1. Chapter 8
The Muscular System

2. Objectives
List, locate in the body, and compare the structure and function of the three major types of muscle tissue
Discuss the microscopic structure of a skeletal muscle sarcomere and motor unit
Discuss how a muscle is stimulated and compare the major types of skeletal muscle contractions

3. Objectives
Name, identify on a model or diagram, and give the function of the major muscles of the body discussed in this chapter
List and explain the most common types of movement produced by skeletal muscles
Name and describe the major disorders of skeletal muscles

4. Introduction Muscular tissue enables the body and its parts to move
Movement caused by ability of muscle cells (called fibers) to shorten or contract
Muscle cells shorten by converting chemical energy (obtained from food) into mechanical energy, which causes movement
Three types of muscle tissue in body
What causes movement of the body? Skeletal muscle contraction.

5. Muscle Tissue Skeletal muscle—also called striated or voluntary muscle
Is 40% to 50% of body weight (“red meat” attached to bones)
Microscope reveals crosswise stripes or striations
Contractions can be voluntarily controlled
What are the three types of muscle tissue? Skeletal, cardiac, and smooth.
If someone weighs 120 pounds, about 50 pounds of the body weight comes from the skeletal muscles.

6. Muscle Tissue Cardiac muscle—comprises bulk of heart
Cardiac muscle cells branch frequently
Characterized by unique dark bands called intercalated disks
Interconnected nature of cardiac muscle cells allows heart to contract efficiently as a unit
What is the value of the interconnected nature of the cardiac muscle? It increases the efficiency of the heart muscle in pumping blood.

7. Muscle Tissue
Smooth muscle—also called nonstriated, involuntary, or visceral muscle
Lacks cross stripes or striations when seen under a microscope; appears smooth
Found in walls of hollow visceral structures such as digestive tract, blood vessels, and ureters
Contractions not under voluntary control; movement caused by contraction is involuntary

8. Muscle tissue. A, Skeletal muscle. B, Cardiac muscle. C, Smooth muscle.

9. Muscle Tissue
Function—all muscle cells specialize in contraction (shortening)

10. Structure of Skeletal Muscle
Major structures
Each skeletal muscle is an organ composed mainly of skeletal muscle cells and connective tissue
Most skeletal muscles extend from one bone across a joint to another bone
What are the origin and the insertion point, and what are their roles in movement of the body? The origin of a muscle is its attachment to the more stationary bone. The insertion is the attachment to the more movable bone. When muscles contract, they pull on the more movable bone.

11. Structure of Skeletal Muscle
Parts of a skeletal muscle
Origin—attachment to the bone that remains relatively stationary or fixed when movement at the joint occurs
Insertion—point of attachment to the bone that moves when a muscle contracts
Body—main part of the muscle

12. Attachments of a skeletal muscle
Attachments of a skeletal muscle. A muscle originates at a relatively stable part of the skeleton (origin) and inserts at the skeletal part that is moved when the muscle contracts (insertion).

13. Structure of Skeletal Muscle
Muscles attach to bone by tendons—strong cords of fibrous connective tissue; some tendons enclosed in synovial-lined tubes called tendon sheaths; tendons lubricated by synovial fluid
Bursae—small synovial-lined sacs containing a small amount of synovial fluid; located between some tendons and underlying bones
Tendons do not tear or pull away from bone easily, yet emergency department physicians and nurses frequently see torn or severed tendon injuries.
Small, fluid-filled sacs called bursae lie between some tendons and the bones beneath them.
What is the role of bursae? Bursae make it easier for a tendon to slide over a bone when the muscle shortens.

14. Structure of Skeletal Muscle
Microscopic structure and function
Contractile cells, or muscle fibers—grouped into bundles and intricately arranged
Fibers contain thick myofilaments (containing the protein myosin) and thin myofilaments (composed of actin)
What are thick and thin myofilaments composed of? Thick myofilaments are formed from protein myosin; thin myofilaments are composed of actin.

