Assessment by bioimpedance of forearm cell mass: a new approach to calibration

Assessment by bioimpedance of forearm cell mass: a new approach to calibration

Changes in skeletal muscle mass are involved in several important clinical disorders including sarcopenia and obesity. Unlike body fat, skeletal muscle is difficult to quantify in vivo, particularly without highly specialized equipment. The present study had a two-fold aim: to develop a regional (40...

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Bibliographic Details
Published in:European journal of clinical nutrition Vol. 56; no. 8; pp. 723 - 728
Main Authors: PIETROBELLI, A, NUNEZ, C, ZINGARETTI, G, BATTISTINI, N, MORINI, P, WANG, Z. M, YASUMURA, S, HEYMSFIELD, S. B
Format: Journal Article
Language:English
Published: Basingstoke Nature Publishing 01-08-2002
Nature Publishing Group
Subjects:
Adult
Arm
Arms
Biological and medical sciences
Body Composition
Body fat
Body Water
Calibration
Cells
Clinical nutrition
Coefficient of variation
Crystals
Electric Impedance
Electrical impedance
Electrical properties
Female
Forearm
Forearm - anatomy & histology
Fundamental and applied biological sciences. Psychology
Humans
Impedance
In vivo methods and tests
Indicator Dilution Techniques
Investigative techniques, diagnostic techniques (general aspects)
Male
Medical sciences
Metabolic diseases
Models, Biological
Multiple regression analysis
Muscle, Skeletal - cytology
Muscles
Muscular system
Musculoskeletal system
Obesity
Pathology. Cytology. Biochemistry. Spectrometry. Miscellaneous investigative techniques
Potassium Radioisotopes
Prediction models
Radiation effects
Regional development
Regression Analysis
Sarcopenia
Sensitivity and Specificity
Sex Characteristics
Sexual differentiation and maturation. Puberty. Climacterium
Skeletal muscle
Skeletal system
Vertebrates: reproduction
Human
Forearm
Lean body mass
Upper limb
Calibration
Measurement method
Impedance
Striated muscle
Body composition
Electrical impedance
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Summary:Changes in skeletal muscle mass are involved in several important clinical disorders including sarcopenia and obesity. Unlike body fat, skeletal muscle is difficult to quantify in vivo, particularly without highly specialized equipment. The present study had a two-fold aim: to develop a regional (40)K counter for non-invasively estimating cell mass in the arm, mainly skeletal muscle cell mass, without radiation exposure; and to test the hypothesis that cell mass in the arm is highly correlated with electrical impedance after adjusting for the arm's length. Forearm cell mass was estimated using a rectangular lead-shielded (40)K counter with 4-NaI crystals; impedance of the arm was measured at multiple frequencies using a segmental bioimpedance analysis (BIA) system. The system's within- and between-day coefficient of variation (CV) for (40)K-derived elemental potassium averaged 1.8+/-1.3 and 5.8+/-1.2%, respectively. The corresponding BIA system's CVs were 1.0+/-0.4 and 2.1+/-1.0%, respectively. Participants in the study were 15 healthy adults (eight females, seven males; age 39+/-2.8 y, BMI 22.9+/-4.5 kg/m(2)). The right arm's K (5.2+/-1.7 g) was highly correlated with length-adjusted impedance (r(2)=0.81, 0.82, and 0.83 for 5, 50 and 300 kHz, respectively; all P<0.001); multiple regression analysis showed no additional improvement by adding age or sex to the prediction models. These results demonstrate the feasibility of calibrating BIA-measured electrical properties of the arm against estimates of arm cell mass, mainly of skeletal muscle, obtained by regional (40)K counting. This simple and practical approach should facilitate the development of BIA-based regional cell mass prediction formulas
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ISSN:0954-3007
1476-5640
DOI:10.1038/sj.ejcn.1601384