The scientists say their study, published in Frontiers of Neuroscience, opens a pathway to studying bat brains in order to understand certain human language disorders and potentially even improving computer speech recognition.
“These findings upset the notion that only humans use different sides of their brains to distinguish different aspects of sound,” says the study’s senior author, Stuart Washington, PhD, a neuroscientist at Georgetown.
Washington says the findings of asymmetrical sound processing in both human and bat brains make evolutionary sense.
“The slower timing of the right hemisphere may allow us to identify who is speaking, to gauge their emotional state via tone-of-voice and to tease out pitch in music, which is thought to be important for getting groups of people to coordinate their activities and can ultimately lead to the formation of cultures,” Washington says. “It is therefore reasonable to understand why humans needed to evolve this asymmetry in their brains.”
For mustached bats, the need is even more compelling, he says. “Bats need to use the fast timing of the left hemisphere to distinguish communication sounds from each other, because their communication sounds have rapid changes in frequency. Otherwise, they cannot communicate with other bats, and bats are even more social than humans.
“The bats also need to use the slow timing of the right hemisphere to use sonar — which relies on detecting small changes in frequency — to track the velocity of the fast-moving insects they fly after and eat,” Washington says.
This asymmetric sampling in bats is sex-dependent (males have more asymmetry than females), which is also consistent with humans, Washington says. “Women tend to use both the left and right hemispheres for language, but men largely use just the left hemisphere. Since this asymmetric sound processing is the basis for left hemispheric specialization for language, it too is assumed to be more common in men than in women. Our results in bats may spur research to confirm that assumption in humans.”
One downside of having such asymmetrical sound processing is that it makes in-depth scientific studies of certain communication disorders, such as aphasia — a collection of language disorders —nearly impossible, he adds. “This problem is due to in-depth studies often requiring methods that can only be permitted in animals, but with our new understanding of bat sound processing, we may be able to do this research.”
Co-author John S. Tillinghast, PhD, of the department of mathematics and statistics at American University, concludes, “Our understanding of the time-frequency tradeoff is relatively new, but bat brains have been using it for millions of years.”
The study was supported by grants from the National Institute on Deafness and Communication Disorders and the Eunice Kennedy Shriver National Institute of Child Health and Human Development (HD046388, DC75763, DC02054 and DC008822). The authors report having no personal financial interests related to the study.
About Georgetown University Medical Center
Georgetown University Medical Center (GUMC) is an internationally recognized academic medical center with a three-part mission of research, teaching and patient care (through MedStar Health). GUMC’s mission is carried out with a strong emphasis on public service and a dedication to the Catholic, Jesuit principle of cura personalis — or “care of the whole person.” The Medical Center includes the School of Medicine and the School of Nursing & Health Studies, both nationally ranked; Georgetown Lombardi Comprehensive Cancer Center, designated as a comprehensive cancer center by the National Cancer Institute; and the Biomedical Graduate Research Organization, which accounts for the majority of externally funded research at GUMC including a Clinical and Translational Science Award from the National Institutes of Health.