1. Biol 2401
Biol 2401 Fundamentals of Anatomy and Physiology Mrs. Willie Grant (210)

2. © 2015 Pearson Education, Inc.

3. 10-1 An Introduction to Muscle Tissue
Learning Outcomes
10-1 Specify the functions of skeletal muscle tissue.
10-2 Describe the organization of muscle at the tissue level.
10-3 Explain the characteristics of skeletal muscle fibers, and identify the structural components of a sarcomere.
10-4 Identify the components of the neuromuscular junction, and summarize the events involved in the neural control of skeletal muscle contraction and relaxation.
10-5 Describe the mechanism responsible for tension production in a muscle fiber, and compare the different types of muscle contraction.
10-6 Describe the mechanisms by which muscle fibers obtain the energy to power contractions.
10-7 Relate the types of muscle fibers to muscle performance, and distinguish between aerobic and anaerobic endurance.
10-8 Identify the structural and functional differences between skeletal muscle fibers and cardiac muscle cells.
10-9 Identify the structural and functional differences between skeletal muscle fibers and smooth muscle cells, and discuss the roles of smooth muscle tissue in systems throughout the body.

4. An Introduction to Muscle Tissue
A primary tissue type, divided into:
Skeletal muscle tissue
Cardiac muscle tissue
Smooth muscle tissue
Skeletal Muscles
Are attached to the skeletal system
Allow us to move

5. 10-1 Functions of Skeletal Muscle Tissue
Six Functions of Skeletal Muscle Tissue
Produce skeletal movement
Maintain posture and body position
Support soft tissues
Guard entrances and exits
Maintain body temperature
Store nutrient reserves
Skeletal Muscle Organization
Muscle tissue (muscle cells or fibers)
Connective tissues
Nerves
Blood vessels

6. 10-2 Organization of Muscle
Organization of Connective Tissues
Muscles have three layers of connective tissues
Epimysium
Exterior collagen layer
Connected to deep fascia
Separates muscle from surrounding tiss
Perimysium
Separates muscle from surrounding tissue
Endomysium
Surrounds individual muscle cells (muscle fibers)
Contains capillaries and nerve fibers contacting muscle cells
Contains myosatellite cells (stem cells) that repair damage

8. Figure 10-2 The Formation of a Multinucleate Skeletal Muscle Fiber
Muscle fibers develop through the fusion of mesodermal cells called myoblasts.
Cells are long
Cells develop from myoblasts
Cells become very large
Cells contain hundreds of nuclei
Myoblasts
A muscle fiber forms by the fusion of myoblasts.
Muscle fiber
LM  612
Nuclei
Sarcolemma
Myofibrils
Myosatellite cell
Nuclei
Mitochondria
Immature muscle fiber
1 Which structure shown releases calcium ions to trigger muscle contraction?
A diagrammatic view and a micrograph of one muscle fiber.
Myosatellite cell
Up to 30 cm in length
Mature muscle fiber 8

9. 10-2 Organization of Muscle
Organization of Connective Tissues
Muscle Attachments
Endomysium, perimysium, and epimysium come together:
At ends of muscles
To form connective tissue attachment to bone matrix
tendon (bundle) or aponeurosis (sheet)
Blood Vessels and Nerves
Muscles have extensive vascular systems that:
Supply large amounts of oxygen
Supply nutrients
Carry away wastes
Skeletal muscles are voluntary muscles, controlled by nerves of the central nervous system (brain and spinal cord)

10. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcolemma and Transverse Tubules
The sarcolemma—cell membrane of a muscle fiber
Surrounds the sarcoplasm (cytoplasm of muscle fiber)
A change in transmembrane potential begins contractions
Transverse tubules (T tubules)
Transmit action potential through cell
Allow entire muscle fiber to contract simultaneously
Have same properties as sarcolemma

11. 10-3 Characteristics of Skeletal Muscle Fibers
Myofibrils
Lengthwise subdivisions within muscle fiber
Made up of bundles of protein filaments (myofilaments)
Myofilaments are responsible for muscle contraction
Types of myofilaments:
Thin filaments
Made of the protein actin
Thick filaments
Made of the protein myosin

12. 10-3 Characteristics of Skeletal Muscle Fibers
The Sarcoplasmic Reticulum (SR)
A membranous structure surrounding each myofibril
Helps transmit action potential to myofibril
Similar in structure to smooth endoplasmic reticulum
Forms chambers (terminal cisternae) attached to T tubules
Triad
Is formed by one T tubule and two terminal cisternae
Cisternae
Concentrate Ca2+ (via ion pumps)
Release Ca2+ into sarcomeres to begin muscle contraction

13. Figure 10-3 The Structure of a Skeletal Muscle Fiber
Myofibril
Sarcolemma
Nuclei
Sarcoplasm
MUSCLE FIBER
Mitochondria
Terminal cisterna
Sarcolemma
Sarcolemma
Sarcoplasm
Myofibril
Myofibrils
Thin filament
Thick filament
Triad
Sarcoplasmic reticulum
T tubules 13

