1. PART 1
Joints

2. Joints Rigid elements of the skeleton meet at joints or articulations
Greek root “arthro” means joint
Articulations can be
Bone to bone
Bone to cartilage
Teeth in bony sockets
Structure of joints
Enables resistance to crushing, tearing, and other forces
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3. Classifications of Joints
Joints can be classified by function or structure
Functional classification – based on amount of movement
Synarthroses – immovable; common in axial skeleton
Amphiarthroses – slightly movable; common in axial skeleton
Diarthroses – freely movable; common in appendicular skeleton (all synovial joints)
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4. Classifications of Joints
Structural classification based on
Material that binds bones together
Presence or absence of a joint cavity
Structural classifications include
Fibrous
Cartilaginous
Synovial
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5. Bones are connected by fibrous connective tissue
Fibrous Joints
Bones are connected by fibrous connective tissue
Do not have a joint cavity
Most are immovable or slightly movable
Types
Sutures
Syndesmoses
Gomphoses
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6. Bones are tightly bound by a minimal amount of fibrous tissue
Sutures
Bones are tightly bound by a minimal amount of fibrous tissue
Only occur between the bones of the skull
Allow bone growth so the skull can expand with brain during childhood
Fibrous tissue ossifies in middle age
Synostoses – closed sutures
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7. Bones are connected exclusively by ligaments
Syndesmoses
Bones are connected exclusively by ligaments
Amount of movement depends on length of fibers
Tibiofibular joint –immovable synarthrosis
Interosseous membrane between radius and ulna
Freely movable diarthrosis
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8. Fibrous Joints Figure 9.1a, b
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9. Connecting ligament – the periodontal ligament
Gomphoses
Tooth in a socket
Connecting ligament – the periodontal ligament
Figure 9.1c
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10. Bones are united by cartilage Lack a joint cavity Two types
Cartilaginous Joints
Bones are united by cartilage
Lack a joint cavity
Two types
Synchondroses
Symphyses
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11. Hyaline cartilage unites bones
Synchondroses
Hyaline cartilage unites bones
Epiphyseal plates
Figure 9.2a
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12. Joint between first rib and manubrium
Synchondroses
Joint between first rib and manubrium
Figure 9.2b
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13. Fibrocartilage unites bones – resists tension and compression
Symphyses
Fibrocartilage unites bones – resists tension and compression
Slightly movable joints that provide strength with flexibility
Intervertebral discs
Pubic symphysis
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14. Hyaline cartilage – also present as articular cartilage
Symphyses
Hyaline cartilage – also present as articular cartilage
Figure 9.2c
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15. Most movable type of joint All are diarthroses
Synovial Joints
Most movable type of joint
All are diarthroses
Each contains a fluid-filled joint cavity
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16. General Structure of Synovial Joints
Articular cartilage
Ends of opposing bones are covered with hyaline cartilage
Absorbs compression
Joint cavity (synovial cavity)
Unique to synovial joints
Cavity is a potential space that holds a small amount of synovial fluid
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17. General Structure of Synovial Joints
Articular capsule – joint cavity is enclosed in a two-layered capsule
Fibrous capsule – dense irregular connective tissue, which strengthens joint
Synovial membrane – loose connective tissue
Lines joint capsule and covers internal joint surfaces
Functions to make synovial fluid
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18. General Structure of Synovial Joints
Synovial fluid
A viscous fluid similar to raw egg white
A filtrate of blood
Arises from capillaries in synovial membrane
Contains glycoprotein molecules secreted by fibroblasts
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19. General Structure of Synovial Joints
Reinforcing ligaments
Often are thickened parts of the fibrous capsule
Sometimes are extracapsular ligaments – located outside the capsule
Sometimes are intracapsular ligaments – located internal to the capsule
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20. A Typical Synovial Joint
Figure 9.3a
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21. General Structure of Synovial Joints
Richly supplied with sensory nerves
Detect pain
Most monitor how much the capsule is being stretched
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22. General Structure of Synovial Joints
Have a rich blood supply
Most supply the synovial membrane
Extensive capillary beds produce basis of synovial fluid
Branches of several major nerves and blood vessels
