EXSC216 Resistance Training: Science & Application – Introduction 2020 PDF

Summary

This document provides an introduction to EXSC216 Resistance Training, covering topics like motor units, microscopic structure of muscle, and muscular contraction. It also includes diagrams and video links for further exploration.

Full Transcript

EXSC216
Resistance
Training:
Science &
Application –
Introduction
Semester 2, 2020
 Content
Introduction Part 4
Part 1 – Resistance Training
– Motor Units Adaptations
Neural
– Microscopic structure of
muscle Part 5
– Muscular contraction – Resistance Training
Adaptations
Part 2 Fibre type
– Fibre Types Endocrine
– Contraction Types Other changes
Part 3 Part 6
– Resistance Training – Terminology & Practical
Adaptations Concepts
Morphological
Part 1: Anatomical Concepts
·MOTOR UNITS
·MICROSCOPIC STRUCTURE OF MUSCLE
·MUSCULAR CONTRACTION
 Skeletal Muscle Motor Unit
A motor unit consists of a motor neuron and
the muscle fibres it innervates
– Normally several hundred fibres per motor unit
Figure 1.4
 Skeletal Muscle Motor Unit
The following video (0:00 - ~5:30) describes
the anatomy of a motor unit

https://www.youtube.com/watch?v=vXb0ZvkFkS8
 How Do Nervous Impulses Cause
Muscle to Contract?
The following video demonstrates how a
nervous impulse initiates a muscle contraction

https://www.youtube.com/watch?v=lRJd56BCidg
Microscopic Structure of Muscle
Sliding Filament Theory
 Actin & Myosin in
Muscular Contraction
https://www.youtube.com/watch?v=zopoN2i7
ALQ

https://www.youtube.com/watch?v=aUc3h6L
vdJ4
 3D multifilament model of a sarcomere

Location of single cross bridge across LT curve

Overlap across LT curve

LT curve for skeletal muscle

Short Long

Williams et. al.; 2013
 Contracting muscle maintains a constant volume (i.e.
when it shortens it expands radially)
This means distance (lattice spacing) between actin &
myosin filaments must increase
Change in lattice spacing play important role in L-T
curve of contracting muscle
Increase in lattice spacing means myosin head is
further from binding site and must diffuse over greater
distance to bind & produce a different force vector
– Pull at sharper angle over greater distance
– Responsible for 20-50% of change in F seen between
sarcomere lengths of 1.4 and 3.5μm
 Muscle Contraction
Molecular Mechanism
Part 2: Fibre Types and Contraction Types
· CLASSIFICATION METHODS
· FIBRE TYPES
· CONTRACTION TYPES
 Muscle Fibre Typing
Initial classification based on whole muscle speed of
shortening (i.e. fast or slow).
Corresponded with morphological difference of “fast”
muscles appearing white and “slow” muscles appearing red
(high myoglobin & capillary content)
Histological analysis showed correlation between myosin
ATPase activity and speed of shortening
This led to initial classification of Type I (slow) and Type II
(fast)
Muscle fibres typed using 3 methods
– Histochemical staining for myosin ATPase
– Myosin heavy chain isoform identification
– Biochemical identification of metabolic enzymes
 Myosin ATPase Staining
Myosin ATPase rates 2-3
times greater in fast fibres
Fibres are separated
based on staining
intensities due to pH
sensitivity
Originally, fibres classified
as type IA, IIA, IIB
Advances in staining
techniques have added
additional types
Myosin Heavy Chain Identification
Identification of myosin
heavy chain isoforms
also used for
classification
Myosin heavy chains
are the motor protein
of the thick muscle
filaments
Identified through
histochemical analysis Vizzaccaro, Elisa & Terracciano, Chiara & Rastelli, Emanuele
& Massa, Roberto. (2017). Aquaporin 4 expression in
human skeletal muscle fiber types. Muscle & Nerve. 57.
10.1002/mus.26024.
 Different myosin ATPase based fibres correspond to
different myosin heavy chain isoforms
– Naming is MHCI, MHCII etc.
Each fibre can contain more than one heavy chain isoform
which explains existence of myosin ATPase fibre types other
than pure Type I, IIA, and IIB
– E.g. mixed fibres contain “neighbours” MHCIIA and MCHIIB
What was called MHCIIb in humans is actually MHCIIx as
humans don’t express the fastest MHC isoform of MHCIIb
– Histochemical myosin ATPase fibre type terminology was
developed using human muscle, type IIB fibres (which
correspond to MHCIIx) unlikely to be renamed
Humans have MHCI, MHCIIa and MHCIIx
 Biochemical Classification
Combines information on fibre myosin ATPase
histochemistry and biochemistry of specific
enzymes
– These enzymes reflect energy metabolism of the fibre

Aerobic/oxidative or anaerobic/glycolytic
Results in 3 fibre types
– Fast twitch glycolytic
– Fast twitch oxidative
– Slow twitch oxidative
 Figure 2 Comparison of 3 different skeletal muscle fiber type
classifications: histochemical staining for myosin...

