Brain Power Goes Green
London, United Kingdom, October 16, 2009 --(PR.com)-- Our brains, it turns out, are eco-friendly. A study published in Science and reviewed by F1000 Biology members Venkatesh Murthy and Jakob Sorensen reveals that our brains have the amazing ability to be energy efficient.
Brain cells generate and propagate nerve impulses, or action potentials, by controlling the flow of positive sodium and potassium ions in and out of the cells. Re-establishing the ion equilibrium after an action potential requires energy.
The amount of energy needed for action potentials was previously estimated using a giant nerve cell from squid. Now, researchers at the Max-Planck Institute for Brain Research in Germany show that squid cell studies overestimated the amount of energy necessary to generate an action potential by almost a factor of four, suggesting human brains have the same potential to be energy efficient.
The researchers used a novel technique to record the voltage generated by nerve cells to “show that a rather subtle separation between the timing of sodium entry and potassium exit during action potentials can determine how much energy is expended to maintain the ionic gradients,” Murthy says.
Murthy goes on to say that “(these results) are important, not just for a basic understanding of brain metabolism, but also for interpreting signals detected by non-invasive brain imaging techniques.” Sorensen concludes that “the amazing thing is that we didn't realize the result a long time ago!”
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Notes to Editors
1. Venkatesh Murthy, Faculty Member for F1000 Biology, is Professor of Molecular and Cellular Biology at Harvard University http://f1000biology.com/about/biography/1467388697212944
2. Jakob Sorensen, Faculty Member for Neuroscience, is Professor of Neuroscience at the Department of Neuroscience and Pharmacology, University of Copenhagen, Denmark http://f1000biology.com/about/biography/9836154631995993
3. The full text of this article is available free for 90 days at http://www.f1000biology.com/article/t6pgnp2cs29949r/id/1164821.
4. An abstract for the paper, Energy-Efficient Action Potentials in Hippocampal Mossy Fibers by Alle, Roth and Geiger, is at
http://www.sciencemag.org/cgi/content/abstract/325/5946/1405
5. Please name Faculty of 1000 Biology in any story you write. If you are writing for the web, please link to the website.
6. Faculty of 1000, http://f1000.com, is a unique online service that helps you stay informed of high impact articles and access the opinions of global leaders in biology. Our distinguished international faculty selects and evaluates key articles across medicine, providing a rapidly updated, authoritative guide to the biomedical literature that matters.
7. Please contact Steve Pogonowski, PR Manager, for a complimentary journalist subscription to Faculty of 1000 http://f1000.com.
Brain cells generate and propagate nerve impulses, or action potentials, by controlling the flow of positive sodium and potassium ions in and out of the cells. Re-establishing the ion equilibrium after an action potential requires energy.
The amount of energy needed for action potentials was previously estimated using a giant nerve cell from squid. Now, researchers at the Max-Planck Institute for Brain Research in Germany show that squid cell studies overestimated the amount of energy necessary to generate an action potential by almost a factor of four, suggesting human brains have the same potential to be energy efficient.
The researchers used a novel technique to record the voltage generated by nerve cells to “show that a rather subtle separation between the timing of sodium entry and potassium exit during action potentials can determine how much energy is expended to maintain the ionic gradients,” Murthy says.
Murthy goes on to say that “(these results) are important, not just for a basic understanding of brain metabolism, but also for interpreting signals detected by non-invasive brain imaging techniques.” Sorensen concludes that “the amazing thing is that we didn't realize the result a long time ago!”
###
Media Contact
Steve Pogonowski
Public Relations Manager
Faculty of 1000
steve.pogonowski@f1000.com
http://blog.f1000.com
http://twitter.com/f1000
http://youtube.com/Facultyof1000
Notes to Editors
1. Venkatesh Murthy, Faculty Member for F1000 Biology, is Professor of Molecular and Cellular Biology at Harvard University http://f1000biology.com/about/biography/1467388697212944
2. Jakob Sorensen, Faculty Member for Neuroscience, is Professor of Neuroscience at the Department of Neuroscience and Pharmacology, University of Copenhagen, Denmark http://f1000biology.com/about/biography/9836154631995993
3. The full text of this article is available free for 90 days at http://www.f1000biology.com/article/t6pgnp2cs29949r/id/1164821.
4. An abstract for the paper, Energy-Efficient Action Potentials in Hippocampal Mossy Fibers by Alle, Roth and Geiger, is at
http://www.sciencemag.org/cgi/content/abstract/325/5946/1405
5. Please name Faculty of 1000 Biology in any story you write. If you are writing for the web, please link to the website.
6. Faculty of 1000, http://f1000.com, is a unique online service that helps you stay informed of high impact articles and access the opinions of global leaders in biology. Our distinguished international faculty selects and evaluates key articles across medicine, providing a rapidly updated, authoritative guide to the biomedical literature that matters.
7. Please contact Steve Pogonowski, PR Manager, for a complimentary journalist subscription to Faculty of 1000 http://f1000.com.
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