1. 8
Joints: Part A

2. Joints (Articulations)
Articulation—site where two or more bones meet
Functions of joints:
Give skeleton mobility
Hold skeleton together

3. Functional Classification of Joints
Based on amount of movement allowed by the joint
Three functional classifications:
Synarthroses—immovable
Amphiarthroses—slightly movable
Diarthroses—freely movable

4. Structural Classification of Joints
Based on material binding bones together and whether or not a joint cavity is present
Three structural classifications:
Fibrous
Cartilaginous
Synovial

5. Bones joined by dense fibrous connective tissue No joint cavity
Fibrous Joints
Bones joined by dense fibrous connective tissue
No joint cavity
Most are synarthrotic (immovable)
Three types:
Sutures
Syndesmoses
Gomphoses

6. Fibrous Joints: Sutures
Rigid, interlocking joints containing short connective tissue fibers
occur between bones of the skull to hold the bones together
Allow for growth during youth
In middle age, sutures ossify and are called synostoses

7. Joint held together with very short,
(a) Suture
Joint held together with very short,
interconnecting fibers, and bone edges
interlock. Found only in the skull.
Suture
line
Dense
fibrous
connective
tissue
Figure 8.1a

8. Fibrous Joints: Syndesmoses
Bones connected by ligaments (cords or bands of fibrous tissue)
Movement varies from immovable to slightly movable
Examples:
Synarthrotic distal tibiofibular joint
Diarthrotic interosseous connection between radius and ulna

9. (b) Syndesmosis Joint held together by a ligament.
Fibrous tissue can vary in length, but
is longer than in sutures.
Fibula
Tibia
Ligament
Figure 8.1b

10. Fibrous Joints: Gomphoses
Peg-in-socket joints of teeth in alveolar sockets
Fibrous connection is the periodontal ligament

11. (c) Gomphosis “Peg in socket” fibrous joint. Periodontal
ligament holds tooth in socket.
Socket of
alveolar
process
Root of
tooth
Periodontal
ligament
Figure 8.1c

12. Bones united by cartilage No joint cavity Two types:
Cartilaginous Joints
Bones united by cartilage
No joint cavity
Two types:
Synchondroses
Symphyses

13. Cartilaginous Joints: Synchondroses
A bar or plate of hyaline cartilage unites the bones
All are synarthrotic
Example: epiphyseal plate

14. Bones united by hyaline cartilage
(a) Synchondroses
Bones united by hyaline cartilage
Sternum
(manubrium)
Epiphyseal
plate (temporary
hyaline cartilage
joint)
Joint between
first rib and
sternum
(immovable)
Figure 8.2a

15. Cartilaginous Joints: Symphyses
Hyaline cartilage covers the articulating surfaces and is fused to an intervening pad of fibrocartilage
Strong, flexible amphiarthroses
Example: pubic symphysis

16. Bones united by fibrocartilage
(b) Symphyses
Bones united by fibrocartilage
Body of vertebra
Fibrocartilaginous
intervertebral
disc
Hyaline cartilage
Pubic symphysis
Figure 8.2b

17. Synovial Joints
All are diarthrotic
Include all limb joints; most joints of the body

18. Synovial Joints
Distinguishing features:
Articular cartilage covers ends of articulating bones (hyaline cartilage)
Joint (synovial) cavity: small potential space filled with synovial fluid

19. Distinguishing features: 3. Articular (joint) capsule:
Synovial Joints
Distinguishing features:
3. Articular (joint) capsule:
Encloses joint cavity
Outer fibrous capsule of dense irregular connective tissue
Inner synovial membrane of loose connective tissue

20. Distinguishing features: 4. Synovial fluid:
Synovial Joints
Distinguishing features:
4. Synovial fluid:
Viscous slippery filtrate of plasma + hyaluronic acid
Lubricates and nourishes articular cartilage
Fills all free space within the joint cavity

21. Ligament Joint cavity (contains synovial fluid) Articular (hyaline)
cartilage
Fibrous
capsule
Articular
capsule
Synovial
membrane
Periosteum
Figure 8.3

22. Distinguishing features:
Synovial Joints
Distinguishing features:
5. Three possible types of reinforcing ligaments to strengthen the joint:
Capsular (intrinsic)—part of the fibrous capsule
Extracapsular—outside the capsule
Intracapsular—deep to capsule; covered by synovial membrane

