1. 8
Articulations

2. Section 1: Joint Design and Movement
Learning Outcomes
8.1 Describe the basic structure of a synovial joint, and describe common accessory structures and their functions.
8.2 Explain the relationship between structure and function for each type of synovial joint.
8.3 Describe flexion/extension, abduction/adduction, and circumduction movements of the skeleton.
8.4 Describe rotational and special movements of the skeleton.

3. Section 1: Joint Design and Movement
Articulations (joints)
Where two bones interconnect
Bones are relatively inflexible so necessary to allow movement
Reflect compromise between need for strength versus need for mobility
Anatomical structure of each joint determines type and amount of movement possible
Categories from range of motion and subgroups from anatomical structure

4. Section 1: Joint Design and Movement
Three functional categories
Synarthrosis (no movement)
Amphiarthrosis (little movement)
Diarthrosis (free movement)
Synarthrotic and amphiarthrotic joints
Relatively simple structure
Direct connections between bones
Diarthrotic joints
Complex in structure
Permit greatest range of motion

5. Module 8.1: Synovial joints
Components of synovial joints
Articular cartilages
Resemble hyaline cartilages
Matrix contains more water comparatively
Have no perichondrium
Slick and smooth, so reduce friction
Are separated by thin film of synovial fluid

6. Module 8.1: Synovial joints
Components of synovial joints (continued)
Synovial fluid
Similar in composition to ground substance in loose connective tissues
Produced at the synovial membrane
Circulates from areolar tissue to joint cavity
Percolates through articular cartilages
Total quantity is less than 3 mL

7. Module 8.1: Synovial joints
Components of synovial joints (continued)
Joint capsule
Dense and fibrous
May be reinforced with accessory structures (tendons and ligaments)
Continuous with periosteum of each bone

8. The structure of synovial joints
Medullary cavity
Periosteum
Components of Synovial Joints
Articular cartilage
Joint capsule
Synovial fluid
Synovial membrane
Spongy bone of epiphysis
Figure Synovial joints are freely movable diarthroses containing synovial fluid
Compact bone
Figure 8

9. Module 8.1: Synovial joints
Functions of synovial fluid
Lubrication
With articular cartilage compression, synovial fluid is squeezed out and reduces friction between moving surfaces
Nutrient distribution
Provide nutrients and oxygen, as well as waste disposal for the chondrocytes of articular cartilages
Compression and reexpansion of articular cartilages pump synovial fluid in and out of cartilage matrix
Shock absorption
Distributes compression forces across articular surfaces and outward to joint capsule

10. Module 8.1: Synovial joints
Accessory structures
Provide support and additional stability
Not all are included in every joint
Most are seen in the knee

11. Module 8.1: Synovial joints
Accessory structures in knee
Tendons of quadriceps
Pass across joint
Limit movement
Provide mechanical support
Bursa (a pouch)
Small pocket filled with synovial fluid
Often form in areas where tendon or ligament rubs against other tissues
Reduce friction and act as shock absorbers

12. Module 8.1: Synovial joints
Accessory structures in knee (continued)
Fat pads
Adipose tissue covered by synovial membrane
Protect articular cartilages
Act as packing material for joint
Meniscus (a crescent)
Pad of fibrous cartilage between bones of synovial joint
May subdivide joint cavity and affect fluid flow or allow variations in shapes of articular surfaces

13. Module 8.1: Synovial joints
Accessory structures in knee (continued)
Accessory ligaments
Support, strengthen, and reinforce joint
Intrinsic ligaments
Localized thickening of joint capsule
Example: cruciate liagments of knee
Extrinsic ligaments
Separate from joint capsule
May pass inside (intracapsular) or outside (extracapsular) the joint capsule
Intracapsular example: cruciate ligaments
Extracapsular example: patellar ligament

14. Accessory structures of complex synovial joints,
as seen in a diagrammatic view of a
sagittal section of the knee
Tendon of the quadriceps muscles
Patella
Accessory Structures
Synovial
membrane
Femur
Bursa
Joint
capsule
Fat pad
Joint cavity
Meniscus
Articular
cartilage
Figure Synovial joints are freely movable diarthroses containing synovial fluid
Tibia
Extracapsular ligament
Intracapsular ligament
Figure 14

15. Module 8.1: Synovial joints
Mobility vs. strength in joints
Greater range of motion = weaker joint
Examples:
Synarthrosis (strongest type of joint, no movement)
Diarthrosis (far weaker but broad range of motion)
Dislocation (luxation)
Movement beyond normal range of motion
Articulating surfaces forced out of position
Can damage joint structures
No pain from inside joint but from nerves or surrounding structures

16. Module 8.1 Review a. Define a joint dislocation (luxation).
b. Describe the components of a synovial joint, and identify the functions of each.
c. Why would improper circulation of synovial fluid lead to the degeneration of articular cartilages in the affected joint?

