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Sport Books Publisher 1
Chapter 3
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Learning Objectives
To describe muscle’s macro and micro structures
To explain the sliding-filament action of muscular
contraction
To differentiate among types of muscle fibres
To describe group action of muscles
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Types of Muscle The human body is comprised of 324 muscles Muscle makes up 30-35% (in women) and 42-47% (in men) of
body mass.
Three types of muscle:
Skeletal muscle
Smooth muscle
Cardiac muscle
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A. Skeletal (Striated) Muscle Connects the various parts of the skeleton through one or more
connective tissue tendons During muscle contraction, skeletal muscle shortens and moves
various parts of the skeleton Through graded activation of the muscles, the speed and smoothness
of the movement can be gradated Activated through signals carried to the muscles via nerves (voluntary
control) Repeated activation of a skeletal muscle can lead to fatigue Biomechanics: assessment of movement and the sequential pattern of
muscle activation that move body segments
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B. Smooth Muscle
Located in the blood vessels, the respiratory
tract, the iris of the eye, the gastro-intestinal
tract
The contractions are slow and uniform
Functions to alter the activity of various
body parts to meet the needs of the body at
that time
Is fatigue resistant
Activation is involuntary
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C. Cardiac Muscle
Has characteristics of both skeletal and
smooth muscle
Functions to provide the contractile
activity of the heart
Contractile activity can be gradated
(like skeletal muscle)
Is very fatigue resistant
Activation of cardiac muscle is
involuntary (like smooth muscle)
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d) myofibril c) muscle fibre b) muscle fibre bundle a) Muscle belly
Components of skeletal muscle
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Muscle Fibres Cylinder-shaped cells that make up skeletal muscle
Each fibre is made up of a number of myofilaments
Diameter of fibre (0.05-0.10 mm)
Length of fibre (appr. 15 cm)
Surrounded by a connective tissue sheath called Sarcolemma
Many fibres are enclosed by connective tissue sheath Perimycium to
form bundle of fibres
Each fibre contains contractile machinery and cell organelles
Activated through impulses via motor end plate
Group of fibres activated via same nerve: motor unit
Each fibre has capillaries that supply nutrients and eliminate waste
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Muscle Teamwork Agonist (prime mover):
- the muscle or group of muscles producing a desired effect
Antagonist:
- the muscle or group of muscles opposing the action
Synergist: - the muscles surrounding the joint being moved
Fixators:
- the muscle or group of muscles that steady joints closer to the body axis so that the desired action can occur
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Bending or straightening of elbow requires the coordinated interplay of the biceps and triceps muscles
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Contractile Machinery:
Sarcomeres Contractile units Organized in series ( attached
end to end) Two types of protein
myofilaments:
- Actin: thin filament
- Myosin: thick filament Each myosin is surrounded by
six actin filaments Projecting from each myosin
are tiny contractile myosin bridges
Longitudinal section of myofibril
(a) At rest
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High microscope magnification of sarcomeres within a myofibril
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Contractile Machinery:Crossbridge formation and movement Cross bridge formation:
- a signal comes from the motor nerve activating the fibre - the heads of the myosin filaments temporarily attach themselves to the actin filaments
Cross bridge movement: - similar to the stroking of the oars and movement of rowing shell- movement of myosin filaments in relation to actin filaments- shortening of the sarcomere- shortening of each sarcomere is additive
b) Contraction
Longitudinal section of myofibril
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Contractile Machinery:Optimal Crossbridge formation
Sarcomeres should be optimal distance apart
For muscle contraction: optimal distance is (0.0019-0.0022 mm)
At this distance an optimal number of cross bridges is formed
If the sarcomeres are stretched farther apart than optimal distance:
- fewer cross bridges can form less force produced
If the sarcomeres are too close together: - cross bridges interfere with one
another as they form less force produced
Longitudinal section of myofibril
c) Powerful stretching
d) Powerful contraction
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Contractile Machinery:
Optimal muscle length and optimal joint
angle
The distance between sarcomeres is dependent on the stretch of
the muscle and the position of the joint
Maximal muscle force occurs at optimal muscle length (lo)
Maximal muscle force occurs at optimal joint angle
Optimal joint angle occurs at optimal muscle length
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Muscle tension during elbow flexion at constant speed
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Contractile Machinery:
Tendons, origin, insertion
In order for muscles to contract, they must be attached to the bones to create movement
Tendons: strong fibrous tissues at the ends of each muscle that attach muscle to bone