15. Structure of skeletal muscle
Structure of skeletal muscle. A, Each muscle organ has many muscle fibers, each containing many bundles of thick and thin myofilaments. The diagrams show the overlapping thick and thin filaments arranged to form adjacent segments called sarcomeres. During contraction, the thin filaments are pulled toward the center of each sarcomere, thereby shortening the whole muscle. B, This electron micrograph shows that the overlapping thick and thin filaments within each sarcomere create a pattern of dark striations in the muscle. The extreme magnification allowed by electron microscopy has revolutionized our concept of the structure and function of skeletal muscle and other tissues. (B, Courtesy Dr. H.E. Huxley.)

16. Structure of Skeletal Muscle
Microscopic structure
Basic functional (contractile) unit called a sarcomere
Sarcomeres are separated from each other by dark bands called Z lines
Sliding filament model explains mechanism of contraction
Thick and thin myofilaments slide past each other as a muscle contracts
Contraction requires calcium and energy-rich ATP molecules
As the osteon (Haversian system) serves as the basic building block in compact bone, the sarcomere serves that function in muscle.
What is required for contraction? Calcium and energy-rich ATP molecules.

17. Mechanisms of muscle contraction.

18. Functions of Skeletal Muscle
Movement
Muscles produce movement by pulling on bones as a muscle contracts
The insertion bone is pulled closer to the origin bone
Movement occurs at the joint between the origin and the insertion
Describe how muscles produce movement. Muscles produce movement by pulling on bones. Contraction, or shortening, of the muscle pulls the insertion bone toward the origin bone.

19. Functions of Skeletal Muscle
Movement
Groups of muscles usually contract to produce a single movement
Prime mover—muscle whose contraction is mainly responsible for producing a given movement
Synergist—muscle whose contractions help the prime mover produce a given movement
Antagonist—muscle whose actions oppose the action of a prime mover in any given movement
When a muscle group produces movement, what are the components of the group called? Prime mover, synergist, antagonist.
When antagonist muscles contract, roles are reversed and they produce opposite movement.
Voluntary movement is normally smooth and free of jerks because skeletal muscles work in coordinated teams, not separately.

20. Functions of Skeletal Muscle
Posture
A type of muscle contraction called tonic contraction enables us to maintain body position
In tonic contraction, only a few of a muscle’s fibers shorten at one time
Tonic contractions produce no movement of body parts
Good posture means that body parts are held in positions that favor best function.
Bad posture causes fatigue and may lead to deformity.

21. Functions of Skeletal Muscle
Posture
Good posture (optimum body positioning) favors best body functioning
Skeletal muscle tone maintains posture by counteracting the pull of gravity

22. Functions of Skeletal Muscle
Heat production
Survival depends on the body’s ability to maintain a constant body temperature
Fever—an elevated body temperature—often a sign of illness
Hypothermia—body temperature below normal
Contraction of muscle fibers produces most of the heat required to maintain normal body temperature
Heat is produced by the breakdown of adenosine triphosphate (ATP) during contractions.

23. Fatigue Reduced strength of muscle contraction
Caused by repeated muscle stimulation without adequate periods of rest
Repeated muscular contraction depletes cellular ATP stores and outstrips the ability of the blood supply to replenish oxygen and nutrients
What can cause a decrease in the strength of muscle contraction? Muscle cells being repeatedly stimulated without adequate rest.

24. Fatigue
Contraction in the absence of adequate oxygen produces lactic acid, which contributes to muscle burning
Oxygen debt—the metabolic effort required to burn excess lactic acid that may accumulate during prolonged periods of exercise
Labored breathing after strenuous exercise is required to “pay the debt”
This increased metabolism helps restore energy and oxygen reserves to pre-exercise levels
Labored breathing is required to help the body pay the oxygen debt—an example of homeostasis at work.
What is the body attempting to do on the cellular level during labored breathing after exercise? To return the cells’ energy and oxygen reserves to pre-exercise levels.