Phys Ther, Volume 81, Issue 11, 1 November 2001, Pages 1810–1816, https://doi.org/10.1093/ptj/81.11.1810
The content of this slide may be subject to copyright: please see the slide notes for details.
 Fibre Types
Type I
– slow twitch
– fatigue resistant
– high capacity for aerobic
energy supply
– limited potential for high
force production due to
low myosin ATPase
Type IIa & IIx
fast twitch
fatigable with low
aerobic power
high force production
capacity
IIa fibres have higher
aerobic capacity than
IIx fibres
Essentials of Str & Cond 2nd Ed
Types of Contraction

Isoinertial: constant external mass
– Concentric: muscle shortens
– Eccentric: muscle lengthens
Isometric: no change in muscle
length/joint angle
Isokinetic: constant angular velocity
 Isoinertial Contractions
Concentric from bottom position Eccentric from top position
 Isometric Isokinetic
http://www.youtube.com/w
atch?v=kY2EzwrUhCw
Part 3: Resistance Training Adaptations
·MORPHOLOGICAL ADAPTATIONS
 Resistance Training Adaptations
Increased
– Hypertrophy
– Strength
– Power
– Strength endurance
 Mechanisms
Morphological
Neural
Endocrine
Cardiovascular
 Morphological Adaptations
Hypertrophy
– Increase in muscle cross-
sectional area (CSA)
– ↑ synthesis/↓ degradation
of contractile protein
– ↑ number of myofibrils
within each fibre
– Fibre splitting (Hyperplasia)?
Fibre Type
– Type II fibres more prone to
hypertrophy
– Transition from I – II or II-I ?
Molecular Biology & Cell Signalling

Spiering et. al.; 2008
Synthesis of protein from Synthesis of RNA from DNA
mRNA

Spiering et. al.; 2008
 Adenosine
monophosphate-
activated protein
kinase

Enzyme to activate
glucose & fatty acid
MTOR is a protein kinase uptake and oxidation

A protein kinase is an enzyme that modifies other molecules (mostly proteins), by
adding phosphate groups to them (phosphorylation).
Endurance & Resistance Training Signalling Pathways

Hawley JA. Appl Physiol Nutr Metab 34:355-61, 2009.
Extra Reading
Camera. et. al.; 2016
 Muscle Memory

Classic Model New Model

Gundersen et. al.; 2016
 Cell Swelling

Strength and Conditioning Journal 2015
Part: 4 Resistance Training Adaptations
·NEURAL CHANGES
Siddique et. al.; Sports Med 2020
 Background
Subtle nervous system changes
important because increases in
strength occur in the absence of
hypertrophy
– Although hypertrophy can be
detected with 3 weeks
Traditionally measured as increase
in muscle activation from surface
electromyography (SEMG)
– Increased SEMG amplitude
thought to represent increased
efferent motor output from
cortical motor areas
– May underestimates motor
unit activity
Recent studies assessing H-reflex,
V-wave and Transcranial Magnetic
Stimulation (TMS)
 Definitions
Hoffman’s (H-reflex) can be used to evaluate
spinal alpha-motorneurone excitability
V-wave is measure representing overall
efferent motor output of alpha-motorneurone
pool
 Transcranial
Magnetic
Stimulation
TMS involves placing a magnetic coil
over the primary motor cortex to
stimulate underlying neurones
Results in muscle response known as
motor-evoked potential (MEP)
Size of MEP represents a measure of
corticospinal excitability
When MEP is recorded during voluntary
contraction there is a pause in the
SEMG signal know as “silent period”
– Measure of corticospinal inhibition
RT reduces inhibition in descending
motor pathways
 Twitch Interpolation
Magnitude of efferent drive to muscle is called “voluntary activation”
Determined via magnetic or electrical stimulus to the motor nerve during isometric
MVC.
Increase in force due to stimulation suggests central drive limitation
Representative output from the twitch interpolation method. The participants perform a maximal voluntary contraction, from
which peak torque is obtained (a). Once a plateau in torque is observed, a superimposed twitch (depicted by the green line)
is administered using a magnetic stimulator (b: maximal voluntary contraction + superimposed twitch; c: superimposed
twitch). Approximately 4 seconds post-maximal voluntary contraction, a potentiated twitch is administered (d). These
variables are input into a number of equations to calculate levels of voluntary activation.
Changes Due To Resistance Training
Corticospinal excitability (MEP)
– No effect of RT at rest
– Increased during MVC
Silent period duration
– Reduced due to RT
H-reflex
– No effect at rest or during MVC
Voluntary Activation
– ? but probably increased
 Summary of Neural Change Sites
Chronic RT modifies both cortical and sub-
cortical motor circuits that improve
motoneurone pool excitability
– Increased motoneurone activation via:
Decreases corticospinal inhibition & short-interval
intracortical inhibition (SICI)
Increases V-wave amplitude
– These factors underpin increase in force
 ↑ neural drive
– ↑ agonist muscle recruitment
– ↓ antagonist inhibition
– ↑ MU synchronisation
↑ firing rate
more efficient timing &
pattern of discharge
Impact of – ↑ stretch reflex
Motor unit recruitment governed
Neural by Size Principle
– low threshold MU’s are
Changes recruited first
– RT results in earlier
recruitment of high threshold
MU’s
Part 5: Resistance Training Adaptations
·FIBRE TYPE CHANGES
·ENDOCRINE CHANGES
·OTHER CHANGES
Fibre Type Changes

