1. Fundamentals of Anatomy & Physiology
Eleventh Edition
Chapter 9
Joints
Lecture Presentation by
Deborah A. Hutchinson
Seattle University

2. 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 joints between the vertebrae of the vertebral column.

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

4. An Introduction to Joints
Joints (articulations)
Where two bones meet
Where body movement occurs
A tradeoff exists between strength and mobility
Two classification schemes
Structural (anatomy)
Functional (range of motion)
Joint structure determines function

5. 9-1 Classification of Joints
Structural classifications
Fibrous
Cartilaginous
Bony
Synovial
Functional classifications
Synarthrosis (immovable joint)
Amphiarthrosis (slightly movable joint)
Diarthrosis (freely movable joint)

6. 9-1 Classification of Joints
Synarthrosis (immovable joint)
Very strong
Edges of bones may touch or interlock
May be fibrous or cartilaginous
Four types of synarthrotic joints
Suture
Gomphosis
Synchondrosis
Synostosis

7. 9-1 Classification of Joints
Synarthrosis
Suture - Found only between bones of skull
Edges of bones interlock
Bound by dense fibrous connective tissue
Gomphosis - Binds teeth to bony sockets
Fibrous connection (periodontal ligament)
Synchondrosis - Rigid cartilaginous bridge between two bones
Found between vertebrosternal ribs and sternum
Also, epiphyseal cartilage of growing long bones
Synostosis - Created when two bones fuse
Example: metopic suture of frontal bone
And epiphyseal lines of mature long bones

8. 9-1 Classification of Joints
Amphiarthrosis
More movable than a synarthrosis
Stronger than a diarthrosis
May be fibrous or cartilaginous
Two types of amphiarthroses
Syndesmosis—bones connected by a ligament
Symphysis—bones connected by fibrocartilage

9. 9-2 Synovial Joints Synovial joints (diarthroses)
Freely movable joints
At ends of long bones
Surrounded by joint capsule (articular capsule)
Contains synovial membrane
Synovial fluid from synovial membrane
Fills joint cavity
Articular cartilage covers articulating surfaces
Prevents direct contact between bones

10. 9-2 Synovial Joints Synovial fluid Has the consistency of egg yolk
Contains proteoglycans
Primary functions include
Lubrication
Nutrient distribution
Shock absorption
Synovial joints are mobile but relatively weak
Stabilized by accessory structures
Cartilages and fat pads
Ligaments
Tendons
Bursae

11. 9-2 Synovial Joints Cartilages Fat pads Ligaments Tendons Bursae
Meniscus—fibrocartilage pad between opposing bones
Fat pads
Adipose tissue covered by synovial membrane
Protect articular cartilages
Ligaments
Support and strengthen joints
Sprain—ligament with torn collagen fibers
Tendons
Attach to muscles around joint
Bursae
Small pockets of synovial fluid
Cushion areas where tendons or ligaments rub against other tissues

12. Figure 9–1a The Structure of a Synovial Joint.
Medullary cavity
Spongy bone
Periosteum
Components of
Synovial Joints
Fibrous joint capsule
Synovial membrane
Articular cartilages
Joint cavity (contains
synovial fluid)
Ligament
Metaphysis
Compact bone a
Synovial joint, sagittal section

13. Figure 9–1b The Structure of a Synovial Joint.
Quadriceps
tendon
Patella
Accessory Structures
of a Knee Joint
Joint capsule
Femur
Synovial
membrane
Bursa
Fat pad
Joint cavity
Articular
cartilage
Meniscus
Ligaments
Tibia
Extracapsular
ligament (patellar)
Intracapsular
ligament (cruciate) b
Knee joint, sagittal section

14. 9-2 Synovial Joints Factors that stabilize synovial joints
Prevent injury by limiting range of motion
Collagen fibers of joint capsule and ligaments
Shapes of articulating surfaces and menisci
Other bones, muscles, or fat pads
Tendons attached to articulating bones

15. 9-3 Movements at Synovial Joints
Axes of Motion
Movement of joints can also be described by the
number of axes that they can rotate around. A joint
that permits movement around one axis is called
monaxial, a joint that permits movement around
two axes is called biaxial, and one that permits
movement around three axes, is called triaxial.
Superior–inferior axis
Lateral–medial axis
Anterior–posterior axis
Movements are described in terms that reflect the
Plane or direction of movement
Relationship between structures
Planes of movement
Monaxial—1 plane (e.g., elbow)
Biaxial—2 planes (e.g., wrist)
Triaxial—3 planes (e.g., shoulder)

16. 9-3 Movements at Synovial Joints
Types of movement at synovial joints
Gliding movement
Angular movement
Circumduction
Rotational movement
Special movements
Simple Model of Articular Motion
Take a pencil as your model and stand it upright
on the surface of a desk. The pencil represents a
bone, and the desk is an articular surface. A lot
of twisting, pushing, and pulling will
demonstrate that there are only three ways to
move the pencil.

