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Chapter 9 Muscle Tissue

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Title: Chapter 9 Muscle Tissue


1
Chapter 9 Muscle Tissue
  • Lab exam next Thurs. 2/12
  • CPR practice, essay entry complete this morning,
    remainder due next Tuesday
  • Knee dissection Tuesday2/5

2
Objectives
  • Discuss organization and functions of muscle as
    an organ including all tissue types
  • Describe the structural modifications of muscle
    cells and their functional significance
  • Describe the neuromuscular junction and events
  • Discuss the sliding filament theory
  • Describe a motor unit and neural control of
    muscle
  • Explain the link between anatomy physiology
    exemplified in the length/tension curve
  • Compare and contrast the three types of skeletal
    muscle cells and relate these to muscular
    performance
  • Compare and contrast the three types of muscle
    tissue
  • Discuss developmental changes of muscle
  • Apply knowledge of levers to human skeletal
    muscles(if time)

3
Muscle Function
  • Movement including moving substances within
    body
  • Contract against resistance
  • Skeletal move against bone
  • Cardiac move against fluid blood
  • Smooth move against other contents
  • Muscles also maintain posture stabilize joints
  • Regulate organ volume
  • Generate heat

4
Functional Characteristics of Muscle Tissue
  • Contractility the ability to shorten forcibly
    is the unique feature of muscle
  • Excitability, or irritability the ability to
    receive and respond to stimuli, have action
    potentials like neurons
  • Extensibility the ability to be stretched or
    extended
  • Elasticity the ability to recoil and resume the
    original resting length

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7
Skeletal Muscle Organs
  • Organs include muscle tissue, blood vessels,
    nerve fibers, and connective tissue
  • The three connective tissue wrappings are
  • Epimysium an overcoat of dense regular CT that
    surrounds the entire muscle
  • Perimysium fibrous CT that surrounds groups of
    muscle fibers called fascicles
  • Endomysium fine sheath of CT composed of
    reticular fibers surrounding each muscle fiber

8
Skeletal Muscle Nerve and Blood Supply
  • Each muscle is served by at least one nerve,
    artery, and vein
  • Each skeletal muscle fiber is supplied with a
    nerve ending that controls contraction a
    neuromuscular junction
  • Contracting fibers require continuous delivery of
    oxygen and nutrients via arteries
  • Wastes must be removed via veins

9
Skeletal Muscle Attachments
  • Muscles span joints and are attached in at least
    two places
  • When muscles contract the movable bone, the
    muscles insertion moves toward the immovable
    bone the muscles origin (i.e., origin is
    stationary flawed concept, but customary)
  • Muscles attach
  • Directly epimysium of the muscle is fused to
    the periosteum of a bone
  • Indirectly (more common) CT wrappings extend
    beyond the muscle as ropelike tendon or sheetlike
    aponeurosis

10
Microscopic Anatomy of a Skeletal Muscle Fiber
  • Each fiber is a long, cylindrical cell with
    multiple nuclei just beneath the sarcolemma
  • Fibers are 10 to 100 ?m in diameter, and up to
    hundreds of centimeters long
  • Each cell is a syncytium produced by fusion of
    myoblasts (embryonic cells)
  • Sarcoplasm has a unique oxygen-binding protein
    called myoglobin
  • Fibers contain the usual organelles plus
    myofibrils, sarcoplasmic reticulum, and T tubules

11
Myoblasts
Syncytium
Note satellite cells
Muscle Cell Formation
12
Sarcoplasmic Reticulum (SR)
  • SR is an elaborate smooth endoplasmic reticulum
    that mostly runs longitudinally and surrounds
    each myofibril
  • Paired terminal cisternae form perpendicular
    cross channels
  • Functions in the regulation of intracellular
    calcium levels
  • Elongated tubes called T tubules penetrate into
    the cells interior at each A bandI band
    junction
  • T tubules associate with the paired terminal
    cisternae to form triads

13
T Tubules
  • T tubules are continuous with the sarcolemma
  • They conduct impulses to the deepest regions of
    the muscle
  • These impulses signal for the release of Ca2
    from adjacent terminal cisternae

14
Myofibrils
  • Myofibrils are densely packed, rodlike
    contractile elements
  • They make up most of the muscle volume
  • The arrangement of myofibrils within a fiber is
    such that a perfectly aligned repeating series of
    dark A bands and light I bands is evident

Figure 9.2b
15
Sarcomeres
  • The smallest contractile unit of a muscle
  • The region of a myofibril between two successive
    Z discs
  • Composed of myofilaments made up of contractile
    proteins
  • Myofilaments are of two major types thick and
    thin

