1. 9
Articulations

2. An Introduction to Articulations
Learning Outcomes
9-1 Contrast the major categories of joints, and explain the relationship between structure and function for each category.
9-2 Describe the basic structure of a synovial joint, and describe common synovial joint accessory structures and their functions.
9-3 Describe how the anatomical and functional properties of synovial joints permit movements of the skeleton.
9-4 Describe the articulations between the vertebrae of the vertebral column.

3. An Introduction to Articulations
Learning Outcomes
9-5 Describe the structure and function of the shoulder joint and the elbow joint.
9-6 Describe the structure and function of the hip joint and the knee joint.
9-7 Describe the effects of aging on articulations, and discuss the most common age-related clinical problems for articulations.
9-8 Explain the functional relationships between the skeletal system and other body systems.

4. An Introduction to Articulations
Body movement occurs at joints (articulations) where two bones, bone & cartilage, or tooth & bone connect
Joint Structure
Determines direction and distance of movement (range of motion or ROM)
Joint strength decreases as mobility increases

5. 9-1 Classification of Joints
Two Methods of Classification
Functional classification is based on range of motion of the joint
Structural classification relies on the anatomical organization of the joint

6. 9-1 Classification of Joints
Functional Classifications
Synarthrosis (immovable joint)
Amphiarthrosis (slightly movable joint)
Diarthrosis (freely movable joint)

7. 9-1 Classification of Joints
Structural Classifications
Bony
Fibrous
Cartilaginous
Synovial

8. Table 9-1 Functional and Structural Classifications of Articulations8

9. Table 9-1 Functional and Structural Classifications of Articulations

10. Table 9-1 Functional and Structural Classifications of Articulations10

11. 9-1 Classification of Joints
Synarthroses (Immovable Joints)
Are very strong
Edges of bones may touch or interlock
Four types of synarthrotic joints
Suture
Gomphosis
Synchondrosis
Synostosis

12. 9-1 Classification of Joints
Suture
Bones interlocked
Are bound by dense fibrous connective tissue
Are found only in skull
Gomphosis
Fibrous connection (periodontal ligament)
Binds teeth to sockets

13. 9-1 Classification of Joints
Synchondrosis
Is a rigid cartilaginous bridge between two bones
Epiphyseal cartilage of long bones
Between vertebrosternal ribs and sternum
Synostosis
Fused bones, immovable
Metopic suture of skull
Epiphyseal lines of long bones

14. 9-1 Classification of Joints
Amphiarthroses
More movable than synarthrosis
Stronger than freely movable joint
Two types of amphiarthroses
Syndesmosis
Bones connected by ligaments
Symphysis
Bones separated by fibrocartilage

15. 9-1 Classification of Joints
Synovial Joints (Diarthroses)
Also called movable joints
At ends of long bones
SPACE BETWEEN ARTICULTING BONES
Within articular capsules
Lined with synovial membrane

16. 9-2 Synovial Joints Articular Cartilages
Pad articulating surfaces within articular capsules
Prevent bones from touching
Smooth surfaces lubricated by synovial fluid
Reduce friction

17. 9-2 Synovial Joints Synovial Fluid
Contains slippery proteoglycans secreted by fibroblasts
Functions of synovial fluid
Lubrication
Nutrient distribution
Shock absorption

18. 9-2 Synovial Joints Accessory Structures Cartilages Fat pads Ligaments
Tendons
Bursae

19. 9-2 Synovial Joints Cartilages Fat Pads Ligaments Cushion the joint
Fibrocartilage pad called a meniscus (or articular disc; plural, menisci)
Fat Pads
Superficial to the joint capsule
Protect articular cartilages
Ligaments
Support, strengthen joints
Sprain – ligaments with torn collagen fibers

20. 9-2 Synovial Joints Tendons Bursae Attach to muscles around joint
Help support joint
Bursae
Singular, bursa, a pouch
Pockets of synovial fluid
Cushion areas where tendons or ligaments rub

