Bioelectrical impedance analysis

Bioelectrical impedance analysis (BIA) is a commonly used method for estimating body composition, in particular body fat and muscle mass. In BIA, a weak electric current flows through the body and the voltage is measured in order to calculate impedance (resistance) of the body. Most of our body water is stored in our muscle. Therefore, if a person is more muscular there is a high chance that the person will also have more body water, which leads to lower impedance. Since the advent of the first commercially available devices in the mid-1980s the method has become popular owing to its ease of use and portability of the equipment. It is familiar in the consumer market as a simple instrument for estimating body fat. BIA[1] actually determines the electrical impedance, or opposition to the flow of an electric current through body tissues which can then be used to estimate total body water (TBW), which can be used to estimate fat-free body mass and, by difference with body weight, body fat.

Accuracy

Many of the early research studies showed that BIA was quite variable and it was not regarded by many as providing an accurate measure of body composition. In recent years technological improvements have made BIA a bit more reliable and therefore more acceptable way of measuring body composition. Nevertheless, it is DEXA - and not BIA - that is regarded as a "gold standard" or reference method in body composition analysis.

Although the instruments are straightforward to use, careful attention to the method of use (as described by the manufacturer) should be given.

Simple devices to estimate body fat, often using BIA, are available to consumers as body fat meters. These instruments are generally regarded as being less accurate than those used clinically or in nutritional and medical practice. They tend to under-read body fat percentage.[2]

Dehydration is a recognized factor affecting BIA measurements as it causes an increase in the body's electrical resistance, so has been measured to cause a 5 kg underestimation of fat-free mass i.e. an overestimation of body fat.[3]

Body fat measurements are lower when measurements are taken shortly after consumption of a meal, causing a variation between highest and lowest readings of body fat percentage taken throughout the day of up to 4.2% of body fat.[4]

Moderate exercise before BIA measurements lead to an overestimation of fat-free mass and an underestimation of body fat percentage due to reduced impedance.[5] For example, moderate intensity exercise for 90–120 minutes before BIA measurements causes nearly a 12 kg overestimation of fat-free mass, i.e. body fat is significantly underestimated.[6] Therefore, it is recommended not to perform BIA for several hours after moderate or high intensity exercise.[7]

BIA is considered reasonably accurate for measuring groups, of limited accuracy for tracking body composition in an individual over a period of time, but is not considered sufficiently precise for recording of single measurements of individuals.[8][9]

Consumer grade devices for measuring BIA have not been found to be sufficiently accurate for single measurement use, and are better suited for use to measure changes in body composition over time for individuals.[10] Two-electrode foot-to-foot measurement is less accurate than 4-electrode (feet, hands) and eight-electrode measurement. Results for some four- and eight-electrode instruments tested found poor limits of agreement and in some cases systematic bias in estimation of visceral fat percentage, but good accuracy in the prediction of resting energy expenditure (REE) when compared with more accurate whole-body magnetic resonance imaging (MRI) and dual-energy X-ray absorptiometry (DEXA).[11]

The use of multiple frequencies in specific BIA devices that utilize eight electrodes has been found to have a 94% correlation method with DEXA when measuring body fat percentage. The correlation with DEXA is as high as 99% when measuring Lean Mass, if strict guidelines are adhered to.[12][13]

Historical background

Electrical properties of tissues have been described since 1872. These properties were further described for a wider range of frequencies on a larger range of tissues, including those that were damaged or undergoing change after death.

In 1962, Thomasset conducted the original studies using electrical impedance measurements as an index of total body water (TBW), using two subcutaneously inserted needles.[14]

In 1969, Hoffer concluded that a whole body impedance measurements could predict total body water. the equation (the squared value of height divided by impedance measurements of the right half of the body) showed a correlation coefficient of 0.92 with total body water. This equation Hoffer proved is known as the impedance index used in BIA.[15]

In 1983, Nyober validated the use of whole body electrical impedance to assess body composition.[16]

By the 1970s the foundations of BIA were established, including those that underpinned the relationships between the impedance and the body water content of the body. A variety of single frequency BIA analyzers then became commercially available, such as RJL Systems and its first commercialized impedance meter.

In the 1980, Lukaski, Segal, and other researchers discovered that the use of a single frequency (50 kHz) in BIA assumed the human body to be a single cylinder, which created many technical limitations in BIA. The use of a single frequency was inaccurate for populations that did not have the standard body type. To improve the accuracy of BIA, researchers created empirical equations using empirical data (gender, age, ethnicity) to predict a user's body composition.

