Download Muscle Tissue

Muscle Tissue
Functions of Muscle
Tissue
Movement
Heat production
Maintenance of posture
Muscle contraction produces 85% of body
heat
Characteristics of Muscle
Tissue
Excitability - able to be stimulated
Contractibility - able to shorten and
thicken
Extensibility - stretchable and extendable
Elasticity - the ability to return to its
original shape
Muscle Tissue Types
Skeletal - found attached to bone,
striated, voluntary
Cardiac - forms the walls of heart,
striated, involuntary
Smooth - found in viscera, non-striated,
involuntary
Gross Anatomy of Skeletal
Muscle
Each muscle is an organ, containing
muscle, blood vessels, nerves, &
connective tissue
Connective Tissue
Components
Fascia - found under the skin, covering organs,
and muscles
Epimysium – surrounds entire muscle
Perimysium – surrounds groups of muscle fibers
called “fascicles”
Endomysium – surrounds individual muscle
fibers
Tendons; Aponeurosis – connect muscle to
bones
Cell Structure
Muscle Cell = Muscle Fiber
Elongated, multi-nucleate, striated cells containing
parallel bundles of myofibrils
Sarcolemma – plasma membrane
Sarcoplasm – cytoplasm containing:
Myoglobin – stores oxygen
Glycosomes – store starch
Peripheral nuclei
Sarcoplasmic reticulum – smooth E.R. – maintains
calcium levels
Transverse tubules – network of membranes
connected to sarcolemma; penetrates deep into each
contractile unit.
Specialized contractile organelles
Myofibrils - thread-like structures
100’s to 1000’s in each muscle fiber (cell)
 Actin - thin filaments containing actin
protein, 2 strands of tropomyosin, & troponin
Myosin - thick protein filaments composed of
myosin molecules
Myofibrils
Actin
Myosin
SARCOMERE – the basic contractile unit
Z discs (lines) - separate sarcomeres;
anchor thin filaments
A band - overlapping area of thick and thin
filaments
I band - contains only actin
H zone - part of A band containing only
myosin
M line - center of H zone; anchors myosin
Sliding Filament
Mechanism
Skeletal Muscle
Contraction
Muscle contraction occurs when actin and
myosin are allowed to interact with each
other and form crossbridges
The binding sites on actin are blocked by
the troponin/tropomyosin complex
Calcium ions in the sarcoplasm will bind to
troponin
Muscle Contraction
This binding will cause the troponin /
tropomyosin complex to pull away from
the active binding site on actin, thus
allowing myosin to bind
The myosin head pivots, pulling the thin
filaments toward the center of the
sarcomere thus shortening the sarcomere
Repeated cycles of attachment, pivoting,
detach and release occurs
Muscle Contraction
Successive interaction causes “sliding” of
the filament, shortening of the sarcomere,
thus shortening of the entire muscle
Calcium is removed from the troponin
molecule and returned to the S.R.
Relaxation occurs
What Role Does Calcium
Play?
What triggers the release
of calcium?
ACTION POTENTIALS
The sudden change in the
transmembrane potential
Action Potentials
Resting Membrane Potential
Polarized - positive charge outside,
negative charge inside
Depolarized - positive charge inside,
negative charge outside
Repolarized - positive charge
reestablished outside, negative charge
inside
Resting Potential/
Polarized
When muscle is relaxed, the sarcolemma
is polarized having a charge difference
between the inside /outside of the cell
When a stimulus is received opening a
channel gate , Na+ ions will flow into the
cell changing the polarity of the cell
Depolarized
The net charge of the sarcolemma
becomes negative in regards to the inside
of the cell which is now positive.
The cell is said to be depolarized and the
muscle contracted
Repolarized
Membrane pumps quickly restore the
original status or condition
The positive charge outside is
reestablished once again and resting
membrane potential is restored
Neuromuscular Junction
Each fiber is controlled by a motor neuron
at a neuromuscular junction
Motor neurons stimulate muscle fibers
Acetylcholine (ACh ) is released into the
synaptic cleft with the arrival of an action
potential
ACh diffuses across the cleft, binding to
receptors on the motor end plate,
initiating a muscle action potential
Once initiated, the action
potential is unstoppable
and self-propagating
RELAXATION
Resting membrane potential is restored
by:
Acetylcholinesterase
active transport pumps that pump Ca+2 ions
back into the sarcoplasmic reticulum
Calsequestrin – binds calcium
Role of ATP
Used to activate the myosin head in order
to bind to actin
After power stroke, ATP used to break the
bond between actin and myosin
ATP used to pump calcium back into the
SR
Production of ATP for
muscles
Direct phosphorylation
Creatine phosphate couples with ADP to form ATP
Provides about 15 sec of energy
Glycolysis
Glucose broken down anaerobically
Produces lactic acid as waste product
Provides about 30-60 sec of energy
Aerobic Respiration
Glucose broken down with oxygen
Hours of energy
Muscle Fatigue
Insufficient oxygen
Build-up of lactic acid
Depletion of glycogen
RECOVERY OXYGEN CONSUMPTION
OXYGEN DEBT
ALL - or -None Principle
Muscle fibers will contract fully OR not at
all once they are stimulated
Threshold stimulus
minimal level of stimulation needed to cause
the muscle to contract
Motor Units
 Motor units - motor
neuron and all the
muscle fibers it
controls
Number of muscle
fibers in motor unit
will vary
The fewer the
number of fibers per
motor unit, the more
precise the
contraction
The number of motor
units being stimulated
will determine the
strength of
contraction of the
entire muscle
Muscle Contraction
Twitch contraction
rapid, jerky contraction to a single stimuli
phases: latent, contraction, relaxation,refractory
Wave summation
increase in the strength of muscle contraction due
to rapid successive stimulation
Tetany
continuous, smooth, sustained contraction
Muscle Contraction
Treppe
 repeated stimulation following stimulation
causing a staircase effect
Isotonic
tone or tension remains constant-muscle
shortens
Isometric
tension increases - muscle length remains
same
Muscle Fiber Types
Red oxidative fibers
more myoglobin
more capillaries
more mitochondria
long, slow contraction
sustained energy
aerobic respiration
non-fatiguable fibers
White glycolytic fibers
less myoglobin
less capillaries
fewer mitochondria
rapid,powerful
contraction
quick energy
anaerobic respiration
fatigue easily
Benefits of Exercise
Increase the size of size and strength of
each fiber
Increase muscle tone
Increases the blood supply, thus
increasing the number of red blood cells
Increased respiratory and cardiovascular
function
Lowers blood pressure
Cardiac Muscle
Involuntary
Intercalated discs
Forms syncytium
Long refractory period
Long contraction rate
More mitochondria than skeletal muscle
Smooth Muscle
 Involuntary - neural &
hormonal stimulation
 No sarcomeres - no
striations
 Very, very long
contraction rate
 Calmodulin - regulatory
protein
 No tendons or
aponeuroses
Muscle / Bone Interaction
Origin – attachment of a muscle to a stationary
bone
Insertion – attachment of a muscle to a
movable bone
Prime mover – provides major force for specific
movement
Antagonist – opposes prime mover
Synergist – assists the prime mover (secondary
muscle)
Muscle / Bone Interactions
Levers – rigid bar (bones) moving on
fixed point
Fulcrum = fixed point (joints)
Effort = applied force
Resistance = load
Levers
First class
Fulcrum in center = seesaw
Lifting head off chest
Second class
Load (resistance) in center = wheelbarrow
Least common
Standing on tiptoes
Third class
Effort in center = tweezers
Biceps brachii
Most common