Muscle histology by dr. armaan singh
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Mar 02, 2015
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About This Presentation
Muscle histology by dr. armaan singh
Slide Content
Complete Muscle
Histology
By- Dr. Armaan SinghBy- Dr. Armaan Singh
Histology
By- Dr. Armaan SinghBy- Dr. Armaan Singh
Functions of muscle tissueFunctions of muscle tissue
Movement
Maintenance of
posture
Joint stabilization
Heat generation
Movement
Maintenance of
posture
Joint stabilization
Heat generation
Special functional characteristics of muscle
Contractility
Only one action: to shorten
Shortening generates pulling force
Excitability
Nerve fibers cause electrical impulse to travel
Extensibility
Stretch with contraction of an opposing muscle
Elasticity
Recoils passively after being stretched
Contractility
Only one action: to shorten
Shortening generates pulling force
Excitability
Nerve fibers cause electrical impulse to travel
Extensibility
Stretch with contraction of an opposing muscle
Elasticity
Recoils passively after being stretched
Types of Muscle Tissue
Skeletal muscle
Cardiac muscle
Smooth muscle
Skeletal muscle
Cardiac muscle
Smooth muscle
Types of Muscle Tissue
Skeletal
•Attach to and move skeleton
•40% of body weight
•Fibers = multinucleate cells (embryonic cells fuse)
•Cells with obvious striations
•Contractions are voluntary
Cardiac: only in the wall of
the heart
•Cells are striated
•Contractions are
involuntary (not voluntary)
Smooth: walls of hollow organs
•Lack striations
•Contractions are involuntary (not voluntary)
Skeletal
•Attach to and move skeleton
•40% of body weight
•Fibers = multinucleate cells (embryonic cells fuse)
•Cells with obvious striations
•Contractions are voluntary
Cardiac: only in the wall of
the heart
•Cells are striated
•Contractions are
involuntary (not voluntary)
Smooth: walls of hollow organs
•Lack striations
•Contractions are involuntary (not voluntary)
Similarities…
Their cells are called fibers because they
are elongated
Contraction depends on myofilaments
Actin
Myosin
Plasma membrane is called sarcolemma
Sarcos = flesh
Lemma = sheath
Their cells are called fibers because they
are elongated
Contraction depends on myofilaments
Actin
Myosin
Plasma membrane is called sarcolemma
Sarcos = flesh
Lemma = sheath
Skeletal muscle
Epimysium:
surrounds
whole muscle
Perimysium
is around
fascicle
Endomysium is around each
muscle fiber
Epimysium:
surrounds
whole muscle
Perimysium
is around
fascicle
Endomysium is around each
muscle fiber
Skeletal
Muscle
Each muscle: one nerve, one
artery, one vein
Branch repeatedly
Attachments
One bone to another
Cross at least one movable joint
Origin: the less movable
attachment
Insertion: is pulled toward the
origin
Usually one bone moves while the
other remains fixed
In muscles of the limb, origin lies
proximal to the insertion (by
convention)
Note: origin and insertion may
switch depending on body position
and movement produced
Muscle
Each muscle: one nerve, one
artery, one vein
Branch repeatedly
Attachments
One bone to another
Cross at least one movable joint
Origin: the less movable
attachment
Insertion: is pulled toward the
origin
Usually one bone moves while the
other remains fixed
In muscles of the limb, origin lies
proximal to the insertion (by
convention)
Note: origin and insertion may
switch depending on body position
and movement produced
Attachments continued
Many muscles span two or more joints
Called biarticular or multijoint muscles
Cause movements at two joints
Direct or “fleshy” attachments
Attachments so short that muscle appears to attach
directly to bone
Indirect: connective tissue extends well beyond
the muscle (more common)
Tendon: cordlike (most muscles have tendons)
Aponeurosis: flat sheet
Raised bone markings where tendons meet bones
Tubercles, trochanters, crests, etc.
Many muscles span two or more joints
Called biarticular or multijoint muscles
Cause movements at two joints
Direct or “fleshy” attachments
Attachments so short that muscle appears to attach
directly to bone
Indirect: connective tissue extends well beyond
the muscle (more common)
Tendon: cordlike (most muscles have tendons)
Aponeurosis: flat sheet
Raised bone markings where tendons meet bones
Tubercles, trochanters, crests, etc.
