Muscular System - Kinesiology 1P99 Fall 2024 PDF

Summary

These lecture notes cover the muscular system, including muscle types (skeletal, cardiac, and smooth), categorizations (striated/unstriated, voluntary/involuntary), functions (locomotion, stability, communication), anatomy (gross and microscopic), connective tissues, myofilaments (actin and myosin), and the role of calcium in muscle contraction.

Full Transcript

THE MUSCULAR
SYSTEM
 Muscle
Muscles make up 40-50% of body weight
Three types of muscle
– Skeletal muscle
Found throughout the body
– Cardiac muscle
Found only in the heart
– Smooth muscle
Appears throughout the body systems as
components of hollow organs and tubes (e.g. in
intestines, veins and arteries)
Classified in two different ways
– Striated or unstriated
– Voluntary or involuntary
 Categorization of Muscle

Tissue
Classified in two different ways

1. Striated or unstriated
striated: alternation in light and dark bands
called striations (stripes)

2. Voluntary or involuntary
voluntary: consciously controlled by CNS
& PNS (somatic nervous system)
involuntary: subconsciously controlled by
PNS (autonomic nervous system)
Categorization of Muscle
Tissue

4
 Functions of Muscle
Locomotion
– obvious
Stability
– Posture/resist gravity
Communication
– Facial expressions,
writing, speaking, etc.
Control of body
openings
– Sphincter muscles
Heat production
– Shivering
Store Glucose
 Gross Anatomy of
Skeletal Muscle SKELETAL MUSCLE

Surrounded by:
Epimysium

Connective tissue Contains:
Muscle fascicles

(epimysium, perimysium,
endomysium)
Muscle
MUSCLE FASCICLE

Surrounded by:

Muscle fascicle
Perimysium

Contains:
Muscle fibers

Muscle fiber
Myofibrils MUSCLE FIBER

Surrounded by:
Endomysium

Contains:
Myofibrils
 Connective Tissue
Muscle is composed of muscle tissue and
connective tissue
Multiple layers of connective tissue
– Fascia
thick connective tissue around
entire muscle
Extension of tendonous tissue
– Separates muscle from skin
– Hold muscles of similar
function together
 Connective Tissue
Each muscle has 3 layers:

1. Epimysium: Surrounds entire muscle
2. Perimysium: Divides muscle into sections (bundles)
called fasciculi
3. Endomysium: Surrounds individual muscle Fibres
 Connective Tissue
3 types of
connective tissue –
extensions of deep
fascia
1. Epimysium
Layer of connective
tissue around
entire muscle –
deep to superficial
fascia
“Epi-” means on
top of
 Connective Tissue

2. Perimysium
Connective tissue
covering that surrounds
a “bundle of muscle
fibers” (muscle cells),
called fascicle.
“Peri-”means around
 Macroscopic Structure:
Connective Tissue
3.
Endomysiu
m
Surrounds
each muscle
fiber (cell)
Thin
Capillaries
and nerves
run along
surface Tortora & Grabowski,
“Endo-”mean 2003
 Skeletal Muscle Fiber
Skeletal muscle consists
of number of muscle
fibers lying parallel to
one another and held
together by connective
tissue
Single skeletal muscle
cell is known as a muscle
fiber
– Multinucleated
– Large, elongated, and
cylindrically shaped
– Fibers usually extend
entire length of muscle
Microscopic Organization
(inside muscle fiber)
 Microscopic Organization
Inside the muscle
fiber
Myofibrils

– Make up the muscle
fiber
– Contractile elements
of muscle fiber
– Majority of the
volume in a muscle
fiber (cell)
– Surrounded by
sarcoplasmic
reticulum
 Microscopic Organization
Myofibrils
(cont’d)

Regular
arrangement of
thick and thin
filaments
– Thick filaments:
myosin (protein)
– Thin filaments:
actin (protein)
 Microscopic Organization
Myofibrils (cont’d)