23. Distinguishing features: 6. Rich nerve and blood vessel supply:
Synovial Joints
Distinguishing features:
6. Rich nerve and blood vessel supply:
Nerve fibers detect pain, monitor joint position and stretch
Capillary beds produce filtrate for synovial fluid

24. Synovial Joints: Friction-Reducing Structures
Bursae:
Flattened, fibrous sacs lined with synovial membranes
Contain synovial fluid
Commonly act as “ball bearings” where ligaments, muscles, skin, tendons, or bones rub together
Reduce friction at synovial joints

25. Coracoacromial ligament Subacromial bursa Humerus resting Cavity in
bursa containing
synovial fluid
Bursa rolls
and lessens
friction.
Humerus head
rolls medially as
arm abducts.
Humerus
moving
(b) Enlargement of (a), showing how a bursa eliminates friction where a ligament (or other structure) would rub against a bone
Figure 8.4b

26. Synovial Joints: Friction-Reducing Structures
Tendon sheath:
Elongated bursa that wraps completely around a tendon
Reduces friction at synovial joints

27. (a) Frontal section through the right shoulder joint
Acromion
of scapula
Coracoacromial
ligament
Joint cavity
containing
synovial fluid
Subacromial
bursa
Fibrous
articular capsule
Hyaline
cartilage
Tendon
sheath
Synovial
membrane
Tendon of
long head
of biceps
brachii muscle
Fibrous
capsule
Humerus
(a) Frontal section through the right shoulder joint
Figure 8.4a

28. Stabilizing Factors at Synovial Joints
Shapes of articular surfaces (minor role)
Ligament number and location (limited role)
prevent excessive or unwanted movements and help to stabilize the joint
the greater the number of ligaments at the joint, the greater the stability
Muscle tone, which keeps tendons that cross the joint taut
Extremely important in reinforcing shoulder and knee joints and arches of the foot

29. Synovial Joints: Movement
Muscle attachments across a joint:
Origin—attachment to the immovable bone
Insertion—attachment to the movable bone
Muscle contraction causes the insertion to move toward the origin
Movements occur along transverse, frontal, or sagittal planes

30. Synovial Joints: Range of Motion
Nonaxial—slipping movements only
Uniaxial—movement in one plane
Biaxial—movement in two planes
Multiaxial—movement in or around all three planes

31. Summary of Characteristics of Body Joints
Consult Table 8.2 for:
Joint names
Articulating bones
Structural classification
Functional classification
Movements allowed

32. Table 8.2 (1 of 4)

33. Table 8.2 (2 of 4)

34. Table 8.2 (3 of 4)

35. Table 8.2 (4 of 4)

36. Movements at Synovial Joints
Gliding
Angular movements:
Flexion, extension, hyperextension
Abduction, adduction
Circumduction
Rotation
Medial and lateral rotation

37. Movements at Synovial Joints
4. Special movements
Supination, pronation
Dorsiflexion, plantar flexion of the foot
Inversion, eversion
Protraction, retraction
Elevation, depression
Opposition

38. One flat bone surface glides or slips over another similar surface
Gliding Movements
One flat bone surface glides or slips over another similar surface
Examples:
Intercarpal joints
Intertarsal joints
Between articular processes of vertebrae

39. (a) Gliding movements at the wrist
Figure 8.5a

40. Increase or decrease the angle between two bones.
Angular Movements
Increase or decrease the angle between two bones.
Movements that occur along the sagittal plane:
Flexion—decreases the angle of the joint; brings the articulating bones closer together
Extension— increases the angle of the joint
Hyperextension—excessive extension beyond normal range of motion

41. (b) Angular movements: flexion, extension, and
Hyperextension
Extension
Flexion
(b) Angular movements: flexion, extension, and
hyperextension of the neck
Figure 8.5b

42. Extension Hyperextension Flexion
(c) Angular movements: flexion, extension, and hyperextension of the vertebral column
Figure 8.5c

43. (d) Angular movements: flexion and extension at the shoulder and knee
Figure 8.5d

44. Angular Movements
Movements that occur along the frontal plane:
Abduction—movement (limb or fingers) away from the midline (of body or hand)
Adduction—movement (limb or fingers) toward the midline (body or hand) ADD TO BODY
Circumduction—flexion + abduction + extension + adduction of a limb so as to describe a cone in space or air

45. Abduction Circumduction Adduction
(e) Angular movements: abduction, adduction, and circumduction of the upper limb at the shoulder
Figure 8.5e