21. 9-2 Synovial Joints Factors That Stabilize Synovial Joints
Prevent injury by limiting range of motion
Collagen fibers (joint capsule, ligaments)
Articulating surfaces and menisci
Other bones, muscles, or fat pads
Tendons of articulating bones

22. Figure 9-1a The Structure of a Synovial Joint
Medullary cavity
Spongy bone
Periosteum
Fibrous joint capsule
Synovial membrane
Articular cartilages
Joint cavity (containing synovial fluid)
Compact bone
Synovial joint, sagittal section 22

23. Figure 9-1b The Structure of a Synovial Joint
Quadriceps tendon
Bursa
Joint capsule
Femur
Patella
Synovial membrane
Articular cartilage
Meniscus
Fat pad
Patellar ligament
Intracapsular ligament
Joint cavity
Tibia
Meniscus
Knee joint, sagittal section 23

24. 9-2 Synovial Joints Injuries Dislocation (luxation) Subluxation
Articulating surfaces forced out of position
Damages articular cartilage, ligaments, joint capsule
Subluxation
A partial dislocation

25. 9-3 Movements Three Types of Dynamic Motion
Linear movement (gliding)
Angular movement
Rotation
Planes (Axes) of Dynamic Motion
Monaxial (1 axis)
Biaxial (2 axes)
Triaxial (3 axes)

26. Figure 9-2 A Simple Model of Articular Movement
Initial position
Gliding movement
Angular movement
Circumduction
Rotation 26

27. Figure 9-2a A Simple Model of Articular Movement
Initial position
Initial position of the model. The pencil is at right angles to surface. 27

28. Figure 9-2b A Simple Model of Articular Movement
Gliding movement
Possible movement 1, showing gliding, an example of linear movement. The pencil remains vertical, but tip moves away from point of origin. 28

29. Figure 9-2c A Simple Model of Articular Movement
Angular movement
Possible movement 2, showing angular movement. The pencil tip remains stationary, but shaft changes angle relative to the surface. 29

30. Figure 9-2d A Simple Model of Articular Movement
Circumduction
Possible movement 2, showing a special type of angular movement called circumduction. Pencil tip remains stationary while the shaft, held at an angle less than 90º, moves in a conical pattern to complete a circle. 30

31. Figure 9-2e A Simple Model of Articular Movement
Rotation
Possible movement 3, showing rotation. With tip at same point, the angle of the shaft remains unchanged as the shaft spins around its longitudinal axis. 31

32. 9-3 Movements Types of Movement at Synovial Joints Terms describe:
Plane or direction of motion
Relationship between structures

33. 9-3 Movements Types of Movement at Synovial Joints Gliding Movement
Two surfaces slide past each other
Between carpal or tarsal bones

34. 9-3 Movements Angular Movement Flexion Extension Angular motion
Anterior–posterior plane
Reduces angle between elements
Extension
Increases angle between elements

35. 9-3 Movements Angular Movement Hyperextension Angular motion
Extension past anatomical position

36. Figure 9-3a Angular Movements
Extension
Flexion
Hyperextension
Flexion
Flexion
Hyper- extension
Extension
Extension
Flexion
Hyperextension
Extension
Flexion/extension 36

37. 9-3 Movements Angular Movement Abduction Adduction Angular motion
Frontal plane
Moves away from longitudinal axis
Adduction
Moves toward longitudinal axis

38. Figure 9-3b Angular Movements
Abduction
Abduction
Adduction
Adduction
Abduction
Adduction
Abduction
Adduction
Abduction/adduction 38

39. Figure 9-3c Angular Movements
Adduction
Abduction
Adduction/abduction 39

40. 9-3 Movements Angular Movement Circumduction
Circular motion without rotation
Angular motion

41. Figure 9-3d Angular Movements
Circumduction 41

42. 9-3 Movements Types of Movement at Synovial Joints Rotation
Direction of rotation from anatomical position
Relative to longitudinal axis of body
Left or right rotation
Medial rotation (inward rotation)
Rotates toward axis
Lateral rotation (outward rotation)
Rotates away from axis

43. Figure 9-4a Rotational Movements
Head rotation
Right rotation
Left rotation
Lateral (external) rotation
Medial (internal) rotation 43