25. Role of Other Body Systems in Movement
Muscle functioning depends on the functioning of many other parts of the body
Most muscles cause movements by pulling on bones across movable joints
Respiratory, circulatory, nervous, muscular, and skeletal systems play essential roles in producing normal movements
Normal function of one body part depends on the normal function of all other parts.

26. Role of Other Body Systems in Movement
Muscle functioning depends on the functioning of many other parts of the body
Multiple sclerosis, brain hemorrhage, and spinal cord injury are examples of how pathological conditions in other body organ systems can dramatically affect movement
What are some examples of pathological conditions that might affect movement of the body? Skeletal system disorders, multiple sclerosis, brain hemorrhage, and spinal cord injury.

27. Motor Unit
Stimulation of a muscle by a nerve impulse is required before a muscle can shorten and produce movement
A motor neuron is the nerve cell that transmits an impulse to a muscle, causing contraction
Specialized chemicals are released by the motor neuron in response to a nerve impulse.

28. Motor Unit
A neuromuscular junction is the point of contact between a nerve ending and the muscle fiber it innervates
A motor unit is the combination of a motor neuron and the muscle cell or cells it innervates

29. Motor neuron. A motor unit consists of one motor neuron and the muscle fibers supplied by its branches. (Courtesy Dr. Paul C. Letourneau, Department of Anatomy, Medical School, University of Minnesota, Minneapolis.)

30. Muscle Stimulus
A muscle will contract only if an applied stimulus reaches a certain minimal level of intensity—called a threshold stimulus
Once stimulated by a threshold stimulus, a muscle fiber will contract completely, a response called all or none
What is a threshold stimulus? The minimal level of stimulation required to cause a muscle fiber to contract.

31. Muscle Stimulus
Different muscle fibers in a muscle are controlled by different motor units having different threshold-stimulus levels
Although individual muscle fibers always respond all or none to a threshold stimulus, the muscle as a whole does not
Different motor units responding to different threshold stimuli permit a muscle as a whole to execute contractions of graded force
How is a graded response of a muscle accomplished? Different motor units responding to different threshold stimuli permit a muscle as a whole to execute contractions of graded force.

32. Types of Skeletal Muscle Contraction
Twitch and tetanic contractions
Twitch contractions—quick, jerky responses to a stimulus—are laboratory phenomena and do not play a significant role in normal muscular activity
Tetanic contractions are sustained and steady muscular contractions caused by a series of stimuli bombarding a muscle in rapid succession
About 30 stimuli per second evoke tetanic contractions in certain types of skeletal muscles.
Are twitch contractions significant for normal activity? No

33. Types of Skeletal Muscle Contraction
Isotonic contractions
Produce movement at a joint
During isotonic contractions, the muscle changes length, causing the insertion end of the muscle to move relative to the point of origin
Concentric contractions shorten muscles
Eccentric contractions allow muscles to increase in length
Most types of body movements such as walking and running are caused by isotonic contractions
What is an isotonic contraction? A contraction that produces movement at a joint. The muscle changes length and the insertion end moves closer to the point of origin.

34. Types of Skeletal Muscle Contraction
Isometric contractions
Isometric contractions are muscle contractions that do not produce movement; the muscle as a whole does not shorten
Although no movement occurs during isometric contractions, tension within the muscle increases
What is an isometric contraction? A muscle contraction that does not produce movement. It increases tension within a muscle but does not change the length of the muscle.
What are the differences between isotonic and isometric contractions? Isotonic contractions produce movement; isometric contractions increase tension within a muscle but do not change the length of the muscle.
Pushing against a wall is an example of an isometric contraction.

35. Types of muscle contraction
Types of muscle contraction. A, In isotonic contraction the muscle changes length, producing movement either by eccentric contraction (muscle lengthens) or concentric contraction (muscle shortens). B, In isometric contraction the muscle pulls forcefully against a load but does not shorten.

