MNB.5 Muscle Anatomy and Physiology PDF

Summary

This document is a presentation on muscle anatomy and physiology which includes skeletal, cardiac, and smooth muscle types, motor units, and muscle contraction.

Full Transcript

Musculoskeletal System,
Nervous System & Bioelectricity
MNB.5 Muscle anatomy and
physiology

N A M E : D r. To m H o d g k i n s o n
Learning outcomes
At the end of this lecture, the learner will be able to

Discuss the three main muscle types: cardiac, smooth and striated.

Describe the structure and arrangement of anatomical muscles

Outline the innervation of the motor unit

Describe the physiology of whole muscle action including twitch and summation

Differentiate between isometric and isotonic contraction

MNB.5 Muscle anatomy and physiology 2
Muscle Types
Muscles are the tissues of movement
in the body.

Some are under voluntary control
and some are involuntary.

Three muscle types:
Skeletal muscle
- Attached to bones
Cardiac muscle
- Walls of the myocardium
Smooth muscle
- Organs

MNB.5 Muscle anatomy and physiology 3
Skeletal Muscle

About 40% of the body is skeletal
muscle.

There are approximately 650 skeletal
muscles in the human body.

There are over 150 surface (anatomical)
muscles in the body.

MNB.5 Muscle anatomy and physiology 4
Skeletal Muscle and associated tissues

Muscle: tissue with the ability to
contract

Tendon: tough band of fibrous
connective tissue that connects
muscle to bone

Ligament: Attaches bone to bone

MNB.5 Muscle anatomy and physiology 5
Skeletal Muscle
A skeletal muscle usually attaches to 2 different bones of the skeleton, i.e.
crosses a joint.
- one attachment is fixed and called the origin
- The other called the insertion is drawn towards the origin

With contraction, the point of insertion is drawn towards the origin.

However, as the skeleton is mobile in practice the action is equal at both ends.

Muscles rarely act alone but tend to work in groups.

Any movement is brought about by the coordinated contraction of a number of
muscles working together or in groups.

Muscles can only contract and never push
- Arranged in antagonistic pairs

Flexor closes a joint

Extensor opens a joint

MNB.5 Muscle anatomy and physiology 6
Skeletal Muscle
Arm:
Biceps Brachii flexes the
arm at the elbow
Triceps Brachii extends the
arm at the elbow

This is a simplification:
Action is more complex –

Not just flexion or extension,
and many more muscles
involved…

MNB.5 Muscle anatomy and physiology 7
Skeletal Muscle
Each muscle is composed of millions of muscle fibres.
In most anatomical muscles the fibres extend the entire length of the muscle.
Each muscle is bound by a loose connective tissue sheath called an epimysium.

epimysium

MNB.5 Muscle anatomy and physiology 8
Skeletal Muscle
Each muscle is composed of bundles of fascicles.

Each fascicle is composed of many muscle fibers.

Each fiber contains many smaller fibers called myofibrils.

The myofibers contain the contractile apparatus – the
sarcomere

MNB.5 Muscle anatomy and physiology 9
Skeletal Muscle
Striated Muscle, also called striped
Voluntary muscle i.e. under direct nervous control
Low endurance muscle
Muscle Biopsy - Wide-bore Needle inserted into muscle, and a small ‘tube’ of
muscle removed.
Muscle analysed using a microscope and histological stains.

Longitudinal section Cross section

Hexagonal
Nuclei on outside (peripheral)
Fibers same size

MNB.5 Muscle anatomy and physiology 10
Cardiac Muscle
Only found in the heart.
A type of striated muscle but also related to
smooth muscle.
Involuntary muscle.
High endurance muscle.
Striated, intercalated discs (gap junctions).
1- 2 nuclei per cell, which are centrally
placed.
Innervated by the pace-maker.

MNB.5 Muscle anatomy and physiology 11
Smooth Muscle

Lines the digestive tract, trachea/
bronchus and blood vessels

Involuntary muscle i.e. not under
direct nervous control

High endurance muscle
1 centrally placed nucleus per cell

No striations

Sustained contraction

MNB.5 Muscle anatomy and physiology 12
Motor Unit
The functional unit of skeletal muscle is the motor unit (MU)
Composed of:
- A single motor neuron
- The group of muscle fibres innervated by it

As there are considerably more muscle fibres than there are
motor neurons some motor neurons must innervate more than
one fibre.