44. 9-3 Movements Types of Movements at Synovial Joints Rotation Pronation
Rotates forearm, radius over ulna
Supination
Forearm in anatomical position

45. Figure 9-4b Rotational Movements
Supination
Pronation
Supination
Pronation 45

46. 9-3 Movements Special Movements Inversion Eversion Dorsiflexion
Twists sole of foot medially
Eversion
Twists sole of foot laterally
Dorsiflexion
Flexion at ankle (lifting toes)
Plantar flexion
Extension at ankle (pointing toes)

47. Figure 9-5 Synovial Joints
Eversion
Inversion 47

48. Figure 9-5 Synovial Joints
Dorsiflexion (ankle flexion)
Plantar flexion (ankle extension) 48

49. 9-3 Movements Special Movements Opposition
Thumb movement toward fingers or palm (grasping)
Reposition
Opposite of opposition
Protraction
Moves anteriorly
In the horizontal plane (pushing forward)
Retraction
Opposite of protraction
Moving anteriorly (pulling back)

50. Figure 9-5 Synovial Joints
Opposition 50

51. Figure 9-5 Synovial Joints
Retraction
Protraction 51

52. 9-3 Movements Special Movements Elevation Depression Lateral flexion
Moves in superior direction (up)
Depression
Moves in inferior direction (down)
Lateral flexion
Bends vertebral column from side to side

53. Figure 9-5 Synovial Joints
Depression
Elevation 53

54. Figure 9-5 Synovial Joints
Lateral flexion 54

55. 9-3 Movements Classification of Synovial Joints by Shape Gliding Hinge
Pivot
Condylar
Saddle
Ball-and-socket

56. 9-3 Movements Gliding Joints Hinge Joints Pivot Joints
Flattened or slightly curved faces
Limited motion (nonaxial)
Hinge Joints
Angular motion in a single plane (monaxial)
Pivot Joints
Rotation only (monaxial)

57. Figure 9-6 Synovial Joints
Gliding joint
Movement: slight nonaxial or multiaxial
Clavicle
Examples:
• Acromioclavicular and claviculosternal joints
Manubrium
• Intercarpal and intertarsal joints
• Vertebrocostal joints
• Sacro-iliac joints 57

58. Figure 9-6 Synovial Joints
Hinge joint
Movement: monaxial
Examples:
Humerus
• Elbow joint
• Knee joint
• Ankle joint
Ulna
• Interphalangeal joint 58

59. Figure 9-6 Synovial Joints
Pivot joint
Movement: monaxial (rotation)
Examples:
Atlas
• Atlanto-axial joint
• Proximal radio-ulnar joint
Axis 59

60. 9-3 Movements Condylar Joints Saddle Joints Ball-and-socket Joints
Oval articular face within a depression
Motion in two planes (biaxial)
Saddle Joints
Two concave, straddled (biaxial)
Ball-and-socket Joints
Round articular face in a depression (triaxial)

61. Figure 9-6 Synovial Joints
Condylar joint
Movement: biaxial
Examples:
• Radiocarpal joint
Scaphoid bone
• Metacarpophalangeal joints 2–5
• Metatarsophalangeal joints
Ulna 61

62. Figure 9-6 Synovial Joints
Saddle joint
Movement: biaxial
Examples:
• First carpometacarpal joint
III II
Metacarpal bone of thumb
Trapezium 62

63. Figure 9-6 Synovial Joints
Ball-and-socket joint
Movement: triaxial
Examples:
Scapula
• Shoulder joint
• Hip joint
Humerus 63

64. 9-3 Movements Joints A joint cannot be both mobile and strong
The greater the mobility, the weaker the joint
Mobile joints are supported by muscles and ligaments, not bone-to-bone connections
ANIMATION Representative Articulations: A Functional Classification
of Synovial Joints

65. 9-4 Intervertebral Articulations
C2 to L5 spinal vertebrae articulate:
At inferior and superior articular processes (gliding joints)
Between adjacent vertebral bodies (symphyseal joints)