17. 9-3 Movements at Synovial Joints
Gliding movement
When two flat surfaces slide past each other
Example: between carpal bones
Moving the Point
Linear motion
Possible movement 1 shows the pencil can move.
If you hold the pencil upright, without securing the
point, you can push the pencil across the surface.
This kind of motion is called gliding. You could
slide the point forward or backward, from side to
side, or diagonally.

18. 9-3 Movements at Synovial Joints
Changing the Shaft Angle
Angular motion
Possible movement 2 shows the pencil
shaft can change its angle with the
surface. With the tip held in position, you
can move the eraser end of the pencil
forward and backward, from side to side,
or at some intermediate angle.
Angular movement
Flexion and extension are movements in the anterior– posterior plane
Flexion - Decreases angle between articulating bones
Extension - Increases angle between articulating bones
Hyperextension - Extension past anatomical position

19. Figure 9–3a Angular Movements and Circumduction.
Extension
Flexion
Hyperextension
Flexion
Flexion
Hyper-
extension
Extension
Extension
Flexion
Hyperextension
Extension a
Flexion/extension

20. 9-3 Movements at Synovial Joints
Angular movement
Abduction and adduction are movements in the frontal plane
Abduction
Movement away from longitudinal axis
Adduction
Movement toward longitudinal axis

21. Figure 9–3b Angular Movements and Circumduction.
Abduction
Abduction
Adduction
Adduction
Abduction
Adduction
Abduction
Adduction b
Abduction/adduction relative to the midline of the body

22. Figure 9–3c Angular Movements and Circumduction.
Adduction
Abduction c
Adduction/abduction relative to central digit

23. 9-3 Movements at Synovial Joints
Circumduction
A complete circular movement without rotation
Changing the Shaft Angle
Circumduction
A more complex angular motion is possible.
Grasp the pencil eraser and move the pencil in
any direction until it is no longer vertical. Now,
swing the eraser through a complete circle in
a movement called circumduction.

24. Figure 9–3d Angular Movements and Circumduction.

25. 9-3 Movements at Synovial Joints
Rotational movement
Rotation in reference to anatomical position
Example: left or right rotation of head
Limb rotation is relative to longitudinal axis of body
Medial rotation (internal rotation toward long axis)
Lateral rotation (external rotation away from body)
Rotating the Shaft
Rotation
Possible movement 3 shows that the pencil shaft
can rotate. If you keep the shaft vertical and the
point at one location, you can still spin the pencil
around its longitudinal axis in a movement called
rotation. No joint can freely rotate because
this would tangle blood vessels, nerves, and
muscles, as they crossed the joint.

26. Figure 9–4a Rotational Movements.
Head rotation
Right
rotation
Left
rotation
Atlanto-axial joint
Lateral
(external)
rotation
Medial
(internal)
rotation a
Rotation

27. 9-3 Movements at Synovial Joints
Rotational movement
Pronation
Rotates forearm so that radius rolls across ulna
Results in palm facing posteriorly
Supination
Turns palm anteriorly
Forearm is supinated in anatomical position

28. Figure 9–4b Rotational Movements.
Supination
Pronation b
Supination/pronation
Supination
Pronation

29. 9-3 Movements at Synovial Joints
Special movements
Inversion
Twists sole of foot medially
Eversion
Twists sole of foot laterally
Dorsiflexion
Flexion at ankle (lifting toes)
Plantar flexion
Extension at ankle (pointing toes)

30. Figure 9–5a Special Movements.
Eversion
Inversion

31. Figure 9–5b Special Movements.
Dorsiflexion
(flexion at ankle)
Plantar flexion
(extension at ankle) b

32. 9-3 Movements at Synovial Joints
Special movements
Opposition
Movement of thumb toward palm or other fingers
Reposition
Opposite of opposition
Protraction
Anterior movement in horizontal plane (forward)
Retraction
Opposite of protraction (pulling back)

