VanPutte_Seeleys_Essentials_11e_Chap07_PPT_Accessible.pptx

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Chapter 7
Muscular System
Lecture Outline
Seeley’s ESSENTIALS OF
ANATOMY & PHYSIOLOGY
Eleventh Edition
Cinnamon VanPutte
Jennifer Regan
Andrew Russo

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Types of Muscles

Skeletal
attached to bones
striated
voluntarily controlled
Cardiac
located in the heart
striated
involuntarily controlled
Smooth
Located in blood vessels, hollow organs
Non-striated
involuntarily controlled
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The Muscular System

Functions
1. Movement
2. Maintain posture
3. Respiration
4. Production of body heat
5. Communication
6. Constriction of organs and vessels
7. Contraction of the heart
Figure 7.1
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Functional Properties of Muscles

Contractility - the ability of muscle to shorten forcefully, or
contract
Excitability - the capacity of muscle to respond to a
stimulus
Extensibility - the ability to be stretched beyond its normal
resting length and still be able to contract
Elasticity - the ability of the muscle to recoil to its original
resting length after it has been stretched

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Whole Skeletal Muscle Anatomy 1

Skeletal muscle, or striated muscle, with its associated
connective tissue, constitutes approximately 40% of body
weight.
Skeletal muscle is so named because many of the
muscles are attached to the skeletal system.
Some skeletal muscles attach to the skin or connective
tissue sheets.

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Whole Skeletal Muscle Anatomy 2

Skeletal muscle is also called striated muscle because
transverse bands, or striations, can be seen in the muscle
under the microscope.
Individual skeletal muscles, such as the biceps brachii, are
complete organs, as a result of being comprised of several
tissues: muscle, nerve, and connective tissue.

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Connective Tissue Coverings

Each skeletal muscle is surrounded by a connective tissue
sheath called the epimysium.
A skeletal muscle is subdivided into groups of muscle
cells, termed fascicles.
Each fascicle is surrounded by a connective tissue
covering, termed the perimysium.
Each skeletal muscle cell (fiber) is surrounded by a
connective tissue covering, termed the endomysium.

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Skeletal Muscle Fiber Anatomy 1

A muscle fiber is a large cell, with several hundred nuclei
located at its periphery.
Muscle fibers range in length 1 mm to 30 cm.
Alternating light and dark bands give muscle fibers a
striated appearance.
The number of muscle fibers remains constant after birth
so enlargement of muscles results from an increase in the
size of muscle fibers, not an increase in fiber number.

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Electrical Component Structures 1

The sarcolemma (cell membrane) has many tubelike
inward folds, called transverse tubules, or T tubules.
T tubules occur at regular intervals along the muscle fiber
and extend into the center of the muscle fiber.
The T tubules are associated with enlarged portions of the
smooth endoplasmic reticulum called the sarcoplasmic
reticulum.

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Electrical Component Structures 2

The enlarged portions are called terminal cisternae.
Two terminal cisternae and their associated T tubule form
a muscle triad.
The sarcoplasmic reticulum has a relatively high
concentration of Ca2+, which plays a major role in muscle
contraction.
The cytoplasm of a muscle fiber is called the sarcoplasm,
which contains many bundles of protein filaments.

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Structure of Skeletal Muscle

Figure 7.2
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Mechanical Component Structures

Bundles of protein filaments are called myofibrils.
Myofibrils consist of two types of myofilaments, actin
(thin filaments) and myosin (thick filaments).
Actin and myosin are arranged into repeating units called
sarcomeres.
The myofilaments in the sarcomere provide for the
mechanical aspect of muscle contraction.

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The Sarcomere 1

The sarcomere is the basic structural and functional unit of
skeletal muscle.
Sarcomeres join end to end to create myofibrils.
Z disks are network of protein fibers that serve as an
anchor for actin myofilaments and separate one
sarcomere from the next.
A sarcomere extends from one Z disk to the next Z disk.

