Human Anatomy and Physiology - Chapter 09 - Muscles and Muscle Tissue PDF

Summary

This document is a chapter from a textbook on human anatomy and physiology. It covers the different types of muscle tissue (skeletal, cardiac, smooth), their characteristics, functions, and related topics.

Full Transcript

Human Anatomy and Physiology
Eleventh Edition

Chapter 09 Part A
Muscles and Muscle Tissue

PowerPoint® Lectures Slides prepared by Karen Dunbar Kareiva, Ivy Tech Community College

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9.1 Overview of Muscle Tissue
Nearly half of body’s mass

Can transform chemical energy (ATP) into directed mechanical energy, which is capable
of exerting force

To investigate muscle, we look at:
– Types of muscle tissue
– Characteristics of muscle tissue
– Muscle functions

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Types of Muscle Tissue (1 of 4)
Terminologies: Myo, mys, and sarco are prefixes for muscle
– Example: sarcoplasm: muscle cell cytoplasm
Three types of muscle tissue
– Skeletal
– Cardiac
– Smooth

Only skeletal and smooth muscle cells are elongated and referred to as muscle fibers

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Types of Muscle Tissue (2 of 4)
Skeletal muscle
– Skeletal muscle tissue is packaged into skeletal muscles: organs that are
attached to bones and skin
– Skeletal muscle fibers are longest of all muscle and have striations (stripes)
– Also called voluntary muscle: can be consciously controlled
– Contract rapidly; tire easily; powerful
– Key words for skeletal muscle: skeletal, striated, and voluntary

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Types of Muscle Tissue (3 of 4)
Cardiac muscle
– Cardiac muscle tissue is found only in heart
 Makes up bulk of heart walls
– Striated
– Involuntary: cannot be controlled consciously
 Contracts at steady rate due to heart’s own pacemaker, but nervous system
can increase rate
– Key words for cardiac muscle: cardiac, striated, and involuntary

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Types of Muscle Tissue (4 of 4)
Smooth muscle
– Smooth muscle tissue: found in walls of hollow organs
 Examples: stomach, urinary bladder, and airways
– Not striated
– Involuntary: cannot be controlled consciously
– Key words for smooth muscle: visceral, nonstriated and involuntary

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Table 9.3-1 Comparison of Skeletal,
Cardiac, and Smooth Muscle

Table 9.3 Comparison of Skeletal, Cardiac, and Smooth Muscle

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Characteristics of Muscle Tissue
All muscles share four main characteristics:
– Excitability (responsiveness): ability to receive and respond to stimuli
– Contractility: ability to shorten forcibly when stimulated
– Extensibility: ability to be stretched
– Elasticity: ability to recoil to resting length

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Muscle Functions
Four important functions
1. Produce movement: responsible for all locomotion and manipulation
 Example: walking, digesting, pumping blood
2. Maintain posture and body position
3. Stabilize joints
4. Generate heat as they contract

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9.2 Skeletal Muscle Anatomy
Skeletal muscle is an organ made up of different tissues with three features: nerve and
blood supply, connective tissue sheaths, and attachments

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Nerve and Blood Supply
Each muscle receives a nerve, artery, and veins
– Consciously controlled skeletal muscle has nerves supplying every fiber to control
activity

Contracting muscle fibers require huge amounts of oxygen and nutrients
– Also need waste products removed quickly

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Connective Tissue Sheaths
Each skeletal muscle, as well as each muscle fiber, is covered in connective tissue

Support cells and reinforce whole muscle

Sheaths from external to internal:
– Epimysium: dense irregular connective tissue surrounding entire muscle; may
blend with fascia
– Perimysium: fibrous connective tissue surrounding fascicles (groups of muscle
fibers)
– Endomysium: fine areolar connective tissue surrounding each muscle fiber

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Connective Tissue Sheaths of Skeletal
Muscle: Epimysium, Perimysium, and
Endomysium (1 of 2)

Figure 9.1 Connective tissue sheaths of skeletal muscle: epimysium, perimysium, and
endomysium.
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Attachments
Muscles span joints and attach to bones

Muscles attach to bone in at least two places
– Insertion: attachment to movable bone
– Origin: attachment to immovable or less movable bone

Attachments can be direct or indirect
– Direct (fleshy): epimysium fused to periosteum of bone or perichondrium of
cartilage
– Indirect: connective tissue wrappings extend beyond muscle as ropelike tendon or
sheetlike aponeurosis

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Connective Tissue Sheaths of Skeletal
Muscle: Epimysium, Perimysium, and
Endomysium (2 of 2)