46. The turning of a bone around its own long axis Examples:
Rotation
The turning of a bone around its own long axis
Examples:
Between C1 and C2 vertebrae
Rotation of humerus and femur

47. (f) Rotation of the head, neck, and lower limb
Lateral
rotation
Medial
rotation
(f) Rotation of the head, neck, and lower limb
Figure 8.5f

48. Movements of radius around ulna:
Special Movements
Movements of radius around ulna:
Supination (turning hand backward)- rotating the forearm laterally so that the palm faces anteriorly or superiorly
Pronation (turning hand forward)- rotating the arm medially so that the palm faces posteriorly or inferiorly

49. (a) Pronation (P) and supination (S)
(radius
rotates
over ulna)
Supination
(radius and
ulna are
parallel)
(a) Pronation (P) and supination (S)
Figure 8.6a

50. Special Movements Movements of the foot:
Dorsiflexion (upward movement)- decreases the angle between the top of the foot (dorsal surface) and the anterior surface of the tibia
Plantar flexion (downward movement) -decreases the angle between the sole of the foot (plantar surface) and the posterior side of the tibia

51. (b) Dorsiflexion and plantar flexion
Figure 8.6b

52. Special Movements Movements of the foot:
Inversion (turn sole medially)
Eversion (turn sole laterally)

53. (c) Inversion and eversion
Figure 8.6c

54. Movements in a transverse plane:
Special Movements
Movements in a transverse plane:
Protraction (anterior movement)- moves the mandible anteriorly, juts the jaw forward
Retraction (posterior movement)- returns the mandible to its original position

55. (d) Protraction and retraction
of mandible
Retraction
of mandible
(d) Protraction and retraction
Figure 8.6d

56. Special Movements
Elevation (lifting a body part superiorly)
Depression (moving a body part inferiorly)

57. (e) Elevation and depression
of mandible
Depression
of mandible
(e) Elevation and depression
Figure 8.6e

58. Opposition of the thumb
Special Movements
Opposition of the thumb
Movement in the saddle joint so that the thumb touches the tips of the other fingers on the same hand

59. Classification of Synovial Joints
Six types, based on shape of articular surfaces:
Plane
Hinge
Pivot
Condyloid
Saddle
Ball and socket

60. Plane Joints
Nonaxial joints
Flat articular surfaces
Short gliding & transitional movements

61. Plane joint (intercarpal joint)f
Nonaxial
Uniaxial
Biaxial
Multiaxial c b a
Plane joint (intercarpal joint) a e d
Figure 8.7a

62. Hinge Joints
Uniaxial joints
Motion along a single plane
Flexion and extension only
consist of a cylindrical projection that nests in a trough-shaped structure

63. Hinge joint (elbow joint)f
Nonaxial
Uniaxial
Biaxial
Multiaxial c b b
Hinge joint (elbow joint) a e d
Figure 8.7b

64. Pivot Joints
Rounded end of one bone conforms to a “sleeve,” or ring of another bone
Uniaxial movement (around the long axis) only

65. Pivot joint (proximal radioulnar joint)f
Nonaxial
Uniaxial
Biaxial
Multiaxial c b c
Pivot joint (proximal radioulnar joint) a e d
Figure 8.7c

66. Condyloid (Ellipsoidal) Joints
Biaxial joints
Both articular surfaces are oval
Permit all angular movements
consist of an oval articular surface that nests in a complementary depression

67. (metacarpophalangeal joint)f
Nonaxial
Uniaxial
Biaxial
Multiaxial c b d
Condyloid joint
(metacarpophalangeal joint) a e d
Figure 8.7d

68. Saddle Joints
Biaxial
Allow greater freedom of movement than condyloid joints
Each articular surface has both concave and convex areas

69. Saddle joint (carpometacarpal joint of thumb)
Nonaxial
Uniaxial
Biaxial
Multiaxial c b e
Saddle joint (carpometacarpal joint
of thumb) a e d
Figure 8.7e

70. Ball-and-Socket Joints
Multiaxial joints
The most freely moving synovial joints
consist of a spherical or hemispherical structure that articulates with a cuplike structure

71. Ball-and-socket joint (shoulder joint)f
Nonaxial
Uniaxial
Biaxial
Multiaxial c b f
Ball-and-socket joint (shoulder joint) a e d
Figure 8.7f

