Chapter 8- Joints Flashcards

Question 1

Q

Joints (articulations)

Answer

A

the site where 2 bones meet

Question 2

Q

The shape of a joint determines

Answer

A

how much movement it allows

Question 3

Q

General functions of joints (2)

Answer

A

Mobility- allow movement of various body parts

2. Stability- hold the skeleton together

Question 4

Q

Joints allow small amounts of movement are

Answer

A

More stable. They are less likely to dislocate and damage internal organs

Question 5

Q

In general, how are joints classified?

Answer

A

By structure and function

Question 6

Q

What is the structural joint classification defined by?

Answer

A

The type of tissue that connects bones at the articulating surface

Question 7

Q

Structural joint classifications (3)

Answer

A

Fibrous
Cartilaginous
Synovial

Question 8

Q

Joint cavity

Answer

A

Only found in synovial joints. It is defined as a very small empty space between the bones that form the joint or around the joint itself. Contains synovial fluid

Question 9

Q

What is the functional joint classification defined by?

Answer

A

The amount of movement allowed by the joint

Question 10

Q

Functional joint classifications (3)

Answer

A

Synarthroses
Amphiarthroses
Diarthroses

Question 11

Q

The axial skeleton typically contains which functional joint categories?

Answer

A

Synarthroses and amphiarthroses are prevalent in the axial skeleton.
Synarthroses are held very tightly together. We don’t want most of the bones in the axial skeleton (ribs, etc.) to move around

Question 12

Q

The appendicular skeleton typically contains which functional joint categories?

Answer

A

Diarthroses are prevalent in the appendicular skeleton

We want the limbs to be able to move around and want the dexterity in fingers for certain tasks

Question 13

Q

Fibrous joints

Answer

A

Joints composed of collagen fibers of connective tissue, contain no joint cavity. Fibrous joints have short collagen fibers, prevents movement

Question 14

Q

Fibrous joints typically include which functional joint classifications?

Answer

A

Mostly synarthroses, some amphiarthroses

Question 15

Q

Types of fibrous joints (3)

Answer

A

Sutures
Syndesmoses
Gomphoses

Question 16

Q

Sutures

Answer

A

“Seams”- joints found only between the bones of the skull. Composed of bundles of extremely strong and short collagen fibers
The fibers are clumped/bundled together, making them strong and allowing VERY little movement

Question 17

Q

Fontanelles

Answer

A

Soft spots of a fetus or infant- this allows skull flexibility during birth. These areas are not ossified and the sutures of the skull are not completely formed. Large chunks of fibrous tissue separate the bone- fibrous tissue is strong and will not tear away easily

Question 18

Q

By what age will fontanelles be ossified?

Answer

A

18 months

Question 19

Q

Why are fontanelles important?

Answer

A

In fetuses, the brain grows very quickly- fontanelles allow the brain to grow without being locked in place
They also allow the infant’s head to squeeze through the pelvic bone without damage

Question 20

Q

Syntoses

Answer

A

What sutures form if they ossify- syntoses are not considered joints. Formation is normal, but it doesn’t happen to everyone and usually happens later in life

Question 21

Q

Syndemoses

Answer

A

Bones are connected to one another only by ligaments. Movement depends on the length of the ligaments. The longer the fiber, the more movement allowed.

Question 22

Q

Ligaments

Answer

A

bands of fibrous tissue that join bone to bone

Question 23

Q

How does the ligament between the distal portions of the tibia and fibula influence their movement?

Answer

A

The interosseous ligaments between the tibia and fibula in the lower leg allow them to move relative to each other but not that much- influences the amount of movement in the foot- we can kind of move the foot but can’t flip it all the way around. Short ligament= limited movement

Question 24

Q

How does the ligament between the radius and ulna influence their movement?

Answer

A

The ligament between the radius and ulna has longer fibers and therefore you can move the hand much more. The bones form an x when the hand is facing downward and are parallel when hand is facing up

Question 25

Q

Gomphoses

Answer

A

The only joint type that does not join bone to another bone- joins the teeth to the bony alveolar sockets. Fibers are very short, providing limited movement- don’t want the teeth moving too much or coming out

Question 26

Q

Periodontal ligament

Answer

A

joins the bone of the mandible/maxilla to the centrum of the tooth

Question 27

Q

How do braces work?

Answer

A

Braces force movement of the periodontal ligament/joint. The periodontal ligament does not want to move, which is why braces are painful.
Retainers are necessary so the periodontal ligament can’t force the teeth back to normal

Question 28

Q

Cartilaginous joints

Answer

A

bones joined by cartilage, no joint cavity

Question 29

Q

Cartilaginous joints typically include which functional joint classifications?

