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RESEARCH ARTICLE
Contents Vol 61(5)

Calibration of a rapid non-lethal method to measure energetic status of a freshwater fish (Murray cod, Maccullochella peelii peelii)

Nick S. Whiterod
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- Author Affiliations

Murray–Darling Freshwater Research Centre, PO Box 991, Wodonga, Vic. 3690, Australia and Charles Sturt University, School of Environmental Sciences, PO Box 789, Albury, NSW 2640, Australia. Email: N.Whiterod@latrobe.edu.au

Marine and Freshwater Research 61(5) 527-531 https://doi.org/10.1071/MF09105
Submitted: 12 May 2009  Accepted: 12 October 2009   Published: 28 May 2010

Abstract

The energetic status of freshwater fish provides a dynamic measure of their energy balance in response to the environment they occupy. Commercially available microwave technology (the ‘energy meter’) provides a rapid, non-lethal and inexpensive alternative to traditional laboratory methods for the determination of energy density. The energy meter requires species-specific confirmation of the water–lipid relationship, and comparison of energy meter readings with laboratory-determined estimates of the whole-body energy density. I explored the applicability of the energy meter to the threatened Murray cod (Maccullochella peelii peelii), using both hatchery and wild individuals. Although hatchery and wild fish varied in lipid content, water content and energy density, the parameter comparisons necessary to calibrate the energy meter were statistically consistent between both groups. Subsequently, a robust combined water–lipid relationship was identified for Murray cod, where energy density was strongly related to both water content and lipid content. Average energy meter readings were capable of providing a rapid, non-lethal and accurate assessment of Murray cod energy density. The successful calibration highlights the applicability of the energy meter to provide a dynamic measure of the energetic status of threatened freshwater fish throughout the world.

Keywords: bioenergetics modelling, energetic status, energy meter, Murray cod, proximate composition.


Acknowledgements

This study forms part of a PhD funded by the Mallee Catchment Management Authority (Mallee CMA), with support from the Murray–Darling Freshwater Research Centre (MDFRC). I thank Simon Noble (Brimin Lodge) and Peter van Lierop (Alexandra Fish Farm) for supplying hatchery fish, and Dave Pasztaleniec and Joy Sloan (DPI Victoria), and Sylvia Zukowski (MDFRC) for assistance with the sampling of wild fish. Thanks go to Neil Menz (National Measurement Institute) for proximate composition analysis and Brett Ingram (Victoria DPI), Giovanni Turchini (Deakin University) and David Fulton (Distell) for helpful advice. The manuscript was improved by valuable comment from Shaun Meredith (MDFRC), Paul Humphries (CSU), Colin Whiterod, John Koehn (Arthur Rylah Institute for Environmental Research), the editor, and two anonymous reviewers. Both field (Latrobe University, AEC07-22-M Research Permit and Victorian Fisheries Collection Permit, RP922) and laboratory (CSU, #08/093 Ethics Permit) components of this study were conducted under the conditions and requirements of relevant research permits.


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