Viewed
microscopically,
display alternating
dark bands (the A
bands) and light
bands (the I bands),
giving appearance of
striations
Made up of
sarcomeres joined
end to end
 Microscopic Organization
(inside muscle fiber)

Sarcolemma
Cell membrane
(electrically
polarized)

Sarcoplasm
(nuclei,
mitochondria,
sarcoplasmic
reticulum)
 Microscopic Organization
(inside muscle fiber)

Mitochondria
– either between
myofibrils
‘intermyofibrill
ar’
– or right under
cell membrane
‘subsarcolem
mal’
 Microscopic Organization
(inside muscle fiber)
T-tubules
– continuous with
cell membrane or
sarcolemma

Sarcoplasmic
reticulum
– Membrane network
– Ca2+ storage
– Lateral sacs
(Terminal
cisternae)
 Sarcomere
smallest functional unit of skeletal
muscle where actual contraction
occurs
made of myofilaments
Actin - Thin protein filaments
Myosin - Thick protein filaments

Between two adjacent Z lines
(discs)
 Myofilaments

ACTIN MYOSIN

Make up the thin and thick filaments…
the contractile machinery of the
muscle cell
 Actin and Myosin
Actin and myosin are often called
contractile proteins. Neither actually
contracts.

Actin and myosin are not unique to
muscle cells, but are more abundant
and more highly organized in muscle
cells.
 Myosin
Component of thick filament
Protein molecule consisting of two
identical subunits shaped somewhat
like a golf club
– Tail ends are intertwined around each other
– Globular heads project out at one end
 Myosin (cont’d)
Tails oriented toward center of filament
and globular heads protrude outward at
regular intervals
– Heads form cross bridges between thick
and thin filaments and have two important
sites critical to contractile process:
– An actin-binding site
– ATP binding site
Structure and Arrangement of Myosin
Molecules
Within Thick Filament

26
 Actin
Primary structural component
of thin filaments
Spherical in shape
Each actin molecule has special binding
site for attachment with myosin cross
bridge
– Binding results in contraction of muscle fiber
Thin filament also has two other proteins
– Tropomyosin and troponin
 Tropomyosin and
Troponin
Often called
regulatory proteins
Tropomyosin
– Thread-like molecules
that lie end to end
alongside of actin spiral
– In this position, covers
actin sites and blocks
interaction with myosin
that leads to muscle
contraction
 Tropomyosin and
Troponin
Troponin
– Made of three polypeptide units
One binds to tropomyosin (Troponin T)
One binds to actin (Troponin I)
One can bind with Ca2+ (Troponin C)
Composition of a Thin Filament
 Actin, Tropomyosin, and
Troponin
When not bound to Ca2+, troponin
stabilizes tropomyosin in blocking
position over actin’s cross-bridge
binding sites
– When Ca2+ binds to troponin,
tropomyosin moves away from blocking
position
– With tropomyosin out of way, actin and
myosin bind, interact at cross bridges
– Muscle contraction results
Role of Calcium in Turning on
Cross Bridges
 fig 17.4

Brent E. Faught
Cross-sectional Arrangement of
Thick and Thin Filaments
 Sarcomere & Bands
Sarcomere
– Z-disc (or line) to
Z-disc
– Contractile unit of
muscle

A-Band
– Dark band
– Made up of thick
filaments along
with portions of
thin filaments that
overlap on both
ends of thick
filaments
35
 Sarcomere & Bands
(cont’d)
H-Band (zone)
– Lighter area in middle
of A-band (where the
thin filaments don’t
reach)
– M line extends
vertically down
middle of A band
within centre of H
zone
I-Band
– Light band
– Consists of remaining
portion of thin
filaments that do not
project into A band

36
 Blood vessels in
skeletal muscle

Arteries

Veins

Capillaries
Structure of Skeletal
Tendon Muscle

Connective
tissue

Figure: Levels of organization in a skeletal muscle
Summary SKELETAL MUSCLE
Surrounded by:
Epimysium
Contains:
Muscle fascicles