33. Figure 9–5c Special Movements.
Opposition c
Opposition
Movement of thumb toward palm or other fingers
Reposition
Opposite of opposition
Retraction
Protraction d
Protraction
Anterior movement in horizontal plane (forward)
Retraction
Opposite of protraction (pulling back)

34. 9-3 Movements at Synovial Joints
Special movements
Depression
Moving a structure inferiorly (down)
Elevation
Moving a structure superiorly (up) e
Depression
Elevation

35. Figure 9–5f Special Movements.
Lateral flexion
Bending vertebral column to the side f
Lateral flexion

36. 9-3 Movements at Synovial Joints
Classification of synovial joints
Plane (gliding)
Hinge
Condylar (ellipsoid)
Saddle
Pivot
Ball-and-socket

37. 9-3 Movements at Synovial Joints
Plane joint (gliding joint)
Flattened or slightly curved surfaces
Limited motion (nonaxial)
Plane joint
Plane joints, or gliding
joints, have flattened or
slightly curved surfaces
that slide across one
another, but the amount of
movement is very slight.
Movement:
Gliding.
Slight
nonaxial
Clavicle
Manubrium
Examples:
• Acromioclavicular and claviculosternal joints
• Intercarpal joints
• Vertebrocostal joints
• Sacro-iliac joints
Hinge joint
Angular motion in a single plane (monaxial)
Hinge joint
Hinge joints permit angular
motion in a single plane,
like the opening and
closing of a door.
Movement:
Angular.
Monaxial
Humerus
Ulna
Examples:
• Elbow joint
• Knee joint
• Ankle joint
• Interphalangeal joint

38. 9-3 Movements at Synovial Joints
Condylar joint
Oval articular face within a depression
Motion in two planes (biaxial)
Condylar joint
Condylar joints, or ellipsoid
joints, have an oval articular face
nestled within a depression on
the opposing surface.
Movement:
Angular.
Biaxial
Radius
Examples:
• Radiocarpal joint
Scaphoid
bone
• Metatarsophalangeal joints
Ulna
• Metacarpophalangeal joints 2–5
Saddle joint
Articular faces fit together like a rider in a saddle
Biaxial
Saddle joint
Saddle joints have complex
articular faces and fit together
like a rider in a saddle. Each
face is concave along one axis
and convex along the other.
Movement:
Angular.
Biaxial
III II
Metacarpal
bone of
thumb
Examples:
• First carpometacarpal joint
Trapezium

39. 9-3 Movements at Synovial Joints
Pivot joint
Rotation only
Monaxial
Pivot joint
Pivot joints only
permit rotation.
Movement:
Rotation.
Monaxial
Examples:
Atlas
• Proximal radio-ulnar joint
Axis
• Atlanto-axial joint
Ball-and-socket joint
Round head in a cup-shaped depression
Triaxial
Ball-and-socket joint
In a ball-and-socket
joint, the round head
of one bone rests within
a cup-shaped depression
in another.
Movement:
Angular,
circumduction,
and rotation.
Triaxial
Humerus
Scapula
Examples:
• Shoulder joint
• Hip joint

40. 9-4 Intervertebral Joints
First two cervical vertebrae are joined by a synovial joint
Synovial joints lie between adjacent articular processes
Adjacent vertebral bodies form symphyses

41. 9-4 Intervertebral Joints
Intervertebral disc
Separates vertebral bodies
Anulus fibrosus
Tough outer layer of fibrocartilage
Attaches disc to vertebrae
Nucleus pulposus
Elastic, gelatinous core
Absorbs shocks
Vertebral end plates of cartilage
Cover superior and inferior surfaces of disc

42. 9-4 Intervertebral Joints
Normal
intervertebral
disc L1
Bulging L2
A lateral view of the lumbar region of
the spinal column, showing a bulging
intervertebral disc a
Damage to intervertebral discs
Bulging disc
Bulge in anulus fibrosus
Invades vertebral canal

43. Clinical Note 9-1b Damage to Intervertebral Discs.
Herniated disc
Nucleus pulposus breaks through anulus fibrosus
Compresses spinal nerves
Compressed area
of spinal nerve
Nucleus pulposus
of herniated disc
Spinal nerve
Spinal cord
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 b

44. 9-4 Intervertebral Joints
As vertebral column moves
Nucleus pulposus compresses
Disc shape conforms to motion
Intervertebral ligaments
Bind vertebrae together
Stabilize the vertebral column
Vertebral movements
Flexion
Extension
Lateral flexion
Rotation