The number of muscle fibres per motor unit varies according
to the fineness of the control required.
Fewer muscle fibres per motor unit leads to increased
dexterity and vice versa, e.g.,
- Larynx muscle 2/3 fibres/MU
- Eye muscles 10 fibres/MU
- Biceps muscles 1000+/MU
- Average for the body is 150 fibres/MU

MNB.5 Muscle anatomy and physiology 13
Motor Unit
Neuromuscular Junction (NMJ), also
known as the motor endplate is the
connection between the muscle fibre
and its motor neuron.

The membranes of the nerve and muscle
cells come into close contact

One NMJ per muscle fibre.

MNB.5 Muscle anatomy and physiology 14
Motor Unit
When muscle fibre is stimulated at the NMJ it contracts - this is an "all-or-nothing" response.

The degree of contraction of a whole muscle is a function of the number of Motor Units which are
stimulated at any time.

Maximal contraction is when all Motor Units are firing together.

In practice to ensure that contraction is a smooth non-jerky process, asynchronous firing of the motor units
gives a graded response.

MNB.5 Muscle anatomy and physiology 15
Types Of Muscle Contraction
Muscles contract in two ways:
Isometric contraction - ‘same length’
Isotonic contraction - ‘same tension’

Isometric contraction Isotonic Contraction
The length of the muscle does not change The muscle length changes.
The tension on the muscle increases The tension remains constant
Two types of Isotonic contraction:
- Concentric – Muscle shortens

- Eccentric – Muscle lengthens

MNB.5 Muscle anatomy and physiology 16
Types Of Muscle Contraction
Concentric Isotonic Contraction Eccentric Isotonic Contraction
Force generated by the muscle is Also occur to slow joint movement
greater than the load to be lifted
Muscles undergoing heavy eccentric loading suffer greater
Muscle shortens in length damage when overloaded leading to greater muscle
damage.

Muscles are approximately 10% stronger during eccentric
contractions than during concentric contractions.

MNB.5 Muscle anatomy and physiology 17
Muscle Physiology
Whole muscle function is studied in laboratory preparations
e.g. Frog gastrocnemius muscle

When the muscle or its nerve is stimulated by a single electric shock it
responds with a quick twitch

- The twitch lasts about 0.1 sec in the Frog
- The twitch lasts in about 0.05 sec humans
- Requires specialized equipment to analyse

MNB.5 Muscle anatomy and physiology 18
Muscle Physiology
Three phases to muscle Stimulus
contraction:

Latent period (0.005 sec)
between the stimulus and first
visible reaction

tension
Contraction period (0.04
sec) when the muscle
shortens

Relaxation period (0.05 sec)
the muscle returns to its
original length
0.005s 0.04s Time 0.05s
After initial stimulation there is a short Latent Contraction Relaxation
period during which muscle will not
respond to further stimulus called the
Refractory period (0.002 sec)

MNB.5 Muscle anatomy and physiology 19
Muscle Physiology
Muscle can respond to a second stimulation while still contracting

Stimulation at frequency shorter than the twitch time results in the second
stimulus being superimposed on the first

This results in a greater shortening of the muscle called summation

MNB.5 Muscle anatomy and physiology 20
Muscle Physiology
Summation
Summation in whole muscle can occur in two different ways:

- By increasing the number of motor units involved - called multiple motor
unit summation (recruitment)

- By increasing the rate of contraction of individual motor units - called wave
summation

In practice both these occur together during contraction helped by the
asynchronous firing of the motor units

MNB.5 Muscle anatomy and physiology 21
 Muscle Physiology
As the impulse frequency increases the twitches become
superimposed upon one another in wave summation (10
pulses/sec)

Eventually increasing stimulus causes the successive contractions
to fuse together in a state of maximal contraction called tetanus
(>40 pulses/sec)

Upon tetanisation further increased stimulation will only result in
very slight shortening.

MNB.5 Muscle anatomy and physiology 22
References
- Solomon et al, Ch 40.
- Alberts et al, Ch 17 p 599 - 604

MNB.5 Muscle anatomy and physiology 23
Thank you
F O R M O R E I N F O R M AT I O N P L E A S E C O N TA N T
N A M E : D r. To m H o d g k i n s o n
EMAIL: [email protected]

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