72. Knee Joint Largest, most complex joint of body
Three joints surrounded by a single joint cavity:
Femoropatellar joint:
Plane joint
Allows gliding motion during knee flexion
Lateral and medial tibiofemoral joints between the femoral condyles and the C-shaped lateral and medial menisci (semilunar cartilages) of the tibia
Allow flexion, extension, and some rotation when knee is partly flexed
PLAY
A&P Flix™: Movement at the knee joint

73. (a) Sagittal section through the right knee joint
Tendon of
quadriceps
femoris
Femur
Suprapatellar
bursa
Articular
capsule
Patella
Posterior
cruciate
ligament
Subcutaneous
prepatellar bursa
Synovial cavity
Lateral
meniscus
Lateral meniscus
Infrapatellar
fat pad
Anterior
cruciate
ligament
Deep infrapatellar
bursa
Tibia
Patellar ligament
(a) Sagittal section through the right knee joint
Figure 8.8a

74. (b) Superior view of the right tibia in the knee joint, showing
Anterior
Anterior
cruciate
ligament
Articular
cartilage on
lateral tibial
condyle
Articular
cartilage
on medial
tibial
condyle
Lateral
meniscus
Medial
meniscus
Posterior
cruciate
ligament
(b) Superior view of the right tibia in the knee joint, showing
the menisci and cruciate ligaments
Figure 8.8b

75. Knee Joint At least 12 associated bursae
Capsule is reinforced by muscle tendons:
E.g., quadriceps and semimembranosus tendons
Joint capsule is thin and absent anteriorly
Anteriorly, the quadriceps tendon gives rise to:
Lateral and medial patellar retinacula
Patellar ligament

76. (c) Anterior view of right knee
Quadriceps
femoris muscle
Tendon of
quadriceps
femoris muscle
Patella
Medial patellar
retinaculum
Lateral patellar
retinaculum
Tibial collateral
ligament
Fibular
collateral
ligament
Patellar ligament
Fibula
Tibia
(c) Anterior view of right knee
Figure 8.8c

77. Capsular and extracapsular ligaments
Knee Joint
Many different types of ligaments stabilize and strengthen the capsule of the knee joint
Capsular and extracapsular ligaments
Help prevent hyperextension
Intracapsular ligaments:
Anterior and posterior cruciate ligaments
Prevent anterior-posterior displacement
Reside outside the synovial cavity

78. (d) Posterior view of the joint capsule, including ligaments
Femur
Tendon of
adductor magnus
Articular capsule
Oblique popliteal
ligament
Medial head of
gastrocnemius
muscle
Lateral head of
gastrocnemius
muscle
Popliteus
muscle (cut)
Bursa
Fibular collateral
ligament
Tibial collateral
ligament
Arcuate popliteal
ligament
Tendon of
semimembranosus
muscle
Tibia
(d) Posterior view of the joint capsule, including ligaments
Figure 8.8d

79. Posterior cruciate ligament Fibular collateral ligament Medial condyle
Tibial collateral
ligament
Lateral condyle
of femur
Anterior cruciate
ligament
Lateral
meniscus
Medial meniscus
Tibia
Patellar ligament
Fibula
Patella
Quadriceps tendon
(e) Anterior view of flexed knee, showing the cruciate ligaments (articular capsule removed, and quadriceps tendon cut and reflected distally)
PLAY
Animation: Rotatable knee
Figure 8.8e

80. Lateral Medial Patella (outline) Hockey puck Tibial collateral
ligament
(torn)
Medial
meniscus (torn)
Anterior
cruciate
ligament (torn)
Figure 8.9

81. Shoulder (Glenohumeral) Joint
Ball-and-socket joint: head of humerus and glenoid fossa of the scapula
Stability is sacrificed for greater freedom of movement

82. Animation: Rotatable shoulder
Acromion
of scapula
Coracoacromial
ligament
Synovial cavity
of the glenoid
cavity containing
synovial fluid
Subacromial
bursa
Fibrous
articular capsule
Hyaline
cartilage
Tendon
sheath
Synovial membrane
Fibrous capsule
Tendon of
long head
of biceps
brachii muscle
Humerus
(a) Frontal section through right shoulder joint
PLAY
Animation: Rotatable shoulder
Figure 8.10a

83. Reinforcing ligaments:
Shoulder Joint
Reinforcing ligaments:
Coracohumeral ligament—helps support the weight of the upper limb
Three glenohumeral ligaments—somewhat weak anterior reinforcements