17. Module 8.2: Types of motion and structural types of synovial joints
Types of motion permitted at synovial joints
Gliding
Movement along two axes in one plane
Angular motion
Movement along two axes in one plane with additional change in angle

18. Module 8.2: Types of motion and structural types of synovial joints
Types of motion permitted at synovial joints (continued)
Circumduction
Special complex angular movement
Proximal end of bone remains fixed while distal end can move in a circle (“trace circumference”)
Rotation
Bone ends remain fixed and shaft rotates
Animation: Synovial Joints: Movement

19. The general types of movement at synovial joints
Starting position
Gliding
Angular motion
Figure Anatomical organization determines the functional properties of synovial joints
Circumduction
Rotation
Figure – 5 19

20. The anatomical types of synovial joints, with joint models and examples
Models of Joint Motion
Examples
Gliding joint
• Acromioclavicular and
claviculosternal joints
Clavicle
• Intercarpal and
intertarsal joints
Manubrium
• Vertebrocostal joints
• Sacro-iliac joints
Hinge joint
• Elbow joints
Humerus
• Knee joints
• Ankle joints
• Interphalangeal joints
Ulna
Pivot joint
• Atlas/axis
Atlas
• Proximal radio-ulnar
joints
Axis
Ellipsoid joint
• Radiocarpal joints
• Metacarpophalangeal
joints 2–5
• Metatarsophalangeal
joints
Scaphoid bone
Ulna
Radius
Figure Anatomical organization determines the functional properties of synovial joints
Saddle joint
• First carpometacarpal
joints
Metacarpal bone
of thumb
Trapezium
Ball-and-socket joint
• Shoulder joints
Scapula
• Hip joints
Humerus
Figure 20

21. Module 8.2 Review
a. Identify the types of synovial joints based on the shapes of the articulating surfaces.
b. What type of synovial joint permits the widest range of motion?
c. Indicate the type of synovial joint for each of the following: shoulder, elbow, ankle, and thumb.

22. Module 8.3: Specific angular movements
Flexion and extension
Usually applied to movements of long bones of limbs but also axial skeleton
Flexion
Anterior/posterior movement that reduces angle between articulating elements
Lateral flexion
Vertebral column bending to the side
Dorsiflexion
Flexion at ankle joint and elevation of sole
Plantar flexion (planta, sole)
Extension at ankle joint and elevation of heel

23. Module 8.3: Specific angular movements
Flexion and extension (continued)
Extension
Anterior/posterior movement that increases angle between articulating elements
Hyperextension
Extension past anatomical position
Animation: Foot Dorsiflexion: Plantar Flexion
Animation: Elbow Flexion/Extension
Animation: Wrist Flexion/Extension

24. Flexion and extension
Extension
Flexion
Hyperextension
Lateral flexion
Dorsiflexion
(ankle flexion)
Flexion
Extension
Figure Broad descriptive terms are used to describe movements with reference to the anatomical position
Plantar flexion
(ankle extension)
Flexion
Hyperextension
Figure 24

25. Module 8.3: Specific angular movements
Abduction and Adduction
Always refers to movements of appendicular skeleton, not axial
Movements are usually toward or away from body midline
For fingers or toes, movements are spreading digits apart or bringing them together
Abduction (ab, from)
Movement away from body longitudinal axis in frontal plane
Adduction (ad, to)
Movement toward body longitudinal axis in frontal plane
Animation: Humerus Abduction/Adduction

26. Abduction and adduction
Figure Broad descriptive terms are used to describe movements with reference to the anatomical position
Abduction
Adduction
Figure 26

27. Module 8.3: Specific angular movements
Circumduction
Moving arm or thigh as if to draw a big circle at distal end of limb
Animation: Wrist Circumduction
Animation: Humerus Circumduction
Animation: Synovial Joints: Angular Movement

28. Module 8.3 Review
a. When doing jumping jacks, which lower limb movements are necessary?
b. Which movements are associated with hinge joints?
c. Compare dorsiflexion to plantar flexion.