Skeletal muscles consist of muscle MUSCLE FASCICLE

fasciculi Surrounded by:
Perimysium
Contains:
Muscle fibers

Muscle fascicle consist of muscle
fibers MUSCLE FIBER

Surrounded by:
Endomysium
Contains:
Myofibrils

Muscle fiber consist of myofibrils
MYOFIBRIL

Myofibrils consist of sarcomeres Surrounded by:
Sarcoplasmic
reticulum
Consists of:
Sarcomeres
(Z line to Z line)

Sarcomere consist of myofilaments SARCOMERE
I band A band

Contains:

Myofilaments are made of actin and
Thick filaments
Thin filaments

myosin Z line M line
H band
Titin Z line
 Action of a Muscle
Fiber
Excitation-Contraction Coupling:
1. Excitation phase
2. Contraction phase
 Contraction Phase
muscle shortens in length
caused by interactions between
thick & thin filaments in the
sarcomere
triggered by the presence of calcium
ions
requires ATP
When a muscle contracts, actin
filaments slide
toward each other
The sarcomere is the “functional”
unit of a muscle fibre.

Z - line Z-
line
 Muscle contracts (shortens) when
each sarcomere contracts (shortens)
 Changes in the Sarcomere
during Contraction
– z-lines pull closer together
– I - bands (thin filaments) and H-zones get smaller
– myosin heads are pulling themselves closer to z-line
– A-band (thick and thin filaments) does not change in
size
So, how do sarcomeres
contract (shorten)?
 Cross-Bridge Formation

 Cross-bridge interaction between
actin and myosin brings about
muscle contraction by means of the
sliding filament mechanism.
 Sliding Filament
Mechanism
Sarcomeres contract when myosin filaments make
contact with actin filaments (cross-bridge) and pull
them towards the centre of the sarcomere.
The length of the thick and thin filaments do not
actually change (only the sarcomere length
becomes shorter).
Thousands of sarcomeres contract at the same time
which causes the muscle as a whole to contract and
generate force.
 Sliding Filament
Mechanism
Increase in Ca2+ starts
filament sliding
Thin filaments on each
side of sarcomere slide
inward over stationary
thick filaments toward
center of A band during
contraction
As thin filaments slide
inward, they pull Z lines
closer together,
Decrease in Ca2+ turns off sliding process
sarcomere shortens
 Sliding Filament
Mechanism
All sarcomeres throughout a muscle
fiber’s length shorten simultaneously
– Contraction is accomplished by thin
filaments from opposite sides of each
sarcomere sliding closer together
between thick filaments
 Power Stroke
Sarcoplasmic reticulum
releases Ca2+ into
sarcoplasm
Myosin heads bind to actin
Myosin heads swivel toward
center of sarcomere (power
stroke) pulling the actin
myofilament
ATP binds to myosin head
and detaches it from actin,
and myosin head returns to
its original position
 Power Stroke
Hydrolysis of ATP
transfers energy to
myosin head and
reorients it
– ATP  ADP + Pi

Contraction
continues if ATP is
available and Ca2+
level in sarcoplasm
is high
 Cross Bridge
Activity
1

2

3

1

During each cross-bridge cycle, the cross-bridge binds with
the actin molecule, bend to pull the thin filament inwards
during the power stroke, then detaches and returns to its
resting conformation, ready to repeat the cycle.
 Cross Bridge
Activity

Each thick filament is surrounded on each side by 6 thin
filaments, which are all pulled inward simultaneously through the
cross-bridging cycle during a muscle contraction
 The Cross-bridge Cycle
A single Power Stroke pulls the thin
filament inward only a small
percentage of the total shortening
distance
Repeated cycles of cross-bridge
complete the shortening
At the end of one cross-bridge cycle,
the link between the myosin cross-
bridge and the actin molecule breaks
and the cross bridge returns to its
original shape in order to bind to the
 Contraction Cycle