66. 9-4 Intervertebral Articulations
Intervertebral Discs
Pads of fibrocartilage
Separate vertebral bodies
Anulus fibrosus
Tough outer layer
Attaches disc to vertebrae
Nucleus pulposus
Elastic, gelatinous core
Absorbs shocks

67. Figure 9-7 Intervertebral Articulations
Superior articular facet
Intervertebral Disc
Vertebral end plate
Intervertebral foramen
Anulus fibrosus
Ligamentum flavum
Nucleus pulposus
Spinal cord
Posterior longitudinal ligament
Spinal nerve
Interspinous ligament
Supraspinous ligament
Anterior longitudinal ligament 67

68. 9-4 Intervertebral Articulations
Vertebral Joints
Also called symphyseal joints
As vertebral column moves:
Nucleus pulposus shifts
Disc shape conforms to motion
Intervertebral Ligaments
Bind vertebrae together
Stabilize the vertebral column

69. 9-4 Intervertebral Articulations
Six Intervertebral Ligaments
Anterior longitudinal ligament
Connects anterior bodies
Posterior longitudinal ligament
Connects posterior bodies
Ligamentum flavum
Connects laminae

70. 9-4 Intervertebral Articulations
Six Intervertebral Ligaments
Interspinous ligament
Connects spinous processes
Supraspinous ligament
Connects tips of spinous processes (C7 to sacrum)
Ligamentum nuchae
Continues supraspinous ligament (C7 to skull)

71. 9-4 Intervertebral Articulations
Damage to Intervertebral Discs
Slipped disc
Bulge in anulus fibrosus
Invades vertebral canal
Herniated disc
Nucleus pulposus breaks through anulus fibrosus
Presses on spinal cord or nerves

72. Figure 9-8a Damage to the Intervertebral Discs
Normal intervertebral disc L1
Slipped disc L2
A lateral view of the lumbar region of the spinal column, showing a distorted intervertebral disc (a “slipped” disc) 72

73. Figure 9-8b Damage to the Intervertebral Discs
Compressed area of spinal nerve
Spinal nerve
Spinal cord
Nucleus pulposus of herniated disc
Anulus fibrosus
A sectional view through a herniated disc, showing the release of the nucleus pulposus and its effect on the spinal cord and adjacent spinal nerves 73

74. 9-4 Intervertebral Articulations
Movements of the Vertebral Column
Flexion
Extension
Lateral flexion
Rotation

75. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
SKULL
Cranial and facial bones
of skull
Various
Synarthroses (suture or synostosis
None
Maxilla/teeth and
mandible/teeth
Alveolar
Synarthrosis (gomphosis)
Temporal bone/mandible
Temporo-mandibular
Combined gliding joint and hinge diarthrosis
Elevation, depression,
and lateral gliding 75

76. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
VERTEBRAL COLUMN
Occipital bone/atlas
Atlanto-occipital
Condylar diarthrosis
Flexion/
extension
Atlas/axis
Atlanto-axial
Pivot diarthrosis
Rotation
Other vertebral elements
Intervertebral (between vertebral bodies)
Amphiarthrosis (symphysis)
Slight movement
Intervertebral (between articular processes)
Gliding diarthritis
Slight rotation and flexion/ extension 76

77. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
VERTEBRAL COLUMN
L5/sacrum
Between L5 body and sacral body
Amphiarthrosis (symphysis)
Slight movement
Between inferior articular processes
of L5 and articular processes of sacrum
Gliding diarthrosis
Slight flexion/ extension 77

78. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
VERTEBRAL COLUMN
Sacrum/coxal bone
Sacro-iliac
Gliding diarthrosis
Slight movement
Sacrum/coccyx
Sacrococcygeal
Gliding diarthrosis (may become fused)
Coccygeal bones
Synarthrosis (synostosis)
No movement 78

79. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
THORACIC CAGE
Bodies of T1–T12 and heads of ribs
Costovertebral
Gliding diarthrosis
Slight movement
Transverse processes of T1–T10
Ribs and costal cartilages
Synarthrosis (synchondrosis)
No movement 79

