Motor Control (MC 2) Past Paper (PDF)

Summary

This document contains lecture notes on Motor Control (MC 2). It discusses acquiring information through sensory proprioception, and includes details on sensory receptors, proprioception, and the assessment.

Full Transcript

EXSS3062
Motor Control & Learning
Motor Control (MC 2)

Acquiring Information:
Sensory Proprioception

Proprioception: A key role in coordinating,
guiding/adjusting movement, & producing
skilled performance.

“The experience of our world, our reality, comes from
sensation!”

Prof. Stephen Cobley
Faculty of Medicine & Health Sciences
The University of Sydney Page 1
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Assessment 1 - Lecture Quiz (Week 2)

- Week 2 lecture quiz (on Canvas) available at 10 am post-lecture session.
- Closes at 8 am pre-lecture of Week 3 (i.e., one week to complete).
- 3 Motor Control & 3 Motor Learning MCQs.
- MCQs are aligned to Learning Outcomes within respective lectures.
- Two attempts per quiz, with highest score recorded.
- Correct answers will become visible after the quiz has closed.

5% mark = Weighted average across quizzes ( X / 30 points possible, 6 per quiz).

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Motor Control (MC 2)
Unit Learning Outcome
LO 1 Explain the structure & function of sensory receptors as they
relate to the control of voluntary & involuntary movement

Lecture Learning Outcomes
1) Understand movement control is dependent on sensory afferent information.
(& then integration with efferent neural activity).

2) Identify sensory sources of afferent information associated with movement.
(i.e., receptors; information transduced to neural signalling; sensory information perceived).

2a) Understand how Cutaneous receptors (sense of touch) operate to inform motor control.
2b) Understand how Muscle spindles (muscle positioning – proprioception) operate to
inform motor control.
MC 2
Sensory Input: Sensory proprioception
Recommended reading

Magill, R. & Anderson, D. (2020). Motor Learning & Control:
Concepts & applications (12th Ed). New York: McGraw-Hill.
- particular sections in Chapter 6.

Magill, R. & Anderson, D. (2016). Motor Learning & Control:
Concepts & applications (11th Ed). New York: McGraw-Hill.
- particular sections in Chapter 6.

See Canvas Reading List
1) Motor Control - Voluntary movement -
Efferent & Afferent (sensory) neural activity is critical.

Kolb & Whishaw (2012)
 1) Motor Control – Afferent (sensory) systems
Central Nervous System
Efference Copy
Perception, Cognition,
Decision-making, Movement Neural commands
planning

Afferent (sensory) systems Efferent Motor System

Proprioception
(muscle spindles;
GTO’s; joint receptors)

Cutaneous receptors

Vision

Vestibular apparatus

Biomechanical constraints
of movement

Muscular movement
stimulation
1) Sensory (Afferent) Information

How do we know sensory (afferent) receptors
are important in movement control?
A case to answer the question:

The man who lost his body (i.e., sensory input)

https://www.dailymotion.com/video/x12647t

Full documentary available in sections on You Tube!

Showcases what happens when you lose your sense of proprioception
- Sensory (afferent nerve) information.
1) Sensory (Afferent) Information
Importance of Proprioception in Motor Control.
1) Sensory (Afferent) Information

Sensory poly-neuropathy =

Degeneration of large afferent fibres carrying proprioceptive & tactile inputs
(i.e., receptors in muscles [spindles, Golgi tendon organs, joint] & tactile/cutaneous receptors).

Afferent neural information returning to the CNS is inhibited.
Efferent motor pathways are intact - strength is normal.
Pain & temperature sensation preserved.
No stretch-reflex (e.g., knee jerk)
Unable to:
- grasp a pen & write
- fasten buttons
- hold a cup in one hand
- unable to detect errors in movement

- In rare cases where individuals re-learn, all movements have to be pre-planned & prepared
(no sensory feedback or use visual feedback to guide movement)
1) Sensory (Afferent) Information
Observations of sensory poly-neuropathy Rothwell (1982)

Normative individual Sensory neuropathy patient.
- Movement sequence with eyes closed. - Movement sequence with eyes closed.
- Initial accuracy through movement - Movement error as task is continued or
planning & sensory feedback preserved. repeated over time.
“Can move the fingers but can’t feel it!”
1) Sensory (Afferent) Information

Sensory poly-neuropathy:

Tells us that sensory system (proprioception)
is vital for movement control.