Figure 9.1a Connective tissue sheaths of skeletal muscle: epimysium, perimysium, and
endomysium.
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Table 9.1-1 Structure and Organizational
Levels of Skeletal Muscle

Table 9.1 Structure and Organizational Levels of Skeletal Muscle

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9.3 Muscle Fiber Microanatomy and
Sliding Filament Model
Skeletal muscle fibers are long, cylindrical cells that contain multiple nuclei

Sarcolemma: muscle fiber plasma membrane

Sarcoplasm: muscle fiber cytoplasm

Contains many glycosomes for glycogen storage, as well as myoglobin for O2 storage

Modified organelles
– Myofibrils
– Sarcoplasmic reticulum
– T tubules

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Myofibrils (1 of 7)
Myofibrils are densely packed, rodlike elements
– Single muscle fiber can contain 1000s
– Accounts for ~80% of muscle cell volume

Myofibril features
– Striations
– Sarcomeres
– Myofilaments
– Molecular composition of myofilaments

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Microscopic Anatomy of a Skeletal Muscle
Fiber (1 of 4)

Figure 9.2b Microscopic anatomy of a skeletal muscle fiber.

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Myofibrils (2 of 7)
Striations: stripes formed from repeating series of dark and light bands along length of
each myofibril
– A bands: dark regions
 H zone: lighter region in middle of dark A band
– M line: line of protein (myomesin) that bisects H zone vertically
– I bands: lighter regions
 Z disc (line): coin-shaped sheet of proteins on midline of light I band

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Microscopic Anatomy of a Skeletal Muscle
Fiber (2 of 4)

Figure 9.2a Microscopic anatomy of a skeletal muscle fiber.

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Myofibrils (3 of 7)
Sarcomere
– Smallest contractile unit (functional unit) of muscle fiber
– Contains A band with half of an I band at each end
 Consists of area between Z discs
– Individual sarcomeres align end to end along myofibril, like boxcars of train

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Microscopic Anatomy of a Skeletal Muscle
Fiber (3 of 4)

Figure 9.2c Microscopic anatomy of a skeletal muscle fiber.

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Myofibrils (4 of 7)
Myofilaments
– Orderly arrangement of actin and myosin myofilaments within sarcomere
– Actin myofilaments: thin filaments
 Extend across I band and partway in A band
 Anchored to Z discs
– Myosin myofilaments: thick filaments
 Extend length of A band
 Connected at M line
– Sarcomere cross section shows hexagonal arrangement of one thick filament
surrounded by six thin filaments

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Microscopic Anatomy of a Skeletal Muscle
Fiber (4 of 4)

Figure 9.2d, e Microscopic anatomy of a skeletal muscle fiber.

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Myofibrils (5 of 7)
Molecular composition of myofilaments
– Thick filaments: composed of protein myosin that contains two heavy and four
light polypeptide chains
 Heavy chains intertwine to form myosin tail
 Light chains form myosin globular head
– During contraction, heads link thick and thin filaments together, forming
cross bridges
 Myosins are offset from each other, resulting in staggered array of heads at
different points along thick filament

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Myofibrils (6 of 7)
Molecular composition of myofilaments (cont.)
– Thin filaments: composed of fibrous protein actin
 Actin is polypeptide made up of kidney-shaped G actin (globular) subunits
– G actin subunits bears active sites for myosin head attachment during
contraction
 G actin subunits link together to form long, fibrous F actin (filamentous)
 Two F actin strands twist together to form a thin filament
– Tropomyosin and troponin: regulatory proteins bound to actin

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Composition of Thick and Thin Filaments
(1 of 4)

Figure 9.3 Composition of thick and thin filaments.
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Composition of Thick and Thin Filaments
(2 of 4)

Figure 9.3 Composition of thick and thin filaments.
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Myofibrils (7 of 7)
Molecular composition of myofilaments (cont.)
– Other proteins help form the structure of the myofibril
 Elastic filament: composed of protein titin
– Holds thick filaments in place; helps recoil after stretch; resists excessive
stretching
 Dystrophin
– Links thin filaments to proteins of sarcolemma
 Nebulin, myomesin, C proteins bind filaments or sarcomeres together
– Maintain alignment of sarcomere

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Clinical – Homeostatic Imbalance 9.1 (1 of 3)
Duchenne muscular dystrophy (DMD) is most common and serious form of muscular
dystrophies, muscle-destroying diseases that generally appear during childhood

Inherited as a sex-linked recessive disease, so almost exclusively in males (1 in 3600
births)

Appears between 2 and 7 years old when boy becomes clumsy and falls frequently

Disease progresses from extremities upward, finally affecting head, chest muscles, and
cardiac muscle.

