Human
Brain Structure Reveals How We Process Numbers
Mark Hoffman
First Posted: Dec 30, 2013 04:39 PM EST
For a long time, scientists thought that everyone of us processed numbers predominantly in a spatial way, imagining numbers from left to right for example. But now a study by Florian Krause from the Donders Institute in Nijmegen demonstrates that this is not the case.
In his own words: ‘Our current study stresses the importance of non-spatial number representations. This is important since researchers in the field tend to focus mainly on spatial representations. Personally, I think that numbers are understood in terms of our body experiences. We use information about size in real life to understand number size in our heads.’ A non-spatial representation is possible, by comparing numbers to other magnitudes such as force or luminosity.
With MRI scans, Krause shows for the first time that these individual differences, processing numbers spatially or non-spatially, have a structural basis in the brain.
Different grey matter volumes
Florian Krause identified this predisposition to spatial or non-spatial number processing in MRI scans of test subjects. He discovered differences in grey matter volume, which contains the cell bodies of nerve cells, in two specific locations.
- Spatially oriented brains have an above-average grey matter volume in the right precuneus, a small area of the brain associated with processing visual-spatial information.
- Non-spatially oriented brains have more grey matter in the left angular gyrus, an area associated with semantic and conceptual processing.
Classifying numbers
The thirty people taking part in the study were put into an MRI scanner and were shown numbers between 1 and 9 (except 5). In two consecutive judgement tasks, they had to classify the presented digits as odd or even. Both tasks differed only in the required response: in the spatial task subjects had to click with their index finger or middle finger to classify the digits, and in the non-spatial task they applied either a small or a large force on a pressure sensor with their thumb.
Both tests were carried out using the right hand. Importantly, participants coupled the spatial response as well as the force response to the size of the presented number, as they responded faster with a left or soft press for small numbers and with a right or hard press for large numbers. Krause worked out those couplings for each subject, and compared the scores with the information from their brain scan.
Potential benefits for teaching maths
At present, maths is largely taught on the basis of a spatial number processing. ‘People with a non-spatial representation of numbers would probably benefit from a different approach to maths teaching’, says Krause. ‘It is possible to let pupils experience the size of numbers in a non-spatial way. This could involve expressing numbers with your body while doing simple arithmetics, for example.’ Krause is planning several new studies to explore the scientific basis of methods like these in more detail. -- Source: Donders Institute in Nijmegen
Reference:
Florian Krause et al., Different Brains Process Numbers Differently: Structural Bases of Individual Differences in Spatial and Nonspatial Number Representations, Journal of Cognitive Neuroscience, 2013, DOI: 10.1162/jocn_a_00518
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First Posted: Dec 30, 2013 04:39 PM EST
For a long time, scientists thought that everyone of us processed numbers predominantly in a spatial way, imagining numbers from left to right for example. But now a study by Florian Krause from the Donders Institute in Nijmegen demonstrates that this is not the case.
In his own words: ‘Our current study stresses the importance of non-spatial number representations. This is important since researchers in the field tend to focus mainly on spatial representations. Personally, I think that numbers are understood in terms of our body experiences. We use information about size in real life to understand number size in our heads.’ A non-spatial representation is possible, by comparing numbers to other magnitudes such as force or luminosity.
With MRI scans, Krause shows for the first time that these individual differences, processing numbers spatially or non-spatially, have a structural basis in the brain.
Different grey matter volumes
Florian Krause identified this predisposition to spatial or non-spatial number processing in MRI scans of test subjects. He discovered differences in grey matter volume, which contains the cell bodies of nerve cells, in two specific locations.
- Spatially oriented brains have an above-average grey matter volume in the right precuneus, a small area of the brain associated with processing visual-spatial information.
- Non-spatially oriented brains have more grey matter in the left angular gyrus, an area associated with semantic and conceptual processing.
Classifying numbers
The thirty people taking part in the study were put into an MRI scanner and were shown numbers between 1 and 9 (except 5). In two consecutive judgement tasks, they had to classify the presented digits as odd or even. Both tasks differed only in the required response: in the spatial task subjects had to click with their index finger or middle finger to classify the digits, and in the non-spatial task they applied either a small or a large force on a pressure sensor with their thumb.
Both tests were carried out using the right hand. Importantly, participants coupled the spatial response as well as the force response to the size of the presented number, as they responded faster with a left or soft press for small numbers and with a right or hard press for large numbers. Krause worked out those couplings for each subject, and compared the scores with the information from their brain scan.
Potential benefits for teaching maths
At present, maths is largely taught on the basis of a spatial number processing. ‘People with a non-spatial representation of numbers would probably benefit from a different approach to maths teaching’, says Krause. ‘It is possible to let pupils experience the size of numbers in a non-spatial way. This could involve expressing numbers with your body while doing simple arithmetics, for example.’ Krause is planning several new studies to explore the scientific basis of methods like these in more detail. -- Source: Donders Institute in Nijmegen
Reference:
Florian Krause et al., Different Brains Process Numbers Differently: Structural Bases of Individual Differences in Spatial and Nonspatial Number Representations, Journal of Cognitive Neuroscience, 2013, DOI: 10.1162/jocn_a_00518
See Now: NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone