide range of frequencies. Before impedance parameters can be calculated and tissue information extracted, impedance spectra should be processed and analyzed by a dedicated software program. National Instruments (NI) Inc. offers LabVIEW, a fast, portable, robust, user-friendly platform for designing data-analyzing software. We developed a LabVIEW-based electrical bioimpedance spectroscopic data interpreter (LEBISDI) to analyze the electrical impedance spectra for tissue characterization in medical, biomedical and biological applications. Here, we test, calibrate and evaluate the performance of LEBISDI on the impedance data obtained from simulation studies as well as the practical EIS experimentations conducted on electronic circuit element combinations and the biological tissue samples. We analyze the Nyquist plots obtained from the EIS measurements and compare the equivalent circuit parameters calculated by LEBISDI with the corresponding original circuit parameters to assess the accuracy of the program developed. Calibration studies show that LEBISDI not only interpreted the simulated and circuit-element data accurately, but also successfully interpreted tissues impedance data and estimated the capacitive and resistive components produced by the compositions biological cells. Finally, LEBISDI efficiently calculated and analyzed variation in bioimpedance parameters of different tissue compositions, health and temperatures. LEBISDI can also be used for human tissue impedance analysis for electrical impedance-based tissue characterization, health analysis and disease diagnosis.

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Section: Equivalent Circuit Modeling Of Biological Tissuesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A LabVIEW-based electrical bioimpedance spectroscopic data interpreter (LEBISDI) for biological tissue impedance analysis and equivalent circuit modelling

Bera

Nagaraju

Lubineau

2016

Journal of Electrical Bioimpedance

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Feasibility research of non-invasive methods for interstitial fluid level measurement

Pockevicius

Cepenas

Miklusis

et al. 2017

BME

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This article explores a non-invasive method to determine interstitial fluid level and pressure in tissue. Interdigital electrodes were chosen by simulated results in software “Comsol multiphysis 4.3a”. Environment model similar to human body was created. Measurements were carried out at different situations which can occur during preoperative and afterwards surgery. Non-invasive method decreases possibility of infection and will improve recovery process in postoperative period.

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The feasibility of using compression bioimpedance measurements to quantify peripheral edema

Cited by 2 publications

References 37 publications

A LabVIEW-based electrical bioimpedance spectroscopic data interpreter (LEBISDI) for biological tissue impedance analysis and equivalent circuit modelling

A LabVIEW-based electrical bioimpedance spectroscopic data interpreter (LEBISDI) for biological tissue impedance analysis and equivalent circuit modelling

Feasibility research of non-invasive methods for interstitial fluid level measurement

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