45. 9-4 Intervertebral Joints
Superior articular
process
Intervertebral
Ligaments
Ligamenta flava
Posterior longitudinal
ligament
Anterior longitudinal
Anterior view a
Intervertebral ligaments
Ligamenta flava
Connect laminae of adjacent vertebrae
Posterior longitudinal ligament
Connects posterior surfaces of vertebral bodies
Anterior longitudinal ligament
Connects anterior surfaces of vertebral bodies

46. 9-4 Intervertebral Joints
Superior
articular facet
Intervertebral
foramen
Intervertebral Disc
Vertebral end plate
Anulus fibrosus
Nucleus pulposus
Spinal cord
Spinal nerve
Lateral and sectional view b
Intervertebral ligaments
Interspinous ligaments
Connect spinous processes of adjacent vertebrae
Supraspinous ligament
Connects tips of spinous processes (C7 to sacrum)
Continuous with ligamentum nuchae (C7 to skull)

47. 9-5 Elbow and Knee Joints Elbow joint Hinge joint
Articulations involve humerus, radius, and ulna
Joints of the elbow
Humero-ulnar joint
Largest, strongest joint at elbow
Between trochlea of humerus and trochlear notch of ulna
Limited movement
Humeroradial joint
Smaller joint
Articulation between capitulum of humerus and head of radius

48. Anular ligament (covering head and neck of radius)
9-5 Elbow and Knee Joints
Humerus
Radial
collateral
ligament
tuberosity
Antebrachial
interosseous
membrane
Radius
Ulna
Capitulum
Anular ligament (covering
head and neck of radius)
Lateral view a
Structures of the elbow
Biceps brachii muscle
Attaches to radial tuberosity
Controls elbow motion
Elbow ligaments
Radial collateral
Anular
Ulnar collateral

49. Figure 9–7b The Right Elbow Joint Showing Stabilizing Ligaments.
Tendon of biceps
brachii muscle
Anular
ligament
Humerus
Articular
capsule
Antebrachial
interosseous
membrane
Medial
epicondyle
Ulnar
collateral
ligament
Radius
Ulna
Olecranon
of ulna b
Medial view

50. 9-5 Elbow and Knee Joints Knee joint Complex hinge joint
Transfers weight from femur to tibia
Three articulations
Two femur–tibia articulations
At medial and lateral condyles
One between patella and patellar surface of femur
Joint capsule and joint cavity of knee
Medial and lateral menisci
Fibrocartilage pads
At femur–tibia articulations
Cushion and stabilize joint

51. 9-5 Elbow and Knee Joints Seven major supporting ligaments
Patellar ligament (anterior)
2. & 3. Two popliteal ligaments (posterior)
4. & 5. Anterior and posterior cruciate ligaments
(inside joint capsule)
6. & 7. Tibial collateral ligament (medial) and
fibular collateral ligament (lateral)

52. Figure 9–8a The Right Knee Joint.
Quadriceps
tendon
Ligaments that
Stabilize
the Knee Joint
Patella
Patellar
retinaculae
Tibial collateral
ligament
Fibular collateral
ligament
Patellar
ligament
Fibula
Tibia a
Anterior view, superficial layer

53. Figure 9–8b The Right Knee Joint.
Patellar
surface
Ligaments that
Stabilize
the Knee Joint
Posterior cruciate
ligament
Lateral
condyle
Medial
condyle
Anterior cruciate
ligament
Tibial collateral
ligament
Menisci
Medial
Fibular collateral
ligament
Tibia
Lateral
Cut tendon of
biceps femoris
muscle
Fibula b
Deep anterior view, flexed

54. Figure 9–8c The Right Knee Joint.
Plantaris muscle
Gastrocnemius
muscle,
medial head
Femur
Gastrocnemius muscle,
lateral head
Ligaments that
Stabilize the
Knee Joint
Bursa
Tibial collateral
ligament
Joint
capsule
Fibular collateral
ligament
Popliteal
ligaments
Cut tendon of
biceps femoris
muscle
Popliteus
muscle
Tibia
Fibula c
Posterior view, superficial layer

55. Figure 9–8d The Right Knee Joint.
Femur
Ligaments that
Stabilize the
Knee Joint
Anterior cruciate
ligament
Fibular
collateral
ligament
Posterior cruciate
ligament
Medial
condyle
Lateral
condyle
Menisci
Lateral
Medial
Cut
tendon
Tibia
Fibula d
Deep posterior view, extended

