Body composition modeling in the calf using an equivalent circuit model of multi-frequency bioimpedance analysis

An equivalent electrical circuit model is used to describe the response of different tissue components in the calf to multi-frequency current. This model includes seven electrical components: skin resistance, contact capacitance, fat resistance, fat capacitance, extracellular resistance, intracellular resistance and cell membrane capacitance. Calf bioimpedance was measured on 30 pts using a multi-frequency bioimpedance device (Xitron 4200) with a range of frequency from 5 kHz to 1000 kHz. MRI was performed on each measured calf to provide body composition components: fat, muscle mass and bone. An equivalent circuit containing seven parameters (P1, P2, P3, P4, Q1, Q2, Q3) was constructed to represent the model. To identify the effect of different body compositions on their parameters, subjects were subgrouped according to (1) their range of fat mass: F1>0.4 kg, F2>0.4 & F2<0.25 kg and F3<0.25 kg; (2) their range of muscle mass: M1>1.2 kg, M2<1.2 & M2>1.0 kg and M3<0.25 kg. Curve fitting and simulation programs (Matlab Toolbox) were used to obtain the solution of the electrical equations. The results show a decrease in impedance with an increase in excitation frequency that differed among subjects with different fat contents. Simulation results show a high correlation (R2>0.98) between the bioimpedance measurements and the value calculated from the model. There are significant differences in parameters P1 (32.5+/-5.9 versus 26+/-4.4, p<0.05), P3 (-15,330+/-3352 versus -10,973+/-3448, p<0.05) and P4 (42,640 versus 24,191, p<0.05) between groups F1 and F3. P2 is significantly different (1045+/-442 versus 1407+/-349, p<0.05) between groups M1 and M2. The parameters that characterize the bioimpedance data depend upon many more tissue characteristics of electrical properties than those incorporated in current models and they are affected by aspects of body composition that are not considered in the fitting of bioimpedance data. This study shows a new model and methodology to analyze bioimpedance data and further work is likely to lead to much better understanding of electrical properties of body tissue.

[1]  Fansan Zhu,et al.  An electrical resistivity model of segmental body composition using bioimpedance analysis , 2003, Proceedings of the 25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (IEEE Cat. No.03CH37439).

[2]  M. P. Bolton,et al.  Sources of error in bioimpedance spectroscopy , 1998, Physiological measurement.

[3]  Y Schutz,et al.  Segmental body composition assessed by bioelectrical impedance analysis and DEXA in humans. , 1996, Journal of applied physiology.

[4]  C. Ronco,et al.  Methods and Reproducibility of Measurement of Resistivity in the Calf Using Regional Bioimpedance Analysis , 2003, Blood Purification.

[5]  H Scharfetter,et al.  A model of artefacts produced by stray capacitance during whole body or segmental bioimpedance spectroscopy. , 1998, Physiological measurement.

[6]  S. Salinari,et al.  New bioimpedance model accurately predicts lower limb muscle volume: validation by magnetic resonance imaging. , 2002, American journal of physiology. Endocrinology and metabolism.

[7]  G B Bradham,et al.  Segmental bioelectrical impedance analysis: theory and application of a new technique. , 1994, Journal of applied physiology.

[8]  L C Ward,et al.  Predicting composition of leg sections with anthropometry and bioelectrical impedance analysis, using magnetic resonance imaging as reference. , 1999, Clinical science.

[9]  JOHN W. Moore Membranes, ions, and impulses , 1976 .

[10]  M. Elia,et al.  Modeling Leg Sections by Bioelectrical Impedance Analysis, Dual‐Energy X‐ray Absorptiometry, and Anthropometry: Assessing Segmental Muscle Volume Using Magnetic Resonance Imaging as a Reference , 2000, Annals of the New York Academy of Sciences.

[11]  D. Schoeller,et al.  Estimation of segmental muscle volume by bioelectrical impedance spectroscopy. , 2004, Journal of applied physiology.

[12]  K J Ellis,et al.  Measurement of body water by multifrequency bioelectrical impedance spectroscopy in a multiethnic pediatric population. , 1999, The American journal of clinical nutrition.

[13]  Albert Lozano-Nieto,et al.  Comparison of segmental and global bioimpedance spectroscopy errors using generalizability theory. , 2002, Physiological measurement.

[14]  B. Brown,et al.  Determination of upper arm muscle and fat areas using electrical impedance measurements. , 1988, Clinical physics and physiological measurement : an official journal of the Hospital Physicists' Association, Deutsche Gesellschaft fur Medizinische Physik and the European Federation of Organisations for Medical Physics.

[15]  T Fukunaga,et al.  Validity of estimating limb muscle volume by bioelectrical impedance. , 2001, Journal of applied physiology.

[16]  Steven B. Heymsfield,et al.  Bioelectrical impedance analysis in body composition measurement: National Institutes of Health Technology Assessment Conference Statement. , 1996, The American journal of clinical nutrition.

[17]  N. Levin,et al.  Validation of changes in extracellular volume measured during hemodialysis using a segmental bioimpedance technique. , 1998, ASAIO journal.

[18]  W W Wong,et al.  Assessing total body and extracellular water from bioelectrical response spectroscopy. , 1997, Journal of applied physiology.

[19]  Michael J. Bolt,et al.  Single- and multifrequency models for bioelectrical impedance analysis of body water compartments. , 1999, Journal of applied physiology.

[20]  H Scharfetter,et al.  Assessing abdominal fatness with local bioimpedance analysis: basics and experimental findings , 2001, International Journal of Obesity.

[21]  K J Ellis,et al.  Human hydrometry: comparison of multifrequency bioelectrical impedance with 2H2O and bromine dilution. , 1998, Journal of applied physiology.

[22]  R. Ross,et al.  Does adipose tissue influence bioelectric impedance in obese men and women? , 1998, Journal of applied physiology.

[23]  R. Patterson,et al.  Fundamentals of impedance cardiography , 1989, IEEE Engineering in Medicine and Biology Magazine.

[24]  K. Cole,et al.  Dispersion and Absorption in Dielectrics I. Alternating Current Characteristics , 1941 .

[25]  J. Matthie,et al.  Predicting body cell mass with bioimpedance by using theoretical methods: a technological review. , 1997, Journal of applied physiology.

[26]  K R Foster,et al.  Whole-body impedance--what does it measure? , 1996, The American journal of clinical nutrition.

[27]  H. Schwan,et al.  A Dielectric Study of the Low-Conductance Surface Membrane in E. coli , 1956, Nature.

[28]  R. Patterson,et al.  Body fluid determinations using multiple impedance measurements , 1989, IEEE Engineering in Medicine and Biology Magazine.