16
Myofilaments Banding Pattern
  • Thick filaments extend the entire length of an
    A band
  • Thin filaments extend across the I band and
    partway into the A band
  • Z-disc coin-shaped sheet of proteins
    (connectins) that anchors the thin filaments and
    connects myofibrils to one another

17
Myofilaments Banding Pattern
  • Thin filaments do not overlap thick filaments in
    the lighter H zone
  • M lines appear darker due to the presence of the
    protein desmin
  • Elastic filaments of protein titin

18
Ultrastructure of MyofilamentsThick Filaments
  • Each myosin molecule has a rodlike tail and two
    globular heads
  • Tails two interwoven, heavy polypeptide chains
  • Heads two smaller, light polypeptide chains
    called cross bridges

Figure 9.3a, b
19
Ultrastructure of MyofilamentsThick Filaments
  • Thick filaments are composed of the protein
    myosin
  • Myosin heads contain
  • 2 smaller, light polypeptide chains that act as
    cross bridges during contraction
  • Binding sites for actin of thin filaments
  • Binding sites for ATP
  • ATPase enzymes

20
Ultrastructure of Myofilaments Thin Filaments
  • Thin filaments are chiefly composed of protein
    actin
  • Each actin molecule is a helical polymer of
    globular subunits called G actin
  • The subunits contain the active sites to which
    myosin heads attach during contraction
  • Tropomyosin (filamentous protein) and troponin
    are regulatory subunits bound to actin

21
Arrangement of Filaments in a Sarcomere
  • Longitudinal section within one sarcomere

Figure 9.3d
22
Sliding Filament Mechanism of Contraction
  • Thin filaments slide past the thick ones so that
    the actin and myosin filaments overlap to a
    greater degree
  • In the relaxed state, thin and thick filaments
    overlap only slightly
  • Upon stimulation, myosin heads bind to actin and
    sliding begins (interactive physiology page 17)
  • Each myosin head binds and detaches several times
    during contraction, acting like a ratchet to
    generate tension and propel the thin filaments to
    the center of the sarcomere
  • As this event occurs throughout the sarcomeres,
    the muscle shortens

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The Sliding Filament Theory
Figure 9.7 Changes in a Sarcomere
25
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26
Sarcomere Structure
Figure 9.4b Sarcomere Structure
27
Regulation of Contraction
  • In order to contract, a skeletal muscle must
  • Be stimulated by a nerve ending (NMJ)
  • Propagate an electrical current, or action
    potential, along its sarcolemma (T-tubules)
  • Have a rise in intracellular Ca2 levels, the
    final trigger for contraction (SR)

28
Nerve Stimulus of Skeletal Muscle
  • Skeletal muscles are stimulated by motor neurons
    of the somatic nervous system
  • Axons of these neurons travel in nerves to muscle
    cells
  • Axons of motor neurons branch profusely as they
    enter muscles
  • Each axonal branch forms a neuromuscular junction
    with a single muscle fiber

29
Neuromuscular Junction
  • The neuromuscular junction is
  • Axonal endings, which have small membranous sacs
    (synaptic vesicles) that contain the
    neurotransmitter acetylcholine (ACh)
  • The motor end plate of a muscle, which is a
    specific part of the sarcolemma that contains ACh
    receptors that helps form the neuromuscular
    junction
  • Though exceedingly close, axonal ends and muscle
    fibers are always separated by a space called the
    synaptic cleft

30
Neuromuscular Junction
Figure 9.8a, b
31
Neuromuscular Junction
  • When a nerve impulse reaches the end of an axon
    at the neuromuscular junction
  • Voltage-regulated calcium channels open and allow
    Ca2 to enter the axon
  • Ca2 inside the axon terminal causes axonal
    vesicles to fuse with the axonal membrane
  • This fusion releases ACh into the synaptic cleft
    via exocytosis
  • ACh diffuses across the synaptic cleft to ACh
    receptors on the sarcolemma
  • Binding of ACh to its receptors initiates an
    action potential in the muscle

32
Neuromuscular Junction
Figure 9.8c
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34
Summary
35
Excitation-Contraction Coupling
36
Motor Unit The Nerve-Muscle Functional Unit
  • A motor unit is a motor neuron and all the muscle
    fibers it supplies
  • The number of muscle fibers per motor unit can
    vary from four to several hundred
  • Muscles that control fine movements (fingers,
    eyes) have small motor units