As long as Ca2+ is present myosin
will be able to bind

Allows a series of cycles to cause
large contractions
So, where does the calcium come
from?
 Action of a Muscle
Fiber
Excitation-Contraction Coupling:
1. Excitation phase
2. Contraction phase
 Excitation Phase
1. An impulse (action potential) travels down
the axon of a nerve
2. Neurotransmitter, acetylcholine (ACh) is
released from the end of the axon into the
neuromuscular junction (synapse)
3. This causes an action potential and
ultimately causes the sarcoplasmic
reticulum to release its stored calcium
ions
4. Calcium binds to active site on actin
5. Begins the contraction of the muscle
 Neuromuscular
Junction (synapse)

Fig. 9- 8
SR and T-Tubules
 STEPS IN INITIATING MUSCLE CONTRACTION STEPS IN MUSCLE RELAXATION

Neuromusc Synaptic Motor
ular terminal end plate T tubule Sarcolemma
junction

2 Action
1 ACh released, binding potential 6 ACh removed by AChE
to receptors reaches
T tubule
3 Sarcoplasmic 7 Sarcoplasmic
reticulum reticulum
releases Ca2+ recaptures Ca2+
Ca2+
4 Active-site
Actin 8 Active sites
exposure,
cross-bridge covered, no
formation Myosin cross-bridge
interaction

9 Contraction
ends
5 Contraction
begins
10 Relaxation occurs,
passive return to
resting length
 Excitation-Contraction
Coupling
The excitation of the sarcolemma
and
T-tubules leads to release of Ca2+
from SR

Thus, excitation and contraction are
“coupled”

Neural signal conveyed to the
contractile machinery
The anatomy of a nerve Cell body
Houses the nucleus and
organelles

Dendrites (rootlike
extensions)
- Project from cell body and
increase surface area
available for receiving
signals from other nerve
cells
- Move the signal toward
the cell body
- Dendrites and cell bodies
serve as the neuron’s
input zone
Axon
- Single, elongated tubular
For a muscle to
contract, it needs a
neural impulse.

Neural
impulses are
“electrical”
currents that
pass along
nerve fibres.
Electrical
Action
Impulse
down membrane potential

= Cell to cell
communication
(e.g. between nerve
cell and muscle cell)
 Excitable Cells
e.g., nerve to nerve
communication
 Excitable cells
e.g., nerve cell to muscle cells
Each “motor” (to muscle)
nerve innervates many
muscle fibers & is called a
motor unit.

From Martini
 Motor Units
- Each muscle fiber is innervated by only
one motor neuron.

- Each motor neuron may innervate up to
several thousand muscle fibers.

- All muscle fibers within a single motor
unit are of the same fiber type.
Schematic Representation of Motor
Units in Skeletal Muscle

Muscle fibers belonging
to a given motor unit
are intermixed with
fibers from other motor
units.

Motor units often differ
in size, with some
having more fibers than
others

Copyright © 2010 by Nelson
Education Ltd.
 Motor Unit
Characteristics
Number of muscle fibers varies
among different motor units
Number of muscle fibers per motor
unit and number of motor units per
muscle vary widely
– Muscles that produce precise, delicate
movements contain fewer fibers per
motor unit (e.g. finger muscles)
– Muscles performing powerful, coarsely
controlled movement have larger
number of fibers per motor unit (e.g. leg
muscles)
 Pathology
Contracture: a condition in which a muscle
shortens its length while at rest.
Cramps: spastic and painful contractions of
muscles.
Myalgia: muscle pain.
Fibromyalgia: a form of rheumatism characterized
by long-term tendon and muscle pain accompanied
by stiffness, occasional muscle spasms, and
fatigue.
Myositis: inflammation of muscle tissue.
Tendinitis: inflammation of a tendon.
 Pathology
Atrophy: decrease in muscle mass due to a lack of
activity, as when a limb is in a cast for a prolonged
period.
Muscular dystrophy: inherited muscular disorder
(most often in males) in which the muscle tissue
degenerates over time.
Plantar fasciitis: inflammation of the connective
tissue (fascia) of the arches of the foot. It is painful
and caused by continuous stretching of the muscles
and ligaments of the foot.