Posts Tagged ‘P-FIT’

So, What Makes a Brain Smart?

December 18, 2018

This post is based on “The Genius Within: Unlocking Your Brain’s Potential” by David Allen. He writes, “Rather than being product of a specific brain region, general intelligence seems to come from how effectively various brain regions can work together. To solve a problem, parts of the temporal and occipital lobes, at the base and back of the brain, first take the raw signals that flood in from the eyes and ears and process them. This information is fed into the parietal cortex, a broad arch of brain tissue just under the crown, where it is annotated and labelled with meaning. It then goes forward to regions of the prefrontal cortex, sitting behind the forehead, which manipulates it, packages it into possible ideas or solutions, and tests them. As one solution emerges as preferred, another part of this prefrontal cortex, the anterior cingulate, is recruited to block the other, incorrect, responses. This model of intelligence is called the Pareto-Frontal Integration Theory (P-FIT). The better this P-FIT circuit works, then the more general intelligence a person will have.

A visible difference is in the way clever people fuel their brain activity. Brain scans of the way glucose is used to release energy, another proxy of mental activity, show that energy demand increases when the brain is put to work. In people who score high on intelligence tests the required increase is smaller. High intelligence is linked to efficient glucose consumption. Those with less effective brains need to burn more glucose to fire more neurons to solve the same problem. This could indicate more intelligent people need to recruit fewer neurons and set into action a smaller number of brain circuits. Understand, that this is not biologically or genetically determined. When we learn, these circuits become more efficient. One way of looking at learning is that it exercises these brain circuits making them more efficient.

Analysis of brain circuitry is a new focus for neuroscience. Intelligence circuits, like all those in the brain, rely on two types of communication: chemical and electrical.

Neuroscientists have shown the way these brain circuits activate is highly personal. Although we all use the brain’s P—FIT system to reason and problem-solve, we each do it in a slightly different way, recruiting a different number of neurons in a different order. Neuroscientists from Yale University found patterns of brain activity so personal that they served as a kind of neuronal fingerprint. The scientists could pick out and identify people from a large group of volunteers by mapping and then looking for their tell-tale patterns of brain connections as they performed cognitive exercises.