29. Module 8.4: Rotation and special movements
When applied to the trunk, described as left and right rotation
When applied to limbs
Medial rotation (internal or inward rotation)
Anterior surface of limb toward trunk long axis
Lateral rotation (external or outward rotation)
Anterior surface of limb away from trunk long axis
Animation: Humerus Rotation

30. Rotational movements
Right
rotation
Left
rotation
Lateral
(external)
rotation
Medial
(internal)
rotation
Figure Terms of more limited application describe rotational movements and special movements
Figure 30

31. Module 8.4: Rotation and special movements
Rotation (continued)
Other special terms for rotation of forearm
Pronation
Proximal end of radius rotates near ulna
Distal end rolls across anterior ulnar surface
Turns the wrist and hand from palm facing front to palm facing back
Supination
Opposing movement
Palm is turned anteriorly
Animation: Elbow Pronation/Supination

32. Rotational movements Supination Pronation
Figure Terms of more limited application describe rotational movements and special movements
Supination
Pronation
Figure 32

33. Module 8.4: Rotation and special movements
Opposition
Movement of thumb toward palm surface or other fingers
Protraction
Movement forward in anterior plane
Retraction
Reverse of protraction
Inversion (in, into + vertere, to turn)
Twisting foot motion to turn sole inward
Eversion (e, out)
Opposing movement to inversion

34. Module 8.4: Rotation and special movements
Special movements (continued)
Depression
Movement inferiorly
Elevation
Movement superiorly
Animation: Foot Inversion/Eversion
Animation: Hand Opposition

35. Special movements
Opposition
Retraction
Protraction
Figure Terms of more limited application describe rotational movements and special movements
Eversion
Inversion
Depression
Elevation
Figure 35

36. Module 8.4 Review
a. Snapping your fingers involves what movement with the thumb and third metacarpophalangeal joint?
b. What movements are made possible by the rotation of the radius head?
c. What hand movements occur when wriggling into tight-fitting gloves?

37. Section 2: Articulations
Learning Outcomes
8.5 Describe the articulations between the vertebrae of the vertebral column.
8.6 Describe the structure and function of the shoulder and hip joints.
8.7 Describe the structure and function of the elbow and knee joints.
8.8 CLINICAL MODULE Explain arthritis, and describe its effects on joint structure and function.

38. Section 2: Articulations
Axial skeleton articulations
Typically are strong but very little movement
Appendicular skeleton articulations
Typically have extensive range of motion
Often weaker than axial articulations

39. Joints of the Axial Skeleton Sutures of the skull
Temporomandibular joint
(temporal bone and
mandible)
Atlanto-occipital joint
(occipital bone and atlas)
and the atlanto-axial joint
(C1–C2)
Joints of the thoracic cage
Intervertebral joints
Figure 8 Section 2 Articulations of the Axial and Appendicular Skeletons
The lumbosacral joint,
which attaches the last
lumbar vertebra to the
sacrum
The sacrococcygeal and
intercoccygeal joints,
which structurally
resemble simplified
intervertebral joints
Figure 8 Section 39

40. Joints of the
Appendicular Skeleton
The sternoclavicular joint,
the only articulation between
the axial skeleton and the
pectoral girdle and upper
limb
Shoulder joint
The sacro-iliac joint, which
firmly attaches the sacrum
of the axial skeleton to the
pelvic girdle of the
appendicular skeleton
Elbow joint
Superior and inferior
radio-ulnar joints
Pubic symphysis
Wrist joint
Joints of the hand
and fingers
Hip joint
Figure 8 Section 2 Articulations of the Axial and Appendicular Skeletons
Knee joint
Ankle joint
Joints of the foot and toes
Figure 8 Section 40

41. Module 8.5: Vertebral articulations
Between superior and inferior articular processes of adjacent vertebrae
Gliding diarthrotic joints
Permit flexion and rotation
Adjacent vertebral bodies form symphyseal joints with intervertebral discs
Numerous ligaments attach bodies and processes of vertebrae to stabilize column 41

42. Module 8.5: Vertebral articulations
Intervertebral discs
Composition
Anulus fibrosis
Tough outer layer of fibrous cartilage
Collagen fibers attach to adjacent vertebrae
Nucleus pulposus
Soft, elastic, gelatinous core
Provides resiliency and shock absorption
Account for ¼ length of vertebral column
Water loss from discs causes shortening of vertebral column with age and increases risk of disc injury 42

43. An intervertebral disc
Anulus fibrosus
Nucleus pulposus
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies
Superior view
Figure 43