37
Motor Unit The Nerve-Muscle Functional Unit
  • Large weight-bearing muscles (thighs, hips) have
    large motor units
  • Muscle fibers from a motor unit are spread
    throughout the muscle therefore, contraction of
    a single motor unit causes weak contraction of
    the entire muscle

38
Neuromuscular Junction
39
Muscle Tone
  • Muscle tone
  • The constant, slightly contracted state of all
    muscles, which does not produce active movements
  • Keeps the muscles firm, healthy, and ready to
    respond to stimulus
  • Spinal reflexes account for muscle tone by
  • Activating one motor unit and then another
  • Responding to activation of stretch receptors in
    muscles and tendons

40
Force of Contraction
  • The force of contraction is affected by
  • The number of muscle fibers contracting the
    more motor fibers in a muscle, the stronger the
    contraction
  • The relative size of the muscle the bulkier
    the muscle, the greater its strength

Figure 9.19a
41
Force of Contraction
  • Frequency of stimulation
  • Length-tension relationships
  • Series-elastic elements the noncontractile
    structures in a muscle
  • Degree of muscle stretch muscles contract
    strongest when muscle fibers are 80-120 of their
    normal resting length

Figure 9.19a
42
Length/Tension Relationship
Maximum force generated between 80-120 of
resting length, interactive physiology page
16 Think of cross-bridge mechanism for explanation
43
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44
Muscle Fiber Type Functional Characteristics
  • Speed of contraction determined by speed in
    which ATPases split ATP
  • The three types of fibers are slow and fast and
    intermediate
  • ATP-forming pathways
  • Oxidative fibers use aerobic pathways
  • Glycolytic fibers use anaerobic glycolysis
  • These two criteria define three categories slow
    oxidative fibers, fast oxidative fibers, and fast
    glycolytic fibers

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47
Training
  • Slow, oxidative respond to endurance training.
    Diameter changes little.
  • Fast, oxidative respond to strength and power
    training. Diameter increases.
  • Intermediate can take on characteristics of fast
    or slow, depending on type of training.

In what birds do you expect to find FT? And ST?
48
Muscle Hypertrophy
  • Exercise causes
  • An increase in the number of mitochondria
  • An increase in the activity of muscle spindles
  • An increase in the concentration of glycolytic
    enzymes
  • An increase in the glycogen reserves
  • An increase in the number of myofibrils
  • The net effect is an enlargement of the
    muscle(hypertrophy)
  • Disuse causes atrophy
  • A decrease in muscle size
  • A decrease in muscle tone

49
Developmental Aspects
  • Muscle tissue develops from embryonic mesoderm
    called myoblasts
  • Multinucleated skeletal muscles form by fusion of
    myoblasts forming a syncytium
  • The growth factor agrin stimulates the clustering
    of ACh receptors at newly forming motor end
    plates
  • As muscles are brought under the control of the
    somatic nervous system, the numbers of fast and
    slow fibers are also determined

50
Developmental Aspects
  • Cardiac myoblasts do not fuse but develop gap
    junctions at an early embryonic stage
  • Most smooth muscle follows the same pattern of
    gap junctions rather than fusion

51
Developmental Aspects After Birth
  • Muscular development reflects neuromuscular
    coordination
  • Development occurs head-to-toe, and
    proximal-to-distal
  • Peak natural neural control of muscles is
    achieved by midadolescence
  • Athletics and training can improve neuromuscular
    control

52
Developmental Aspects Male and Female
  • There is a biological basis for greater strength
    in men than in women
  • Womens skeletal muscle makes up 36 of their
    body mass
  • Mens skeletal muscle makes up 42 of their body
    mass
  • These differences are due primarily to the male
    sex hormone testosterone
  • With more muscle mass, men are generally stronger
    than women
  • Body strength per unit muscle mass, however, is
    the same

53
Homeostatic Imbalance Age Related
  • With age, connective tissue increases and
    myofibrils, glycogen and myoglobin decrease
  • Muscles become stringier and more sinewy
  • By age 80, 50 of muscle mass is lost
    (sarcopenia), and myosatellite cells decrease
  • Regular exercise reverses sarcopenia
  • Aging of the cardiovascular system affects every
    organ in the body
  • Atherosclerosis may block distal arteries,
    leading to intermittent claudication and causing
    severe pain in leg muscles

54
Developmental Aspects Regeneration
  • Cardiac and skeletal muscle become amitotic, but
    can lengthen and thicken (hypertrophy)
  • Myoblastlike satellite cells of skeletal muscle
    show very limited regenerative ability (Cardiac
    tissue lacks satellite cells)
  • Smooth muscle has good regenerative ability
    (hyperplasia)

