Intelligent behavior requires strategic processing of numbers and abstract quantity information in accordance with internally maintained goals. For instance, we typically adopt a "less than" strategy when shopping for a product to pay the smallest amount of money. When searching for a job, on the other hand, our plan of action is "greater than", and we strive to earn the largest sum of money. In such pragmatic situations, our decisions on quantities are guided by mathematical rules applied to them. They constitute the foundation of mathematical operations and are thus taught to first-graders. Neurobiologists in the laboratory of Andreas Nieder at the University of TГјbingen now showed for the first time how brain cells process simple mathematical rules. The study is published online in the journal Proceedings of the National Academy of Sciences of the United States of America (PNAS) (January 18.-24. 2010).
Humans are unrivalled in their understanding of numbers and rules, but the foundations of such high-level skills can already be found in the animal kingdom. To get a glimpse of where and how brain cells master such complex tasks, scientists at the Institute of Neurobiology in TГјbingen trained rhesus monkeys to compare set sizes (numerosities) and to switch flexibly between two abstract mathematical rules. The "greater than" rule required the monkeys to release a lever if the first test display showed more dots than the sample display, whereas the "less than" rule required a lever release if the number of items in the test display was smaller compared to the first test display. The monkeys learned the quantitative "greater than/less than"-rule and were able to choose the smaller or greater set size relative to the sample numerosity, independently of the absolute numerosity of the displays. While the animals were performing this task, neurons recorded in the prefrontal cortex of the frontal lobe exhibited interesting activity. Irrespective of the absolute magnitude of the dot sets, the brain cells exclusively represented the mathematical rule at hand. Approximately one half of these neurons were only active whenever the animal followed the "greater than"-rule, whereas the other half preferred the "less than"-rule.
This new study provides valuable insight into the neurobiological foundations of highly abstract thinking that is necessary for mathematical operations. "First of all we want to understand how neurons process mathematical operations" Andreas Nieder explains. "At the same time, our investigations of the number sense are meaningful for assessing the very complex thinking processes that are necessary, for instance, when dealing with numbers." It is the cerebral cortex at the frontal pole of the brain that constitutes the brain's highest cognitive control center. This region of the brain also gives rise to mental activities that build personality. Damage to the frontal lobe (e.g. after injuries or stroke) disturb goal-directed logical thinking and reasoning. The new study provides important clues to how the healthy brain obeys abstract mathematical rules, which in turn will help to elucidate and treat related mental illnesses.
Source: Universitaet Tuebingen
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