84. Shoulder joint Reinforcing muscle tendons:
Tendon of the long head of biceps:
Travels through the intertubercular groove
Secures the humerus to the glenoid cavity
Four rotator cuff tendons encircle the shoulder joint:
Subscapularis
Supraspinatus
Infraspinatus
Teres minor
PLAY
A&P Flix™: Rotator cuff muscles: An overview (a)
PLAY
A&P Flix™: Rotator cuff muscles: An overview (b)

85. (c) Anterior view of right shoulder joint capsule
Acromion
Coracoid
process
Coracoacromial
ligament
Articular
capsule
reinforced by
glenohumeral
ligaments
Subacromial
bursa
Coracohumeral
ligament
Subscapular
bursa
Greater
tubercle
of humerus
Tendon of the
subscapularis
muscle
Transverse
humeral
ligament
Scapula
Tendon sheath
Tendon of long
head of biceps
brachii muscle
(c) Anterior view of right shoulder joint capsule
Figure 8.10c

86. of biceps brachii muscle
Acromion
Coracoid process
Articular capsule
Glenoid cavity
Glenoid labrum
Tendon of long head
of biceps brachii muscle
Glenohumeral ligaments
Tendon of the
subscapularis muscle
Scapula
Posterior
Anterior
(d) Lateral view of socket of right shoulder joint, humerus removed
Figure 8.10d

87. Radius and ulna articulate with the humerus
Elbow Joint
Radius and ulna articulate with the humerus
Hinge joint formed mainly by trochlear notch of ulna and trochlea of humerus
Flexion and extension only
PLAY
A&P Flix™: Movement at the elbow joint

88. (a) Median sagittal section through right elbow (lateral view)
Articular
capsule
Synovial
membrane
Humerus
Synovial cavity
Articular cartilage
Fat pad
Coronoid process
Tendon of
triceps
muscle
Tendon of
brachialis muscle
Ulna
Bursa
Trochlea
Articular cartilage
of the trochlear
notch
(a) Median sagittal section through right elbow (lateral view)
Figure 8.11a

89. Anular ligament—surrounds head of radius
Elbow Joint
Tendons of several arm muscles, the biceps and the triceps, also provide additional stability by crossing the elbow joint.
Anular ligament—surrounds head of radius
Two capsular ligaments restrict side-to-side movement:
Ulnar collateral ligament
Radial collateral ligament

90. (b) Lateral view of right elbow joint
Humerus
Anular
ligament
Radius
Lateral
epicondyle
Articular
capsule
Radial
collateral
ligament
Olecranon
process
Ulna
(b) Lateral view of right elbow joint
Figure 8.11b

91. Animation: Rotatable elbow
Articular
capsule
Anular
ligament
Humerus
Coronoid
process
Medial
epicondyle
Ulnar
collateral
ligament
Radius
Ulna
(d) Medial view of right elbow
PLAY
Animation: Rotatable elbow
Figure 8.11d

92. Ball-and-socket joint
Hip (Coxal) Joint
Ball-and-socket joint
Head of the femur articulates with the acetabulum
Good range of motion, but limited by the deep socket
Acetabular labrum—enhances depth of socket
PLAY
A&P Flix™: Movement at the hip joint: An overview

93. (a) Frontal section through the right hip joint
Coxal (hip) bone
Articular cartilage
Ligament of
the head of
the femur
(ligamentum
teres)
Acetabular
labrum
Femur
Synovial cavity
Articular capsule
(a) Frontal section through the right hip joint
Figure 8.12a

94. Reinforcing ligaments:
Hip Joint
Reinforcing ligaments:
Iliofemoral ligament
Pubofemoral ligament
Ischiofemoral ligament
Ligamentum teres

95. Iliofemoral ligament Ischium Ischiofemoral ligament Greater trochanter
of femur
(c) Posterior view of right hip joint, capsule in place
PLAY
Animation: Rotatable hip
Figure 8.12c

96. Iliofemoral Anterior inferior ligament iliac spine Pubofemoral
Greater
trochanter
(d) Anterior view of right hip joint, capsule in place
Figure 8.12d

97. Temporomandibular Joint (TMJ)
Mandibular condyle articulates with the temporal bone
Two types of movement
Hinge—depression and elevation of mandible
Gliding—e.g. side-to-side (lateral excursion) grinding of teeth
Most easily dislocated joint in the body
contains an articular disc that divides the synovial cavity into compartments that support each type of movement
lateral aspect of the fibrous capsule contains a lateral ligament that reinforces the joint

