Energy expenditure is a key variable in the study of ageing,and the fruit fly Drosophila melanogaster is a model organism that has been used to make step changes in our understanding of the ageing process.Standard methods for measurement of energy expenditure involve placing individuals in metabolic chambers where their oxygen consumption and CO:production can be quantified.These measurements require separating individuals from any social context,and may only poorly reflect the environment in which the animals normally live.The doubly-labeled water(DLW) method is an isotope-based technique for measuring energy expenditure which overcomes these problems.However,technical challenges mean that the smallest animals this method has been previously applied to weighed 50-200 mg.We overcame these technical challenges to measure energy demands in Drosophila weighing 0.78 mg.Mass-specific energy expenditure varied between 43 and 65 raW-g.These estimates are considerably higher than estimates using indirect calorimetry of Drosophila in small metabolic chambers(around 18 mW-g).The methodology we have established extends downwards by three orders of magnitude the size of animals that can be measured using DLW.This approach may be of considerable value in future ageing research attempting to understand the genetic and genomic basis of ageing. Energy expenditure is a key variable in the study of aging, and the fruit fly Drosophila melanogaster is a model organism that has been used to make step change in our understanding of the aging process. Contact methods for measurement of energy expenditure involved organisms in metabolic chambers where their oxygen consumption and CO: production can be quantified.These choices require separating individuals from any social context, and may only poorly reflect the environment in which the animals normally live. The doubly-labeled water (DLW) method is an isotope- based technique for measuring energy investment which overcomes these problems. However, technical challenges mean that the smallest animals this method has been previously applied to weighed 50-200 mg. We overcame these technical challenges to measure energy demands in Drosophila weighing 0.78 mg.Mass- specific energy expenditure varied between 43 and 65 raW-g.These estimates are relatively higher than estimates usi ng indirect calorimetry of Drosophila in small metabolic chambers (around 18 mW-g). The methodology we have established extends downwards by three orders of magnitude the size of animals that can be measured using DLW. This approach may be of comparable value in future aging research attempting to understand the genetic and genomic basis of aging.