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The Sarcomere 2

The organization of actin and myosin myofilaments gives
skeletal muscle its striated appearance and gives it the
ability to contract.
The myofilaments slide past each other, causing the
sarcomeres to shorten.
Each sarcomere consists of two light-staining bands
separated by a dark-staining band.

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The Sarcomere 3

Light bands, consist only of actin, and are called I bands.
They extend from the Z disc, toward the center of the
sarcomere, to the ends of the myosin myofilaments.
Dark staining bands are called A bands. They extend the
length of the myosin myofilaments.
Actin and myosin myofilaments overlap for some distance
on both ends of the A band; this overlap causes the
contraction.

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Myofilament Structure

Actin myofilaments are made up of three components:
actin, troponin, and tropomyosin.
Troponin molecules have binding sites for Ca2+ and
tropomyosin filaments block the myosin myofilament
binding sites on the actin myofilaments.
Myosin myofilaments, or thick myofilaments, resemble
bundles of tiny golf clubs.
Myosin heads have ATP binding sites, ATPase and
attachment spots for actin.

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Skeletal Muscle Fiber

(a) SPL/Getty Images

Figure 7.3
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Neuromuscular Junction Structure 1

A motor neuron is a nerve cell that stimulates muscle
cells.
A neuromuscular junction is a synapse where a neuron
connects with a muscle fiber.
A synapse refers to the cell-to-cell junction between a
nerve cell and either another nerve cell or an effector cell,
such as in a muscle or a gland.
A motor unit is a group of muscle fibers that a single
motor neuron stimulates.

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Neuromuscular Junction Structure 2

A presynaptic terminal is the end of a neuron cell axon
fiber.
A synaptic cleft is the space between the presynaptic
terminal and postsynaptic membrane.
The postsynaptic membrane is the muscle fiber
membrane (sarcolemma).
A synaptic vesicle is a vesicle in the presynaptic terminal
that stores and releases neurotransmitter chemicals.

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Neuromuscular Junction Structure 3

Neurotransmitters are chemicals that stimulate or inhibit
postsynaptic cells.
Acetylcholine is the neurotransmitter that stimulates
skeletal muscles.

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Neuromuscular Junction

Figure 7.4
(b) Ed Reschke/Photolibrary/Getty Images

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Sliding Filament Model

When a muscle contracts, the actin and myosin
myofilaments in the sarcomere slide past one another and
shorten the sarcomere.
When sarcomeres shorten, myofibrils, muscle fibers,
muscle fascicles, and muscles all shorten to produce
muscle contraction.
During muscle relaxation, sarcomeres lengthen.

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Excitability of Muscle Fibers

Muscle fibers are electrically excitable.
Electrically excitable cells are polarized.
The inside of the cell membrane is negatively charged
compared with the outside.
A voltage difference, or electrical charge difference, exists
across each cell membrane.
The charge difference is due to differences in
concentrations of ions on either side of the membrane.

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Ion Channels

The phospholipid bilayer is impermeable to ions.
Two types of membrane proteins, called ion channels,
permit ions to pass through the membrane.
Leak channels allow the slow leak of ions down their
concentration gradient.
Gated channels may open or close in response to various
types of stimuli.

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Resting Membrane Potential 1

The electrical charge difference across the cell membrane
of an unstimulated cell is called the resting membrane
potential.
Muscle cells (fibers) have a resting membrane potential but
can also perform action potentials.
The resting membrane potential is due to the inside of the
membrane being negatively charged in comparison to the
outside of the membrane which is positively charged.
Action potentials are due to the membrane having gated
channels.

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Resting Membrane Potential 2

The resting membrane potential exists because of:
The concentration of K+ being higher on the inside of the
cell membrane and the concentration of Na+ being higher
on the outside
The presence of many negatively charged molecules, such
as proteins, inside the cell that are too large to exit the cell
The presence of leak channels in the membrane that are
more permeable to K+ than they are to Na+

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Resting Membrane Potential 3

Na+ tends to diffuse into the cell and K+ tends to diffuse out.
In order to maintain the resting membrane potential, the
sodium-potassium pump recreates the Na+ and K+ ion
gradient by pumping Na+ out of the cell and K+ into the cell.