In deafferented patients, CNS cannot construct accurate internal understanding
of what is happening to limbs & body position during movement.

Hence, starting points & changes in movement are unknown
(i.e., not consciously aware of change).

Sensory systems help generate internal representations (models) of the body &
outside world. Condition invokes reliance on intact senses (i.e., vision)
(e.g., watch feet when walking).

Substantial training (years) needed to re-gain bodily control via alternate senses.
2) Identify sensory sources
Core Facts: Sensory (afferent) system

The sensory system has 5 common properties when stimulated:

(i) Modalities (vision, touch etc) & their receptors.
(ii) Location (where it is on/in body)
(iii) Intensity (how many/much?)
(iv) Timing (when & how long?)
(v) Transduction (i.e., conversion of a signal to neural signalling for CNS)

Together, the 5 properties link a stimulus with the yielding of sensation.
All sensory systems convey similar types of neural information & may account for why they
all have similar organization.
 2a) Sensory System - Proprioception - Touch Modality

Micro-
neurography
monitoring
Fast Adapting Slow Adapting Fast Adapting Slow Adapting
Type 1 Type 1 Type 2 Type 2
2a) Sensory System - Proprioception - Touch Modality
2a) Sensory System - Proprioception - Touch Modality

(ii) Touch - Location

Sensitivity in precise locations is important in many situations where actions
are guided by spatial information (fingers, toes, mouth).
Spatial distribution & density of cutaneous receptors conveys specific
information about location of a stimulus on the body.
Density of receptors determines how well sensory system can resolve the
detail of stimuli.
Two-point discrimination testing can determine how sensitive - densely
populated - receptors are across the body.
2a) Sensory System - Proprioception - Touch Modality

(ii & iii) Location & Intensity (Sensitivity)

Two-Point Discrimination test

Different distance points
for different sections of the
body.

Distance until 2-point detection
lost.
2a) Sensory System - Proprioception - Touch Modality
(iii, iv, v) Intensity, Timing & Transduction
Are quantitative relationships between sensory stimuli & psychological sensation.
How physical stimuli correlate with psychological sensations = Psychophysics.

Lawful relationship permits
accuracy in perceptions of
stimulus.

You are interpreting info from
your sensory nerves.

Left chart = Degree of skin Right chart = Perceived
indentation & afferent nerve firing intensity of sensation with
rate. skin stimulus intensity
 2a) Sensory System - Proprioception - Touch Modality
(iii, iv, v) Intensity, Timing & Transduction
Skin Indentation: Different receptors have different sensitivities

Static Dynamic
Pressure Change
Meissner’s
Merkel Cells
Corpuscle

Meissner’s &
Merkel Cells +
Pacinian
Ruffini Endings
Corpuscle

Slow = mechanical static pressure Rapidly = mechanical
fixed indentation dynamic indentation change.

Different receptors stimulated at different points with different frequencies that
provides info on when, degree, & change in skin indentation over time.
 2a) Sensory System - Proprioception - Touch Modality
How do we know the properties of different objects or surfaces?

Identification via texture =
rubbing surface of skin.

Probe onto skin

Sideways movement

Fast-Adapting Type 1
Receptor Response (i.e.,
Meissner’s corpuscle)

Differences in neural
firing patterns lead to an
association of different
objects & surfaces.
2b) Sensory System - Proprioception - Muscle Receptors
2 Types - Muscle Spindles & Golgi Tendon Organs
(i) Modality = Muscle Spindles

https://www.youtube.com/watch?v=F0dp7A4IKyY
2b) Sensory System - Proprioception - Muscle receptors
2 Types - Muscle Spindles & Golgi Tendon Organs

(i) Modality = Muscle Spindles

Muscle spindles are responsive to stretch
(lengthening & partial shortening)

Detects:
- Rate of change (speed) in muscle.
- Absolute muscle fiber length

Different modality but similar structural properties:
(ii) Location
(iii) Intensity
(iv) Timing
(v) Transduction
Targeted at gathering similar sensory information
Magill & Anderson (2014)
2b) Sensory System - Proprioception - Muscle Spindles

(ii) Non-uniform distribution (Location)

Significantly larger spindle numbers (3000+ est.) in
muscles associated with head & neck movement.

