1. Chapter 9 Lecture PowerPoint
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2. 9.1: Introduction Three (3) Types of Muscle Tissues Skeletal Muscle
Usually attached to bones
Under conscious control
Somatic
Striated
Cardiac Muscle
Wall of heart
Not under conscious control
Autonomic
Striated
Smooth Muscle
Walls of most viscera, blood vessels and skin
Not under conscious control
Autonomic
Not striated

3. 9.2: Structure of Skeletal Muscle
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Skeletal Muscle
Organ of the muscular system
Skeletal muscle tissue
Nervous tissue
Blood
Connective tissues
Fascia
Tendons
Aponeuroses
Aponeuroses
Skeletal muscles
Tendons

4. Connective Tissue Coverings
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Muscle coverings:
Epimysium
Perimysium
Endomysium
Muscle
Bone
Fascicles
Tendon
Muscle fibers (cells)
Fascia
(covering muscle)
Myofibrils
Epimysium
Muscle organ
Fascicles
Muscle cells or fibers
Myofibrils
Thick and thin myofilaments
Actin and myosin proteins
Titin is an elastic myofilament
Perimysium
Thick and thin filaments
Endomysium
Fascicle
Axon of motor
neuron
Blood vessel
Nucleus
Sarcoplasmic
reticulum
Myofibril
Filaments
Muscle fiber
Sarcolemma 5

5. Skeletal Muscle Fibers
Sarcolemma
Sacroplasm
Sarcoplasmic reticulum (SR)
Transverse (‘T’) tubule
Triad
Cisternae of SR
T tubule
Myofibril
Actin myofilaments
Myosin myofilaments
Sarcomere
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Myofibrils
Cisternae of
sarcoplasmic reticulum
Triad
Nucleus
Transverse tubule
Sarcoplasmic
reticulum
Openings into
transverse tubules
Mitochondria
Nucleus
Thick and thin
filaments
Sarcolemma
Sarcoplasm

6. 9.3: Skeletal Muscle Contraction
Movement within the myofilaments
I band (thin)
A band (thick and thin)
H zone (thick)
Z line (or disc)
M line
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Skeletal muscle fiber
Sarcoplasmic
reticulum
Thick (myosin)
filaments
Thin (actin)
filaments
Myofibril
Sarcomere
Z line
H zone
Z line
M line
I band
A band
I band
A band
(a)
(b)

7. Myofilaments Thick myofilaments Composed of myosin protein
Form the cross-bridges
Thin myofilaments
Composed of actin protein
Associated with troponin and tropomyosin proteins
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Cross-bridges
Thin filament
Troponin
Tropomyosin
Myosin
molecule
Thick
filament
Actin molecule

8. Neuromuscular Junction
Also known as NMJ or myoneural junction
Site where an axon and muscle fiber meet
Parts to know:
Motor neuron
Motor end plate
Synapse
Synaptic cleft
Synaptic vesicles
Neurotransmitters
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Synaptic
vesicles
Mitochondria
Motor
neuron axon
Acetylcholine
Synaptic
cleft
Folded
sarcolemma
Axon branches
Motor
end plate
Muscle fiber
nucleus
Myofibril of
muscle fiber 9
(a)

9. Motor Unit Single motor neuron
All muscle fibers controlled by motor neuron
As few as four fibers
As many as 1000’s of
muscle fibers
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Motor neuron
of motor unit 2
Motor neuron
of motor unit 1
Branches of
motor neuron
axon
Skeletal muscle
fibers

10. Stimulus for Contraction
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Acetylcholine (ACh)
Nerve impulse causes release of ACh from synaptic vesicles
ACh binds to ACh receptors on motor end plate
Generates a muscle impulse
Muscle impulse eventually reaches the SR and the cisternae
Synaptic
vesicles
Mitochondria
Motor
neuron axon
Acetylcholine
Synaptic
cleft
Folded
sarcolemma
Axon branches
Motor
end plate
Muscle fiber
nucleus
Myofibril of
muscle fiber
(a) 11

11. Excitation-Contraction Coupling
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Muscle impulses cause SR to release calcium ions into cytosol
Calcium binds to troponin to change its shape
The position of tropomyosin is altered
Binding sites on actin are now exposed
Actin and myosin molecules bind via myosin cross-bridges
Tropomyosin
Troponin
Thin filament
Actin monomers
ADP + P
ADP + P
Thick filament 1
Relaxed muscle
Ca+2
Ca+2
Muscle contraction
Muscle relaxation
Release of Ca+2 from sarcoplasmic
reticulum exposes binding sites on
actin:
Active transport of Ca+2 into sarcoplasmic
reticulum, which requires ATP, makes
myosin binding sites unavailable.
Ca+2 binds to troponin
ATP
Tropomyosin pulled aside
Binding sites on
actin exposed
Ca+2
Ca+2
Ca+2
ADP + P
ADP + P 2
Exposed binding sites on actin molecules
allow the muscle contraction cycle to occur
ADP + P
ADP + P
Contraction cycle
ADP + P
ADP + P 6
ATP splits, which
provides power to
“cock” the myosin
cross-bridges 3
Cross-bridges
bind actin to
myosin
ADP
ADP
ATP
ATP
ATP P P
ATP
ADP + P 5
New ATP binds to myosin, releasing linkages 4
Cross-bridges pull thin filament (power stroke),
ADP and P released from myosin 13

