Zapping the Brain Improves Math Skills

Zapping the brain with mild electric current may help improve math skills, a study finds.


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THE GIST

- A mild electrical current improves a person's ability to learn math skills.

- The effect lasts up to six months.

- The technique could help students learn other skills besides math as well.

It's barely enough to light a light bulb, but passing a very mild current of electricity through the brain can turn on a metaphorical light bulb in a person's brain.

Scientists from the University of Oxford have shown that they can improve a person's math abilities for up to six months. The research could help treat the nearly 20 percent of the population with moderate to severe dyscalculia (math disability), and could probably aid students in other subjects as well.

"I am certainly not advising people to go around giving themselves electric shocks," said Roi Cohen Kadosh, a scientist at the University of Oxford and a co-author of a new paper. "But we are extremely excited by the potential of our findings."

The UK scientists used a method known as transcranial direct current stimulation, or TDCS. This non-invasive technique involves passing electricity through the skull to increase or decrease the activity of neurons, usually for less than 15 minutes.

The amount of electricity is tiny, so small that most patients don't even know it is happening. In fact, many scientists were initially skeptical it would have any effect at all, said Jim Stinear, Director of the Neuralplasticity Laboratory at the Rehabilitation Institute of Chicago.

For this experiment the scientists directed the current into the brain's parietal lobe, which is involved in number processing. Instead of learning familiar Arabic numerals, however, the scientists had the participants learn a new series of symbols that represented numbers. Then, while their brains were being stimulated, they tested the participants ability to organize those numbers.

Patients who were on TDCS showed an improved ability to order the numbers.

The electric current makes it subtly easier or more difficult to stimulate a particular group of nerves, depending on the needs of the researchers and the patient. For example, if researchers want to make it easier for a patient to learn, then the nerves will fire more readily.

Other studies have shown that TDCS can improve a variety of brain functions, from pain management to rehabilitation after traumatic events, said Jim Stinear, Director of the Neuralplasticity Laboratory at the Rehabilitation Institute of Chicago. But what is "really remarkable," about this new research is how long the effects lasted: six months.

If TDCS can improve number processing in normal people, it should be able to improve number processing in people who have lower than normal number processing skills, and that's who the Oxford scientists will be testing next. TDCS should be able to improve other types of learning, such as language, as long as they are near the surface of the brain.

Structures like the hippocampus, which are buried under entire lobes of the brain, are likely beyond the reach of TDCS, said Cohen Kadosh.

While the Oxford scientists don't advocate plugging yourself into a wall socket, they do eventually hope to create a device that will provide an appropriate amount of electrical current to the brain, and have filed a patent on such a device.

Such a device won't instantly make you better at math, help you recover from a stroke faster, or manage pain better, said Stinear. Anybody using a device will still have to put in a significant amount of effort.

Drawing a parallel between a popular stimulant, Stinear said that coffee can help you wake up,but if you just sit on the couch you still aren't being productive. The same goes for TDCS.

"Electrical stimulation will most likely not turn you into Albert Einstein," said Kadosh, "but if we're successful it might be able to help some people to cope better with math."