36. Effects of Exercise on Skeletal Muscles
Exercise, if done regularly and practiced properly, improves muscle tone and posture, results in more efficient heart and lung functioning, and reduces fatigue
Specific effects of exercise on skeletal muscles
Muscles undergo changes related to the amount of work they normally do
Prolonged inactivity causes disuse atrophy
Regular exercise increases muscle size, called hypertrophy
What are some of the health benefits of regular exercise? Greatly improved muscle tone, better posture, more efficient heart and lung function, less fatigue, looking and feeling better!
What type of changes do muscles undergo relative to the amount of work they normally do? Disuse atrophy, hypertrophy

37. Effects of Exercise on Skeletal Muscles
Strength training involves contraction of muscles against heavy resistance
Strength training increases the number of myofilaments in each muscle fiber, and as a result, the total mass of the muscle increases
Strength training does not increase the number of muscle fibers
What are examples of strength training? Isometric exercises and weight lifting

38. Effects of Exercise on Skeletal Muscles
Endurance training increases a muscle’s ability to sustain moderate exercise over a long period; sometimes called aerobic training
Endurance training allows more efficient delivery of oxygen and nutrients to a muscle via increased blood flow
Endurance training does not usually result in muscle hypertrophy
What are the differences between strength training and endurance training? Strength training can produce muscle hypertrophy by contracting muscles against resistance. Endurance training, also called aerobic training, increases a muscle’s ability to sustain moderate exercise over a long period without muscle hypertrophy.

39. Skeletal Muscle Groups
Muscles of the head and neck
Facial muscles
Orbicularis oculi
Orbicularis oris
Zygomaticus
What are the names of the “kissing muscle” and the “smiling muscle”? Orbicularis oris is the kissing muscle, and zygomaticus is the smiling muscle.

40. Skeletal Muscle Groups
Muscles of the head and neck
Muscles of mastication
Masseter
Temporal
Sternocleidomastoid—flexes head
Trapezius—elevates shoulders and extends head
Mastication muscles are among the strongest muscles in the body.

41. General overview of the body musculature. A, Anterior view
General overview of the body musculature. A, Anterior view. B, Posterior view. (John V. Hagen.)

42. Muscles of the head and neck
Muscles of the head and neck. Muscles that produce most facial expressions surround the eyes, nose, and mouth. Large muscles of mastication stretch from the upper skull to the lower jaw. These powerful muscles produce chewing movements. The neck muscles connect the skull to the trunk of the body, rotating the head or bending the neck. (John V. Hagen.)

43. Skeletal Muscle Groups
Muscles that move the upper extremities
Pectoralis major—flexes upper arm
Latissimus dorsi—extends upper arm
Deltoid—abducts upper arm
Biceps brachii—flexes forearm
Triceps brachii—extends forearm
The upper extremity is attached to the thorax by the pectoralis major.
What is the name of the “boxer’s muscle”? Triceps brachii

44. Skeletal Muscle Groups
Muscles of the trunk
Abdominal muscles
Rectus abdominis
External oblique
Internal oblique
Transversus abdominis
Respiratory muscles
Intercostal muscles
Diaphragm
Rectus abdominis flexes the spinal column.
Which muscles change the size of the chest during respiration? Respiratory muscles, intercostal muscles and diaphragm

45. Muscles of the trunk. A, Anterior view showing superficial muscles
Muscles of the trunk. A, Anterior view showing superficial muscles. B, Anterior view showing deeper muscles. (John V. Hagen.)

46. Skeletal Muscle Groups
Muscles that move the lower extremities
Iliopsoas—flexes thigh
Gluteus maximus—extends thigh
Adductor muscles—adduct thighs
Hamstring muscles—flex lower leg
Semimembranosus
Semitendinosus
Biceps femoris
Iliopsoas normally flexes the thigh, but it can flex the trunk if the thigh is fixed/immovable, as in sit-ups.

