1. Skeletal Muscle Contraction
&
Fiber types
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SAP2b

2. Fig08.01

3. Skeletal Muscle Histology
Fibers--represent a single cell
Sarcolemma--cell membrane
Sarcoplasm--the cytoplasm that contains nuclei, mitochondria, and myofibrils
Sarcoplasmic reticulum--similar to but not identical to E.R.-- releases Ca+ for muscle contraction
Myofibrils--contain two kinds of protein
myosin--thick filaments
Attach to actin during contractions
(2) actin--thin filaments
Also contains tropomyosin and troponin
Histology-study of microscopic structure of tissues
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SAP2b

4. A Bands – dark striations; location of myosin filaments
Histology Continued
The alternating light and dark striations are named for their positions within the fiber
A Bands – dark striations; location of myosin filaments
I Bands- light striations; location of actin filaments
Z Lines- attachment point of actin filaments at end of I Bands
Sarcomere- Segment of myofibril between two Z lines
Transverse Tubules- A membranous channel that extends inward from a muscle fiber membrane and passes through the fiber
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SAP2b

5. Sarcomere = structural unit of myofibril from Z line to Z line—striations of skeletal muscle in repeating patterns
I bands – light - anchored to Z lines
A bands – dark – made of overlapping thick & thin filaments
H Zone – in center of A bands

6. Transmission Electron Microscope
technique in which a beam of electrons is transmitted through a specimen to form an image.
The specimen is most often an ultrathin section less than 100 nm thick or a suspension on a grid
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SAP2b

7. Neuromuscular Junction
Electrical nerve impulse (action potential) reaches axon terminal
Neurotransmitter (ACh) released from synaptic vesicle across synaptic cleft
ACh binds with ACh receptors on sarcolemma (muscle membrane)
@ axon terminal synaptic vesicles join the synaptic cleft & release Ach. Acetic acid & choline released. Ach binds to receptors to open Na & K channels
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SAP2b

8. Neuromuscular Junction
Summary:
electrical signal  > chemical signal >electrical signal   AP         ACh                  AP on motor neuron    in synaptic cleft       on sarcolemma
AP= action potential
@ axon terminal synaptic vesicles join the synaptic cleft & release Ach. Acetic acid & choline released. Ach binds to receptors to open Na & K channels
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SAP2b

9. Excitation-Contraction Coupling
4. Stimulation of ACh receptor triggers release of sodium ions
5. Na+ travels down the (Transverse) T-tubules of the sarcoplasmic reticulum
6. Stimulation of T-Tubules triggers release of Ca+
7. Ca+ combines with troponin (troponin prevents myosin from interacting w/ actin normally)
ACH receptors release Na ions----Na ions travel thru T tubules –triggers release of Ca ions
Ca ions join with troponin

10. Sliding Filament Model of Contraction
8. Tropomyosin on actin shifts exposing binding sites for myosin heads
9. ATP is used-allows myosin heads to attach to actin exposed binding sites
10. The myosin “power stroke” the actin filaments towards the middle
11. Filaments slide past each other contracting the muscle
12. Release of myosin heads allows muscle to relax
When Ca ions join with troponin -tropomyosin moves ---exposes binding sites for myosin heads
Myosin heads attach to actin
Myosin pulls actin filaments to middle for muscle contraction
Muscle Contraction Process

11. 5/7/2019
SAP2b

12. Fig08.06
When Ca ions join with troponin -tropomyosin moves ---exposes binding sites for myosin heads
Myosin heads attach to actin
Myosin pulls actin filaments to middle for muscle contraction

14. Table08.01

15. 3 Events are recorded
Latent: first milliseconds between the stimulus and contraction, when excitation-coupling contraction occurs
Contraction: When cross-bridges (myosin & actin) are active between milliseconds
Relaxation: resting of muscle, re-entry of Ca+ into SR-returns to baseline
Latent period- delay of time between stimulation & beginning of contraction

16. Energy for Muscle Contractions
Comes from breaking high-energy bonds of ATP
1. Muscles are fueled by the breakdown of sugar in which ATP byproducts (ADP) are reconstructed into ATP molecules
Creatine phosphate-stores excess energy released from mitochondria
2. Anaerobic glycolysis
Use of ATP energy requires no O2- when ATP is depleted, muscle cells must use cellular respiration to obtain energy
Anaerobic glycolysis provides sec of ATP
Once muscle is at rest-ATP stores are replenished (appx 45 sec to 2 mins)

17. All-or-None Response
When a muscle fiber contracts, it contracts to its fullest extent. It cannot contract partially
Slightly misleading---in normal use of muscles, force generated by muscles varies
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SAP2b

18. Graded Strength Principle
Skeletal muscles contract with varying degrees of strength at different times.
No always using 100% strength.
Muscle’s contraction depends on:
Number of fibers contracting simultaneously (muscle recruitment)
Recruitment of motor neurons
Load placed on muscle
Slightly misleading---in normal use of muscles, force generated by muscles varies
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SAP2b

19. Types of Skeletal Muscle Fibers
Slow oxidative (Low ATP activity)
Muscle fibers that twitch at a very slow rate
Resistant to fatigue
Aerobic activities
Fast oxidative (large ATP activity)
Muscles contract at a fast rate & have large force but resistant to tiring
High in oxidative & glycolytic enzymes
Aerobic activities for prolonged intervals
Slow Ox—Slow Twitch (one muscle contraction) ---Needs O2---Cross X running
Builds lots of endurance----
Fast Ox –higher tension contractions Power walking or sprinting---Needs O2---breathing fast---body undergoes cellular respiration so O2 can be produced
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20. Slow-greater blood supply & O2 supply to muscles = better endurance
Many oxidative enzymes= aerobic respiration
Fast-Few mitochondria-whiter in appearance
many glycolysis enzymes for anaerobic respiration
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SAP2b

21. Types of Skeletal Muscle Fibers
Fast glycolytic (high ATP)
Fibers tire easily
Muscle requires rest after small amt of exertion
Low oxidative capacity
Anaerobic activities-short durations
Uses glucose for power and exercise----anaerobic
Run fast—over exert yourself---body can’t make enough ATP
Super out of breath because body is trying to reoup or regain the lost O2
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SAP2b

22. Location of Muscle Fibers
White muscle
Human Muscles
Fast fibers
Mixture of fibers (Pink)
Typically pale
Found in chicken breast
Red muscle
Slow fibers
Typically dark
Found in chicken legs
5/7/2019
SAP2b