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Press Release Is "THREE" more than "three"? Brain Research is Looking for Answers How do we process numbers? A new project from the Austrian Science Fund - FWF hopes to find the complex answer to this seemingly simple question by building on the recent findings of a team from Innsbruck. These show that while children and adults are equally good at processing numbers, they actually use different regions of the brain to do so. The new project is now comparing the cerebral activity of children with and without numeracy deficits in order to arrive at a deeper knowledge of children's numerical and spatial magnitude processing. What's more, 15 Smarties or 5 toy cars? Even if we restrict the concept of "more" to the number of objects, the brain requires a considerable degree of abstraction to answer this question, as the spatial dimensions of the objects must be isolated from their number. Though 15 Smarties may take up less space there are still "more" of them than 5 toy cars. Computation is a Team Sport According to information published by Dr. Kaufmann and her team, this
interplay changes as people grow up. Different areas of the brain are
activated in adults than in children, even when solving simple numerical
problems such as comparing one-digit numerals according to their numerical
magnitude. Adults primarily use posterior (parietal) brain areas, while
children rely predominantly on frontal regions. Dr. Kaufmann sees this
as clear evidence of children's significantly more complex information
processing activity - something which surprisingly does not affect the
speed or accuracy of their solutions. Commenting on her research, Dr. Kaufmann said: "We have known for some time that numeracy deficits are often associated with certain genetic disorders, such as Turner Syndrome, Fragile X Syndrome and Williams Syndrome. As those affected also have difficulty processing spatial magnitude, we can learn a lot about the links between these two abilities by carefully observing their cerebral activity." Functional magnetic resonance tomography is an important tool for the work of the group under Dr. Kaufmann. This method makes it possible to visualise the oxygen consumption of brain cells, thus giving a picture of the activities of different areas of the brain. Together with the analysis of behavioural data such as accuracy and speed in solving arithmetic problems, conclusions can also be drawn on the functional coordination of different brain regions. Dr. Kaufmann will carry out her comprehensive analysis by comparing children with and without numeracy deficits and will also differentiate between dyscalculia of genetic origin and isolated learning disorders without organic aetiology. The question posed by this new FWF project will contribute to a better understanding of the brain's functional organisation and the processes involved in number processing and calculation. The findings will also be a starting point for developing effective intervention methods for children with dyscalculia. Scientific Contact The Austrian Science Fund FWF Copy Editing & Distribution Vienna, 10th April 2006
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