Final exam condensed

Question 1

Simple epithelium

Answer 1

One layer, found in areas like the alveoli that need thin tissue for diffusion

Question 2

Stratified epithelium

Answer 2

2+ layers, found in areas like the esophagus that need thick tissue to resist mechanical or chemical stress

Question 3

Where is the body is epithelial tissue found?

Answer 3

Covers/lines organs and body cavities (outer layer of skin, urogenital, digestive, and respiratory systems). Also glandular epithelium that makes up the glands of the body

Question 4

Basement membrane

Answer 4

The epithelial tissue is attached to the basement membrane, which is made up of fibers rather than cells. This allows nutrients to diffuse to the epithelial tissue, which is avascular.

Question 5

Connective tissue characteristics (3)

Answer 5

1. Cells
2. Ground substance
3. Fibers
   The ground substance and fibers make up the matrix

Question 6

Covering epithelium is joined by

Answer 6

Tight junctions and desmosomes

Question 7

Basement membrane layers (2)

Answer 7

1. Basal lamina- secreted by the epithelium itself
2. Reticular lamina- contains fibers that belong to connective tissue. Bottom layer of the basement membrane, sits closest to connective tissue

Question 8

Epithelial tissue is the only tissue type that has apical basal polarity. Why is this important?

Answer 8

One free (apical) surface is necessary, as the epithelium covers the body and lines body cavities

Question 9

Pseudostratified columnar epithelium

Answer 9

“False” stratified cell nuclei lie at different levels- the nuclei are displaced so it looks like there are multiple layers of cells. Only some cells stretch from the apical surface to the basal surface. “Short” cells give rise to “tall” cells (the cells are different sizes). Shorter cells attach to the basement membrane. Located in respiratory tract, male ducts, and ducts of large glands. Responsible for secretion and absorption.

Question 10

Under a microscope, you see that many cells of an exocrine gland are in metaphase. Is this a merocrine or a holocrine gland?

Answer 10

Holocrine. Holocrine glands release products as a result of cell rupture. Sebaceous glands are an example

Question 11

Merocrine glands

Answer 11

Product secreted from the acinus via exocytosis, cell remains unchanged. Example- sweat or salivary glands

Question 12

Apocrine glands

Answer 12

Similar to holocrine, but do not truly rupture. The cells have a small tear in the membrane so the secretion can leave, and the membrane quickly reassembles. Mammary glands could be an example

Question 13

Functions of connective tissue (5)

Answer 13

1. Binding and supporting
2. Protecting
3. Insulating
4. Storing reserve fuel
5. Transporting substances within the body

Question 14

What types of fibers can be found in connective tissue (3)?

Answer 14

1. Collagen- resist pulling forces
2. Elastic- high density in areas of the body that are subjected to frequent stretching- skin, lungs
3. Reticular- high density in areas of the body where connective tissue attaches to another tissue

Question 15

What type of connective tissue is capable of acting as a fluid reservoir?

Answer 15

Areolar tissue can act as a fluid reservoir because of its web-like nature.

Question 16

What type of connective tissue is damaged when you lacerate a tendon?

Answer 16

Dense regular connective tissue

Question 17

When aging cartilage tends to ossify, its cells die. What survival needs are not being met in those cells?

Answer 17

Oxygen and nutrient needs are not being met. The calcified cartilage matrix is too hard to allow for these substances to reach the cell by diffusion.

Question 18

What type of membrane consists of epithelial and connective tissue, and lines body cavities open to the exterior?

Answer 18

Mucous membranes fit this criteria. It lines any body cavity that leads out of the body and is a wet/moist membrane. Function- absorption/secretion.

Question 19

What type of membrane lines the thoracic walls and covers the lungs?

Answer 19

The serous membranes (pleurae) line the body cavity and cover the lungs.

Question 20

What is the difference between the serous and mucus membranes, and the plasma membrane and basement membrane?

Answer 20

Plasma membranes surround cells and are made of phospholipids. The basement membrane is a layer of extracellular material that lies just outside the basal surface of epithelial cells. Serous and mucous membranes are considered organs because they are composed of multiple types of tissues.

Question 21

The serous membranes are held together by serous fluid, which is mainly water. What property of water makes them stick together?

Answer 21

Water’s high surface tension due to its hydrogen bonds

Question 22

What are the 3 main steps of tissue repair?

Answer 22

1. Inflammation
2. Organization
3. Permanent repair via regeneration and fibrosis

Question 23

Why does a deep injury to the skin result in abundant scar tissue?

Answer 23

More severe injuries damage and destroy more tissue, requiring greater replacement with scar tissue.