In 1986, Lukaski published empirical equations using the impedance index, body weight, and reactance.[17]

In 1986, Kushner and Scholler published empirical equations using the impedance index, body weight, and gender.[18]

However, empirical equations were only useful in predicting the average population's body composition and was inaccurate for medical purposes for populations with diseases.[19] In 1992, Kushner proposed the use of multiple frequencies to increase the accuracy of BIA devices to measure the human body as 5 different cylinders (right arm, left arm, torso, right leg, left leg) instead of one. The use of multiple frequencies would also distinguish intracellular and extracellular water.[20]

By the 1990s, the market included several multi-frequency analyzers. The use of BIA as a bedside method has increased because the equipment is portable and safe, the procedure is simple and noninvasive, and the results are reproducible and rapidly obtained. More recently, segmental BIA has been developed to overcome inconsistencies between resistance (R) and body mass of the trunk.

In 1996, an eight-polar BIA device that did not utilize empirical equations was created and was found to "offer accurate estimates of TBW and ECW in women without the need of population-specific formulas."[21]

Measurement configuration

The impedance of cellular tissue can be modeled as a resistor (representing the extracellular path) in parallel with a resistor and capacitor in series (representing the intracellular path). This results in a change in impedance versus the frequency used in the measurement. The impedance measurement is generally measured from the wrist to the contralateral ankle and uses either two or four electrodes. A small current on the order of 1-10 μA is passed between two electrodes, and the voltage is measured between the same (for a two electrode configuration) or between the other two electrodes.[22]