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23. Synovial Joints with Articular Discs
Some synovial joints contain an articular disc
Occur in the temporomandibular joint and at the knee joint
Occur in joints whose articulating bones have somewhat different shapes
Figure 9.3c
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24. Summary of Joint Classes
Table 9.1 (1 of 2)
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25. PART 2
Joints

26. How Synovial Joints Function
Synovial joints – lubricating devices
Friction could overheat and destroy joint tissue
Are subjected to compressive forces
Fluid is squeezed out as opposing cartilages touch
Cartilages ride on the slippery film
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27. Bursae and Tendon Sheaths
Bursae and tendon sheaths are not synovial joints
Closed bags of lubricant
Reduce friction between body elements
Bursa – a flattened fibrous sac lined by a synovial membrane
Tendon sheath – an elongated bursa that wraps around a tendon
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28. Bursae and Tendon Sheaths
Figure 9.4a, b
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29. Factors Influencing Joint Stabililty
Articular surfaces – seldom play a major role in joint stability
The elbow, the knee and the hip do provide stability
Ligaments – the more ligaments in a joint, the stronger it is
Muscle tone – the most important factor in joint stability
Keeps tension on muscle tendons
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30. Movements Allowed by Synovial Joints
Three basic types of movement
Gliding – one bone across the surface of another
Angular movement – movements change the angle between bones
Rotation – movement around a bone's long axis
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31. Flat surfaces of two bones slip across each other
Gliding Joints
Flat surfaces of two bones slip across each other
Gliding occurs between
Carpals
Articular processes of vertebrae
Tarsals
Figure 9.5a
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32. Increase or decrease angle between bones Movements involve
Angular Movements
Increase or decrease angle between bones
Movements involve
Flexion and extension
Abduction and adduction
Circumduction
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33. Angular Movements Figure 9.5b
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34. Angular Movements Figure 9.5c
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35. Angular Movements Figure 9.5d
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36. Angular Movements PLAY Movement of the pectoral girdle (a) Figure 9.5e
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37. Involves turning movement of a bone around its long axis
Rotation
Involves turning movement of a bone around its long axis
The only movement allowed between atlas and axis vertebrae
Occurs at the hip and shoulder joints
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38. Supination – forearm rotates laterally, palm faces anteriorly
Special Movements
Supination – forearm rotates laterally, palm faces anteriorly
Pronation – forearm rotates medially, palm faces posteriorly
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39. Special Movements Figure 9.6a
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40. Plantar flexion – depressing the foot, pointing the toes
Special Movements
Dorsiflexion – lifting the foot so the superior surface approaches the shin
Plantar flexion – depressing the foot, pointing the toes
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41. PART 3
Joints

42. Inversion – turning the sole medially
Special Movements
Inversion – turning the sole medially
Eversion – turning the sole laterally
PLAY
Movement of the ankle and foot (a)
Figure 9.6c
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43. Protraction – nonangular movement of jutting out the jaw
Special Movements
Protraction – nonangular movement of jutting out the jaw
Retraction – opposite movement to protraction
Figure 9.6d
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44. Elevation – lifting a body superiorly
Special Movements
Elevation – lifting a body superiorly
Depression – moving the elevated part inferiorly
Figure 9.6e
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45. Opposition – movement of the thumb to touch the tips of other fingers
Special Movements
Opposition – movement of the thumb to touch the tips of other fingers
Figure 9.6f
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46. Synovial Joints Classified by Shape
Plane joint
Articular surfaces are flat planes
Short gliding movements are allowed
Intertarsal and intercarpal joints
Movements are nonaxial
Gliding does not involve rotation around any axis
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47. Plane Joint
Figure 9.7a
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48. Synovial Joints Classified by Shape
Hinge joints
Cylindrical end of one bone fits into a trough on another bone
Angular movement is allowed in one plane
Elbow, ankle, and joints between phalanges
Movement is uniaxial – allows movement around one axis only