Question 24

One patient has brain damage from a stroke, one had a heart attack, and one has a damaged liver (a gland) due to a car accident. Which one will regain full function of the damaged organ through tissue regeneration?

Answer 24

The liver is a gland derived from epithelial tissue. Epithelial tissue regenerates well, but nervous tissue in the brain and cardiac muscle exhibit virtually no functional regeneration.

Question 25

Types of covering and lining membranes (3)

Answer 25

These are considered simple organs.

1. Cutaneous (skin)- composed of keratinized stratified squamous epithelia
2. Mucous
3. Serous- line closed body cavities

Question 26

Types of cartilage (3)

Answer 26

1. Hyaline- found in trachea, nose, ends of joints
2. Elastic- very flexible
3. Fibrocartilage- found in areas of the body that need a lot of support/bear a lot of weight

Question 27

Types of connective tissue

Answer 27

1. Connective tissue proper (areolar, adipose, dense regular)
2. Cartilage
3. Osseous tissue
4. Blood

Question 28

Marfan Syndrome

Answer 28

A genetic disorder that affects the body’s connective tissue. Results from a mutation in the FBN1 gene, which codes the production of fibrillin. This protein contributes to strength and elasticity. Connective tissue loses strength/elasticity. Connective tissue is located throughout the body, so symptoms are widespread- bones, blood vessels, eyes, respiratory system

Question 29

Simple gland

Answer 29

Unbranched duct- one straight tube into secretory unit

Question 30

Functions of the skin (6)

Answer 30

1. Protection (chemical, physical, biological)
2. Temperature regulation
3. Sensation- cutaneous receptors
4. Metabolic functions (vitamin D absorption and production)
5. Reservoir for blood
6. Excretory- sweat eliminates waste

Question 31

Tactile and lamellar corpuscles

Answer 31

Responsible for touch sensations

Question 32

Hypodermis functions (4)

Answer 32

1. Storage- easy to access energy source for the body
2. Protection/shock absorption- prevents physical trauma to internal organs
3. Insulation- prevents excessive heat loss
4. Anchor- holds skin to underlying skeletal muscle tissue- is still flexible

Question 33

Cellular portion of epidermis (4)

Answer 33

1. Keratinocytes- produce keratin (fibrous protein, very tough). Give the epidermis its dry and tough quality.
2. Melanocytes
3. Dendritic cells
4. Tactile cells (Merkel cells)

Question 34

Keratinocytes are linked by

Answer 34

Linked by desmosomes (with some tight junctions). Tight junctions are important to prevent releasing water to the environment

Question 35

Where are melanocytes located?

Answer 35

The stratum basale

Question 36

Dendritic cells (Langerhans cells)

Answer 36

Move to epidermis from bone marrow. Active macrophages- this activates the immune system

Question 37

Tactile cells (Merkel cells)

Answer 37

Present in epidermal-dermal junction. Associated with nerve endings- sensory receptor function (2 types of touch)- light touch
and vibration

Question 38

5 layers of the epidermis

Answer 38

1. Stratum corneum- dead keratinocytes
2. Stratum lucidum- dead cells, relatively transparent, not found in thin skin
3. Stratum granulosum- keratinization begins here, has lamellar granules to make the skin waterproof
4. Stratum spinosum- contains pre-keratin- thick bundles of filaments that resist tension. Dendritic cells are most abundant here (immune system).
5. Stratum basale- single layer of stem cells attached to dermis
   All reproduction in the epidermis comes from this layer- melanocytes and keratinocytes are found here.

Question 39

Papillary dermis

Answer 39

More superficial layer, made of thin areolar connective tissue. Fibers are thin- defensive cells wander freely here. Has projections called dermal papillae. Can have either pain receptors or tactile corpuscles
Increase the surface area of the dermis so the epidermis can be better attached to the dermis. Also, the amount of nutrients and oxygen passed on to the epidermis will increase. Attaches to the epidermis, pulling it in- indents overlying epidermis forms friction ridges (fingerprints)

Question 40

Reticular dermis

Answer 40

Deep layer, made of dense irregular connective tissue. Forms cleavage lines in the skin. Not visible externally, lines are formed by alternating dense and less dense regions of fibers. This is very important for surgeons. The direction of the cleavage line determines the type of incision. Also forms flexure lines at joints to make the skin more flexible.

