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Differences in language circuits in the brain linked to dyslexia

Posted on Monday, Apr. 26, 2010 — 11:42 AM

Differences in language circuits in the brain linked to dyslexia

Children with dyslexia often struggle with reading, writing and spelling, despite getting an appropriate education and demonstrating intellectual ability in other areas. New neurological research from Vanderbilt University has found that these children’s difficulties with written language may be linked to structural differences within an important information highway in the brain known to play a role in oral language.

The findings were published in the June 2010 issue of Cortex.

Vanderbilt researchers Sheryl Rimrodt and Laurie Cutting and colleagues at Johns Hopkins University and Kennedy Krieger Institute used an emerging MRI technique, called diffusion tensor imaging (DTI), to discover evidence linking dyslexia to structural differences in an important bundle of white matter in the left-hemisphere language network. White matter is made up of fibers that can be thought of as the wiring that allows communication between brain cells; the left-hemisphere language network is made up of bundles of these fibers and contains branches that extend from the back of the brain (including vision cells) to the front parts that are responsible for articulation and speech.

“When you are reading, you are essentially saying things out loud in your head,” Cutting said. “If you have decreased white matter integrity in this area, the front and back part of your brain are not talking to one another. This would affect reading, because you need both to act as a cohesive unit.”

Rimrodt and Cutting used the DTI technique to map the course of an important white matter bundle in this network and discovered that it ran through a frontal brain region known to be less well-organized in the dyslexic brain. They also found that fibers in that frontal part of the tract were oriented differently in dyslexia.

“Finding a convergence of MRI evidence that goes beyond identifying a region of the brain that differs in dyslexia to linking that to an identifiable structure and beginning to explore physical characteristics of the region is very exciting,” Rimrodt said. “It brings us a little bit closer to understanding how dyslexia happens.”

Rimrodt is assistant professor of developmental medicine. Cutting is Patricia and Rodes Hart Chair at Vanderbilt’s Peabody College of education and human development and an investigator in the Vanderbilt Kennedy Center for Research on Human Development. The researchers completed the work at the Kennedy Krieger Institute with their colleagues there before moving to Vanderbilt.

The research was funded by the Johns Hopkins School of Medicine General Clinical Research Center, the Kennedy Krieger Institute’s Learning Disability Research Center and F.M. Kirby Research Center for Functional Brain Imaging, the National Institute for Neurological Disorders and the Eunice Kennedy Shriver National Institute of Child Health and Human Development.

For more information about Vanderbilt’s Peabody College, visit http://peabody.vanderbilt.edu .

Media contact: Melanie Moran, (615) 322-NEWS
melanie.moran@vanderbilt.edu




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