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Resting Membrane Potential 4

Figure 7.6b
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Action Potentials 1

An action potential reverses the resting membrane potential
so that the inside of the cell becomes positive and the
outside negative.
Occurs because gated ion channels open when the cell is
stimulated.
The diffusion of ions through these channels changes the
charge across the cell membrane and produces an action
potential.
Action potential lasts for 1 to 3 milliseconds.

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Action Potential 2

The entry of Na+ causes the inside of the cell membrane to
become more positive than when the cell is at resting
membrane potential.
This increase in positive charge inside the cell membrane is
called depolarization.
If the depolarization changes the membrane potential to a
value called threshold, an action potential is triggered.
An action potential is a rapid change in charge across the
cell membrane.

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Action Potential 3

The action potential travels across the sarcolemma.
Near the end of depolarization, the positive charge causes
gated Na+ channels to close and gated K+ channels to open.
Opening of gated K+ channels starts repolarization of the
cell membrane.

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Action Potential 4

Repolarization is due to the exit of K+ from the cell.
The outward diffusion of K+ returns the cell to its resting
membrane conditions and the action potential ends.
In a muscle fiber, an action potential results in muscle
contraction.

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Resting Membrane Potential

Figure 7.7(1)
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Depolarization

change in charges inside becomes more + and outside
more – Na+ channels open

Figure 7.7 (2)
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Repolarization

Na+ channels close change back to resting potential

Figure 7.7 (3)
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Ion Channels and Action Potentials

Figure 7.7
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Function of the Neuromuscular Junction 1

Each muscle fiber is innervated by a branch of a motor
neuron at a neuromuscular junction.
Contact between the axon terminal and the sarcolemma
results in an action potential in the muscle fiber which, in
turn, stimulates the fiber to contract.
The action potential is stimulated by the release of
acetylcholine from the motor neuron.

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Function of the Neuromuscular Junction 2

Figure 7.8
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Muscle Contraction 1

1. An action potential travels down the motor neuron to the
presynaptic terminal.
2. The action potential causes Ca2+ channels to open and
Ca2+ to enter the terminal.
3. Ca2+ causes synaptic vesicles to release acetylcholine into
synaptic cleft.
4. Acetylcholine opens Na+ channels in the sarcolemma and
causes an action potential.

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Muscle Contraction 2

5. The action potential travels along the entire sarcolemma
6. The action potential moves down T tubules.
7. Action potentials open gated Ca2+ channels in the
sarcoplasmic reticulum which releases stored calcium.

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Muscle Contraction 3

8. Ca2+ binds to troponin which is attached to actin causing
tropomyosin to move exposing attachment sites for
myosin. Myosin heads bind to actin. Muscles contract
when cross bridges move.
9. The heads of the myosin myofilaments bend, causing the
actin to slide past the myosin. As long as Ca2+ is present,
the cycle repeats.

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Skeletal Muscle Excitation 1

Figure 7.9 (1,2,3,4)
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Skeletal Muscle Excitation 4

Figure 7.9 (5,6,7)
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Skeletal Muscle Excitation 6

Figure 7.9 (8,9)
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Cross Bridge Movement

The mechanical component of muscle contraction is called
cross-bridge cycling.
The energy from one ATP molecule is required for one
cross bridge cycle.

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ATP and Muscle Contractions

Energy for muscle contractions is supplied by ATP.
Energy is released as ATP → ADP + Pi and energy from
ATP is stored in myosin heads.
A new ATP must bind to myosin before cross-bridge is
released.
Rigor mortis will occur when a person dies and no ATP is
available to release cross-bridges.

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ATP Breakdown and Cross-Bridge Movement

Figure 7.10
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Muscle Relaxation 1

Muscle relaxation occurs when acetylcholine is no longer
released at the neuromuscular junction.
Action potentials to the sarcoplasmic reticulum stop.
Ca2+ is actively transported back into the sarcoplasmic
reticulum using energy supplied by ATP.