44. Module 8.5: Vertebral articulations
Primary vertebral ligaments
Ligamentum flavum
Connects adjacent vertebral laminae
Posterior longitudinal ligament
Connects posterior surfaces of adjacent vertebral bodies
Interspinous ligament
Connects spinous processes of adjacent vertebrae
Supraspinous ligament
Connects spinous processes from sacrum to C7
Ligamentum nuchae from C7 to base of skull
Anterior longitudinal ligament
Connects anterior surfaces of adjacent vertebral bodies 44

45. Primary Vertebral Ligaments
The ligaments attached to the bodies and processes of all vertebrae
Primary Vertebral Ligaments
Ligamentum flavum
Intervertebral disc
Anulus fibrosus
Posterior longitudinal ligament
Nucleus pulposus
Spinal cord
Interspinous ligament
Spinal nerve
Supraspinous ligament
Posterior
longitudinal
ligament
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies
Anterior longitudinal ligament
Lateral view
Sectional view
Figure 45

46. Module 8.5: Vertebral articulations
Disorders of vertebral column
Slipped disc
Posterior longitudinal ligaments weaken causing more pressure on discs
Nucleus pulposus compresses, distorts anulus fibrosus
Disc bulges into vertebral canal (doesn’t actually slip)
Herniated disc
Nucleus pulposus breaks through anulus fibrosus
Spinal nerves are often affected 46

47. A slipped disc, as seen in a lateral view
Normal
intervertabral
disc L1
Slipped
disc
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies L2
Figure 47

48. A herniated disc, as seen in a superior view
Compressed area
of spinal nerve
Spinal nerve
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies
Spinal cord
Nucleus pulposus
of herniated disc
Anulus
fibrosis
Figure 48

49. Module 8.5: Vertebral articulations
Disorders of vertebral column (continued)
Osteopenia (penia, lacking)
Inadequate ossification leading to loss of bone mass
Often occurs with age beginning between ages 30 and 40
More severe in women than men
Osteoporosis (porosus, porous)
Bone loss sufficient to affect normal function 49

50. The effects of osteoporosis on spongy bone
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies
Clinical scan of a compression
fracture in a lumbar vertebra
Figure 50

51. The effects of osteoporosis on spongy bone
Figure Adjacent vertebrae have gliding diarthroses between their articular processes, and symphyseal joints between their vertebral bodies
Normal spongy bone
SEM x 25
Spongy bone with
osteoporosis
SEM x 21
Figure 51

52. Module 8.5 Review a. Identify the primary vertebral ligaments.
b. Describe the nucleus pulposus and anulus fibrosus of an intervertebral disc.
c. Compare a slipped disc with a herniated disc. 52

53. Module 8.6: Shoulder and hip joints
Shoulder joint (glenohumeral joint)
Greatest range of motion of any joint
Most frequently dislocated joint
Demonstrates stability sacrificed for mobility
Most stability provided by surrounding skeletal muscles, associated tendons, and various ligaments
Ball-and-socket diarthrosis
Formed by head of humerus and glenoid cavity of scapula
Socket of glenoid cavity increased by fibrous-cartilaginous glenoid labrum (labrum, lip or edge)
Animation: Scapula Clavicle Humerus 53

54. Module 8.6: Shoulder and hip joints
Shoulder joint (continued)
Ligaments stabilizing the shoulder
Coracoclavicular ligaments
Acromioclavicular ligament
Coraco-acromial ligament
Coracohumeral ligament
Glenohumeral ligaments 54

55. The shoulder joint (glenohumeral joint)
Coracoid process
Clavicle
Acromion
Ligaments Stabilizing
the Shoulder
Bursae
Coracoclavicular ligaments
Articular
capsule
Acromioclavicular ligament
Figure The shoulder and hip are ball-and-socket joints
Scapula
Coraco-acromial ligament
Tendon of the biceps
brachii muscle
Coracohumeral ligament
Glenohumeral ligaments
Humerus
Figure 55

56. The structures within and surrounding the shoulder joint
A frontal section of the shoulder joint
A lateral view of the shoulder joint
Subdeltoid
bursa
Articular
capsule
Coraco-acromial
ligament
Coracoclavicular
ligaments
Acromioclavicular
ligament
Clavicle
Tendon of
supraspinatus muscle
Clavicle
Acromion
Tendon of
infraspinatus muscle
Tendon of biceps
brachii muscle
Coracohumeral
ligament (cut)
Articular
cartilages
Articular
capsule
Glenoid
cavity
Humerus
Scapula
Glenohumeral
ligaments
Subscapularis muscle
Glenoid
labrum
Glenoid
labrum
Figure The shoulder and hip are ball-and-socket joints
Teres minor muscle
Scapula
Synovial
membrane
Frontal section
Lateral view
Figure – 3 56