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49. Hinge Joint
Figure 9.7b
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50. Pivot Joint
Figure 9.7c
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51. Synovial Joints Classified by Shape
Condyloid joints
Allow moving bone to travel
Side to side – abduction-adduction
Back and forth – flexion-extension
Classified as biaxial – movement occurs around two axes
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52. Condyloid Joint Figure 9.7d
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53. Synovial Joints Classified by Shape
Saddle joints
Each articular surface has concave and convex surfaces
Classified as biaxial joints
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54. Synovial Joints Classified by Shape
Figure 9.7e
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55. PART 4
Joints

56. Synovial Joints Classified by Shape
Pivot joints
Classified as uniaxial – rotating bone only turns around its long axis
Examples
Proximal radioulnar joint
Joint between atlas and axis
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57. Pivot Joint
Figure 9.7c
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58. Synovial Joints Classified by Shape
Condyloid joints
Allow moving bone to travel
Side to side – abduction-adduction
Back and forth – flexion-extension
Classified as biaxial – movement occurs around two axes
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59. Condyloid Joint Figure 9.7d
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60. Synovial Joints Classified by Shape
Saddle joints
Each articular surface has concave and convex surfaces
Classified as biaxial joints
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61. Synovial Joints Classified by Shape
Figure 9.7e
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62. Synovial Joints Classified by Shape
Ball-and-socket joints
Spherical head of one bone fits into round socket of another
Classified as multiaxial – allow movement in all axes
Shoulder and hip joints
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63. Ball-and-Socket Joint
PLAY
Movement of the glenohumeral joint (a)
Figure 9.7f
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64. Sternoclavicular Joint
Figure 9.8a
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65. Sternoclavicular Joint
Figure 9.8b
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66. Part 5
Joints

67. Selected Synovial Joints
Shoulder (Glenohumeral) joint
The most freely movable joint lacks stability
Articular capsule is thin and loose
Muscle tendons contribute to joint stability
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68. Glenohumeral Joint Figure 9.8a
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69. Rotator cuff injuries are common shoulder injuries
Glenohumeral Joint
The rotator cuff is made up of four muscles and their associated tendons
Subscapularis
Supraspinatus
Infraspinatus
Teres minor
Rotator cuff injuries are common shoulder injuries
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70. The shoulder joint Figure 9.8b, c
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71. The Shoulder Joint Figure 9.8d, e
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72. Selected Synovial Joints
Elbow joint
Allows flexion and extension
The humerus’ articulation with the trochlear notch of the ulna forms the hinge
Tendons of biceps and triceps brachii provide stability
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73. Elbow Joint
Figure 9.9a, b
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74. Elbow Joint
Figure 9.9c, d
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75. Stabilized by numerous ligaments
Wrist Joint
Stabilized by numerous ligaments
Composed of radiocarpal and intercarpal joint
Radiocarpal joint – joint between the radius and proximal carpals (the scaphoid and lunate)
Allows for flexion, extension, adduction, abduction, and circumduction
Intercarpal joint – joint between the proximal and distal rows or carpals
Allows for gliding movement
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76. Wrist Joint
Figure 9.10a
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77. Wrist Joint
Figure 9.10b
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78. Wrist Joint
Figure 9.10c
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79. Selected Synovial Joints
Hip joint
A ball-and-socket structure
Movements occur in all axes
Limited by ligaments and acetabulum
Head of femur articulates with acetabulum
Stability comes chiefly from acetabulum and capsular ligaments
Muscle tendons contribute somewhat to stability
PLAY
Movement at the hip joint: An overview
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80. Frontal Section and Anterior View of the Hip Joint
Figure 9.11a, b
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81. Posterior View of the Hip Joint
Figure 9.11c, d
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82. Selected Synovial Joints
Knee joint
The largest and most complex joint
Primarily acts as a hinge joint
Has some capacity for rotation when leg is flexed
Structurally considered compound and bicondyloid