56. 9-6 Shoulder and Hip Joints
Shoulder joint (glenohumeral joint)
Ball-and-socket diarthrosis
Between head of humerus and glenoid cavity of scapula
Greatest range of motion of any joint
Most frequently dislocated joint
Supported by skeletal muscles, tendons, and ligaments

57. 9-6 Shoulder and Hip Joints
Joint capsule and joint cavity of shoulder
Glenoid labrum
Rim of fibrocartilage
Extends beyond bony rim and deepens socket of glenoid cavity
Acromion and coracoid process of scapula
Project laterally, superior to humerus
Help stabilize the joint

58. 9-6 Shoulder and Hip Joints
Acromioclavicular
ligament
Tendon of
supraspinatus
muscle
Articular
capsule
Subdeltoid
bursa
Synovial
membrane
Humerus
Coraco-acromial
Clavicle
Coracoclavicular
ligaments
Acromion
Coracoid
process
Scapula
Articular cartilages
Joint cavity
Glenoid labrum
Articular capsule
Anterior view, frontal section a
Shoulder ligaments
Acromioclavicular
Coracoclavicular
Coraco-acromial
Coracohumeral
Glenohumeral
Shoulder separation
Partial or complete dislocation of acromioclavicular joint

59. 9-6 Shoulder and Hip Joints
Muscles of rotator cuff
Supraspinatus
Infraspinatus
Teres minor
Subscapularis
Shoulder bursae
Subdeltoid
Subcoracoid
Subacromial
Subscapular
Subcoracoid bursa
Tendon of biceps
brachii muscle
Subacromial bursa
Muscles and
Tendons of the
Rotator Cuff
Tendon of
supraspinatus
muscle
infraspinatus
Teres minor
Subscapularis
Scapula
Lateral view of pectoral girdle
Ligaments
Stabilizing the
Shoulder Joint
Clavicle
Acromioclavicular
ligament
Coracoclavicular
ligaments
Coraco-acromial
Coracohumeral
ligament (cut)
Glenohumeral
Subscapular bursa
Glenoid cavity
Glenoid labrum
Articular capsule
Acromion b

60. 9-6 Shoulder and Hip Joints
Between head of femur and acetabulum of hip bone
Strong ball-and-socket diarthrosis
Wide range of motion
Acetabular labrum
Rim of fibrocartilage
Increases depth of joint cavity
Seals in synovial fluid

61. Figure 9–10a The Right Hip Joint.
Iliofemoral ligament
Articular cartilage
Acetabular labrum
Acetabulum
Ligament of the
femoral head
Transverse acetabular
ligament (spanning
acetabular notch)
Fat pad
in acetabular
fossa
A lateral view with the femur removed a

62. Ligaments of the hip joint Iliofemoral Pubofemoral Ischiofemoral
Transverse acetabular
Ligament of the femoral head
Pubofemoral
ligament
Greater
trochanter
Iliofemoral
Lesser
An anterior view b
Iliofemoral
ligament
Ischiofemoral
Greater
trochanter
Lesser
Ischial tuberosity
A posterior view, showing additional ligaments
that add strength to the capsule c

63. 9-7 Effects of Aging on Joints
Degenerative changes
Rheumatism
Pain and stiffness in musculoskeletal system
Arthritis (joint inflammation)
All rheumatic diseases that affect synovial joints
Osteoarthritis
Caused by wear and tear of joint surfaces, or genetic factors affecting collagen formation
Generally affects people over age 60

64. 9-7 Effects of Aging on Joints
Degenerative changes
Rheumatoid arthritis
An inflammatory condition
Immune system attacks joint tissues
Gouty arthritis
Crystals of uric acid form within synovial fluid

65. 9-7 Effects of Aging on Joints
Degenerative changes
Can be caused from joint immobilization
Reduces flow of synovial fluid
Can cause symptoms of arthritis
Treated by continuous passive motion (CPM)
As we age
Bone mass decreases
Bones weaken
Risk of fractures increases

66. 9-8 Integration with Other Systems
Living bones undergo remodeling that involves
Bone formation (osteoblasts)
And bone recycling (osteoclasts)
Factors affecting the balance between bone formation and recycling
Age
Physical stresses
Hormone levels
Calcium and phosphorus uptake and excretion
Genetic or environmental factors

67. 9-8 Integration with Other Systems
Other systems interact with the skeletal system
Muscles attach to bones
Bones are controlled by endocrine system
Digestive and urinary systems provide calcium and phosphate minerals to bones for growth
Skeleton serves as a reserve for calcium, phosphate, and other minerals