47. Skeletal Muscle Groups
Muscles that move the lower extremities
Quadriceps femoris group—extend lower leg
Rectus femoris
Vastus muscles
Tibialis anterior—dorsiflex foot
Gastrocnemius—plantar flex foot
Peroneus group—flexes foot
Gastrocnemius is sometimes called the toe dancer’s muscle.

48. Types of Movements Produced by Skeletal Muscle Contractions
Flexion—movement that decreases the angle between two bones at their joint: bending
Extension—movement that increases the angle between two bones at their joint: straightening

49. Flexion and extension of the lower arm
Flexion and extension of the lower arm. A and B, When the lower arm is flexed at the elbow, the biceps brachii contracts while its antagonist, the triceps brachii, relaxes. B and C, When the lower arm is extended, the biceps brachii relaxes while the triceps brachii contracts. (A, C, Rolin Graphics.)

50. Flexion and extension of the lower leg
Flexion and extension of the lower leg. A and B, When the lower leg _ exes at the knee, muscles of the hamstring group contract while their antagonists in the quadriceps femoris group relax. B and C, When the lower leg extends, the hamstring muscles relax while the quadriceps femoris muscle contracts. (A, C, Rolin Graphics.)

51. Types of Movements Produced by Skeletal Muscle Contractions
Abduction—movement of a part away from the midline of the body
Adduction—movement of a part toward the midline of the body
Rotation and circumduction—movement around a longitudinal axis
What are examples of the types of movements listed here? Flexion: bending elbow or knee; extension: straightening elbow or knee; abduction: lowering arm; rotation: shaking head “no.”

52. Types of Movements Produced by Skeletal Muscle Contractions
Supination and pronation—hand positions that result from rotation of the forearm; supination results in a hand position with the palm turned to the anterior position; pronation occurs when the palm faces posteriorly
What are the origins of the words “supination” and “pronation”? Supine, which means lying face up and prone, which means lying face down.

53. Types of Movements Produced by Skeletal Muscle Contractions
Dorsiflexion and plantar flexion—foot movements; dorsiflexion results in elevation of the dorsum or top of the foot; during plantar flexion, the bottom of the foot is directed downward

54. Examples of body movements. A, Adduction and abduction. B, Rotation
Examples of body movements. A, Adduction and abduction. B, Rotation. C, Pronation and supination. D, Dorsiflexion and plantar flexion.

55. Major Muscular Disorders
Myopathies—muscle disorders; can range from mild to life threatening
Muscle injury
Strain—injury from overexertion or trauma; involves stretching or tearing of muscle fibers
Often accompanied by myalgia (muscle pain)
May result in inflammation of muscle (myositis) or of muscle and tendon (fibromyositis)
If injury is near a joint and involves ligament damage, it may be called a sprain

56. Major Muscular Disorders
Muscle injury
Cramps are painful muscle spasms (involuntary twitches)
Crush injuries result from severe muscle trauma and may release cell contents that ultimately cause kidney failure
Stress-induced muscle tension can cause headaches and back pain

57. Major Muscular Disorders
Infections
Several bacteria, viruses, and parasites can infect muscles
Poliomyelitis is a viral infection of motor nerves that ranges from mild to life threatening
Why is polio no longer a threat to the U.S. population? A successful vaccination program has halted transmission of the disease.
Is polio a threat anywhere in the world? It is still contracted in Third World regions where the population has not been vaccinated, but it is becoming less and less of a threat.
What are the effects of polio on the body? It is a viral infection of the nerves that control skeletal muscle movement. It can cause paralysis that may progress to death because of the muscles affected.

58. Major Muscular Disorders
Muscular dystrophy
A group of genetic disorders characterized by muscle atrophy
Duchenne (pseudohypertrophic) muscular dystrophy is the most common type
Characterized by rapid progression of weakness and atrophy, resulting in death by age 21
X-linked inherited disease, affecting mostly boys

59. Major Muscular Disorders
Myasthenia gravis—autoimmune muscle disease characterized by weakness and chronic fatigue