Origin: the end of the muscle attached to the bone that does not move
Insertion: the point of attachment of the muscle on the bone that moves
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Muscle Fibre Types
Slow twitch fibres:
Slow Oxidative (Type I)
Fast twitch fibres: Fast Glycolytic (Type IIb) Fast Oxidative Glyc. (Type IIb)
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A. Slow Twitch Fibres
Suited for repeated contractions during activities requiring a
force output of < 20-25% of max force output
Examples: lower power activities, endurance events
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B) Fast Twitch Fibres Significantly greater force and speed generating capability than
slow twitch fibres
Well suited for activities involving high power
Examples: sprinting, jumping, throwing
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The Muscle Biopsy
Used to determine muscle fibre type
1. Injection of local anesthetic into the muscle being sampled
2. Incision of approximately 5-7mm is made in the skin and fascia
of the muscle
3. The piece of tissue (250-300mg) removed via the biopsy needle
is imbedded in OCT compound
4. The sample is frozen in isopentane cooled to –180C
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Muscle Biopsy
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The Histochemistry
The biopsy samples are first sectioned (8-10 μm thickness) Sections are processed for myosin ATPase:
Fast twitch fibres – rich in myosin ATPase (alkaline labile)
Slow twitch fibres – low in myosin ATPase (acid labile) Sections are processed for other metabolic characteristics
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Nerve-Muscle Interaction
Skeletal muscle activation is initiated through neural activation
NS can be divided into central (CNS) and peripheral (PNS)
The NS can be divided in terms of function: motor and sensory
activity
Sensory: collects info from the various sensors located
throughout the body and transmits the info to the brain
Motor: conducts signals to activate muscle contraction
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Activation of motor unit and its innervation systems
1. Spinal cord 2. Cytosome 3. Spinal nerve 4. Motor nerve 5. Sensory nerve 6. Muscle with muscle fibres
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Motor Unit
Motor nerves extend from the spinal cord to the muscle fibres Each fibre is activated through impulses delivered via motor end plate Motor unit: a group of fibres activated via the same nerve All muscle fibres of one particular motor unit are always of the same
fibre type Muscles needed to perform precise movements generally consist of a
large number of motor units and few muscle fibres Less precise movements are carried out by muscles composed of
fewer motor units with many fibres per unit
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All-or-none Principle Whether or not a motor unit activates upon the
arrival of an impulse depends upon the so called all-or-none principle
An impulse of a certain magnitude (or strength) is required to cause the innervated fibres to contract
Every motor unit has a specific threshold that must be reached for such activation to occur
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Intra-muscle Coordination
The capacity to apply motor units simultaneously is known as intra-muscle coordination
Many highly trained power athletes, such as weightlifters, wrestlers, and shot putters, are able to activate up to 85% of their available muscle fibres simultaneously (untrained: 60%)
Force deficit: the difference between assisted and voluntarily generated maximal force (trained: 10%, untrained: 20-35%)
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Intra-muscle Coordination cont.
Trained athletes have not only a larger muscle mass than untrained individuals, but can also exploit a larger number of muscle fibres
Athletes are more restricted in further developing strength by improving intra-muscular coordination
Trained individuals can further increase strength only by increasing muscle diameter
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Inter-muscle Coordination
The interplay between muscles that generate movement through contraction (agonists) and muscles responsible for opposing movement (antagonists) is called inter-muscle coordination
The greater the participation of muscles and muscle groups, the higher the importance of inter-muscle coordination
To benefit from strength training the individual muscle groups can be trained in relative isolation
Difficulties may occur if the athlete fails to develop all the relevant muscles in a balanced manner
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Inter-muscle Coordination cont. High-level inter-muscle coordination greatly improves
strength performance and also enhances the flow, rhythm, and precision of movement
Trained athlete is able to translate strength potential to enhance inter-muscle coordination
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Muscle’s Adaptation to Strength Training
Individual’s performance improvements occur through a process of biological adaptation, which is reflected in the body’s increased strength
Adaptation process proceeds at different time rates for different functional systems and physiological processes
Adaptation depends on intensity levels used in training and on athlete’s unique biological make-up
Enzymes adapt within hours, cardiovascular adaptation within 10 to 14 days
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