Indirect calorimetry


Indirect calorimetry calculates heat that living organisms produce by measuring either their production of carbon dioxide and nitrogen waste, or from their consumption of oxygen. Indirect calorimetry is the method by which the type and rate of substrate utilization, and energy metabolism are estimated in vivo starting from gas exchange measurements. This technique provides unique information, is noninvasive, and can be advantageously combined with other experimental methods to investigate numerous aspects of nutrient assimilation, thermogenesis, the energetics of physical exercise, and the pathogenesis of metabolic diseases.

Scientific background

Indirect calorimetry measures O2 consumption and CO2 production. On the assumption that all the oxygen is used to oxidize degradable fuels and all the CO2, thereby evolved is recovered, it is possible to calculate the total amount of energy produced. It should be clear that “energy production” means conversion of the chemical free-energy of nutrients into the chemical energy of ATP plus loss of some energy during the oxidation process.
Respiratory indirect calorimetry, or indirect calorimetry as it is known by most authors, is a noninvasive and highly accurate method of metabolic rate which has an error rate lower than 1%. It has high reproducibility and has been considered a gold standard method. This method allows estimating BEE and REE, and also allows for identification of energy substrates that are being predominantly metabolized by the body at a specific moment. It is based on the indirect measure of the heat produced by oxidation of macronutrients, which is estimated by monitoring oxygen consumption and carbon dioxide production for a certain period of time.
The calorimeter has a gas collector that adapts to the subject and a system that measures the volume and concentrations of O2 and CO2 minute by minute. Through a unidirectional valve, the calorimeter collects and quantifies the volume and concentration of O2 inspired and CO2 expired by the subject. After a volume is met, Resting Energy Expenditure is calculated by the Weir formula and results are displayed in software attached to the system. Another formula used is:
where RQ is the respiratory quotient, is, the heat released per litre of oxygen by the oxidation of carbohydrate, and is, the value for fat. This gives the same result as the Weir formula at RQ = 1, and almost the same value at RQ = 0.7.
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History

noted in 1780 that heat production can be predicted from oxygen consumption, using multiple regression. The Dynamic Energy Budget theory explains why this procedure is correct. Indirect calorimetry, as we know it, was developed at the turn of the century's as an application of thermodynamics to animal life. Although the development of indirect calorimetry dates back over 200 years, its greatest use has been in the last two decades with the development of total parenteral nutrition, interdisciplinary nutrition support teams, and the production of portable, reliable, relatively inexpensive calorimeters.

Collection methods

Four different gas collection and measurement techniques can be used to perform this test:
Indirect calorimetry provides at least two pieces of information: a measure of energy expenditure or 24-hour caloric requirements as reflected by the Resting Energy Expenditure and a measure of substrate utilization as reflected in the Respiratory Quotient. Knowledge of the many factors that affect these values has led to a much broader range of applications. Studies of indirect calorimetry over the past 20 years have led to the characterization of the hypermetabolic stress response to injury and the design of nutritional regimens whose substrates are most efficiently assimilated in different disease processes and organ failure states. Indirect calorimetry has influenced everyday practices of medical and surgical care, such as the warming of burn unit and surgical suites and the weaning of patients from ventilators.