Answer

A

Synarthroses and amphiarthroses

Benefit- prevents excessive moment

Question 30

Q

Types of cartilaginous joints (2)

Answer

A

Synchondroses

2. Sympheses

Question 31

Q

Synchondroses

Answer

A

bones united with a plate of hyaline cartilage. Example- epiphyseal plate in long bones, costal cartilage

Question 32

Q

Which functional classification of joints are typically found in synchondroses?

Answer

A

synarthroses

Question 33

Q

Costal cartilage

Answer

A

Costal cartilage joins the ribs to the sternum- don’t want the ribs shifting too much. Found at the epiphyseal plate- joins two parts of the bone. This is the only temporary joint

Question 34

Q

Symphyses

Answer

A

Fibrocartilage joins bone, hyaline cartilage is still found on the bone surface
Some movement is allowed, but it’s limited
Excellent shock absorber- can withstand tension and return to original shape
Ex- intervertebral joints and pubic symphysis

Question 35

Q

Intervertebral joints

Answer

A

Intervertebral discs are good shock absorbers (body weight, walking, running, etc) and allows for flexibility to the vertebral column without damage- this can change with age

Question 36

Q

Intervertebral disc herniation

Answer

A

Discs can herniate- a part of the fibrocartilaginous joint pops out of the side of the vertebrae. Can press on a muscle (impairs function and causes some pain) or a nerve (very painful). This can occur with hard blow/trauma to the back, with weight lifting if the weight is way too heavy, or with bad posture for extended periods of time, sleeping in weird position for too long

Question 37

Q

Pubic symphysis function

Answer

A

Pubic symphysis doesn’t allow much movement- movement occurs slightly when you shift from one leg to the other

Question 38

Q

Synovial joints

Answer

A

Structurally more complex than cartilaginous or fibrous joints- most joints in the body fall under this classification
Almost all located in the appendicular skeleton, they contribute to the movements of our limbs

Question 39

Q

Which functional joint classification do synovial joints usually include?

Answer

A

Diarthroses- they allow for substantial amount of movement compared to fibrous/cartilaginous joints

Question 40

Q

Which 6 features are found in synovial joints?

Answer

A

Articular cartilage
Joint cavity
Articular capsule
Synovial fluid
Reinforcing ligaments
Nerves and blood vessels

Question 41

Q

Articular cartilage

Answer

A

Hyaline cartilage covering bone ends
Function- provides cushion to prevent bone damage when weight is placed on a joint-prevents the bone ends from directly rubbing together (very painful), stores synovial fluid

Question 42

Q

Articular capsule

Answer

A

two layered capsule that encloses the joint cavity- forms the walls of the joint cavity. This and the articular cartilage are 2 separate structures.
Contains 2 layers

Question 43

Q

2 layers of the articular capsule

Answer

A

Fibrous (outer) layer

2. Synovial membrane (inner)

Question 44

Q

Fibrous layer of the articular capsule

Answer

A

Outer layer that is continuous with the periosteum of bone (the diaphysis).
Function- strengthens and provides stability to joint, prevents excessive movement at the joint

Question 45

Q

Synovial membrane

Answer

A

Inner layer of the articular capsule. Lines any part of joint cavity except where hyaline cartilage is present
Function- produces and secretes synovial fluid

Question 46

Q

Synovial fluid

Answer

A

slippery fluid occupying space in joint capsule and articular cartilages. Location depends if the joint is being used (if you’re moving or not)

Question 47

Q

What happens to the synovial fluid when the joint is not active?

Answer

A

When the joint is not active, the fluid is viscous (like an uncooked egg white). The fluid is soaked into the articular cartilage (It is usually stored in articular cartilages).

Question 48

Q

What happens to the synovial fluid when the joint is active?

Answer

A

When the joint is active, fluid thins and becomes watery

Fluid is pressed out when the joint is compressed- the fluid is squeezed out into the joint cavity

Question 49

Q

What is the function of the synovial fluid?

Answer

A

Reduces friction between articular cartilages of articulating bones

Question 50

Q

Reinforcing ligaments

Answer

A

bandlike ligaments that join articulating bones. Named for location relative to the articular capsule. There are 3 types

Question 51

Q

Types of reinforcing ligaments (3)

Answer

A

Capsular ligaments
Extracapsular ligaments
Intracapsular ligaments

Question 52

Q

Capsular ligaments

Answer

A

Ligaments that are a part of the outer layer of a joint capsule

Question 53

Q

Extracapsular ligaments

Answer

A

Ligament found outside the joint capsule

Question 54

Q

Intracapsular ligaments

Answer

A

Ligament found deep to the joint capsule (but not in the joint capsule)

Question 55

Q

Function of the reinforcing ligaments

Answer

A

Reinforce joints to provide extra stability, as these joints tend to be less stable

Question 56

Q

How are the reinforcing ligaments different in “double jointed” individuals?

