Download Muscular System

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
page
29
page
30
page
31
page
32
page
33
page
34
page
35
page
36
page
37
page
38
page
39
page
40
page
41
page
42
page
43
Document related concepts
no text concepts found
Transcript 
Skeletal Muscles
Anatomy and innervation of
skeletal muscle tissue
• Connective tissue components:
– Fascia (“bandage”) –sheet or band of fibrous
C.T. under the skin or around organs
– Superficial fascia (subcutaneous fascia):
• Areolar C.T. and adipose tissue
• Stores water and fat
• Reduces heat loss (insulates)
• Protects against trauma
• Framework for nerves and blood vessels
• Deep fascia:
– Dense irregular C.T. – holds muscles together
and separates them into groups
– 3 layers:
• Epimysium – surrounds the whole muscle
• Perimysium – separates muscle into
bundles of muscle fibers – fascicles
• Endomysium – covers individual fibers
• These three layers come together to form
cords of dense, regular connective tissue
called tendons. Tendons attach muscle to
the periosteum of bones.
• When the connective tissues form a broad,
flat layer, the tendon is called an
aponeurosis.
Microscopic Anatomy
• Muscle cells are called muscle fibers or
myofibers
• Plasma membrane – sarcolemma
• Cytoplasm – sarcoplasm
• Myoblasts fuse to form one myofiber –
several nuclei
• Myofibrils run lengthwise
Myofibrils are made of filaments
• Thin filaments – primarily actin
• Thick filament – myosin
• Elastic filaments
• Sarcomeres are the basic, functional units
of striated muscle fibers.
Thick filaments
• Made of about 200 molecules of myosin
• Each myosin molecule has two “heads”
• Each head has an actin binding site and
an ATP binding site
• The ATP site splits ATP and transfers
energy to myosin head; which remains
charged (“cocked”) until contraction.
Thin Filaments
• Actin molecules form a helix
– Each actin molecule has a myosin binding site
• Other proteins:
• Tropomyosin – long, filamentous protein,
it wraps around the actin and covers the
myosin binding sites
• Troponin – a smaller molecule bound to
tropomyosin, it has calcium binding sites.
Sarcoplasmic reticulum
• Specialized smooth E. R.
• Tubes fuse to form cisternae
• In a relaxed muscle, S.R. stores Ca++
(Ca++ active transport pumps)
• When stimulated, Ca++ leaves through
Ca++ release channels.
Transverse tubules (T-tubules)
• Infoldings of sarcolemma that penetrate
into muscle fiber at right angles to
filaments. They are filled with extracellular
fluid.
• T-tubules and the cisternae on either side
form a triad.
Blood and nerve supply
• Muscle contraction uses a lot of ATP
• To generate ATP, muscles need oxygen
• Each muscle fiber is in close contact with
one or more capillaries
• Motor neurons – originate in brain and
spinal cord; cause muscle contraction
Motor unit
• A Motor Unit is made of one motor neuron
and all the muscle fibers it innervates.
• These cells all contract together.
• A single motor unit can have 2 – 2,000
muscle fibers.
• Precise movements are controlled by
small motor units, and large movements
by large motor units.
Neuromuscular Junction (NMJ)
• Nerves communicate with muscles and other
organs at structures called synapses.
• Synaptic cleft – gap between neuron and
sarcolemma
• Axon releases a chemical called a
neurotransmitter – Acetylcholine (Ach)
• Axon branches into axon terminals.
• At the end of each axon terminal is a swelling
called the synaptic end bulb.
• The region across the synaptic cleft from
the synaptic end bulb is called the motor
end plate.
• The sarcolemma of the motor end plate is
folded and contains many receptors for
ACh .
• When a nerve impulse reaches the
synaptic end bulbs, it causes synaptic
vesicles to fuse with the membrane and
release ACh by exocytosis.
• Acetylcholine diffuses across the synaptic cleft,
and binds with receptors on the motor end
plate.
• This binding causes the receptor to change
shape, and opens Na+ channels in the
membrane.
• When enough Na+ channels are opened, an
electrical current is generated and is carried
along the sarcolemma. This is called a muscle
impulse or muscle action potential. This
electrical activity can be recorded in an
electromyogram.
Sliding Filament Mechanism
• When a nerve impulse reaches an axon
terminal, the synaptic vesicles release
acetylcholine (ACh)
• ACh crosses the synaptic cleft and binds with
receptors on the motor end plate.
• This binding opens channels that allow
sodium to rush in, beginning a muscle action
potential in the sarcolemma.
• The action potential or impulse travels down the
sarcolemma and into the T-tubules, causing the
sarcoplasmic reticulum to release Ca++ into the
sarcoplasm.
• The Ca++ binds to the troponin, which changes
shape, pulling the tropomyosin away from the
myosin binding sites on the actin.
• The activated myosin attaches to the actin,
forming actin/myosin crossbridges.
• The myosin head moves toward the center of
the sarcomere, pulling the actin filaments past
the myosin. This is called a power stroke.
• When the myosin heads turn, they release
ADP, and ATP binds to the heads.
• When ATP binds, it causes the myosin to
release the actin.
• ATP is split, and the myosin heads again bind
to the actin, but further down the filament.
• The myosin again pulls the actin.
• This action is repeated many times.
• The Z lines (discs) get closer together as the
actin and myosin filaments slide past each
other, and the muscle fiber shortens.
Relaxation
• ACh is broken down by an enzyme called
acetylcholinesterase.
• Action potentials are no longer generated,
so the Ca++ release channels in the S.R.
close.
• Ca++ active transport pumps take Ca++ out
of the sarcoplasm and into the S.R. where
it binds to a protein called calsequestrin.
• As the Ca++ levels in the sarcoplasm fall,
troponin releases tropomyosin, which falls
back and covers the myosin binding sites
on the actin.
• The thin filaments slip back into their
relaxed positions.
Rigor mortis
• After death, muscle cells begin autolysis, and
Ca++ leaks out of the S.R.
• This causes muscles to begin to contract.
• Since the body is dead, no more ATP is
produced.
• Without the ATP to recharge the myosin heads,
they remain linked to the actin, and neither
relax nor contract any further.
• After about 24 - 72 hours it disappears as the
tissues begin to disintegrate.
Origin and Insertions
• Origin – the attachment of a muscle to the
less movable part (torso, etc.)
• Insertion – the attachment of a muscle to
the more movable part
Interactions of muscles
• Prime mover – the muscle primarily
responsible for a movement
• Synergist – stabilizes or assists prime
mover
• Antagonist – opposes action of prime
mover and must relax for prime mover to
contract completely
Related documents
12 Steps to Muscle Contraction
12 Steps to Muscle Contraction
Game on Muscles
Game on Muscles
Muscular System Unit Test Study Guide
Muscular System Unit Test Study Guide
Identify the following muscles
Identify the following muscles
Muscle Contraction - Warren County Schools
Muscle Contraction - Warren County Schools
17.4 Myosin in plants: cytoplasmic streaming
17.4 Myosin in plants: cytoplasmic streaming
Chapter 10
Chapter 10
B - Notes - Skeletal Muscle Contraction
B - Notes - Skeletal Muscle Contraction
THE MUSCULAR SYSTEM: MOVEMENT FOR THE JOURNEY
THE MUSCULAR SYSTEM: MOVEMENT FOR THE JOURNEY
how do action potentials trigger muscle
how do action potentials trigger muscle
Exam 3 Review KEY
Exam 3 Review KEY
Control of Muscle Fiber Contraction 1. Contraction is under control of
Control of Muscle Fiber Contraction 1. Contraction is under control of