Wilson et. al.; JSCR 2014
 Fibre Type Changes
Type I fibres
Type II fibres
Roberts et. al. ; Frontiers 2018
 Endocrine Responses
Hormones are signaling
molecules that co-ordinate
& regulate physiological &
metabolic functions by
acting on receptors located
in target cells
Involved in wide variety of
homeostatic mechanisms
Endocrine glands are
stimulated to release
hormones into the blood by
a chemical signal or neural
stimulation
 Acute Endocrine Response
– Testosterone (T)
– Growth Hormone (GH)
– Cortisol (C)
– IGF-1
– Epinephrine, Nor-epinephrine, dopamine
– Some question over whether these acute
elevations are relevant in driving adaptation (see
later lecture on contemporary issues)
 Chronic Endocrine Adaptations
Testosterone, GH, IGF-1, Cortisol changes
unclear
Hormone receptor changes
Volume & intensity of training important in
determining response
Cardiovascular Adaptations
Acute responses
– ↑ Heart rate
– ↑ Stroke Volume
– ↑ Cardiac Output
– ↑ ventilation rate
Chronic adaptations
– No change in HR or BP
– ↑ ventricular wall
thickness
– Reduced HR & BP to
given absolute
workload
– Ventilation changes
Other Tissue Adaptations
Bones
– ↑ bone mineral
density
Minimal essential
strain
– Intensity
– Volume
– Speed
– Direction of
force
Tendons, Ligaments, Fascia
– Requires high intensity
training to cause
change
 Other Changes
↑ myofibrillar volume
↑ cytoplasmic density
↑ sarcoplasmic reticulum
↑ T-tubule density
↑ sodium-potassium ATPase activity
↑ calcium release
↑ pennation angle
↓ mitochondrial & capillary density
↑ stored ATP & CP
↑ muscle glycogen content
Part 6: Terminology & Practical Concepts
·ACTIONS
·MUSCLE ACTION
·ETIQUETTE & SAFETY
·TERMINOLOGY
 Movements & Muscles
Movement classification
Agonist/antagonist
Prime mover/synergist/stabiliser
 Flexion & Extension
Flexion: decreasing the angle at a joint
Extension: increasing the angle at a joint
 Adduction & Abduction
Adduction: moving towards the mid-line
Abduction: moving away from the mid-line
Bench Press Example
Prime Mover & Agonist
Synergist
Stabiliser
Antagonist
 Gym Etiquette & Safety
Hygiene
Clothing & footwear
Sharing equipment
Exercise technique
Spotting
Use of collars
Weight selection
Equipment maintenance
Floor layout & other hazards
 Spotting
Insurance against injury
Proprioceptive technique
feedback
Forced (partner assisted
reps)
Requires concentration
Particularly important
– Overhead movements
– Load on back
– Load over face/head
Use multiple people if
required
Exercise Technique
 Grip
– Hand position
Pronated - overhand
(palms down)
Supinated – underhand
(palms up)
Neutral - handshake
Mixed/Alternating
Hook - thumb under index
& middle finger
– Width
Range of Motion

Range
influences load
that can be lifted
changes forces on
specific structures
Desired range depends
on:
Program goals
Individual
participant
limitations
Breathing
Generally aim to exhale
through sticking point
(transition from ecc to
conc)
Valsalva manoeuvre
– Increase abdominal
pressure
– Increase BP
– Beneficial for max effort
Weight Belts

Provide external
support for abdominal
muscles
May be useful in some
circumstances
 Terminology

Repetition (Rep): 1 cycle of movement from the
start to the end of range and return
Set: group of repetitions
Rest: passive time between sets
– 4 x 8/90 s
Repetition maximum (RM) – maximum load that can
be lifted for a specified number of repetitions
 Terminology

Intensity
– Absolute = load lifted in kg
4 x 3 @ 80 , 90 , 95 , 100 kg
– Relative = load lifted as a % of an RM load
4 x 3 @ 70%, 80%, 85%, 90% 1RM
Very high intensity = 90-100% 1RM (1-4 reps)
High intensity = 80-90% 1RM (4-8 reps)
Moderate intensity = 70-80% 1RM (8-12 reps)
Low intensity = 60-70% 1RM (12-20 reps)
 Terminology

Volume
– Often calculated as : sets x reps x load lifted
e.g. 3 x 10 @ 80 kg = 2400 units
Equating volumes using % RM
– Allows researchers to compare different training methods
& control for volume
e.g.3 x 10 x 70% = 2100 units
6 x 4 x 87.5% = 2100 units
 Terminology

Tempo (s)
– Eccentric/Pause/Concentric
e.g. 3/1/2
2/0/1
1/0/X