14. 10-3 Structural Components of a Sarcomere
Sarcomeres
The contractile units of muscle
Structural units of myofibrils
Form visible patterns within myofibrils
A striped or striated pattern within myofibrils
Alternating dark, thick filaments (A bands) and light, thin filaments (I bands)

15. 10-3 Structural Components of a Sarcomere
Sarcomeres
The A Band
M line
The center of the A band
At midline of sarcomere
The H Band
The area around the M line
Has thick filaments but no thin filaments
Zone of overlap
The densest, darkest area on a light micrograph
Where thick and thin filaments overlap
The I Band
Z lines
The centers of the I bands
At two ends of sarcomere
Titin
Are strands of protein
Reach from tips of thick filaments to the Z line
Stabilize the filaments
2 Which proteins are present in the A band? In the I band?

17. A superficial view of a sarcomere
Figure 10-5 Sarcomere Structure, Superficial and Cross-Sectional Views.
Sarcomere
Myofibril a
A superficial view of a sarcomere
Thin filament
Thick filament
Actinin filaments
Thin filaments
Titin filament
Thick filaments
Attachment of titin
Z line
I band
M line
H band
Zone of overlap b
Cross-sectional views of different regions of a sarcomere

18. Figure 10-6 Levels of Functional Organization in a Skeletal Muscle
Myofibril
Surrounded by: Epimysium
Surrounded by: Sarcoplasmic reticulum
Epimysium
Contains: Muscle fascicles
Consists of: Sarcomeres (Z line to Z line)
Sarcomere
I band
A band
Muscle Fascicle
Contains: Thick filaments
Surrounded by: Perimysium
Thin filaments
Perimysium
Contains: Muscle fibers
Z line
M line
Titin
Z line
H band
Muscle Fiber
3 Which of the following is the smallest:
muscle fiber, thick filament, myofibril?
Which is the largest?
Surrounded by: Endomysium
Endomysium
Contains: Myofibrils 18

19. 10-3 Structural Components of a Sarcomere
Thin Filaments
F-actin (filamentous actin) Is two twisted rows of globular G-actin The active sites on G-actin strands bind to myosin
Nebulin Holds F-actin strands together
Tropomyosin Is a double strand that prevents actin–myosin interaction
Troponin A globular protein that binds tropomyosin to G-actin Controlled by Ca2+

20. 10-3 Structural Components of a Sarcomere
Thick Filaments
Contain about 300 twisted myosin subunits
Contain titin strands that recoil after stretching
The mysosin molecule: Tail (binds to other myosin molecules)
Head (reaches the nearest thin filament)
Myosin Action
During contraction, myosin heads:
Interact with actin filaments, forming cross-bridges
Pivot, producing motion

21. 10-3 Structural Components of a Sarcomere
Sliding Filaments and Muscle Contraction
Sliding Filament Theory
Thin filaments of sarcomere slide toward M line, alongside thick filaments
The width of A zone stays the same
Z lines move closer together

22. 4 What happens to the I band and the H zone as muscles contract
4 What happens to the I band and the H zone as muscles contract? Do the lengths of the thick and thin filaments change?

23. 10-4 Components of the Neuromuscular Junction
The Control of Skeletal Muscle Activity
The neuromuscular junction (NMJ)
Special intercellular connection between the nervous system and skeletal muscle fiber
Controls calcium ion release into the sarcoplasm
A single axon may branch to control more than one skeletal muscle fiber, but each muscle fiber has only one neuromuscular junction (NMJ). At the NMJ, the synaptic terminal of the neuronlies near the motor end plate of the muscle fiber.
5 What part of the sarcolemma contains acetylcholine receptors?

28. Figure 10-12 The Contraction Cycle
Resting Sarcomere
Zone of overlap (shown in sequence above) 28

29. Figure 10-12 The Contraction Cycle
Contracted Sarcomere 29

30. 10-4 Skeletal Muscle Relaxation
Contraction Duration depends on:
Duration of neural stimulus
Number of free calcium ions in sarcoplasm
Availability of ATP
Ca2+ concentrations fall
Ca2+ detaches from troponin
Rigor Mortis
A fixed muscular contraction after death
Caused when:
Ion pumps cease to function; ran out of ATP
Calcium builds up in the sarcoplasm
Summary
Skeletal muscle fibers shorten as thin filaments slide between thick filaments
Free Ca2+ in the sarcoplasm triggers contraction
SR releases Ca2+ when a motor neuron stimulates the muscle fiber
Contraction is an active process
Relaxation and return to resting length are passive