With supportive care, people with DMD can live into 30s and beyond

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Clinical – Homeostatic Imbalance 9.1 (2 of 3)
Caused by defective gene for dystrophin, a protein that links thin filaments to
extracellular matrix and helps stabilize sarcolemma

Sarcolemma of DMD patients tear easily, allowing entry of excess calcium which
damages contractile fibers

Inflammation follows and regenerative capacity is lost resulting in increased apoptosis of
muscle cells and drop in muscle mass

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A Boy with Duchenne Muscular Dystrophy
(DMD)

Figure 9.4 A boy with Duchenne muscular dystrophy (DMD).
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Clinical – Homeostatic Imbalance 9.1 (3 of 3)
chest muscles, and cardiac muscle. The weakness continues to

progress, but with supportive care, DMD patients are living into

their 30s and beyond.

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Sarcoplasmic Reticulum and T Tubules
(1 of 4)

Sarcoplasmic reticulum: network of smooth endoplasmic reticulum tubules
surrounding each myofibril
– Most run longitudinally
– Terminal cisterns form perpendicular cross channels at the A–I band junction
– SR functions in regulation of intracellular Ca2+ levels
– Stores and releases Ca2+

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Sarcoplasmic Reticulum and T Tubules
(2 of 4)

T tubules
– Tube formed by protrusion of sarcolemma deep into cell interior
 Increase muscle fiber’s surface area greatly
 Lumen continuous with extracellular space
 Allow electrical nerve transmissions to reach deep into interior of each muscle
fiber
– Tubules penetrate cell’s interior at each A–I band junction between terminal
cisterns
 Triad: area formed from terminal cistern of one sarcomere, T tubule, and
terminal cistern of neighboring sarcomere

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Sarcoplasmic Reticulum and T Tubules
(3 of 4)

Triad relationships
– T tubule contains integral membrane proteins that protrude into intermembrane
space (space between tubule and muscle fiber sarcolemma)
 Tubule proteins act as voltage sensors that change shape in response to an
electrical current
– SR cistern membranes also have integral membrane proteins that protrude into
intermembrane space
 SR integral proteins control opening of calcium channels in SR cisterns

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Sarcoplasmic Reticulum and T Tubules
(4 of 4)

Triad relationships (cont.)
– When an electrical impulse passes by, T tubule proteins change shape, causing SR
proteins to change shape, causing release of calcium into cytoplasm

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Relationship of the Sarcoplasmic Reticulum
and T Tubules to Myofibrils of Skeletal
Muscle

Figure 9.5 Relationship of the sarcoplasmic reticulum and T tubules to myofibrils of skeletal
muscle.
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Sliding Filament Model of Contraction
(1 of 3)

Contraction: the activation of cross bridges to generate force

Shortening occurs when tension generated by cross bridges on thin filaments exceeds
forces opposing shortening

Contraction ends when cross bridges become inactive

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Sliding Filament Model of Contraction
(2 of 3)

In the relaxed state, thin and thick filaments overlap only slightly at ends of A band

Sliding filament model of contraction states that during contraction, thin filaments
slide past thick filaments, causing actin and myosin to overlap more
– Neither thick nor thin filaments change length, just overlap more

When nervous system stimulates muscle fiber, myosin heads are allowed to bind to
actin, forming cross bridges, which cause sliding (contraction) process to begin

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Sliding Filament Model of Contraction
(3 of 3)

Cross bridge attachments form and break several times, each time pulling thin filaments
a little closer toward center of sarcome in a ratcheting action
– Causes shortening of muscle fiber

Z discs are pulled toward M line

I bands shorten

Z discs become closer

H zones disappear

A bands move closer to each other

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Sliding Filament Model of Contraction
(1 of 2)

Figure 9.6-1 Sliding filament model of contraction.

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Sliding Filament Model of Contraction
(2 of 2)

Figure 9.6-2 Sliding filament model of contraction.