Answer

A

Longer and looser reinforcing ligaments- allows for more flexibility in the joint. This might not be a full body thing and only happen in a specific set of joints

Question 57

Q

Innervation of the joints

Answer

A

Joints supplied with sensory nerve fibers (position, stretch, and pain)
Function- prevents excessive movements that could damage joints, also allows the brain to monitor posture and body movement. This prevents you from falling and causing damage/pain.

Question 58

Q

Vascularization of the joints

Answer

A

There is a rich blood supply to joints.

Function- capillary beds in the synovial membrane provide raw material to build synovial fluid

Question 59

Q

Bursae

Answer

A

Flattened sacs that contain a small amount of synovial fluid, found where ligaments, muscles, skin, tendons, and/or bone would rub together. This structure may or may not be associated with a synovial joint.

Question 60

Q

Bursae function

Answer

A

Reduce friction between adjacent structures

Question 61

Q

Tendon sheath

Answer

A

Elongated bursa that wraps completely around a tendon subjected to frequent friction, found in “crowded” tendon areas (example- tendons in the wrist and ankle).
Some joints have both (indicates a complex joint), some have one, some don’t have any. This structure may or may not be found in synovial joints

Question 62

Q

Tendon sheath function

Answer

A

Prevents excessive friction for a particular tendon

Question 63

Q

Tendonitis

Answer

A

Damage to the tendon when the tendons rub against each other

Question 64

Q

Which factors influence joint stability? (3)

Answer

A

Articular surfaces
Ligaments
Muscle tone

Answer 65

A

The better 2 bones fit together, the more stable the joint in general.
For example, the coxal joint is more stable than the glenohumeral joint.

Answer 66

A

The acetabulum wraps almost completely around the head of the femur- very stable.
In contrast, the glenoid fossa is short and does not wrap around the head of the humerus. The head sits in the glenoid fossa like a golf ball sits on a tee- this is not very stable

Answer 67

A

Generally, the more ligaments that surround the joint, the stronger the joint. However, if ligaments are the only supportive structure, the joint will lose stability

Answer 68

A

The ligaments need something to back it up to be most effective, like a reinforcing structure, or they will be overstretched. Ligaments that are overstretched will not return to their normal shape.

Answer 69

A

Tendons attach muscle to bone and often wrap around/over joints. If the muscles are always slightly contracted, they pull slightly on tendons- this braces the joint

Answer 70

A

the shape of the epiphyses

Answer 71

A

Results in gliding motion, involves flat articular surfaces on both bones
Example- plane joint in intercarpal and intertarsal joints, vertebrae

Answer 72

A

Movement allowed in one axis only
Movement allowed- flexion, extension, rotation
Example- hinge joint between humerus and ulna and pivot joint between radius and ulna. Allows for rotation of the hand (you can supinate or pronate).

Answer 73

A

Decreases the angle of a joint and brings the articulating bones closer together

Answer 74

A

Increases the angle between the articulating bones, typically involves straightening a flexed trunk, elbow, etc.

Answer 75

A

The turning of a bone along its long axis. Common at the hip and is the only movement allowed between the first two cervical vertebrae. The movement can be directed toward the midline or away from it

Answer 76

A

The palm of the hand faces upward/forward, the radius and the ulna are parallel

Answer 77

A

The palm of the hand faces downward/backward, the radius rotates over the ulna

Answer 78

A

A joint with flat articular surfaces, an example are intercarpal joints and vertebral articular surfaces. Usually allows nonaxial movement

Answer 79

A

A joint where one articular surface is cylinder shaped and the other is trough shaped, such as the joint between the humerus and the ulna (the distal end of the humerus is cylindrical). Allows for uniaxial movement

Answer 80

A

Contains 2 axes of movement, usually at right angles to each other
Movement allowed- flexion and extension, abduction and adduction
Examples- condylar joint in knuckle, saddle joint at base of thumb

Answer 81

A

Moving a limb away from the midline along the frontal plane

Answer 82

A

Moving a limb toward the body midline along the frontal plane

Answer 83

A

A joint where the bones have oval articulating surfaces. Example- knuckle and wrist joints (metacarpals). Allows for biaxial movement

Answer 84

A

A joint where one articular surface is concave and the other is convex (curved outward). Example- carpometacarpal joints of the thumbs. Allows for biaxial movement.