Two fibrocartilage menisci occur within the joint cavity
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83. Sagittal Section and Superior View of Knee Joint
Figure 9.12a
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84. Sagittal Section and Superior View of Knee Joint
Figure 9.12b
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85. Knee Joint Capsule of knee joint
Covers posterior and lateral aspects of the knee
Covers tibial and femoral condyles
Does not cover the anterior aspect of the knee
Anteriorly covered by three ligaments
Patellar, medial, and lateral retinacula
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86. Anterior View of Knee Figure 9.12c
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87. Ligaments of the knee joint
Become taut when knee is extended
These extracapsular ligaments are
Fibular and tibial collateral ligament
Oblique popliteal ligament
Arcuate popliteal ligament
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88. Posterior View of Knee Joint
Figure 9.12d
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89. Intracapsular ligaments
Knee Joint
Intracapsular ligaments
Cruciate ligaments
Cross each other like an “X”
Each cruciate ligament runs from the proximal tibia to the distal femur
Anterior cruciate ligament
Posterior cruciate ligament
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90. Anterior View of Flexed Knee
Figure 9.12e, f
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91. Knee Joint Cruciate ligaments
Prevent undesirable movements at the knee joint
Figure 9.13a
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92. Selected Synovial Joint
Ankle Joint
A hinge joint between
United inferior ends of tibia and fibula
The talus of the foot
Allows the movements
Dorsiflexion and plantar flexion only
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93. The Ankle Joint Medially and laterally stabilized by ligaments
Medial (deltoid) ligament
Lateral ligament
Inferior ends of tibia and fibula are joined by ligaments
Anterior and posterior tibiofibular ligaments
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94. The Ankle Joint Figure 9.15a
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95. Ligaments of the Ankle Joint
Figure 9.15b
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96. Ligaments of the Ankle Joint
Figure 9.15c
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97. Ligaments of the Ankle Joint
Figure 9.15d
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98. Selected Synovial Joints
Temporomandibular joint (TMJ)
Lies anterior to the ear
Head of the mandible articulates with the mandibular fossa
Two surfaces of the articular disc allow two kinds of movement
Hinge-like movement
Superior surface of disc glides anteriorly
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99. The Temporomandibular Joint
Figure 9.16a, b
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100. Selected Synovial Joints
Sternoclavicular Joint
Is a saddle joint
Muscles and ligaments contribute to joint stability
Unique joint shape allows for multiple complex movements
Another example of a saddle joint
Joint between trapezium and metacarpal 1
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101. Sternoclavicular Joint
Figure 9.17a
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102. Sternoclavicular Joint
Figure 9.17b
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103. Structure of joints makes them prone to traumatic stress
Disorders of Joints
Structure of joints makes them prone to traumatic stress
Function of joints makes them subject to friction and wear
Affected by inflammatory and degenerative processes
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104. Sprains – ligaments of a reinforcing joint are stretched or torn
Joint Injuries
Sprains – ligaments of a reinforcing joint are stretched or torn
Dislocation – occurs when the bones of a joint are forced out of alignment
Torn cartilage – common injury to meniscus of knee joint
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105. Inflammatory and Degenerative Conditions
Bursitis – inflammation of a bursa do to injury or friction
Tendonitis – inflammation of a tendon sheath
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106. Inflammatory and Degenerative Conditions
Arthritis – describes over 100 kinds of joint-damaging diseases
Osteoarthritis – most common type “wear and tear” arthritis
Rheumatoid arthritis – a chronic inflammatory disorder
Gouty arthritis (gout) – uric acid build-up causes pain in joints
Lyme disease – inflammatory disease often resulting in joint pain
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107. The Joints Throughout Life
Synovial joints develop from mesenchyme
By week 8 of fetal development, joints resemble adult joints
Outer region of mesenchyme becomes fibrous joint capsule
Inner region becomes the joint cavity
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108. The Joints Throughout Life
During youth – injury may tear an epiphysis off a bone shaft
Advancing age – osteoarthritis becomes more common
Exercise – helps maintain joint health
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