98. (a) Location of the joint in the skull
Mandibular fossa
Articular tubercle
Zygomatic process
Infratemporal fossa
External
acoustic
meatus
Lateral
ligament
Articular
capsule
Ramus of
mandible
(a) Location of the joint in the skull
Figure 8.13a

99. (b) Enlargement of a sagittal section through the joint
Articular disc
Articular
tubercle
Mandibular
fossa
Superior
joint
cavity
Articular
capsule
Synovial
membranes
Mandibular
condyle
Ramus of
mandible
Inferior joint
cavity
(b) Enlargement of a sagittal section through the joint
Figure 8.13b

100. Lateral excursion: lateral (side-to-side) movements of the mandible
Superior view
Outline of
the mandibular
fossa
Lateral excursion: lateral (side-to-side) movements of the
mandible
Figure 8.13c

101. Common Joint Injuries Sprains Cartilage tears
The ligaments are stretched or torn
Partial tears slowly repair themselves
Complete ruptures require prompt surgical repair
Cartilage tears
Due to compression and shear stress (meniscus)
Fragments may cause joint to lock or bind
Cartilage rarely repairs itself
Repaired with arthroscopic surgery
Often at the knee

102. Torn
meniscus
Figure 8.14

103. Dislocations (luxations)
Common Joint Injuries
Dislocations (luxations)
Occur when bones are forced out of alignment
Accompanied by sprains, inflammation, and joint immobilization
Caused by serious falls or playing sports
Subluxation—partial dislocation of a joint

104. Inflammatory and Degenerative Conditions
Bursitis
An inflammation of a bursa, usually caused by a blow or friction
Treated with rest and ice and, if severe, anti-inflammatory drugs
Tendonitis
Inflammation of tendon sheaths typically caused by overuse
Symptoms and treatment similar to bursitis

105. Arthritis
>100 different types of inflammatory or degenerative diseases that damage joints
Most widespread crippling disease in the U.S.
Symptoms; pain, stiffness, and swelling of a joint
Acute forms: caused by bacteria, treated with antibiotics
Chronic forms: osteoarthritis, rheumatoid arthritis, and gouty arthritis

106. Osteoarthritis (OA)
Common, irreversible, degenerative (“wear-and-tear”) arthritis
85% of all Americans develop OA, more women than men
Probably related to the normal aging process

107. Osteoarthritis (OA)
More cartilage is destroyed than replaced in badly aligned or overworked joints
Exposed bone ends thicken, enlarge, form bone spurs, and restrict movement
Treatment: moderate activity, mild pain relievers, capsaicin creams, glucosamine and chondroitin sulfate

108. Rheumatoid Arthritis (RA)
Chronic, inflammatory, autoimmune disease of unknown cause
Usually arises between age 40 and 50, but may occur at any age; affects 3 times as many women as men
Signs and symptoms include joint pain and swelling (usually bilateral), anemia, osteoporosis, muscle weakness, and cardiovascular problems

109. Rheumatoid Arthritis
RA begins with synovitis of the affected joint
Inflammatory blood cells migrate to the joint, release inflammatory chemicals
Inflamed synovial membrane thickens into a pannus
Pannus erodes cartilage, scar tissue forms, articulating bone ends connect (ankylosis)

110. Figure 8.15

111. Rheumatoid Arthritis: Treatment
Conservative therapy: aspirin, long-term use of antibiotics, and physical therapy
Progressive treatment: anti-inflammatory drugs or immunosuppressants
New biological response modifier drugs neutralize inflammatory chemicals

112. Gouty Arthritis
Deposition of uric acid crystals in joints and soft tissues, followed by inflammation
More common in men
Typically affects the joint at the base of the great toe
In untreated gouty arthritis, the bone ends fuse and immobilize the joint
Treatment: drugs, plenty of water, avoidance of alcohol

113. Lyme Disease
Caused by spirochete bacteria transmitted by the bites of ticks (usually living on deer or mice)
Symptoms: skin rash, flu-like symptoms, and foggy thinking
May lead to joint pain and arthritis
Treatment: antibiotics

114. Developmental Aspects of Joints
By embryonic week 8, synovial joints resemble adult joints
A joint’s size, shape, and flexibility are modified by use
Advancing years take their toll on joints:
Ligaments and tendons shorten and weaken
Intervertebral discs become more likely to herniate
Most people in their 70s have some degree of OA
Exercise that coaxes joints through their full range of motion is key to postponing joint problems