Answer 85

A

Has multiple axes of movement. Movement allowed- flexion/extension, abduction/adduction, rotation
Example- ball and socket joints of shoulder and hip

Answer 86

A

Joint where one articular surface is cup shaped like a socket, and the other is spherical. Example- shoulder joints and hip joints. Allows for multiaxial movement

Answer 87

A

The mandible articulates to the temporal bone

Answer 88

A

Articular disc divides the synovial cavity into superior and inferior portions. This is why you can move your jaw up and down.
Both of these movements occur during chewing. This is an evolutionary advantage in eating solid foods if you can move your jaw in a circular type of motion
This joint is most easily dislocated

Answer 89

A

Superior- allows lateral excursion. Sits closer to the mandibular fossa. This is why you can move your jaw left and right
Inferior- allows elevation/depression.

Answer 90

A

Shoulder joint- where the humerus articulates to the glenoid fossa of the scapula.
This joint is the most frequently dislocated.
Type- ball and socket joint
Most freely moving joint in the body

Answer 91

A

Reinforcing ligaments are very thin and loose
Rotator cuff
Glenoid labrum

Answer 92

A

Includes the coracohumeral ligament and glenohumeral ligaments (3). They wrap around the joint to provide stability

Answer 93

A

4 muscles: subscapularis, infraspinatus, supraspinatus, and teres minor (and associated tendons) encircle the shoulder joint

Answer 94

A

Tearing these muscles and tendons will decrease joint stability. Fixing the rotator cuff or healing it is difficult, and when it heals it won’t be the same functionally

Answer 95

A

The rotator cuff is very easily damaged by excessive/extreme movements. For example, circumduction (like pitching in baseball) puts a lot of stress on these muscles.

Answer 96

A

Rim of fibrocartilage around glenoid fossa- provides some stability to the shoulder joint

Answer 97

A

The humerus articulates with the ulna

Answer 98

A

Stability is provided by close fit of the trochlea (on humerus) and trochlear notch (on ulna). This is again based on how the articular surfaces fit together.
2 ligaments
Muscle and tendon of arm muscles wrap around elbow to provide further stability

Answer 99

A

Articular capsule is thin and loose, which allows flexion/extension movement
Ulnar collateral ligament (medial) and radial collateral ligament (lateral) prevent side to side movement

Answer 100

A

Ulnar collateral ligament (medial) and radial collateral ligament (lateral)

Answer 101

A

The head of the femur articulates with the os coxa. This is a ball and socket joint

Answer 102

A

Shape- this is a ball and socket joint and has a deep socket. The acetabulum of the os coxa has acetabular labrum to further deepen the socket
The joint is reinforced by strong ligaments. The ligaments twist themselves completely around the joint

Answer 103

A

Iliofemoral ligament
Pubofemoral ligament
Ischiofemoral ligament

Answer 104

A

Ligament of the head of the femur. This is not found in the glenohumeral joint. Attaches to the head of the femur on the inside of the joint and extends to the inner surface of the acetabulum.

Answer 105

A

Function is unclear- probably serves as a coxal joint stabilizer for certain movement of the joint, like flexion or rotation. It also allows for blood and nerve supply to the head of the femur. People who damage this ligament tend to have severe arthritis at this joint- damage causes less synovial fluid and cartilage

Answer 106

A

Femoropatellar joint

2. Tibiofemoral joints- there are 2 of these, lateral and medial

Answer 107

A

The joint between the patella and femur- it’s a plane joint (intermediate to the other two joints)

Answer 108

A

Two joints between the femur and tibia (lateral and medial). It’s a hinge joint allows flexion/extension

Answer 109

A

The joint is only partially closed by joint capsule- anterior surface of the knee has no capsule, it is enclosed with ligaments

Answer 110

A

Menisci
Extracapsular and capsular ligaments
Intracapsular ligaments (cruciate ligaments)

Answer 111

A

C-shaped joint cartilage of the knee. They form ridges laterally and medially and help with absorbing shock.

Answer 112

A

Only attached to the tibia along the outer margins of the bone, the rest is unattached. Therefore, it can tear or rip away easily. This is a very common sports injury, especially with sudden or lateral movements. Usually needs surgery to fix it

Answer 113

A

Extracapsular and capsular ligaments prevent hyperextension of the knee. If you could freely hyperextend your knee, it would bend backwards.

Answer 114

A

Intracapsular ligaments of the knee joint. They secure articulating bones, prevent displacement. Named according to where they attach to the tibia.

