| What's
New:
Researchers
find new learning strategy: A size of a mistake makes
no difference
By
Tony Fitzpatrick
Central
to being human is the ability to adapt: we learn from
our mistakes. Previous theories of learning have assumed
that the size of learning naturally scales with the
size of the mistake. But now WUSTL biomedical engineers
have shown that people can use alternative strategies:
Learning does not necessarily scale proportionally with
error.
In
so doing, Kurt Thoroughman, Ph.D., assistant professor
of biomedical engineering, and graduate student Michael
Fine have discovered a learning strategy they call categorical
adaptation, in which steps of learning are sensitive
to the direction of error, but do not scale proportionally
with the size of the error. Eventually, their findings
could have an impact in the rehabilitation of people
with neurological ailments — such as strokes — by making
use of different learning environments.
If
you make a movement error in one direction, it makes
sense that your next movement would correct toward the
opposite direction, in exact proportion to the error.
An example would be a pitcher correcting to the right,
after missing home plate to the left with a pitch.
"We
show that learning does not necessarily scale with error,"
Thoroughman said. "I think we have uncovered a
part of human adaptation that certainly doesn't do that.
We are not claiming that all previous theories are false
in the behaviors that were captured. It's just that
we have for the first time found a part of human adaptation
that clearly does not scale with the size of the error."
Thoroughman
is interested in how humans learn motor skills incrementally,
how information from a single movement can inform the
generation of the next movement. He and Fine asked volunteers
to make reaching movements while holding the end of
a robotic arm. Volunteers were trained for about 40
minutes a day for two days. On each day, subjects were
asked to make half-second, 10-centimeter reaching movements,
directed away from their bodies.
Subjects
learned the baseline task on the first day. On the second
day, Thoroughman and Fine tricked volunteers by having
the robotic arm push the human hand with a perturbing
pulse of force in 20 percent of movements. The pulse
pushed subjects from their normal trajectory, either
to the right or the left, with three different pulse
strengths. Thoroughman and Fine observed how the pulse
altered that trajectory and how subjects corrected,
or adapted, in the very next movement.
"The
pulse should induce an error in that movement that scales
with the size of the pulse," said Thoroughman,
who also has appointments in neurobiology and in physical
therapy. "And we did see that — big pulse, big
error; small pulse, small error. But then we expected,
just as previous theories would predict, that the adaptation
in the next movement would also scale with the size
of the force pulse.
"But
it didn't — the adaptation countered the direction of
the pulse but was flat with respect to the size of the
pulse."
The
results were published in the August issue of the Journal
of Neurophysiology.
Thoroughman
said the discovery raises interesting new questions
in motor learning and neurophysiology and eventually
could have an impact on physical therapy protocols.
"By
changing environments in a specific way and by not providing
the same environment all of the time, we can change
the way that people learn," he said. "We're
hopeful that this kind of technology can help in neurological
rehabilitation so that stroke patients, for instance,
could better relearn movements and reduce recovery time."
By
Tony Fitzpatrick
Central
to being human is the ability to adapt: we learn from
our mistakes. Previous theories of learning have assumed
that the size of learning naturally scales with the
size of the mistake. But now WUSTL biomedical engineers
have shown that people can use alternative strategies:
Learning does not necessarily scale proportionally with
error.
In
so doing, Kurt Thoroughman, Ph.D., assistant professor
of biomedical engineering, and graduate student Michael
Fine have discovered a learning strategy they call categorical
adaptation, in which steps of learning are sensitive
to the direction of error, but do not scale proportionally
with the size of the error. Eventually, their findings
could have an impact in the rehabilitation of people
with neurological ailments — such as strokes — by making
use of different learning environments.
If
you make a movement error in one direction, it makes
sense that your next movement would correct toward the
opposite direction, in exact proportion to the error.
An example would be a pitcher correcting to the right,
after missing home plate to the left with a pitch.
"We
show that learning does not necessarily scale with error,"
Thoroughman said. "I think we have uncovered a
part of human adaptation that certainly doesn't do that.
We are not claiming that all previous theories are false
in the behaviors that were captured. It's just that
we have for the first time found a part of human adaptation
that clearly does not scale with the size of the error."
Thoroughman
is interested in how humans learn motor skills incrementally,
how information from a single movement can inform the
generation of the next movement. He and Fine asked volunteers
to make reaching movements while holding the end of
a robotic arm. Volunteers were trained for about 40
minutes a day for two days. On each day, subjects were
asked to make half-second, 10-centimeter reaching movements,
directed away from their bodies.
Subjects
learned the baseline task on the first day. On the second
day, Thoroughman and Fine tricked volunteers by having
the robotic arm push the human hand with a perturbing
pulse of force in 20 percent of movements. The pulse
pushed subjects from their normal trajectory, either
to the right or the left, with three different pulse
strengths. Thoroughman and Fine observed how the pulse
altered that trajectory and how subjects corrected,
or adapted, in the very next movement.
"The
pulse should induce an error in that movement that scales
with the size of the pulse," said Thoroughman,
who also has appointments in neurobiology and in physical
therapy. "And we did see that — big pulse, big
error; small pulse, small error. But then we expected,
just as previous theories would predict, that the adaptation
in the next movement would also scale with the size
of the force pulse.
"But
it didn't — the adaptation countered the direction of
the pulse but was flat with respect to the size of the
pulse."
The
results were published in the August issue of the Journal
of Neurophysiology.
Thoroughman
said the discovery raises interesting new questions
in motor learning and neurophysiology and eventually
could have an impact on physical therapy protocols.
"By
changing environments in a specific way and by not providing
the same environment all of the time, we can change
the way that people learn," he said. "We're
hopeful that this kind of technology can help in neurological
rehabilitation so that stroke patients, for instance,
could better relearn movements and reduce recovery time."
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