55
Levers
  • F1L1 F2L2
  • MassForce Llength
  • There are several ways to increase the force
    efficiency of a lever
  • increasing the length of the in-lever arm
  • decreasing the length of the out-lever
  • or doing both of the above

56
See-saw
Wheelbarrow Less distance
Hotdog tongs most common, least mechanical
advantage, more force, more speed/distance
57
The Arm is a Lever and Fulcrum System
Figure 12-21b
58
The Lever-Fulcrum System Amplifies the Load
Distance Traveled and the Speed of Movement
Figure 12-22
59
Smooth Muscle
  • Composed of spindle-shaped fibers diameter of
    2-10 ?m and lengths of several hundred ?m
  • Lack the coarse CT sheaths of skeletal muscle,
    but have fine endomysium

Figure 9.23
60
Smooth Muscle
  • Are generally organized into two layers
    (longitudinal and circular) of closely apposed
    fibers
  • Found in walls of hollow organs (except the heart)

Figure 9.23
61
Innervation of Smooth Muscle
  • Most smooth muscle lacks neuromuscular junctions
  • Innervating nerves have bulbous swellings called
    varicosities
  • Varicosities release neurotransmitters into wide
    synaptic clefts called diffuse junctions

62
Microscopic Anatomy of Smooth Muscle
  • SR is less developed than in skeletal muscle and
    lacks a specific pattern (no cisterns)
  • T tubules are absent
  • Plasma membranes have pouchlike infoldings called
    caveoli
  • Ca2 is sequestered in the extracellular space
    near the caveoli, allowing rapid influx when
    channels are opened
  • There are no visible striations and no sarcomeres
  • Thin and thick filaments are present

63
Proportion and Organization of Myofilaments in
Smooth Muscle
  • Ratio of thick to thin filaments (12) is much
    lower than in skeletal (16) or cardiac (14)
  • Thick filaments have heads along their entire
    length
  • There is no troponin complex

Figure 9.25
64
Proportion and Organization of Myofilaments in
Smooth Muscle
  • Thick and thin filaments are arranged diagonally,
    causing smooth muscle to contract in a corkscrew
    manner

Figure 9.25
65
Proportion and Organization of Myofilaments in
Smooth Muscle
  • Noncontractile intermediate filament bundles
    attach to dense bodies (analogous to Z discs) at
    regular intervals

Figure 9.25
66
Contraction of Smooth Muscle
  • Whole sheets of smooth muscle exhibit slow,
    synchronized contraction
  • They contract in unison, reflecting their
    electrical coupling with gap junctions
  • Action potentials are transmitted from cell to
    cell
  • Some smooth muscle cells
  • Act as pacemakers and set the contractile pace
    for whole sheets of muscle
  • Are self-excitatory and depolarize without
    external stimuli

67
Contractile Mechanism
  • Actin and myosin interact according to the
    sliding filament mechanism
  • The final trigger for contractions is a rise in
    intracellular Ca2
  • Ca2 is released from the SR and from the
    extracellular space
  • Ca2 interacts with calmodulin and myosin light
    chain kinase to activate myosin

68
Special Features of Smooth Muscle Contraction
  • Unique characteristics of smooth muscle include
  • Smooth muscle tone
  • Slow, prolonged contractile activity
  • Low energy requirements
  • Response to stretch

69
Response to Stretch
  • Smooth muscles exhibits a phenomenon called
    stress-relaxation response in which
  • Smooth muscle responds to stretch only briefly,
    and then adapts to its new length
  • The new length, however, retains its ability to
    contract
  • This enables organs such as the stomach and
    bladder to temporarily store contents

70
Types of Smooth Muscle Single Unit
  • The cells of single unit smooth muscle, commonly
    called visceral muscle
  • Contract rhythmically as a unit
  • Are electrically coupled to one another via gap
    junctions
  • Often exhibit spontaneous action potentials
  • Are arranged in opposing sheets and exhibit
    stress-relaxation response

71
Types of Smooth Muscle Multiunit
  • Multiunit smooth muscles are found
  • In large airways to the lungs
  • In large arteries
  • In arrector pili muscles
  • In the internal eye muscles
  • Characteristics include
  • Rare gap junctions
  • Infrequent spontaneous depolarizations
  • Structurally independent muscle fibers
  • A rich nerve supply, which, with a number of
    muscle fibers, forms motor units
  • Graded contractions in response to neural stimuli

72
Muscle Comparison Summary
Table 12-3
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