Some sites showing animations
of muscle contraction
http://entochem.tamu.edu/MuscleStrucContractswf/index.html
http://www.brookscole.com/chemistry_d/templates/student_resources/shared_resources/animations/muscles/muscles.html
of muscle contraction
http://entochem.tamu.edu/MuscleStrucContractswf/index.html
http://www.brookscole.com/chemistry_d/templates/student_resources/shared_resources/animations/muscles/muscles.html
Skeletal
muscle
Fibers (each is one
cell) have striations
Myofibrils are
organelles of the
cell: these are made
up of filaments
Sarcomere
Basic unit of
contraction
Myofibrils are long
rows of repeating
sarcomeres
Boundaries: Z discs
(or lines)
This big
cylinder is a
fiber: 1 cell -an organelle
muscle
Fibers (each is one
cell) have striations
Myofibrils are
organelles of the
cell: these are made
up of filaments
Sarcomere
Basic unit of
contraction
Myofibrils are long
rows of repeating
sarcomeres
Boundaries: Z discs
(or lines)
This big
cylinder is a
fiber: 1 cell -an organelle
Myofibrils
Made of three types of filaments (or
myofilaments):
Thick (myosin)
Thin (actin)
Elastic (titin)
______actin
_____________myosin
titin_____
Made of three types of filaments (or
myofilaments):
Thick (myosin)
Thin (actin)
Elastic (titin)
______actin
_____________myosin
titin_____
Sliding Filament Model
__relaxed sarcomere__ _partly contracted_
fully contracted
“A” band constant
because it is
caused by myosin,
which doesn’t
change length
Sarcomere shortens
because actin pulled
towards its middle
by myosin cross
bridges
Titin resists overstretching
__relaxed sarcomere__ _partly contracted_
fully contracted
“A” band constant
because it is
caused by myosin,
which doesn’t
change length
Sarcomere shortens
because actin pulled
towards its middle
by myosin cross
bridges
Titin resists overstretching
Another pic
EM (electron
microscope): parts
of 2 myofibrils
Labeled and unlabeled
microscope): parts
of 2 myofibrils
Labeled and unlabeled
Sarcoplasmic reticulum is smooth ER
Tubules surround myofibrils
Cross-channels called “terminal cisternae”
Store Ca++ and release when muscle stimulated to contract
To thin filaments triggering sliding filament mechanism of contraction
T tubules are continuous with sarcolemma, therefore whole muscle
(deep parts as well) contracts simultaneously
Tubules surround myofibrils
Cross-channels called “terminal cisternae”
Store Ca++ and release when muscle stimulated to contract
To thin filaments triggering sliding filament mechanism of contraction
T tubules are continuous with sarcolemma, therefore whole muscle
(deep parts as well) contracts simultaneously
Neuromuscular
Junction
Motor neurons innervate muscle
fibers
Motor end plate is where they
meet
Neurotransmitters are released
by nerve signal: this initiates
calcium ion release and muscle
contraction
Motor Unit: a motor neuron and all the muscle fibers it innervates (these all
contract together)
•Average is 150, but range is four to several hundred muscle fibers in a motor unit
•The finer the movement, the fewer muscle fibers /motor unit
•The fibers are spread throughout the muscle, so stimulation of a single motor unit
causes a weak contraction of the entire muscle
Junction
Motor neurons innervate muscle
fibers
Motor end plate is where they
meet
Neurotransmitters are released
by nerve signal: this initiates
calcium ion release and muscle
contraction
Motor Unit: a motor neuron and all the muscle fibers it innervates (these all
contract together)
•Average is 150, but range is four to several hundred muscle fibers in a motor unit
•The finer the movement, the fewer muscle fibers /motor unit
•The fibers are spread throughout the muscle, so stimulation of a single motor unit
causes a weak contraction of the entire muscle
Types of skeletal muscle fibers
Fast, slow and intermediate
Whether or not they predominantly use oxygen to
produce ATP (the energy molecule used in muscle
contraction)
Oxidative – aerobic (use oxygen)
Glycolytic – make ATP by glycolysis (break down of sugars
without oxygen=anaerobic)
Fast fibers: “white fibers” – large, predominantly
anaerobic, fatigue rapidly (rely on glycogen reserves);
most of the skeletal muscle fibers are fast
Slow fibers: “red fibers” – half the diameter, 3X slower,
but can continue contracting; aerobic, more
mitochondria, myoglobin
Intermediate: in between
Fast, slow and intermediate
Whether or not they predominantly use oxygen to
produce ATP (the energy molecule used in muscle
contraction)
Oxidative – aerobic (use oxygen)
Glycolytic – make ATP by glycolysis (break down of sugars
without oxygen=anaerobic)
Fast fibers: “white fibers” – large, predominantly