See also

References
  1. Kyle UG, Bosaeus I, De Lorenzo AD, Deurenberg P, Elia M, Gómez JM, Heitmann BL, Kent-Smith L, Melchior JC, Pirlich M, Scharfetter H, Schols AM, Pichard C (October 2004). "Bioelectrical impedance analysis--part I: review of principles and methods". Clinical Nutrition. 23 (5): 1226–43. doi:10.1016/j.clnu.2004.06.004. PMID 15380917.
  2. "Body fat scales review and compare". 10 January 2010. Retrieved 11 January 2010.
  3. Lukaski HC, Bolonchuk WW, Hall CB, Siders WA (April 1986). "Validation of tetrapolar bioelectrical impedance method to assess human body composition". Journal of Applied Physiology. 60 (4): 1327–32. doi:10.1152/jappl.1986.60.4.1327. PMID 3700310.
  4. Slinde F, Rossander-Hulthén L (October 2001). "Bioelectrical impedance: effect of 3 identical meals on diurnal impedance variation and calculation of body composition". The American Journal of Clinical Nutrition. 74 (4): 474–8. doi:10.1093/ajcn/74.4.474. PMID 11566645. percentage of body fat varied by 8.8% from the highest to the lowest measurement in women and by 9.9% from the highest to the lowest measurement in men, The subject with the largest decrease in percentage of body fat had a decrease of 23%, from 17.9% body fat at baseline to 13.7% body fat at measurement no. 17.
  5. Kushner RF, Gudivaka R, Schoeller DA (September 1996). "Clinical characteristics influencing bioelectrical impedance analysis measurements". The American Journal of Clinical Nutrition. 64 (3 Suppl): 423S–427S. doi:10.1093/ajcn/64.3.423S. PMID 8780358.
  6. Abu Khaled M, McCutcheon MJ, Reddy S, Pearman PL, Hunter GR, Weinsier RL (May 1988). "Electrical impedance in assessing human body composition: the BIA method". The American Journal of Clinical Nutrition. 47 (5): 789–92. doi:10.1093/ajcn/47.5.789. PMID 3364394.
  7. Dehghan M, Merchant AT (September 2008). "Is bioelectrical impedance accurate for use in large epidemiological studies?". Nutrition Journal. 7: 26. doi:10.1186/1475-2891-7-26. PMC 2543039. PMID 18778488.
  8. Buchholz AC, Bartok C, Schoeller DA (October 2004). "The validity of bioelectrical impedance models in clinical populations". Nutrition in Clinical Practice. 19 (5): 433–46. doi:10.1177/0115426504019005433. PMID 16215137. In general, bioelectrical impedance technology may be acceptable for determining body composition of groups and for monitoring changes in body composition within individuals over time. Use of the technology to make single measurements in individual patients, however, is not recommended.
  9. Fosbøl, Marie Ø; Zerahn, Bo (2015). "Contemporary methods of body composition measurement". Clinical Physiology and Functional Imaging. 35 (2): 81–97. doi:10.1111/cpf.12152. ISSN 1475-097X. PMID 24735332.
  10. Peterson JT, Repovich WE, Parascand CR (2011). "Accuracy of Consumer Grade Bioelectrical Impedance Analysis Devices Compared to Air Displacement Plethysmography". Int J Exerc Sci. 4 (3): 176–184.
  11. Bosy-Westphal A, Later W, Hitze B, Sato T, Kossel E, Gluer CC, Heller M, Muller MJ (2008). "Accuracy of bioelectrical impedance consumer devices for measurement of body composition in comparison to whole body magnetic resonance imaging and dual X-ray absorptiometry". Obesity Facts. 1 (6): 319–24. doi:10.1159/000176061. PMC 6452160. PMID 20054195. One of the eight authors of this study is employed by body composition monitor manufacturer Omron, who financed the study.
  12. Miller, Ryan M.; Chambers, Tony L.; Burns, Stephen P. (October 2016). "Validating InBody 570 Multi-frequency Bioelectrical Impedance Analyzer versus DXA for Body Fat Percentage Analysis" (PDF). Journal of Exercise Physiology Online. 19: 71–78. ISSN 1097-9751.
  13. Ling, Carolina H.Y.; de Craen, Anton J.M.; Slagboom, Pieternella E.; Gunn, Dave A.; Stokkel, Marcel P.M.; Westendorp, Rudi G.J.; Maier, Andrea B. (October 2011). "Accuracy of direct segmental multi-frequency bioimpedance analysis in the assessment of total body and segmental body composition in middle-aged adult population". Clinical Nutrition. 30 (5): 610–615. doi:10.1016/j.clnu.2011.04.001. PMID 21555168.
  14. Thomasset, MA (15 July 1962). "Proprietes bioelectrique des tissuş, Mesures de l'impedance en clinique" [Bioelectric properties of tissue. Impedance measurement in clinical medicine. Significance of curves obtained]. Lyon Medical (in French). 94: 107–18. PMID 13920843.
  15. Hoffer, E C; Meador, C K; Simpson, D C (October 1969). "Correlation of whole-body impedance with total body water volume". Journal of Applied Physiology. 27 (4): 531–4. doi:10.1152/jappl.1969.27.4.531. PMID 4898406.
  16. Nyboer, J.; Liedtke, R.J.; Reid, K.A.; Gessert, W.A. (1983). Nontraumatic electrical detection of total body water and density in man. Proceeding of the 6th International Conference of Electrical Bioimpedance. pp. 381–4.
  17. Lukaski HC, Bolonchuk WW, Hall CB, Siders WA (April 1986). "Validation of tetrapolar bioelectrical impedance method to assess human body composition". Journal of Applied Physiology. 60 (4): 1327–32. doi:10.1152/jappl.1986.60.4.1327. PMID 3700310.
  18. Kushner RF, Schoeller DA (September 1986). "Estimation of total body water by bioelectrical impedance analysis". The American Journal of Clinical Nutrition. 44 (3): 417–24. doi:10.1093/ajcn/44.3.417. PMID 3529918.
  19. Dehghan M, Merchant AT (September 2008). "Is bioelectrical impedance accurate for use in large epidemiological studies?". Nutrition Journal. 7: 26. doi:10.1186/1475-2891-7-26. PMC 2543039. PMID 18778488.
  20. Kushner RF (April 1992). "Bioelectrical impedance analysis: a review of principles and applications". Journal of the American College of Nutrition. 11 (2): 199–209. PMID 1578098.
  21. Sartorio A, Malavolti M, Agosti F, Marinone PG, Caiti O, Battistini N, Bedogni G (February 2005). "Body water distribution in severe obesity and its assessment from eight-polar bioelectrical impedance analysis" (PDF). European Journal of Clinical Nutrition. 59 (2): 155–60. doi:10.1038/sj.ejcn.1602049. PMID 15340370.
  22. Foster, K R; Lukaski, H C (September 1996). "Whole-body impedance--what does it measure?". The American Journal of Clinical Nutrition. 64 (3): 388S–396S. doi:10.1093/ajcn/64.3.388S. PMID 8780354.

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