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Muscle Relaxation 2

Ca2+ diffuses away from the troponin molecules and
tropomyosin again blocks the attachment sites on the actin
molecules.
The cross-bridge cycle stops and the muscle relaxes.

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Muscle Twitch 1

A muscle twitch is a single contraction of a muscle fiber in
response to a stimulus.
A muscle twitch has three phases: latent phase, contraction
phase, and relaxation phase.
The latent phase is the time between the application of a
stimulus and the beginning of contraction.
The contraction phase is the time during which the muscle
contracts and the relaxation phase is the time during which
the muscle relaxes.

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Muscle Twitch 2

Figure 7.11
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Types of Contractions

There are two types of muscle contractions: isometric and
isotonic.
The isometric contraction has an increase in muscle
tension, but no change in length.
The isotonic contraction increases the tension in a muscle
and decreases the length.

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Summation and Recruitment 1

The strength of muscle contraction strength depends on
two factors:
The amount of force in an individual muscle fiber, called
summation
The amount of force in a whole muscle, called recruitment.

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Motor Unit

A motor unit consists of a single motor neuron and all the
muscle fibers it innervates.
An action potential in the neuron of a motor unit causes
contraction of all the muscle fibers in that unit.
Small, delicate muscles have very few fibers per motor unit.
Large, powerful, less precise muscles have fewer, larger
motor units.

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Force of Contraction in Individual Muscle Fibers 1

Individual muscle fibers can generate different amounts of
force.
The amount of force generated depends upon the number
of cross-bridges formed.
More cross-bridges creates more force.
One factor that influences the number of cross-bridges
formed is the frequency of stimulation.

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Force of Contraction in Individual Muscle Fibers 2

A low frequency of stimuli allows a muscle fiber to undergo
twitches that contract then fully relax.
If the frequency of stimuli increases, the muscle fiber is
unable to relax completely between twitches, more cross
bridges form and summation occurs. The tension
generated by the muscle increases.

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Summation and Recruitment 2

Incomplete Tetanus occurs when the frequency of
stimulation only allows for partial relaxation of the muscle
fiber.
Tetanus is a sustained contraction that occurs when the
frequency of stimulation is so rapid that no relaxation
occurs.
Recruitment is the stimulation of several motor units.

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Multiple-Wave Summation

Figure 7.12
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Muscle Tone

Muscle tone is the constant tension produced by body
muscles over long periods of time.
Muscle tone is responsible for keeping the back and legs
straight, the head in an upright position, and the abdomen
from bulging.
Muscle tone depends on a small percentage of all the motor
units in a muscle being stimulated at any point in time,
causing their muscle fibers to contract tetanically and out of
phase with one another.

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Types of Isotonic Contractions 2

Concentric contractions are isotonic contractions in which
muscle tension increases as the muscle shortens.
Eccentric contractions are isotonic contractions in which
tension is maintained in a muscle, but the opposing
resistance causes the muscle to lengthen.

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Skeletal Muscle Fiber Types 1

Slow twitch fibers
contract slowly
fatigue slowly
have a considerable amount of myoglobin
use aerobic respiration
are dark in color
used by long distance runners

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Skeletal Muscle Fiber Types 2

Fast twitch fibers
contract quickly
fatigue quickly
use anaerobic respiration
energy from glycogen
light color
used by sprinters

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Skeletal Muscle Fiber Types 3

Most human muscles have a blend of fast twitch and slow
twitch fibers. The amount of each type varies for each
muscle.
The large postural muscles of the back and lower limbs
contain more slow-twitch fibers.
The muscles of the upper limbs contain more fast-twitch
muscle fibers.

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Energy for Muscle Contractions 1

Muscle fibers have three ATP dependent proteins
The myosin head
The Na+/K+ ATPase to maintain resting membrane
potential
The Ca2+ pump in the sarcoplasmic reticulum
Muscle fibers store enough ATP to contract for about 5–6
seconds. If contraction is to continue beyond this time, more
ATP must be produced.