31. Table 10-1 Steps Involved in Skeletal Muscle Contraction and Relaxation
Steps in Initiating Muscle Contraction
Steps in Muscle Relaxation
Synaptic terminal
Motor end plate
T tubule
Sarcolemma
Action potential reaches T tubule
ACh released, binding to receptors
ACh broken down by AChE
Sarcoplasmic reticulum releases Ca2
Sarcoplasmic reticulum recaptures Ca2
Ca2
Active site exposure, cross-bridge formation
Actin
Active sites covered, no cross-bridge interaction
Myosin
Contraction ends
Contraction begins
Relaxation occurs, passive return to resting length 31

33. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
As a whole, a muscle fiber is either contracted or relaxed
Depends on:
The number of pivoting cross-bridges
The fiber’s resting length at the time of stimulation
The frequency of stimulation
Length–Tension Relationships
Number of pivoting cross-bridges depends on:
Amount of overlap between thick and thin fibers
Optimum overlap produces greatest amount of tension
Too much or too little reduces efficiency
Normal resting sarcomere length
Is 75% to 130% of optimal length

34. Figure 10-14 The Effect of Sarcomere Length on Active Tension
A muscle fiber is either “on” (producing tension) or “off” (relaxed).
In a skeletal muscle fiber, the amount of tension
generated during a contraction depends on the
number of pivoting cross-bridges in each of the
myofibrils. The number of cross-bridges that can
form depends on the degree of overlap between
thick and thin filaments with these sarcomeres.
Skeletal muscle fibers contract most forcefully when stimulated over a narrow range of lengths.
Tension (percent of maximum)
Normal range
Decreased length
Increased sarcomere length
Optimal resting length: The normal range of sarcomere lengths in the body is 75 to 130 percent of the optimal length. 34

35. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
The Frequency of Stimulation
A single neural stimulation produces:
A single contraction or twitch
Which lasts about 7–100 msec.
Sustained muscular contractions
Require many repeated stimuli

36. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
Twitches
Latent period
The action potential moves through sarcolemma
Causing Ca2+ release
Contraction phase
Calcium ions bind
Tension builds to peak
Relaxation phase
Ca2+ levels fall
Active sites are covered and tension falls to resting levels

37. Figure 10-15b The Development of Tension in a Twitch
Maximum tension development
Tension
Stimulus
Resting phase
Latent period
Contraction phase
Relaxation phase
The details of tension over time for a single twitch in the gastrocnemius muscle. Notice the presence of a latent period, which corresponds to the time needed for the conduction of an action potential and the subsequent release of calcium ions by the sarcoplasmic reticulum. 37

38. Figure 10-15a The Development of Tension in a Twitch
Eye muscle
Gastrocnemius
Soleus
Tension
Time (msec)
Stimulus
A myogram showing differences in tension over time for a twitch in different skeletal muscles. 38

39. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
Treppe
A stair-step increase in twitch tension
Repeated stimulations immediately after relaxation phase
Stimulus frequency <50/second
Causes a series of contractions with increasing tension

40. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
Wave summation
Increasing tension or summation of twitches
Repeated stimulations before the end of relaxation phase
Stimulus frequency >50/second
Causes increasing tension or summation of twitches

41. 10-5 Tension Production and Contraction Types
Tension Production by Muscles Fibers
Incomplete tetanus
Twitches reach maximum tension
If rapid stimulation continues and muscle is not allowed to relax, twitches reach maximum level of tension

42. Tension Production and Contraction Types
Complete tetanus
If stimulation frequency is high enough, muscle never begins to relax, and is in continuous contraction

43. 10-5 Tension Production and Contraction Types
Tension Production by Skeletal Muscles
Depends on:
Internal tension produced by muscle fibers
External tension exerted by muscle fibers on elastic extracellular fibers
Total number of muscle fibers stimulated
Motor units (all muscle fibers controlled by a single motor neuron) in a skeletal muscle:
Contain hundreds of muscle fibers
That contract at the same time
Controlled by a single motor neuron

44. 10-5 Tension Production and Contraction Types
Motor Units and Tension Production
Recruitment (multiple motor unit summation)
In a whole muscle or group of muscles, smooth motion and increasing tension are produced by slowly increasing the size or number of motor units stimulated
Maximum tension
Achieved when all motor units reach tetanus
Can be sustained only a very short time

45. 10-5 Tension Production and Contraction Types
Motor Units and Tension Production
Sustained tension
Less than maximum tension
Allows motor units rest in rotation
Muscle tone
The normal tension and firmness of a muscle at rest
Muscle units actively maintain body position, without motion
Increasing muscle tone increases metabolic energy used, even at rest

47. Figure 10-9 An Overview of Skeletal Muscle Contraction
Neural control
Contraction occurs when skeletal muscle
Fibers are activated by neurons.
Excitation–contraction coupling
Calcium ions are released from SR.
Excitation
Calcium release
Calcium ions trigger interaction between
thick/thin filaments.
triggers
ATP
Thick-thin filament interaction
Muscle fiber contraction
Mulscle fiber contracts.
leads to
Tension is produced.
Tension production 47