202360 EHR525 Week 4b Motor Learning in Neurorehabiltation (1 Slide).pdf

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School of Allied Health, Exercise and Sports Sciences

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EHR525
EXERCISE FOR NEUROLOGICAL
& MENTAL HEALTH CONDITIONS
Motor Learning Concepts in
Neurorehabilitation
Presenter: Jack Cannon
School of Allied Health, Exercise and Sports Sciences

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WHAT WILL WE COVER:
■ Review key motor learning concepts.
■ Applications to neurorehabilitation.

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KEY MOTOR LEARNING CONCEPTS IN
NEUROREHABILITATION
■ Meaningfulness
□ Motivation/goals.

■ Timing
□ Distribution and frequency of
practise.

■ Repetition

■ Challenging
□ Functional difficulty.

■ Task specificity
□ Transfer to real life.
□ Practise variability.
□ Practise strategies.

□ Amount of practise.
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MEANINGFULLNESS/ MOTIVATION
■ Influences task attention and allocation of cognitive resources.
■ Motivation has a strong influence on successful rehabilitation.
■ Making the task seem important: Add meaning to exercises can
serve as an intrinsic motivator and enhance performance.
■ Goal-setting: Specific goals that are adjusted during practice lead
to improved learning compared to telling people to do their best.
■ Positive feedback: Can have a motivational effect that can
enhance learning.
Attention during exercise drives
neuroplasticity
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TIMING/ DISTRIBUTION AND FREQUENCY OF
PRACTISE
■ There is weak evidence that distributed practice might be better
for neurorehab than massed practice.
■ Benefits of rest periods: Frequent and longer rest periods
between repetitions (distributed practice) improve learning
compared to no rests (massed practice) in healthy subjects.
■ Trade-off: Massed practice enables increased amounts of training
per time but higher fatigue reducing motivation and increasing the
chance of injury.
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REPETITION/ AMOUNT OF PRACTISE
■ More practise is assumed to be better than less practise.
■ Increasing the amount of task repetitions results in greater cortical
changes and better functional improvement.
■ A minimal amount of repetitions might be required for recovery to
take place.
■ Power law of practice: Early in practice we experience a lot of
success but later in practice amount of improvement rate
decreases.
Practice makes perfect.
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TASK DIFFICULTY
■ Active generation of controlled movements are necessary for
effective motor learning.
■ Too much movement assistance can reduce physical effort and
therefore diminish skill learning.
■ Increasing task difficulty can lead to increased effort.
■ Clients should participate as actively as possible and be
cognitively challenged without being overwhelmed.
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TASK DIFFICULTY
■ Learning is optimal when difficulty
is out of “comfort zone”.

overchallenge

□ More complex tasks enhance shortand long-term neuronal changes.

■ Tasks should be adjusted for each
client for an optimal challenge.
■ The optimal learning difficulty is
not identical with the difficulty
under which performance is
greatest.
School of Allied Health, Exercise and Sports Sciences

“comfort zone”

optimal learning

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TASK SPECIFICITY
■ Clients should focus practice on activities essential in daily-life in a
setting which is as realistic as possible.
■ Task oriented training improves function and changes cortical
activation.
■ Practice with real objects under realistic situations significantly
improves transfer of learning.

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PRACTISE VARIABILITY
■ In general, practicing a task in variable settings or in a random
order improves learning and the ability to generalise.
■ Forgetting helps remembering.
■ Motor performance and motor learning are not the same.
■ Alternating randomly between training of multiple tasks (random
practice) seems to be more effective than constant practice
(blocked practice) in improving motor function.
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PRACTISE METHODS
■ Tasks should only be broken down into parts if composed of
distinct subparts or if the whole task proves to be too difficult.
■ Fractionalisation: E.g. Breaking bilateral tasks into two unilateral
parts.
■ Progressive part practice: E.g. Separate task into several
subparts.
■ Simplification: E.g. Reducing complexity of the task or parts of it.
■ Continuous tasks such as walking and fast, discrete tasks should
be learned as whole.
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SUMMARY
■ Principles of motor learning can help drive neuroplasticity and
recovery and support the development optimal training
environments.
■ Motivation is very important for effective therapy and can be
increased by making the training enjoyable, adequately
challenging, and goal-oriented.
■ Practice should be variable and include different tasks while motor
goals should be approached in small steps reinforcing client’s
progress.
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