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Energy for Muscle Contractions 2

ATP is derived from four processes in skeletal muscle.
1. Conversion of two ADP to one ATP and one adenosine
monophosphate (AMP) by the enzyme adenylate kinase
2. Transfer of a phosphate from a molecule called creatine
(krē′a-tēn) phosphate by the enzyme creatine kinase from
ADP to form ATP

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Energy for Muscle Contractions 3

3. Anaerobic production of ATP during intensive short-term
exercise
4. Aerobic production of ATP during most exercise and
normal conditions

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ATP Production as Exercise Progresses 1

Muscle fibers store enough ATP for about 5 to 6 seconds of
contraction.
Next, ATP production by adenylate kinase and creatine
kinase occurs. This is depleted after about 15 seconds.
When a muscle fiber is working too strenuously for ATP
stores and creatine phosphate to be able to provide enough
ATP, anaerobic respiration predominates.

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ATP Production as Exercise Progresses 2

Fast-twitch muscle fibers are the primary anaerobic muscle
fibers.
Slow-twitch fibers utilize aerobic pathways.
The lactate produced by anaerobic fast-twitch fibers is used
as a starting point for aerobic ATP production in slow-twitch
fibers.

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Muscle Fatigue 1

Fatigue is a temporary state of reduced work capacity.
Without fatigue, muscle fibers would be worked to the point
of structural damage to them and their supportive tissues.

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Muscle Fatigue 2

Mechanisms of fatigue include:
Acidosis and ATP depletion due to either an increased ATP
consumption or a decreased ATP production
Oxidative stress, which is characterized by the buildup of
excess reactive oxygen species (ROS; free radicals)
Local inflammatory reactions

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Muscle Soreness

Following vigorous exercise, people sometimes experience
muscle pain, which can last for several days.
The pain is related to the effects of inflammatory chemicals
on the muscle fibers.
Exercise schedules that alternate exercise with periods of
rest, such as lifting weights every other day, provide time for
the repair of muscle tissue.

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Oxygen Deficit

There are two distinct phases of O2 use:
Oxygen deficit is the lag time between when a person
begins to exercise and when they begin to breathe more
heavily because of the exercise.
Excess postexercise oxygen consumption is the lag
time before breathing returns to its preexercise rate once
exercise stops.

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Smooth Muscle

Smooth muscle cells are non-striated small, spindle-shaped
muscle cells, usually with one nucleus per cell.
The myofilaments are not organized into sarcomeres.
The cells comprise organs controlled involuntarily, except
the heart.
Neurotransmitter substances, hormones, and other factors
can stimulate smooth muscle.

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Cardiac Muscle 1

Cardiac muscle cells are long, striated, and branching, with
usually only one nucleus per cell.
Cardiac muscle is striated as a result of the sarcomere
arrangement.
Cardiac muscle contraction is autorhythmic.

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Cardiac Muscle 2

Cardiac muscle cells are connected to one another by
specialized structures that include desmosomes and gap
junctions called intercalated disks.
Cardiac muscle cells function as a single unit in that action
potential in one cardiac muscle cell can stimulate action
potentials in adjacent cells.

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Skeletal Muscle Anatomy 1

A tendon connects skeletal muscle to bone.
Aponeuroses are broad, sheetlike tendons.
A retinaculum is a band of connective tissue that holds
down the tendons at each wrist and ankle.
Skeletal muscle attachments have an origin and an
insertion, with the origin being the attachment at the least
mobile location.
The insertion is the end of the muscle attached to the bone
undergoing the greatest movement.

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Skeletal Muscle Anatomy 2

The part of the muscle between the origin and the insertion
is the belly.
A group of muscles working together are called agonists.
A muscle or group of muscles that oppose muscle actions
are termed antagonists.

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Muscle Attachment

Figure 7.14
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Muscle Names 1

Muscles are named according to:
1. Location – a pectoralis muscle is located in the chest.
2. Size – the size could be large or small, short or long.
3. Shape - the shape could be triangular, quadrate,
rectangular, or round.
4. Orientation of fascicles – fascicles could run straight
(rectus) or at an angle (oblique).