80. 9-4 Articulations of the Axial Skeleton
Element
Joint
Type of Articulation
Movement(s)
THORACIC CAGE
Sternum and first costal cartilage
Sternocostal (1st)
Synarthrosis (synchondrosis)
No movement
Sternum and costal cartilages 2–7
Sternocostal (2nd–7th)
Gliding diarthrosis
Slight movement 80

81. 9-5 The Shoulder Joint The Shoulder Joint
Also called the glenohumeral joint
Allows more motion than any other joint
Is the least stable
Supported by skeletal muscles, tendons, ligaments
Ball-and-socket diarthrosis
Between head of humerus and glenoid cavity of scapula

82. 9-5 The Shoulder Joint Socket of the Shoulder Joint Glenoid labrum
Deepens socket of glenoid cavity
Fibrocartilage lining
Extends past the bone

83. 9-5 The Shoulder Joint Processes of the Shoulder Joint
Acromion (clavicle) and coracoid process (scapula)
Project laterally, superior to the humerus
Help stabilize the joint

84. 9-5 The Shoulder Joint Shoulder Ligaments Shoulder Separation
Glenohumeral
Coracohumeral
Coraco-acromial
Coracoclavicular
Acromioclavicular
Shoulder Separation
Dislocation of the shoulder joint

85. 9-5 The Shoulder Joint Shoulder Muscles (Rotator Cuff) Supraspinatus
Infraspinatus
Subscapularis
Teres minor

86. 9-5 The Shoulder Joint Shoulder Bursae Subacromial Subcoracoid
Subdeltoid
Subscapular

87. Figure 9-9a The Shoulder Joint
Acromioclavicular ligament
Coracoclavicular ligaments
Tendon of supraspinatus muscle
Clavicle
Acromion
Articular capsule
Coraco-acromial ligament
Subdeltoid bursa
Coracoid process
Scapula
Synovial membrane
Articular cartilages
Joint cavity
Humerus
Glenoid labrum
Articular capsule
Anterior view, frontal section 87

88. Figure 9-9b The Shoulder Joint
Acromioclavicular ligament
Clavicle
Coraco-acromial ligament
Coracoclavicular ligaments
Tendon of supraspinatus muscle
Tendon of biceps brachii muscle
Coracohumeral ligament (cut)
Acromion
Coracoid process
Subacromial bursa
Subcoracoid bursa
Tendon of infraspinatus muscle
Subscapular bursa
Subscapularis muscle
Teres minor muscle
Glenohumeral ligaments
Articular capsule
Glenoid cavity
Scapula
Glenoid labrum
Lateral view of pectoral girdle 88

89. 9-5 The Elbow Joint The Elbow Joint A stable hinge joint
With articulations involving humerus, radius, and ulna

90. 9-5 The Elbow Joint Articulations of the Elbow Humero-ulnar joint
Largest articulation
Trochlea of humerus and trochlear notch of ulna
Limited movement

91. 9-5 The Elbow Joint Articulations of the Elbow Humeroradial joint
Smaller articulation
Capitulum of humerus and head of radius

92. Figure 9-10a The Right Elbow Joint Showing Stabilizing Ligaments
Humerus
Radial collateral ligament
Radial tuberosity
Antebrachial interosseous membrane
Radius
Ulna
Capitulum
Annular ligament (covering head and neck of radius)
Lateral view 92

93. 9-5 The Elbow Joint Supporting Structures of the Elbow
Biceps brachii muscle
Attached to radial tuberosity
Controls elbow motion
Elbow Ligaments
Radial collateral
Annular
Ulnar collateral

94. Figure 9-10b The Right Elbow Joint Showing Stabilizing Ligaments
Tendon of biceps brachii muscle
Annular ligament
Humerus
Articular capsule
Antebrachial interosseous membrane
Medial epicondyle
Ulnar collateral ligament
Radius
Ulna
Olecranon of ulna
Medial view 94

95. 9-6 The Hip Joint The Hip Joint Also called coxal joint
Strong ball-and-socket diarthrosis
Wide range of motion

