1. The Muscular System 7 Chapter
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2. Functions and Types of Muscles
Smooth Muscle
Located in the walls of hollow organs and blood vessels
Involuntary contraction
Moves materials through organs and regulates blood flow
Cylindrical cells with pointed ends
Each cell is uninucleate

3. Functions and Types of Muscles
Cardiac Muscle
Forms the heart wall
Fibers are uninucleated, striated, tubular, and branched
Fibers interlock at intercalated disks, which permit contractions to spread quickly throughout the heart
Contraction does not require outside nervous stimulation
Nerves do affect heart rate and strength of contraction

4. Functions and Types of Muscles
Skeletal Muscle
Fibers are tubular, multinucleated, and striated
Make up muscles attached to the skeleton
Contraction is voluntary

6. Functions and Types of Muscles
Connective Tissue Coverings of Skeletal Muscle
Endomysium
Thin layer of areolar connective tissue
Surrounds each skeletal muscle fiber
Perimysium – surrounds bundles of muscle fibers (fascicles)
Epimysium
Layer that surrounds the entire muscle
Becomes part of the fascia (separates muscles from each other)
Collagen fibers extend from epimysium to form tendons that attach muscles to bone

8. Functions and Types of Muscles
Functions of Skeletal Muscles
Support the body
Make bones and other body parts move
Help maintain a constant body temperature
Assists movement in cardiovascular and lymphatic vessels
Help protect bones and internal organs, and stabilize joints

9. Microscopic Anatomy Muscle fiber components
Sarcolemma – plasma membrane
Sarcoplasm – cytoplasm
Contains glycogen that provides energy for muscle contraction
Contains myoglobin which binds oxygen until needed
Sarcoplasmic reticulum – endoplasmic reticulum
T (transverse) tubules
Formed by the sarcolemma penetrating into the cell
Come into contact with expanded portions of the sarcoplasmic reticulum

10. Microscopic Anatomy Myofibrils and Sarcomeres
Myofibrils run the length of the muscle fiber
Composed of numerous sarcomeres
Extends between two vertical Z lines
Contains two types of protein myofilaments
Thick filaments – made up of myosin
Thin filaments – made up of actin, tropomyosin, and troponin
I band contains only thin filaments
A band in the center of the sarcomere contains thick and thin filaments
H zone in the center of the A band has only myosin filaments

11. Microscopic Anatomy Myofilaments Thick filaments Thin filaments
Composed of several hundred of molecules of myosin
Myosin molecules end in a cross-bridge
Thin filaments
Two strands of actin
Double strands of tropomyosin coil of each actin strand
Troponin occurs at intervals on the tropomyosin strand

12. Microscopic Anatomy Sliding filaments
Occurs when sarcomeres shorten (during muscle contraction)
Actin filaments slide past the myosin filaments
Thick and thin filaments remain the same length

14. Contraction of Skeletal Muscle
Neuromuscular junction
Axon terminals
Come into close proximity to the sarcolemma
Have vesicles that contain acetylcholine (Ach)
Synaptic cleft – a small gap that separates the axon from the sarcolemma

15. Fig 7.4

16. Contraction of Skeletal Muscle
Steps involved in skeletal muscle contraction
Nerve signal arrives at the axon terminal
The synaptic vesicles release Ach
Ach binds to receptors on the sarcolemma
The sarcolemma generates a signal that travels down the T tubules to the SR
The SR releases calcium
Calcium from the SR causes the filaments to slide past one another

17. Contraction of Skeletal Muscle
The Role of Actin and Myosin
Myosin binding sites on actin molecules
Covered by tropomyosin when muscle is relaxed
Released calcium combines with troponin and myosin binding sites are exposed
Cross-bridges of myosin have two binding sites
One site binds to ATP
Second binding site binds to actin

19. Contraction of Skeletal Muscle
Energy for Muscle Contraction
ATP present before strenuous exercise only lasts a few seconds
Muscles acquire new ATP in three ways
Creatine phosphate breakdown
Cellular respiration
Fermentation

21. Contraction of Skeletal Muscle
Creatine Phosphate Breakdown
Does not require oxygen (anaerobic)
Regenerates ATP by transferring its phosphate to ADP
Fastest way to make ATP available to muscles
ATP produced only lasts about 8 seconds
TA 7.1

22. Contraction of Skeletal Muscle
Cellular Respiration
Usually provides most of a muscle’s ATP
Uses glucose from stored glycogen and fatty acids from stored fats
Required oxygen
Myoglobin can make oxygen available to muscle mitochondria
Carbon dioxide and water are end products
Heat is a by-product

23. Contraction of Skeletal Muscle
Fermentation
Anaerobic process
Produces ATP for short bursts of exercise
Glucose is broken down to lactate (lactic acid)

24. Contraction of Skeletal Muscle
Oxygen Debt
Occurs when muscles use fermentation to supply ATP
Requires replenishing creatine phosphate supplies and disposing of lactic acid