Significantly larger spindle numbers (4000+ est.)
associated with muscles in trunk & hip movement.

Large numbers of spindles in muscles spanning
across joint areas (e.g., shoulder; 1300+ est. )

Lower number of spindles in smaller size muscle fibres
of simpler movement forms (e.g., 3rd & 4th finger = 50-60
est.)

Helps generate substantial sensory information about
general & specific muscle positions.
2b) Sensory System - Proprioception - Muscle Spindles
(iii & iv) Intensity & timing (sensitivity change)

Static & dynamic activation of
muscle (efferent nerves)
sensitises static & dynamic
muscle spindles.

Muscle spindles also have
adjustable sensitivity due to
fusimotor drive (i.e., efferent
nerves changing muscle fibre
length).

Means static or dynamic
spindle sensitivity is adjusted
according to the task
performed & degree of need
for movement control.
 2b) Sensory System - Proprioception - Muscle Spindles
(iii & iv) Intensity & timing (sensitivity change)
Recordings of muscle spindle types in a cat according to movement type.

Sensitivity of
spindle type
adjusted according
to movement type

No movement or
fixed position =
static.

Imposed
movement =
dynamic

Dangerous
Movement = Both
(highly sensitive)

Sensitivity of muscles spindles according to task (rest - precarious)
2b) Sensory System - Proprioception - Muscle Spindles
(iii & iv) Intensity & timing (sensitivity change).
Example: Consider active muscles in a Single-Leg Hip Hinge (e.g., without vision)
Sense awareness of position via active muscle spindles

https://youtu.be/tX_0Pas9iNI?s
i=FW2vxChjc2P4ZSlz Target muscle = Gluteus Maximus (red).
Synergists = Hamstrings (dark-pink)
Stabilizers = Abdom. muscles, Erector Spinae,
Gluteus Medius. Transversus Abdominis.
2b) Sensory System - Proprioception - Muscle Spindles
Muscle spindle function & activity.

Alternative overview:
https://www.youtube.com/watch?v=q-ImnmP-0Cg
Motor Control (MC 2)
Acquiring Information - Sensory (Afferent) Input:

Sensory Proprioception

Lecture Summary:

Lecture content has explained how:

Sensory afferent input is integral to movement control. Sensory (afferent) input
continually occurs in different modalities & during movement.

Cutaneous receptors - a form of proprioception (sense of touch) - provides preparatory
&/or feedback related to body contact on external objects/surfaces, contributing to
movement control.

Muscles spindles - a form of proprioception (sense of muscular positioning) - provides
continuous (& changeable) sensory feedback related to present muscle position. The
rate of change in length and sustained positional information helps guide movement
adjustment (i.e., control).
Motor Control - Lecture Content in MC 2-4
Red highlights content covered in today’s lecture
Sensory Receptor Organ Transduce (convert) Information Provided
Eyes 3D light detector (adjustable) vision

Ears sound detector hearing

Vestibular System (utricle, multi-axial accelerometers
balance, equilibrium
saccule, semicircular canals) (linear & angular; adjustable)

Cutaneous Receptors
(Merkel cells, Ruffini endings, pressure, stretch, mechanical
touch, pressure & texture
Meissner's corpuscles, deformation, vibration
Pacinian corpuscles)
muscle length & velocity, joint
Muscle Spindles length, velocity (adjustable)
position & vibration
Golgi Tendon Organs tension/force muscle tension (force)
Joint Receptors mechanical deformation joint position & movement
Efference Copy A copy of commands to reference information for
Multiple locations within CNS muscles movement
pain, itch, mechanical impacts
Nociceptors mechanical impacts, vibrations
& vibration
MC 2 - Lecture Content
Supplementary videos/material to assist learning:

https://www.youtube.com/watch?v=X7xOEez75B0

https://www.dailymotion.com/video/x12647t

https://www.youtube.com/watch?v=q-ImnmP-0Cg

https://www.youtube.com/watch?v=F0dp7A4IKyY

https://www.youtube.com/watch?v=wwQKSFKyD3U&t=221s