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First published online July 20, 2006
Journal of Experimental Biology 209, iii (2006)
Copyright © 2006 The Company of Biologists Limited
doi: 10.1242/jeb.02428

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Inside JEB

VISUALISING A HALF SLEEPING BRAIN

Kathryn Phillips

kathryn{at}biologists.com

The brains of all mammals are divided into two separate, but connected hemispheres that function together. However, dolphin brain hemispheres appear capable of operating independently; as well as moving each eye separately, each half of the brain can generate slow-wave-sleep brain patterns independently of the other. Little else was known about the mammal's remarkable ability to apparently send one half of its brain to sleep while the other half remains conscious until Sam Ridgway and his colleagues in San Diego, California, embarked on a series of groundbreaking brain imaging experiments to find out how a dolphin's half-sleeping brain functions (p. 2902).

After months of training (learning to slide out of the water and listening to recordings of the noisy scanner), 3 dolphins were ready to have their brains imaged. Having injected the animals with materials to visualise blood flow and sites of metabolic activity, the team induced slow-wave-sleep in one brain hemisphere with diazepam before beginning the scanning process. Fortunately the animals were content to lie on the specially constructed scanner table, accompanied by a trainer, for 37 min while the scans were completed, and then they were returned to the water quickly. Reconstructing images of the animals' brains, the team could clearly see that the blood flow to the `sleeping' half was reduced significantly, and this was also accompanied by a significant reduction in the `sleeping' half's metabolic activity.

So why are dolphins capable of shutting one half of their brain down while the other remains active? Ridgway and his colleagues suggest that this could be an energy saving mechanism for deep diving dolphins, allowing the mammal to conserve precious oxygen supplies while foraging at depth. They add that sending half of the brain to sleep while the other is conscious may also allow the animal to remain aware and keep swimming while sleeping.

References

Ridgway, S., Houser, D., Finneran, J., Carder, D., Keogh, M., Van Bonn, W., Smith, C., Scadeng, M., Dubowitz, D., Mattrey, R. and Hoh, C. (2006). Functional imaging of dolphin brain metabolism and blood flow. J. Exp. Biol. 209,2902 -2910.[Abstract/Free Full Text]

Related articles in JEB:

Functional imaging of dolphin brain metabolism and blood flow

Sam Ridgway, Dorian Houser, James Finneran, Don Carder, Mandy Keogh, William Van Bonn, Cynthia Smith, Miriam Scadeng, David Dubowitz, Robert Mattrey, and Carl Hoh
JEB 2006 209: 2902-2910. [Abstract] [Full Text]  

This Article Full Text (PDF) Alert me when this article is cited Alert me if a correction is posted Services Email this article to a friend Related articles in JEB Similar articles in this journal Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via Google Scholar Google Scholar Articles by Phillips, K. Search for Related Content PubMed Articles by Phillips, K.