25. Contraction of Smooth Muscle
Smooth muscle fibers contain thick and thin filaments
Filaments are not arranged into myofibrils that create striations
Thin filaments are anchored to the sarcolemma or dense bodies
When contracted, the elongated cells become shorter and wider
Contraction occurs very slowly
Contractions can last for long periods of time without fatigue

26. Muscle Responses in the Laboratory
All-or-none law – a muscle fiber contracts completely or not at all
A whole muscle shows degrees of contraction
Muscle twitch – a single contraction that lasts only a fraction of a second
Latent period
Contraction period
Relaxation period
Summation – increased muscle contraction
Tetanic contraction – maximal sustained contraction

27. Muscle Responses in the Laboratory
Fatigue
Muscle relaxes even though stimulation continues
Reasons for fatigue
ATP is depleted
Accumulation of lactic acid in the sarcoplasm inhibits muscle function
ACh may become depleted

28. Muscle Responses in the Body
Motor unit
A nerve fiber together with all of the muscle fibers it innervates
Obeys the all-or-none law
Recruitment
As the intensity of nervous stimulation increases, more motor units are activated
Results in stronger muscle contractions
Tone
Some muscle fibers are always contracting
Important in maintaining posture

29. Muscle Responses in the Body
Athletics and muscle contraction
Size of muscles
Atrophy – a decrease in muscle size
Hypertrophy – an increase in muscle size
Slow-twitch fibers (Type I fibers)
Tend to be aerobic
Have more endurance
Have many mitochondria
Dark in color because they contain myoglobin
Highly resistant to fatigue

30. Muscle Responses In the Body
Fast-twitch fibers (Type II fibers)
Tend to be anaerobic
Designed for strength
Light in color
Have fewer mitochondria, little or no myoglobin, and fewer blood vessels than fast-twitch fibers
Vulnerable to accumulation of lactic acid and can fatigue easily

32. Skeletal Muscles of the Body
Basic Principles
Origin – attachment of a muscle to the immovable bone
Insertion – attachment of a muscle to the bone that moves
Prime mover – muscle that does most of the work in a movement
Synergist – muscles that assist the prime mover
Antagonists – muscles that work opposite one another to bring about movement in opposite directions

34. Skeletal Muscles of the Body
Naming Muscles
Size
Shape
Direction of fibers
Location
Attachment
Number of attachments
Action

36. Skeletal Muscles of the Body
Muscles of the Head
Muscles of Facial Expression
Frontalis
Orbicularis oculi
Orbicularis oris
Buccinator
Zygomaticus
Muscles of Mastication
Masseter muscles
Temporalis muscles
Fig 7.13

37. Skeletal Muscles of the Body
Muscles of the Neck
Swallowing
Tongue and buccinators
Suprahyoid and infrahyoid muscles
Palatini muscles
Pharyngeal constrictor muscles
Muscles that move the head
Sternocleidomastoid
Trapezius muscles

38. Skeletal Muscles of the Body
Muscles of the Trunk
Muscles of the thoracic wall
External intercostal muscles
Diaphragm
Internal intercostal muscles
Muscles of the abdominal wall
External and internal obliques
Transversus abdominis
Rectus abdominis

40. Skeletal Muscles of the Body
Muscles of the Shoulder
Muscles that move the scapula
Trapezius
Serratus anterior
Muscles that move the arm
Deltoid
Pectoralis major
Latissimus dorsi
Rotator cuff muscles
Supraspinatus
Infraspinatus
Teres minor
Subscapularis

41. Fig 7.15

43. Skeletal Muscles of the Body
Muscles of the Arm
Biceps brachii
Brachialis
Triceps brachii
Muscles of the Forearm
Flexor carpi and extensor carpi
Flexor digitorum and extensor digitorum

45. Skeletal Muscles of the Body
Muscles of the Hip and Lower Limb
Muscles that move the thigh
Iliopsoas
Gluteus maximus
Gluteus medius
Adductor group muscles
Pectineus
Adductor longus
Adductor magnus
Gracilis

46. Skeletal Muscles of the Body
Muscles that move the leg
Quadriceps femoris group
Rectus femoris
Vastus lateralis
Vastus medialis
Vastus intermedius
Sartorius
Hamstring group
Biceps femoris
Semimembranosus
Semitendinosus

48. Skeletal Muscles of the Body
Muscles that move the ankle and foot
Gastrocnemius
Tibialis anterior
Fibularis longus
Fibularis brevis
Flexor and extensor digitorum longus

50. Effects of Aging
Muscle mass and strength tend to decrease
Endurance decreases
Exercise at any age can stimulate muscle buildup

51. Homeostasis
Cardiac muscle contraction forces blood into the arteries and arterioles
Smooth muscle in arteries and arterioles help maintain blood pressure
Smooth muscle contraction moves food along the digestive tract and assists in the voiding of urine
Skeletal muscles protect internal organs and stabilizes joints
Skeletal muscles are active during breathing
Heat produced by skeletal muscle contraction helps maintain normal body temperature
Skeletal muscle contraction allows us to relocate our bodies