Critical illness affects body composition profoundly, especially body cell mass (BCM). BCM loss reflects lean tissue wasting and could be a nutritional marker in critically ill patients. However, BCM assessment with usual isotopic or tracer methods is impractical in intensive care units (ICUs). We aimed to modelize the BCM of critically ill patients using variables available at bedside. Fat-free mass (FFM), bone mineral (Mo), and extracellular water (ECW) of 49 critically ill patients were measured prospectively by dual-energy X-ray absorptiometry and multifrequency bioimpedance. BCM was estimated according to the four-compartment cellular level: BCM ϭ FFM Ϫ (ECW/0.98) Ϫ (0.73 ϫ Mo). Variables that might influence the BCM were assessed, and multivariable analysis using fractional polynomials was conducted to determine the relations between BCM and these data. Bootstrap resampling was then used to estimate the most stable model predicting BCM. BCM was 22.7 Ϯ 5.4 kg. The most frequent model included height (cm), leg circumference (cm), weight shift (⌬) between ICU admission and body composition assessment (kg), and trunk length (cm) as a linear function: BCM (kg) ϭ 0.266 ϫ height ϩ 0.287 ϫ leg circumference ϩ 0.305 ϫ ⌬weight Ϫ 0.406 ϫ trunk length Ϫ 13.52. The fraction of variance explained by this model (adjusted r 2 ) was 46%. Including bioelectrical impedance analysis variables in the model did not improve BCM prediction. In summary, our results suggest that BCM can be estimated at bedside, with an error lower than Ϯ20% in 90% subjects, on the basis of static (height, trunk length), less stable (leg circumference), and dynamic biometric variables (⌬weight) for critically ill patients. critical illness; body composition; bioelectrical impedance; dualenergy X-ray absorptiometry OTHER THAN THE BASIC TWO-COMPARTMENT [fat and fat-free mass (FFM)] model, the composition of the human body can be described by multicompartment models from the atomic to the functional level (11). Body cell mass (BCM) is the metabolically active compartment of FFM that reflects the body's cellular components involved in oxygen consumption, carbon dioxide production, and resting metabolism (11,19,20). Thus, physiological modeling of body composition at the cellular level can be separated into different compartments associated with functions: energy store in fat mass (FM), energy expenditure and metabolism by BCM, exchanges in extracellular water (ECW), and support by bone mineral (Mo).In healthy adults, homeostasis maintains a stable body composition. Conversely, body composition is profoundly modified in acutely or chronically ill patients (28). BCM is altered by changes of nutritional status and the catabolic effects of disease (11,39,47). In this context, BCM could be a marker of malnutrition or prognosis of chronically or critically ill patients (14, 37). BCM is associated with resting energy expenditure (REE), and it has been shown that assessment of energy balance may have particular significance for the nutritional management of the...
