Metabolic rate is a critical factor in animal biology and ecology, providing an objective measure that can be used in attributing a cost to different activities and to assessing what animals do against some optimal behaviour. Ideally, metabolic rate would be estimated directly by measuring heat output but, until recently, this has not been easily tractable with fishes so instead metabolic rate is usually estimated using indirect methods. In the laboratory, oxygen consumption rate is the indirect method most frequently used for estimating metabolic rate, but technical requirements preclude the measurement of either heat output or oxygen consumption rate in free-ranging fishes. There are other field methods for estimating metabolic rate that can be used with mammals and birds but, again, these cannot be used with fishes. Here, the use of electronic devices that record body acceleration in three dimensions (accelerometry) is considered. Accelerometry is a comparatively new telemetric method for assessing energy metabolism in animals. Correlations between dynamic body acceleration (DBA) and oxygen consumption rate demonstrate that this will be a useful proxy for estimating activity-specific energy expenditure from fishes in mesocosm or field studies over extended periods where other methods (e.g. oxygen consumption rate) are not feasible. DBA therefore has potential as a valuable tool for attributing cost to different activities. This could help in gaining a full picture of how fishes make energy-based trade-offs between different levels of activity when faced with conflicting or competing demands arising from increased and combined environmental stressors.
METABOLIC RATE AS A UNIVERSAL CURRENCYMetabolic rate is widely regarded as a universal currency in animal biology and ecology, providing an objective measure that can be used in attributing a cost to different activities and specifically helping to assess what animals do against some optimal behaviour (i.e. a behaviour that maximizes one or more biological characteristics such as growth or reproductive success). In their seminal paper, Brown et al. (2004) proposed that, 'Metabolism provides a basis for using first principles of physics, chemistry, and biology to link the biology of individual organisms to the ecology of populations, †Author to whom correspondence should be addressed. Tel.: +44 1502 524353; email: Julian.metcalfe@ cefas.co.uk This article is published with the permission of the Controller of HMSO and the Queen's Printer for Scotland.1