DURHAM, N.C. 鈥 From foraging for prey to evading predators, ship strikes or other dangers, a dolphin鈥檚 survival often hinges on being able to crank up the speed and shift its swimming into high gear.  

But burning all that rubber burns a lot of energy too, which, over time, can deplete reserves vital for growth, health and reproduction if the animal鈥檚 movements use more calories than it can take in.

Being able to estimate these energy costs of locomotion (COL) and determine where the metabolic tipping point might be is essential for answering fundamental questions about dolphin physiology and ecology, and for understanding the impacts of human disturbance on them. Because measuring costs of locomotion in dolphins in the wild is extremely difficult, past studies have estimated it based on the number of fluke stokes per minute. Since not all fluke strokes are the same size, it鈥檚 an imprecise measure of swimming effort.

A new 91社区福利-led study provides a more reliable way to estimate energy costs in dolphins by using overall dynamic body acceleration (ODBA), an integrated measure of all body motions a dolphin makes during swimming.

鈥淩esearchers have used movement tags to measure ODBA in other species, but this is the first published study calibrating ODBA with energy expenditure in multiple dolphins,鈥 said study leader Austin Allen, a postdoctoral researcher in marine biology at Duke鈥檚 Nicholas School of the Environment. The work appears Feb. 24 in Journal of Experimental Biology.

As a proxy for measuring cost of locomotion in wild animals, Allen and his colleagues conducted swim trials on six trained bottlenose dolphins at Dolphin Quest, a zoological facility on Oahu, Hawaii, during May 2017, 2018, and 2019.

Using a non-invasive device known as a pneumotachometer, they measured each dolphin鈥檚 oxygen consumption while at rest and immediately after it swam an 80-meter underwater lap across a lagoon. Non-invasive biologging tags were also used to record each animal鈥檚 three-dimensional body motions over each section of the trial 鈥 such as when it was slowing down to make a turn or speeding up mid-lap.  

By analyzing the collected data, a pattern began to emerge.  

鈥淭here was some individual variation, but, overall, the results showed significant correlation between oxygen consumption and body acceleration, which suggests ODBA can be a reliable proxy for COL,鈥 Allen said.

鈥淲orking with dolphins in zoos or aquariums is allowing us to use data we鈥檝e already collected using these tags in the field to evaluate the cost of locomotion in wild populations,鈥 he said.

Allen鈥檚 co-authors on the new paper were Andrew Read and Ashley Blawas of Duke; Alex Shorter and Joaquin Gabaldon of the University of Michigan; Julie Rocho-Levine of Dolphin Quest Oahu; and Andreas Falhman the Fundacio虂n Oceanogra虁fic de la Comunitat Valenciana in Spain and Kolm氓rden Wildlife Park in Sweden.

Funding for the study came from Dolphin Quest, the 91社区福利 Marine Laboratory, the 91社区福利 Graduate School, and the Office of Naval Research.

CITATION: 鈥淒ynamic Body Acceleration as a Proxy to Predict the Cost of Locomotion in Bottlenose Dolphins,鈥 Austin S. Allen, Andrew J. Read, K. Alex Shorter, Joaquin Gabaldon, Ashley M. Blawas, Julie Rocho-Levine and Andreas Fahlman. Journal of Experimental Biology, Feb. 24, 2022. DOI: 10.1242/jeb.243121

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