New neural model reveals how the brain adapts to new information

brain
Credit: Wikimedia Commons

Humans can perform a vast array of mental operations and adjust their behavioral responses based on external instructions and internal beliefs. For example, to tap your feet to a musical beat, your brain has to process the incoming sound and also use your internal knowledge of how the song goes.

MIT neuroscientists have now identified a strategy that the uses to rapidly select and flexibly perform different mental operations. To make this discovery, they applied a mathematical framework known as dynamical systems analysis to understand the logic that governs the evolution of neural activity across large populations of neurons.

"The brain can combine internal and external cues to perform novel computations on the fly," says Mehrdad Jazayeri, the Robert A. Swanson Career Development Professor of Life Sciences, a member of MIT's McGovern Institute for Brain Research, and the senior author of the study. "What makes this remarkable is that we can make adjustments to our behavior at a much faster time scale than the brain's hardware can change. As it turns out, the same hardware can assume many different states, and the brain uses instructions and beliefs to select between those states."

Previous work from Jazayeri's group has found that the brain can control when it will initiate a movement by altering the speed at which patterns of neural activity evolve over time. Here, they found that the brain controls this speed flexibly based on two factors: external sensory inputs and adjustment of internal states, which correspond to knowledge about the rules of the task being performed.

Evan Remington, a McGovern Institute postdoc, is the lead author of the paper, which appears in the June 6 edition of Neuron. Other authors are former postdoc Devika Narain and MIT graduate student Eghbal Hosseini.

Ready, set, go

Neuroscientists believe that "cognitive flexibility," or the ability to rapidly adapt to new information, resides in the brain's higher cortical areas, but little is known about how the brain achieves this kind of flexibility.

To understand the new findings, it is useful to think of how switches and dials can be used to change the output of an electrical circuit. For example, in an amplifier, a switch may select the sound source by controlling the input to the circuit, and a dial may adjust the volume by controlling internal parameters such as a variable resistance. The MIT team theorized that the brain similarly transforms instructions and beliefs to inputs and internal states that control the behavior of neural circuits.

To test this, the researchers recorded in the of animals trained to perform a flexible timing task called "ready, set, go." In this task, the animal sees two visual flashes—"ready" and "set"—that are separated by an interval anywhere between 0.5 and 1 second, and initiates a movement—"go"—some time after "set." The animal has to initiate the movement such that the "set-go" interval is either the same as or 1.5 times the "ready-set" interval. The instruction for whether to use a multiplier of 1 or 1.5 is provided in each trial.

Neural signals recorded during the "set-go" interval clearly carried information about both the multiplier and the measured length of the "ready-set" interval, but the nature of these representations seemed bewilderingly complex. To decode the logic behind these representations, the researchers used the dynamical systems analysis framework. This analysis is used in the study of a wide range of physical systems, from simple electrical circuits to space shuttles.

The application of this approach to neural data in the "ready, set, go" task enabled Jazayeri and his colleagues to discover how the brain adjusts the inputs to and initial conditions of frontal cortex to control movement times flexibly. A switch-like operation sets the input associated with the correct multiplier, and a dial-like operation adjusts the state of neurons based on the "ready-set" interval. These two complementary control strategies allow the same hardware to produce different behaviors.

"A bridge between behavior and neurobiology"

Many unanswered questions remain about how the brain achieves this flexibility, the researchers say. They are now trying to find out what part of the brain sends information about the multiplier to the frontal cortex, and they also hope to study what happens in these neurons as they first learn tasks that require them to respond flexibly.

"We haven't connected all the dots from behavioral flexibility to neurobiological details. But what we have done is to establish an algorithmic understanding based on the mathematics of dynamical systems that serves as a bridge between behavior and neurobiology," Jazayeri says.

The researchers also hope to explore whether this type of model could help to explain behavior of other parts of the brain that have to perform computations flexibly.


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Journal information: Neuron

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Jun 06, 2018
how does it work without logic

Jun 06, 2018
or what's the logic, cause and affect; first? chicken or the egg; show me tha' diff 'tween logical and no idea

require's min 300 samples;

if Health Care at least we'd have the data and if ya know how to quantify qualifications to be; then, using fuzzy logic,. 'cause it's fuzzy! but

Jun 06, 2018
ya got it backwards, results are defined with Formal Logic as well as your fuzzification, 2 unique concepts; one, precise; the other imprecise!

the study of imprecision with unreliable sampling is Easter Egging, Childish!

Jun 06, 2018
continuous data! computer analysis, data

Jun 06, 2018
adapts to what?

Jun 06, 2018
whose their prof. could he at least direct, duh, humans respond, look brain activity, what'cha have for lunch? wow, see that! on the fly!

heard from the audience,

"whose their case manager"

Jun 06, 2018
yeah, with health care, it'd be free! but, then you would have to allow logic. nooooo, not since Hypatia! Danger Will Robinson

Jun 06, 2018
"how does it work without logic"


Logic as a cognitive function is a learned concept. Brains don't automatically -do- logic.

But a brain can have functional processes which can be described as mechanisms of logic, similiar to digital logic circuits. A neural network can be trained to perform AND, OR, XOR... etc. functions.

In my understanding, brains operate on some sort of echo-replay structures where a pattern of input signals is encoded (learned) in the neural circuitry and amplified by repetition as long as the input pattern persists. This pattern serves as flag "A is happening", and internal states can also be encoded as similiar repeating patterns, "state B is active", and yet another neural circuit responds to the concurrent pattern A + B by repetition with "AB is happening" which triggers behaviour.

It's like one guy says "Marco", another says "Polo", and a third goes "Marco Polo!" and punches a button that does something.

Jun 07, 2018
A + B by repetition with "AB is happening" which triggers behaviour.

It's like one guy says "Marco", another says "Polo", and a third goes "Marco Polo!" and punches a button that does something.

OK, but correct, so what activity gave rise to the modus ponens and the necessity to remain within the universe of discourse; and how does this magic prepare the next, etc. or know that or does it?

Jun 07, 2018
Lets say that is known, communication shares what is known to one that does not know; scientific discovery! or "Mommy, I found an egg!" that you knew was there. In context, OK, science, noisy or simply nonsense! The above research is clearly in need of data and dichotomy and related to the physical, origin, path, i/o functional. Not informative, obvious! Why? Word knowledge? Experience? Age? Logic used? Relationship to flexibility and group behavior. An entire group born and fed nothing but logic, i.e. necessary and sufficient information as a minimum; with Grace, Wisdom, Human Passion to expand consciousness!

Jun 07, 2018
I challenge the entire scientific community, that my later statement is a requirement for an acceptable paper on human cognition or neural control. This should be obvious. ..or, do we destroy all 'correctness' and dig the oil anyway!

Dare you to define one community! "The Glass Bead Game" was a joke!

Jun 07, 2018
'cause we have no idea?

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