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9.4 Muscle Fiber Contraction (2 of 2)
Background and Overview

Decision to move is activated by brain, signal is transmitted down spinal cord to motor
neurons which then activate muscle fibers

Neurons and muscle cells are excitable cells capable of action potentials
– Excitable cells are capable of changing resting membrane potential voltages

AP crosses from neuron to muscle cell via the neurotransmitter acetylcholine (ACh)

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Background and Overview (1 of 4)
Ion Channels
– Play the major role in changing of membrane potentials
– Two classes of ion channels:
 Chemically gated ion channels – opened by chemical messengers such as
neurotransmitters
– Example: ACh receptors on muscle cells
 Voltage-gated ion channels – open or close in response to voltage changes in
membrane potential

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“Chemically Gated Ion Channel” and
“Voltage-Gated ion Channel”

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Background and Overview (2 of 4)
Anatomy of Motor Neurons and the Neuromuscular Junction
– Skeletal muscles are stimulated by somatic motor neurons
– Axons (long, threadlike extensions of motor neurons) travel from central nervous
system to skeletal muscle
– Each axon divides into many branches as it enters muscle
– Axon branches end on muscle fiber, forming neuromuscular junction or motor
end plate
 Each muscle fiber has one neuromuscular junction with one motor neuron

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Overview of Skeletal Muscle Contraction
(1 of 3)

Figure 9.7 Overview of skeletal muscle contraction.

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Background and Overview (3 of 4)
– Axon terminal (end of axon) and muscle fiber are separated by gel-filled space
called synaptic cleft
– Stored within axon terminals are membrane-bound synaptic vesicles
 Synaptic vesicles contain neurotransmitter acetylcholine (ACh)
– Infoldings of sarcolemma, called junctional folds, contain millions of ACh
receptors
– NMJ consists of axon terminals, synaptic cleft, and junctional folds

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Overview of Skeletal Muscle Contraction
(2 of 3)

Figure 9.7 Overview of skeletal muscle contraction.

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Background and Overview (4 of 4)
The Big Picture - Four steps must occur for skeletal muscle to contract:
1. Events at neuromuscular junction
2. Muscle fiber excitation
3. Excitation-contraction coupling
4. Cross bridge cycling

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Overview of Skeletal Muscle Contraction
(3 of 3)

Figure 9.7 Overview of skeletal muscle contraction.

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Events at the Neuromuscular Junction
1. AP arrives at axon terminal

2. Voltage-gated calcium channels open, calcium enters motor neuron

3. Calcium entry causes release of ACh neurotransmitter into synpatic cleft

4. ACh diffuses across to ACh receptors (Na+ chemical gates) on sarcolemma

5. ACh binding to receptors, opens gates, allowing Na+ to enter resulting in end plate
potential

6. Acetylcholinesterase degrades ACh

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When a Nerve Impulse Reaches a
Neuromuscular Junction, Acetylcholine
(ACh) is Released (6 of 6)

FOCUS FIGURE 9.1 Events at the Neuromuscular Junction

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Clinical – Homeostatic Imbalance 9.2
Many toxins, drugs, and diseases interfere with events at the neuromuscular junction
– Example: myasthenia gravis: disease characterized by drooping upper eyelids,
difficulty swallowing and talking, and generalized muscle weakness
– Involves shortage of Ach receptors because person’s ACh receptors are attacked
by own antibodies
– Suggests this is an autoimmune disease

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Generation of an Action Potential Across the
Sarcolemma (1 of 4)
Resting sarcolemma is polarized, meaning a voltage exists across membrane
– Inside of cell is negative compared to outside

Action potential is caused by changes in electrical charges

Occurs in three steps
1. Generation of end plate potential
2. Depolarization
3. Repolarization

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Generation of an Action Potential Across the
Sarcolemma (2 of 4)
1. End plate potential
– ACh released from motor neuron binds to ACh receptors on sarcolemma
– Causes chemically gated ion channels (ligands) on sarcolemma to open
– Na+ diffuses into muscle fiber
 Some K+ diffuses outward, but not much
– Because Na+ diffuses in, interior of sarcolemma becomes less negative (more
positive)
– Results in local depolarization called end plate potential

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Summary of Events in the Generation and
Propagation of an Action Potential in a
Skeletal Muscle Fiber (1 of 3)

Figure 9.8 Summary of events in the generation and propagation of an action potential in a
skeletal muscle fiber.
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Generation of an Action Potential Across the
Sarcolemma (3 of 4)
2. Depolarization: generation and propagation of an action potential (AP)
– If end plate potential causes enough change in membrane voltage to reach critical
level called threshold, voltage-gated Na+ channels in membrane will open
– Large influx of Na+ through channels into cell triggers AP that is unstoppable and
will lead to muscle fiber contraction
– AP spreads across sarcolemma from one voltage-gated Na+ channel to next one in
adjacent areas, causing that area to depolarize