12. The Sliding Filament Model of Muscle Contraction
When sarcromeres shorten, thick and thin filaments slide past one another
H zones and I bands narrow
Z lines move closer together
Sarcomere
A band
Z line
Z line 1
Relaxed
Thin
filaments
Thick
filaments 2
Contracting 3
Fully contracted
(a)

13. Cross Bridge Cycling
Myosin cross-bridge attaches to actin binding site
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Tropomyosin
Troponin
Thin filament
Actin monomers
Myosin cross-bridge pulls thin filament
ADP + P
ADP + P
Thick filament 1
Relaxed muscle
Ca+2
Ca+2
Muscle contraction
Muscle relaxation
Release of Ca+2 from sarcoplasmic
reticulum exposes binding sites on
actin:
Active transport of Ca+2 into sarcoplasmic
reticulum, which requires ATP, makes
myosin binding sites unavailable.
ADP and phosphate released from myosin
Ca+2 binds to troponin
ATP
Tropomyosin pulled aside
Binding sites on
actin exposed
New ATP binds to myosin
Ca+2
Ca+2
Ca+2
ADP + P
ADP + P 2
Exposed binding sites on actin molecules
allow the muscle contraction cycle to occur
Linkage between actin and myosin cross-bridge break
ADP + P
ADP + P
Contraction cycle
ADP + P
ADP + P 6
ATP splits, which
provides power to
“cock” the myosin
cross-bridges 3
Cross-bridges
bind actin to
myosin
ATP splits
ADP
ADP
ATP
ATP
ATP P P
Myosin cross-bridge goes back to original position
ATP
ADP + P 5
New ATP binds to myosin, releasing linkages 4
Cross-bridges pull thin filament (power stroke),
ADP and P released from myosin

14. Relaxation
Acetylcholinesterase – rapidly decomposes Ach remaining in the synapse
Muscle impulse stops
Stimulus to sarcolemma and muscle fiber membrane ceases
Calcium moves back into sarcoplasmic reticulum (SR)
Myosin and actin binding prevented
Muscle fiber relaxes

15. Energy Sources for Contraction
1) Creatine phosphate and 2) Cellular respiration
Creatine phosphate – stores energy that quickly converts ADP to ATP
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When cellular
ATP
is low
When cellular
ATP
is low
Creatine P
ADP
Creatine P
ADP
Creatine
ATP
Creatine
ATP 17

16. Oxygen Supply and Cellular Respiration
Anaerobic Phase
Glycolysis
Occurs in cytoplasm
Produces little ATP
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Glucose 2
In the absence of
sufficient oxygen,
glycolysis leads to
lactic acid
accumulation.
Energy 2
ATP
Pyruvic acid
Lactic acid
Cytosol
Aerobic Phase
Citric acid cycle
Electron transport system
Occurs in the mitochondria
Produces most ATP
Myoglobin stores extra oxygen
Mitochondria 1
Oxygen carried from
the lungs by
hemoglobin in red
blood cells is stored
in muscle cells by
myoglobin and is
available to support
aerobic respiration.
Citric acid
cycle
Electron
transport
chain
Synthesis of 34
ATP
CO2 + H2O + Energy
Heat

17. Oxygen Debt
Oxygen debt – amount of oxygen needed by liver cells to use the accumulated lactic acid to produce glucose
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Oxygen not available
Glycolysis continues
Pyruvic acid converted to lactic acid
Liver converts lactic acid to glucose
Glycogen
Energy to
synthesize
Glucose
Energy
from
ATP
ATP
Pyruvic acid
Lactic acid
Glycolysis and
lactic acid formation
(in muscle)
Synthesis of glucose
from lactic acid
(in liver)

18. Muscle Fatigue Inability to contract muscle Commonly caused from:
Decreased blood flow
Ion imbalances across the sarcolemma
Accumulation of lactic acid
Cramp – sustained, involuntary muscle contraction
Physiological vs. psychological fatigue

19. Heat Production By-product of cellular respiration
Muscle cells are major source of body heat
Blood transports heat throughout body core

20. 9.4: Muscular Responses
Muscle contraction can be observed by removing a single skeletal muscle fiber and connecting it to a device that senses and records changes in the overall length of the muscle fiber.