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Muscle Names 2

5. Origin and insertion. The sternocleidomastoid has its origin
on the sternum and clavicle and its insertion on the
mastoid process of the temporal bone.
6. Number of heads. A biceps muscle has two heads
(origins), and a triceps muscle has three heads (origins).
7. Function. Abductors and adductors are the muscles that
cause abduction and adduction movements.

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Skeletal Muscles 1

Figure 7.15a
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Skeletal Muscles 2

Figure 7.15b
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Muscles of Mastication

Temporalis
Masseter
Pterygoids (two pairs)

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Muscles of Facial Expression and Mastication

Figure 7.16
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(b) McGraw Hillwritten consent of McGraw
Education/Photo Hill LLC.
and Dissection by Christine Eckel 84
Tongue and Swallowing Muscles

Figure 7.17
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Deep Neck and Back Muscles

Figure 7.18
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Thoracic Muscles

External intercostals:
elevate ribs for inspiration
Internal intercostals:
depress ribs during forced expiration
Diaphragm:
moves during quiet breathing

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Muscles of the Thorax

Figure 7.19
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Abdominal Wall Muscles 1

Rectus abdominis:
center of abdomen
compresses abdomen
External abdominal oblique:
sides of abdomen
compresses abdomen

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Abdominal Wall Muscles 2

Internal abdominal oblique:
compresses abdomen
Transverse abdominis:
compresses abdomen

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Muscles of the Anterior Abdominal Wall

Figure 7.20
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Pelvic Diaphragm Muscles 1

Levator ani
Ischiocavernosus
Bulbospongiosus
Deep transverse perineal
Superficial transverse perineal

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Pelvic Diaphragm Muscles 2

Figure 7.21
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Upper Scapular and Limb Muscles 1

Trapezius:
shoulders and upper back
extends neck and head
Pectoralis major:
chest
elevates ribs

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Upper Scapular and Limb Muscles 2

Serratus anterior:
between ribs
elevates ribs
Deltoid:
shoulder
abductor or upper limbs

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Muscles of the Shoulder

Figure 7.22
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Upper Limb Muscles 1

Triceps brachii:
3 heads
extends elbow
Biceps brachii:
“flexing muscle”
flexes elbow and shoulder

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Upper Limb Muscles 2

Brachialis:
flexes elbow
Latissimus dorsi:
lower back
extends shoulder

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Arm Muscles

(a) McGraw Hill Education/Photo and Dissection by Christine Eckel

Figure 7.23
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Forearm Muscles

Flexor longus
Flexor carpi radialis
Flexor carpi ulnaris
Flexor digitorum profundus
Flexor digitorum superficialis
Pronator
Brachioradialis
Extensor carpi radialis brevis

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Muscles of the Forearm

Figure 7.24
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Muscles of Hips and Thighs

Iliopsoas:
flexes hip
Gluteus maximus:
buttocks
extends hip and abducts thigh
Gluteus medius:
Hip
abducts and rotates thigh

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Muscles of the Upper Leg 1

The quadriceps femoris is comprised of 4 thigh muscles:
The rectus femoris:
front of thigh
extends knee and flexes hip
The vastus lateralis:
extends knee
The vastus medialis:
extends knee
The vastus intermedius:
extends knee
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Muscles of the Upper Leg 2

Gracilis:
adducts thigh and flexes knee
Biceps femoris, semimembranosus, semitendinosus:
Hamstring
back of thigh
flexes knee, rotates leg, extends hip

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Muscles of the Upper Leg 3

The rectus femoris:
front of thigh
extends knee and flexes hip
The vastus lateralis:
extends knee
The vastus medialis:
extends knee
The vastus intermedius:
extends knee

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Muscles of the Hip and Thigh

Figure 7.25
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Muscles of Lower Leg

Tibialis anterior:
front of lower leg
inverts foot
Gastrocnemius:
calf
flexes foot and leg
Soleus:
attaches to ankle
flexes foot

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Lower Leg Muscles

Figure 7.26
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