anaerobic, fatigue rapidly (rely on glycogen reserves);
most of the skeletal muscle fibers are fast
Slow fibers: “red fibers” – half the diameter, 3X slower,
but can continue contracting; aerobic, more
mitochondria, myoglobin
Intermediate: in between
A skeletal muscle contracts when its motor
units are stimulated
Amount of tension depends on
1.the frequency of stimulation
2.the number of motor units involved
Single, momentary contraction is called a
muscle twitch
All or none principle: each muscle fiber either
contracts completely or not at all
Amount of force: depends on how many motor
units are activated
Muscle tone
Even at rest, some motor units are active: tense the
muscle even though not causing movement: “resting
tone”
units are stimulated
Amount of tension depends on
1.the frequency of stimulation
2.the number of motor units involved
Single, momentary contraction is called a
muscle twitch
All or none principle: each muscle fiber either
contracts completely or not at all
Amount of force: depends on how many motor
units are activated
Muscle tone
Even at rest, some motor units are active: tense the
muscle even though not causing movement: “resting
tone”
Muscle hypertrophy
Weight training (repeated intense workouts): increases diameter and
strength of “fast” muscle fibers by increasing production of
Mitochondria
Actin and myosin protein
Myofilaments containing these contractile proteins
The myofibril organelles these myofilaments form
Fibers enlarge (hypertrophy) as number and size of myofibrils
increase
[Muscle fibers (=muscle cells) don’t increase in number but increase
in diameter producing large muscles]
Endurance training (aerobic): doesn’t produce hypertrophy
Muscle atrophy: loss of tone and mass from lack of
stimulation
Muscle becomes smaller and weaker
Note on terminology: in general, increased size is hypertrophy; increased number
of cells is hyperplasia
Weight training (repeated intense workouts): increases diameter and
strength of “fast” muscle fibers by increasing production of
Mitochondria
Actin and myosin protein
Myofilaments containing these contractile proteins
The myofibril organelles these myofilaments form
Fibers enlarge (hypertrophy) as number and size of myofibrils
increase
[Muscle fibers (=muscle cells) don’t increase in number but increase
in diameter producing large muscles]
Endurance training (aerobic): doesn’t produce hypertrophy
Muscle atrophy: loss of tone and mass from lack of
stimulation
Muscle becomes smaller and weaker
Note on terminology: in general, increased size is hypertrophy; increased number
of cells is hyperplasia
Cardiac muscle
Bundles form thick
myocardium
Cardiac muscle cells are
single cells (not called fibers)
Cells branch
Cells join at intercalated
discs
1-2 nuclei in center
Here “fiber” = long row of
joined cardiac muscle cells
Inherent rhythmicity: each
cell! (muscle cells beat
separately without any
stimulation)
Intercalated
disc__________
Bundles form thick
myocardium
Cardiac muscle cells are
single cells (not called fibers)
Cells branch
Cells join at intercalated
discs
1-2 nuclei in center
Here “fiber” = long row of
joined cardiac muscle cells
Inherent rhythmicity: each
cell! (muscle cells beat
separately without any
stimulation)
Intercalated
disc__________
Smooth muscle
•Muscles are spindle-shaped cells
•One central nucleus
•Grouped into sheets: often running
perpendicular to each other
•Peristalsis
•No striations (no sarcomeres)
•Contractions are slow, sustained and
resistant to fatigue
•Does not always require a nervous signal:
can be stimulated by stretching or hormones
6 major locations:
1.inside the eye 2. walls of vessels 3. respiratory tubes
4. digestive tubes 5. urinary organs 6. reproductive organs
•Muscles are spindle-shaped cells
•One central nucleus
•Grouped into sheets: often running
perpendicular to each other
•Peristalsis
•No striations (no sarcomeres)
•Contractions are slow, sustained and
resistant to fatigue
•Does not always require a nervous signal:
can be stimulated by stretching or hormones
6 major locations:
1.inside the eye 2. walls of vessels 3. respiratory tubes
4. digestive tubes 5. urinary organs 6. reproductive organs
This is included because troponins are measured clinically in
heart attacks…but be careful because the colors are opposite
Calcium attaches to troponin/
tropomyosin; they roll away,
exposing the active site on actin.
heart attacks…but be careful because the colors are opposite
Calcium attaches to troponin/
tropomyosin; they roll away,
exposing the active site on actin.
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