Answer 115

A

Anterior cruciate ligament

2. Posterior cruciate ligament

Answer 116

A

Ligament that prevents forward sliding of tibia and prevents hyperextension. It attaches to the tibia on the anterior side.
The ACL is smaller and thinner and therefore tears more easily, so it’s more of a problem than the PCL.

Answer 117

A

This is also a very common sports injury caused by sudden changes in direction
Treatment- ranges from time and immobilization to never being able to play sports again

Answer 118

A

Ligament that prevents backward sliding of tibia and forward sliding of femur. It attaches to the tibia on the posterior side

Answer 119

A

Overusing your joints- excessive pressure and stress will cause damage. Often caused by people in a manual labor profession like construction workers
Not using your joints- the joints are not maintained, like people who work office jobs and sit all day
Using your joints the wrong way- trying to force a movement or doing something like weight lifting the wrong way

Answer 120

A

Joint cartilage (usually menisci) is overstretched, can snap and break.
Healing (if any) takes time. Thick cartilage will probably have too much damage and not be able to heal through diffusion (cartilage is avascular). The joint is less stable after injury

Answer 121

A

Compression (pushing together) and shear stress (rubbing against each other) occur simultaneously. This will rip cartilage if it occurs at the same time.

Answer 122

A

Pieces of broken cartilage from cartilage tears can interfere with joint function, called “locking”.

Answer 123

A

Ligaments reinforcing joint are damaged. There are 2 types: a partial/stretch tear and a completely torn ligament

Answer 124

A

A type of sprain where the ligament is capable of healing on its own. Similar to cartilage, this is a slow process

Answer 125

A

This is a type of sprain- more difficult to repair. Treatments:

Time/immobilization
Sew ends of the ligament together (basically like trying to sew spaghetti together- very difficult)
Grafting- taking a piece of tendon and using it to replace the torn ligament

Answer 126

A

Incomplete/partial dislocation of a joint

Answer 127

A

Occurs when the joint comes out of alignment. You can dislocate any synovial joint, but stable joints take more stress to dislocate

Answer 128

A

Less stable joints

Answer 129

A

The ligaments have been overstretched and will remain overstretched when the joint is put back in place- the joint will be less stable than before

Answer 130

A

Pathophysiology (degenerative or inflammatory)

2. Time of onset (acute or chronic)

Answer 131

A

The joint tissue is inflamed, swollen, and painful. Rheumatoid arthritis is an example

Answer 132

A

Losing joint tissue and not replacing it with anything. Eventually the bones are rubbing together- this is very painful. Osteoarthritis is an example.

Answer 133

A

Bacterial, inflammatory- easily treated with antibiotics

Answer 134

A

Inflammatory/degenerative, long lasting

Answer 135

A

Most common form of chronic arthritis- progresses slowly and is irreversible. More articular cartilage is destroyed than can be replaced by the body- exposed bone tissue rubs together, forming bone spurs. Poorly aligned and/or overused joints are most likely to exhibit OA

Answer 136

A

Bone spurs are permanent bone deformities.
Osteoarthritis deforms bone ends (excessive growth of bone in strange places) and restricts movement at joint because it gets in the way.
Bone spurs aren’t always necessarily a result of osteoarthritis, however.

Answer 137

A

Older individuals are more affected than other age groups, and more women are affected than men

Answer 138

A

Treatment- pain medication or complete joint replacement surgery. The ends of the epiphyses are cut off and covered with metal.

Answer 139

A

Strengthening a muscle around a joint will make it more stable

Answer 140

A

Autoimmune chronic inflammatory disorder (immune system is attacking your joints). Bilateral degenerative condition (occurs in the same joints on both sides). Individuals affected have flare ups followed by periods of remission (mostly symptom free). It never goes into a permanent period of remission, however, and flare ups will usually get worse over time.

Answer 141

A

Joints of fingers, wrist, ankles, feet most likely to be affected.

Answer 142

A

Pain and swelling felt in joints affected by RA

Answer 143

A

More women affected than men, typically diagnosed between ages 30-50

Answer 144

A

Synovial membrane becomes inflamed
Lymphocytes and macrophages flood area to destroy the cause of inflammation
Accumulation of synovial fluid and formation of a pannus

Answer 145

A

Release chemicals in such a large amount that it destroys healthy tissue
Macrophages also destroy some of the synovial membrane

Answer 146

A

a thickened portion of the synovial membrane as a result of rheumatoid arthritis- breaks down cartilage tissue over time

Answer 147

A

Occurs with rheumatoid arthritis- scar tissue forms where the hyaline cartilage tissue once was, fusing bones together

Answer 148

A

No cure, but can be treated with painkillers or steroids (immune system depressants)

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Chapter 8- Joints Flashcards

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