MEDI258 Week 7 PDF

Summary

This document provides a lecture outline on the control of single joint and multi-joint movements. It discusses topics like muscle activation patterns and how those patterns change in response to variations in speed and other factors. The paper also introduces the concepts of agonist and antagonist muscles and examines their roles to produce coordination of movement.

Full Transcript

MEDI258 - Week 7
Control of single joint and multi-joint movements

1. Single joint movements - Triphasic pattern

2. Can elements of this basic pattern be
reproduced according to the movement context?

3. How has the musculoskeletal system evolved
to fulfil the movement requirements of everyday
life (multi-joint movements)?

Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 1
 Patterns of muscle activation

2 Types of muscle activation:

1. Tonic: relatively long, change slowly Examples?

2. Phasic: Characterized by short bursts...Examples?

Lecture will outline basic characteristics of phasic muscle
activation in human movement.

Will also explain how muscles have evolved to satisfy
constraints of everyday life - multi-joint movements.

Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 2
Phasic activation: wrist flexor and extensor
muscles - wrist flexion # velocities

fast

slow

Basic characteristics of triphasic EMG pattern...
Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 3
 Symmetry of movement = timing
and amplitude of AG/ANT
activity
How does timing and amplitude of max velocity
AG/ANT relationship affect
symmetry?
max velocity
What is symmetry of movement?

Increase in AG activation and max velocity
earlier onset of ANT =>
acceleration shorter

Decrease AG and delay ANT =>
lengthen acceleration
Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 4
Cooke and Brown 1990a
Movements are bell-shaped. Why?

How does CNS produce symmetry of movement?

Triphasic pattern exists for simple arm
movements:

AG1 (initiation)
ANT1 (braking, control)
AG2 (stretch reflex-dependent damping
mechanism) Controls oscillations

Studied relations between EMG and temporal
structure of movements

What did they do?
Manipulated different SR movements using
phase-plane paradigm
Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 5
Results: Phase-plane exp
Subject 1 Subject 2 A. Peak velocity
B. Amplitude
C. Duration
SR = 1 SR = 1
Peak Vel 2 subjects

What does it show?
Amplitude
Very tight
relationship between
distribution of 3
Duration
characteristics using
paradigm

Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 6
Anything else?
Different SR give different patterns

As SR increased, duration
of AG1 increased

Onset of ANT1 delayed
AG1
ANT Movements with large SR’s
SRs showed large AG2
AG1
Why would that occur (large
AG2 with larger SR’s)?
AG1

Prof Paul Stapley, MEDI258 Sensorimotor Control, Week 7 7
 AG1 duration as
function of SR AG1 magnitude

Decreased as SR increased
0.2-0.8

What does it show? Then remained virtually
Sometimes were clusters unchanged
More variable for movements