96. 9-6 The Hip Joint Structures of the Hip Joint
Head of femur fits into it
Socket of acetabulum
Which is extended by fibrocartilaginous acetabular labrum

97. 9-6 The Hip Joint Ligaments of the Hip Joint Iliofemoral Pubofemoral
Ischiofemoral
Transverse acetabular
Ligamentum teres

98. Figure 9-11a The Right Hip Joint
Iliofemoral ligament
Fibrocartilage pad
Acetabular labrum
Ligament of the femoral head
Acetabulum
Transverse acetabular ligament (spanning acetabular notch)
Fat pad in acetabular fossa
A lateral view with the femur removed 98

99. Figure 9-11b The Right Hip Joint
Pubofemoral ligament
Greater trochanter
Iliofemoral ligament
Lesser trochanter
An anterior view 99

100. Figure 9-11c The Right Hip Joint
Iliofemoral ligament
Ischiofemoral ligament
Greater trochanter
Lesser trochanter
Ischial tuberosity
A posterior view, showing addi- tional ligaments that add strength to the capsule
100

101. 9-6 The Knee Joint The Knee Joint A complicated hinge joint
Transfers weight from femur to tibia
Articulations of the knee joint
Two femur–tibia articulations
At medial and lateral condyles
One between patella and patellar surface of femur

102. 9-6 The Knee Joint The Articular Capsule and Joint Cavity
Medial and lateral menisci
Fibrocartilage pads
At femur–tibia articulations
Cushion and stabilize joint
Give lateral support

103. 9-6 The Knee Joint Seven Major Supporting Ligaments
Patellar ligament (anterior)
2. & 3. Two popliteal ligaments (posterior)
4. & 5. Anterior and posterior cruciate ligaments (inside joint capsule)
Tibial collateral ligament (medial)
Fibular collateral ligament (lateral)

104. Figure 9-12a The Right Knee Joint
Quadriceps tendon
Patella
Joint capsule
Patellar retinaculae
Tibial collateral ligament
Fibular collateral ligament
Patellar ligament
Tibia
Anterior view, superficial layer
104

105. Figure 9-12b The Right Knee Joint
Femur
Joint capsule
Plantaris muscle
Gastrocnemius muscle, medial head
Gastrocnemius muscle, lateral head
Bursa
Fibular collateral ligament
Tibial collateral ligament
Cut tendon of biceps femoris muscle
Popliteal ligaments
Popliteus muscle
Tibia
Fibula
Posterior view, superficial layer
105

106. Figure 9-12c The Right Knee Joint
Patellar surface
Fibular collateral ligament
Posterior cruciate ligament
Lateral condyle
Medial condyle
Tibial collateral ligament
Lateral meniscus
Cut tendon
Medial meniscus
Anterior cruciate ligament
Tibia
Fibula
Deep anterior view, flexed
106

107. Figure 9-12d The Right Knee Joint
Femur
Posterior cruciate ligament
Fibular collateral ligament
Medial condyle
Lateral condyle
Tibial collateral ligament
Lateral meniscus
Medial meniscus
Cut tendon
Anterior cruciate ligament
Fibula
Tibia
Deep posterior view, extended
107

108. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PECTORAL GIRDLE AND UPPER LIMB
Sternum/ clavicle
Sternoclavicular
Gliding diarthrosis
Protraction/ retraction,
elevation/ depression, slight rotation
Scapula/ clavicle
Acromioclavicular
Slight movement
Scapula/ humerus
Shoulder, or glenohumeral
Ball-and-socket diarthrosis
Flexion/ extension, adduction/ abduction,
circumduction, rotation
108

109. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PECTORAL GIRDLE AND UPPER LIMB
Humerus/ulna
and humerus/ radius
Elbow (humero-ulnar and humeroradial)
Hinge diarthrosis
Flexion/ extension
Radius/ulna
Proximal radio-ulnar
Pivot diarthrosis
Rotation
Distal radio-ulnar
Pronation/ supination
Radius/carpal bones
Radiocarpal
Condylar diarthrosis
Flexion/ extension, adduction/ abduction,
circumduction
109

110. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PECTORAL GIRDLE AND UPPER LIMB
Carpal bone to carpal bone
Intercarpal
Gliding diarthrosis
Slight movement
Carpal bone to
metacarpal bone (I)
Carpometacarpal of thumb
Saddle diarthrosis
Flexion/ extension, adduction/ abduction,
circumduction, opposition
metacarpal bone (II–V)
Carpometacarpal
Slight flexion/ extension, adduction/abduction
110

111. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PECTORAL GIRDLE AND UPPER LIMB
Metacarpal bone to phalanx
Metacarpo-phalangeal
Condylar diarthrosis
Flexion/extension, adduction/abduction,
circumduction
Phalanx/phalanx
Interphalangeal
Hinge diarthrosis
Flexion/extension
111

112. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PELVIC GIRDLE AND LOWER LIMB
Sacrum/ilium of coxal bone
Sacro-iliac
Gliding diarthrosis
Slight movement
Coxal bone/ coxal bone
Pubic symphysis
Amphiarthrosis
None
Coxal bone/femur
Hip
Ball-and-socket diarthrosis
Flexion/extension,
adduction/abduction, circumduction, rotation
Femur/tibia
Knee
Complex, functions as hinge
Flexion/extension, limited rotation
112

113. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PELVIC GIRDLE AND LOWER LIMB
Tibia/fibula
Tibiofibular (proximal)
Gliding diarthrosis
Slight movement
Tibiofibular (distal)
Gliding diarthrosis and amphiarthrotic syndesmosis
Tibia and fibula with talus
Ankle, or talocrural
Hinge diarthrosis
Flexion/extension (dorsiflexion/plantar flexion)
Tarsal bone to tarsal bone
Intertarsal
113

114. 9-6 Articulations of the Appendicular Skeleton
Element
Joint
Type of Articulation
Movements
ARTICULATIONS OF THE PELVIC GIRDLE AND LOWER LIMB
Tarsal bone to metatarsal bone
Tarsometatarsal
Gliding diarthrosis
Slight movement
Metatarsal bone to phalanx
Metatarso-phalangeal
Condylar diarthrosis
Flexion/extension, adduction/abduction
Phalanx/phalanx
Interphalangeal
Hinge diarthrosis
Flexion/extension
114

115. 9-7 Effects of Aging on Articulations
Degenerative Changes
Rheumatism
A pain and stiffness of skeletal and muscular systems
Arthritis
All forms of rheumatism that damage articular cartilages of synovial joints
Osteoarthritis
Caused by wear and tear of joint surfaces, or genetic factors affecting collagen formation
Generally in people over age 60

116. 9-7 Effects of Aging on Articulations
Rheumatoid Arthritis
An inflammatory condition
Caused by infection, allergy, or autoimmune disease
Involves the immune system
Gouty Arthritis
Occurs when crystals (uric acid or calcium salts)
Form within synovial fluid
Due to metabolic disorders

117. 9-7 Effects of Aging on Articulations
Joint Immobilization
Reduces flow of synovial fluid
Can cause arthritis symptoms
Treated by continuous passive motion or CPM (therapy)
Bones and Aging
Bone mass decreases
Bones weaken
Increases risk of hip fracture, hip dislocation, or pelvic fracture

118. 9-8 Integration with Other Systems
Bone Recycling
Living bones maintain equilibrium between:
Bone building (osteoblasts)
And breakdown (osteoclasts)

119. 9-8 Integration with Other Systems
Factors Affecting Bone Strength
Age
Physical stress
Hormone levels
Calcium and phosphorus uptake and excretion
Genetic and environmental factors

120. 9-8 Integration with Other Systems
Bones Support Body Systems
Support and protect other systems
Store fat, calcium, and phosphorus
Manufacture cells for immune system

121. 9-8 Integration with Other Systems
Bones Support Body Systems
Disorders in other body systems can cause:
Bone tumors
Osteoporosis
Arthritis
Rickets (vitamin D deficiency)