57. Module 8.6: Shoulder and hip joints
Sturdy ball-and-socket joint
Although not directly aligned with weight distribution along femur shaft, which can produce fractures of femoral neck or intertrochanteric region
Permits flexion, extension, adduction, abduction, circumduction, and rotation
Formed by head of femur and acetabulum of hip bone
Socket of acetabulum increased by projecting rim of fibrous cartilage (acetabular labrum)
Articular capsule extends from lateral/inferior surfaces of pelvic girdle to intertrochanteric line and crest of femur 57

58. The hip joint in lateral view
Iliofemoral ligament
Fibrous cartilage pad
Acetabular labrum
Fat pad
Acetabulum
Ligamentum teres
(ligament of the
femoral head)
Figure The shoulder and hip are ball-and-socket joints
Transverse acetabular ligament
Figure 58

59. Module 8.6: Shoulder and hip joints
Hip joint (continued)
Reinforcing ligaments
Transverse acetabular ligament
Crosses acetabular notch, filling gap in inferior border
Ligamentum teres (teres, long and round)
Originates along transverse acetabular ligament and attached to fovea capitis
Pubofemoral ligament
Iliofemoral ligament
Ischiofemoral ligament
Animation: Pelvic Girdle: Hip Femur 59

60. Reinforcing Ligaments Ischiofemoral ligament
The ligaments of the hip joint
Reinforcing Ligaments
Pubofemoral ligament
Iliofemoral ligament
Ischiofemoral ligament
Greater
trochanter
Ischial
tuberosity
Posterior view
Inter-
trochanteric
line
Figure The shoulder and hip are ball-and-socket joints
The ligaments of the hip joint in posterior view
Lesser trochanter
Anterior view
The ligaments of the hip joint in anterior view
Figure 60

61. Module 8.6 Review
a. Which tissues or structures provide most of the stability for the shoulder joint?
b. At what site are the iliofemoral ligament, pubofemoral ligament, and ischiofemoral ligament located?
c. A football player received a hard tackle to the upper surface of his shoulder, causing a shoulder separation. What bones and ligaments would be affected? 61

62. Module 8.7: Elbow and knee joints
Elbow joint
Complex hinge joint involving humerus, radius, and ulna
Extremely strong and stable due to:
Bony surfaces of humerus and ulna interlock
Single, thick articular capsule surrounds both humero-ulnar and proximal radio-ulnar joints
Articular capsule reinforced by strong ligaments
Severe stresses can still produce dislocations or other injuries
Example: nursemaid’s elbow
Muscles flexing elbow attach on anterior while those extending attach on the posterior 62

63. Module 8.7: Elbow and knee joints
Elbow joint (continued)
Specific joints of the elbow
Humeroradial joint
Capitulum of humerus articulating with head of radius
Humero-ulnar joint
Largest and strongest articulation
Trochlea of humerus articulates with trochlear notch of ulna
Shape of ulnar notch determines plane of movement
Shapes of olecranon fossa and olecranon limit degree of extension
Proximal radio-ulnar joint is not part of elbow joint 63

64. The elbow joint Anterior view Humeroradial joint Humerus
Humeroulnar joint
Figure The elbow and the knee are hinge joints
Radius
Ulna
Proximal radio-ulnar joint
(not part of the elbow joint)
Figure 64

65. Module 8.7: Elbow and knee joints
Elbow joint (continued)
Reinforcing ligaments
Radial collateral ligament
Stabilizes lateral surface of joint
Ulnar collateral ligament
Stabilizes medial surface of joint
Annular ligament
Binds head of radius to ulna 65

66. The elbow joint Posterior view Humerus Olecranon fossa
Humeroulnar joint
Figure The elbow and the knee are hinge joints
Ulna
Olecranon
Figure 66

67. Module 8.7: Elbow and knee joints
Contains three separate articulations
Medial condyle of tibia to medial condyle of femur
Lateral condyle of tibia to lateral condyle of femur
Patella and patellar surface of femur
Permits flexion, extension, and very limited rotation
Animation: Patella Tibia Fibula 67