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Summary of Events in the Generation and
Propagation of an Action Potential in a
Skeletal Muscle Fiber (2 of 3)

Figure 9.8 Summary of events in the generation and propagation of an action potential in a
skeletal muscle fiber.
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Generation of an Action Potential Across the
Sarcolemma (4 of 4)
3. Repolarization: restoration of resting conditions
– Na+ voltage-gated channels close, and voltage-gated K+ channels open
– K+ efflux out of cell rapidly brings cell back to initial resting membrane voltage
– Refractory period: muscle fiber cannot be stimulated for a specific amount of
time, until repolarization is complete
– Ionic conditions of resting state are restored by Na+-K+ pump
 Na+ that came into cell is pumped back out, and K+ that flowed outside is
pumped back into cell

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Summary of Events in the Generation and
Propagation of an Action Potential in a
Skeletal Muscle Fiber (3 of 3)

Figure 9.8 Summary of events in the generation and propagation of an action potential in a
skeletal muscle fiber.
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Action Potential Tracing Indicates Changes
in Na+ and K+ ion Channels

Figure 9.9 Recording of an action potential (AP) in a muscle fiber.

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Excitation-Contraction (E-C) Coupling
Excitation-contraction (E-C) coupling: events that transmit AP along sarcolemma
(excitation) are coupled to sliding of myofilaments (contraction)

AP is propagated along sarcolemma and down into T tubules, where voltage-sensitive
proteins in tubules stimulate Ca2+ release from SR
– Ca2+ release leads to contraction

AP is brief and ends before contraction is seen

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Excitation-Contraction (E-C) Coupling is the Sequence of
Events by Which Transmission of an Action Potential Along
the Sarcolemma Leads to the Sliding of Myofilaments (1 of 3)

FOCUS FIGURE 9.2 Excitation-Contraction Coupling
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Excitation-Contraction (E-C) Coupling is the Sequence of
Events by Which Transmission of an Action Potential Along
the Sarcolemma Leads to the Sliding of Myofilaments (2 of 3)

FOCUS FIGURE 9.2 Excitation-Contraction Coupling
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Excitation-Contraction (E-C) Coupling is the Sequence of
Events by Which Transmission of an Action Potential Along
the Sarcolemma Leads to the Sliding of Myofilaments (3 of 3)

FOCUS FIGURE 9.2 Excitation-Contraction Coupling
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Muscle Fiber Contraction: Cross Bridge
Cycling (1 of 3)
At low intracellular Ca2+ concentration:
– Tropomyosin blocks active sites on actin
– Myosin heads cannot attach to actin
– Muscle fiber remains relaxed

Voltage-sensitive proteins in T tubules change shape, causing sarcoplasmic reticulum
(SR) to release Ca2+ to cytosol

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Muscle Fiber Contraction: Cross Bridge
Cycling (2 of 3)
At higher intracellular Ca2+ concentrations, Ca2+ binds to troponin

Troponin changes shape and moves tropomyosin away from myosin-binding sites

Myosin heads is then allowed to bind to actin, forming cross bridge

Cycling is initiated, causing sarcomere shortening and muscle contraction

When nervous stimulation ceases, Ca2+ is pumped back into SR, and contraction ends

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Muscle Fiber Contraction: Cross Bridge
Cycling (3 of 3)
Four steps of the cross bridge cycle
1. Cross bridge formation: high-energy myosin head attaches to actin thin filament
active site
2. Working (power) stroke: myosin head pivots and pulls thin filament toward M line
3. Cross bridge detachment: ATP attaches to myosin head, causing cross bridge to
detach
4. Cocking of myosin head: energy from hydrolysis of ATP “cocks” myosin head
into high-energy state
 This energy will be used for power stroke in next cross bridge cycle

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The Cross Bridge Cycle is the Series of Events During
Which Myosin Heads Pull Thin Filaments Toward the
Center of the Sarcomere (4 of 4)

FOCUS FIGURE 9.3 Cross Bridge Cycle
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Clinical – Homeostatic Imbalance 9.3
Rigor mortis
– 3–4 hours after death, muscles begin to stiffen
 Peak rigidity occurs about 12 hours postmortem
– Intracellular calcium levels increase because ATP is no longer being synthesized,
so calcium cannot be pumped back into SR
 Results in cross bridge formation
– ATP is also needed for cross bridge detachment
 Results in myosin head staying bound to actin, causing constant state of
contraction
– Muscles stay contracted until muscle proteins break down, causing myosin to
release

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Copyright

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