21. Threshold Stimulus Threshold Stimulus
Minimal strength required to cause contraction

22. Recording of a Muscle Contraction
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Recording a Muscle Contraction
Twitch
Latent period
Period of contraction
Period of relaxation
Refractory period
All-or-none response
Force of contraction
Latent
period
Period of
contraction
Period of
relaxation
Time of
stimulation
Time

23. Length-Tension Relationship
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(a) Optimal length
(b) Overly shortened
(c) Overly stretched
Force
Muscle fiber length

24. Summation Process by which individual twitches combine
Produces sustained contractions
Can lead to tetanic contractions
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Force of
contraction
(a)
Force of
contraction
(b)
Force of
contraction
(c)
Time

25. Recruitment of Motor Units
Recruitment - increase in the number of motor units activated
Whole muscle composed of many motor units
More precise movements are produced with fewer muscle fibers within a motor unit
As intensity of stimulation increases, recruitment of motor units continues until all motor units are activated

26. Sustained Contractions
Smaller motor units (smaller diameter axons) - recruited first
Larger motor units (larger diameter axons) - recruited later
Produce smooth movements
Muscle tone – continuous state of partial contraction

27. Types of Contractions Isotonic – muscle contracts and changes length
Concentric – shortening contraction
Isometric – muscle contracts but does not change length
Eccentric – lengthening contraction
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(a) Muscle contracts with
force greater than
resistance and
shortens (concentric
contraction)
(b) Muscle contracts
with force less than
resistance and
lengthens (eccentric
contraction)
(c) Muscle contracts but
does not change length
(isometric contraction) No
movement
Movement
Movement 29

28. Fast Twitch and Slow Twitch Muscle Fibers
Slow-twitch fibers (Type I)
Always oxidative
Resistant to fatigue
Red fibers
Most myoglobin
Good blood supply
Fast-twitch fatigue-resistant fibers (Type IIb)
Intermediate fibers
Oxidative
Intermediate amount of myoglobin
Pink to red in color
Resistant to fatigue
Fast-twitch glycolytic fibers (Type IIa)
White fibers (less myoglobin)
Poorer blood supply
Susceptible to fatigue

29. 9.5: Smooth Muscles
Compared to skeletal muscle fibers, smooth muscle fibers are:
Shorter
Single, centrally located nucleus
Elongated with tapering ends
Myofilaments randomly organized
Lack striations
Lack transverse tubules
Sarcoplasmic reticula (SR) not well developed

30. Smooth Muscle Fibers Visceral Smooth Muscle Single-unit smooth muscle
Sheets of muscle fibers
Fibers held together by gap junctions
Exhibit rhythmicity
Exhibit peristalsis
Walls of most hollow organs
Multi-unit Smooth Muscle
Less organized
Function as separate units
Fibers function separately
Iris of eye
Walls of blood vessels

31. Smooth Muscle Contraction
Resembles skeletal muscle contraction in that:
Interaction between actin and myosin
Both use calcium and ATP
Both are triggered by membrane impulses
Different from skeletal muscle contraction in that:
Smooth muscle lacks troponin
Smooth muscle uses calmodulin
Two neurotransmitters affect smooth muscle
Acetlycholine (Ach) and norepinephrine (NE)
Hormones affect smooth muscle
Stretching can trigger smooth muscle contraction
Smooth muscle slower to contract and relax
Smooth muscle more resistant to fatigue
Smooth muscle can change length without changing tautness

32. 9.6: Cardiac Muscle Located only in the heart
Muscle fibers joined together by intercalated discs
Fibers branch
Network of fibers contracts as a unit
Self-exciting and rhythmic
Longer refractory period than skeletal muscle

33. Characteristics of Muscle Tissue

34. 9.7: Skeletal Muscle Actions
Skeletal muscles generate a great variety of body movements.
The action of each muscle mostly depends upon the kind of joint it is associated with and the way the muscle is attached on either side of that joint.

35. Body Movement Four Basic Components of Levers: Rigid bar – bones
Fulcrum – point on which bar moves; joint
Object - moved against resistance; weight
Force – supplies energy for movement; muscles
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Resistance
Resistance
Force
Resistance
Force
Resistance
Fulcrum
Fulcrum
Fulcrum
Fulcrum
Force
Force
(a) First-class lever
(b) Second-class lever
Resistance
Force
Resistance
Fulcrum
(c) Third-class lever
Fulcrum
Force

36. Levers and Movement Movement Movement Forearm movement Biceps brachii
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Forearm
movement
Movement
Biceps brachii
contracting muscle
Force
Radius
Relaxed
muscle
(a)
Fulcrum
Resistance
Relaxed
muscle
Triceps brachii
contracting muscle
Ulna
Force
Movement
Fulcrum
Resistance
(b)

37. Origin and Insertion Origin – immovable end Insertion – movable end
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Origin – immovable end
Insertion – movable end
Coracoid process
Origins of
biceps brachii
Tendon of
long head
Tendon of
short head
Biceps
brachii
Radius
Insertion of
biceps brachii

38. Interaction of Skeletal Muscles
Prime mover (agonist) – primarily responsible for movement
Synergists – assist prime mover
Antagonist – resist prime mover’s action and cause movement in the opposite direction of the prime mover
Fixators