68. Module 8.7: Elbow and knee joints
Knee joint (continued)
External support
Quadriceps tendon to patella
Continues as patellar ligament to anterior tibia
Fibular collateral ligament
Lateral support
Tibial collateral ligament
Medial support
Popliteal ligaments
Posterior support extending between femur and heads of tibia and fibula
Tendons of several muscles that attach to femur and tibia 68

69. The knee joint Superficial Superficial anterior view posterior view
Femur
Quadriceps
tendon
Joint capsule
Fibular
collateral
ligament
Bursa
Patella
Tibial collateral
ligament
Fibular
collateral
ligament
Cut tendon
of biceps
femoris
muscle
Patellar
ligament
Popliteal ligaments
Tibia
Figure The elbow and the knee are hinge joints
Fibula
Fibula
Tibia
Figure – 4 69

70. Module 8.7: Elbow and knee joints
Knee joint (continued)
Internal support
Cruciate ligaments limit anterior/posterior movement of femur and maintain alignment of condyles
Anterior cruciate ligament (ACL)
At full extension, knee becomes “locked” (slight lateral rotation tightens ACL, and lateral meniscus forced between tibia and femur)
Opposite motion to “unlock”
Posterior cruciate ligament (PCL) 70

71. Module 8.7: Elbow and knee joints
Knee joint (continued)
Internal support (continued)
Medial and lateral menisci
Fibrous cartilage pads between tibial and femoral condyles
Act as cushions and provide lateral stability to joint 71

72. The knee joint Deep anterior Deep posterior view, flexed
view, extended
PCL
ACL
Patellar
surface
of femur
ACL
PCL
Femur
Fibular
collateral
ligament
Lateral
condyle
Medial
condyle
Fibular
collateral
ligament
Medial
condyle
Lateral
condyle
Tibial collateral ligament
Tibia
Medial and lateral menisci
Tibia
Fibula
Figure The elbow and the knee are hinge joints
Fibula
Figure – 4 72

73. Module 8.7 Review
a. Between the elbow and knee joints, which have menisci?
b. What signs and symptoms would you expect in an individual who has damaged the menisci of the knee joint? 73

74. CLINICAL MODULE 8.8: Disruption to normal joint function
Arthritis
Damage to articular cartilages but specific cause varies
Exposed surfaces change from slick, smooth-gliding to rough feltwork of collagen fibers increasing friction
Rheumatism (pain and stiffness affecting the skeletal and/or muscular systems) is often a symptom
Osteoarthritis
Also known as degenerative arthritis or degenerative joint disease
Generally affects individuals age 60 and older
25% of women, 15% of men
Can result from cumulative wear and tear of joints or genetic factors affecting collagen formation 74

75. Normal Joint Arthritic Joint
Comparisons of normal articular cartilage with articular cartilage damaged by osteoarthritis
Normal Joint
Arthritic Joint
Fibrous
remains
of the
articular
cartilage
Articular
cartilage
Degenerating
articular
cartilage
LM x 180
LM x 180
Figure Arthritis can disrupt normal joint structure and function
Arthroscopic view of normal cartilage
Arthroscopic view of damaged cartilage
Figure – 2 75

76. CLINICAL MODULE 8.8: Disruption to normal joint function
Visualizing problematic joints
Arthroscopic surgery
Optical fibers (arthroscope) inserted into joint through small incision without major surgery to visualize joint interior
If necessary, other instruments can be inserted through other incisions to permit surgery within view of arthroscope
Magnetic resonance imaging
Cost-effective and noninvasive viewing technique that allows examination of soft tissues around joint as well 76

77. An arthroscopic view of the interior of the left knee,
showing injuries to the anterior and
posterior cruciate ligaments.
PCL
Femoral
condyle
ACL
Meniscus
Figure Arthritis can disrupt normal joint structure and function
Figure 77

78. Figure 8.8.4 Arthritis can disrupt normal joint structure and function78

79. CLINICAL MODULE 8.8: Disruption to normal joint function
Artificial joints
May be last resort if other solutions (exercise, physical therapy, drugs) for joint problems fail
Not as strong as natural joints, so most suitable for elderly
Typically have service life of about 10 years 79

80. Figure 8.8.5 Arthritis can disrupt normal joint structure and function80

81. CLINICAL MODULE 8.8 Review
a. Compare rheumatism to osteoarthritis.
b. Explain the use of an arthroscope.
c. What can a person do to slow the progression of arthritis? 81