Question 41

3 factors that determine skin color

Answer 41

1. Melanin- reddish yellow and brownish black pigment, synthesized by tyrosinase enzyme
2. Carotene- yellow orange pigment that can be used for vitamin A synthesis. Accumulates in stratum corneum and adipose tissue
3. Hemoglobin- pink/red pigment found in blood cells- influences skin color in fair skinned individuals

Question 42

Hair functions (2)

Answer 42

1. Sensory structures: nerves associated with hair follicle
2. Protection- scalp (from the sun), eyes (from dirt/debris), nose (hairs trap dirt and debris and prevent it from entering the lungs)

Question 43

3 layers of hair

Answer 43

1. Medulla- central core composed of large cells and air space. Absent in fine hairs of the body (vellus hairs)
2. Cortex- several layers of flattened cells- less air space, cells are tightly packed together
3. Cuticle- outermost layer that is most heavily keratinized, cells stacked like roof shingles. Separates individual hairs to prevent mats

Question 44

3 layers of the hair follicle

Answer 44

1. Peripheral sheath- most external layer composed of dermis. Like a follicle wall.
2. Glassy membrane- “basement membrane” joining the peripheral sheath to the root sheath
3. Root sheath- most internal layer derived from epidermis. Surrounds and protects the growing hair so cells can be added.

Question 45

Root hair plexus

Answer 45

found at base of hair (hair bulb). Contains nerve endings, detects when the hair bends/moves

Question 46

Dermal papilla

Answer 46

Provides capillaries to the hair follicle. Need to have blood supply to grow hair

Question 47

Shape of hair depends on

Answer 47

Hair follicle: round= straight hair, oval= wavy/slightly curly, flattened= very curly

Question 48

Hair matrix

Answer 48

Composed of rapidly dividing cells from hair bulb- new cells push old cells up and out to become the hair shaft- hair growth. Most growth is cyclical. When hair is in the dormant stage it won’t actually grow/cells won’t divide. The hair could also shed. Not all follicles are in the same stage at the same time

Question 49

Telogen effluvium

Answer 49

Hair loss for no apparent reason- maybe poor diet or chronic stress

Question 50

Alopecia universalis

Answer 50

Complete loss of hair on the scalp and the rest of the body. Can take shots that help to stimulate the follicles

Question 51

Nail root

Answer 51

Underneath the skin, can’t be seen externally, covered by nail matrix- cells divide rapidly

Question 52

Nail plate

Answer 52

Part that can be seen externally

Question 53

Free edge of nail

Answer 53

Most terminal portion of the nail not attached to the skin

Question 54

What part of the nail is responsible for nail growth?

Answer 54

Nail matrix responsible for nail growth- cells are very heavily keratinized, push outward during growth

Question 55

Eccrine sweat glands

Answer 55

Especially abundant on palms, soles of feet, forehead. Sweat is mostly water and used for body temperature regulation

Question 56

Apocrine sweat glands

Answer 56

Located in axillary and anogenital areas, function after puberty. Same components as sweat from eccrine, plus fatty substances and proteins. Function is unclear- could be pheromones as they only function after puberty

Question 57

Sebaceous glands

Answer 57

Secretes sebum (oily substance). Sebum is largely lipid based with cell components. Release to skin is dependent on arrector pili. Empty into hair follicle, released to skin

Question 58

Sebum functions (3)

Answer 58

1. Lubricant for skin/hair
2. Slows water loss from epidermal surface
3. Kills bacteria

Question 59

Basal cell carcinoma is a cancer of the

Answer 59

Stratum basale

Question 60

Squamous cell carcinoma is a cancer of the

Answer 60

Stratum spinosum

Question 61

Types of burns

Answer 61

1. 1st degree- painful, reddened skin, inflammation. No scarring involved in healing
2. 2nd degree- pain, redness, fluid filled pouches (blisters). Takes longer to heal than 1st degree burns, no scarring
3. 3rd degree- full thickness burns. Treatment usually requires IV fluids, skin grafts, and heavy antibiotic use. When epidermis and dermis are burned away, so are the free nerve endings that sense pain. Most often die from dehydration (constant water loss if you have no skin in most of the body).

Question 62

Functions of the skeletal system (6)

Answer 62

1. Support- holds up the body and cradles organs
2. Protection- central nervous system, some visceral organs by ribs
3. Attachment point- skeletal muscle attaches to bone via tendons
4. Storage- minerals and fat (yellow marrow in the bones of adults)
5. Hematopoiesis- formation of blood cells in red bone marrow
6. Hormone production- osteocalcin- regulates insulin release, glucose homeostasis, and energy expenditure

Question 63

Cartilage is surrounded externally by

Answer 63

Perichondrium (tissue sheet). Contains blood vessels. Resists outward expansion of cartilage- prevents it from being too compressed

Question 64

2 basic components of cartilage

Answer 64

1. Chondrocytes

2. Extracellular matrix- has fibers, more viscous

Question 65

Types of cartilage (3)

Answer 65

1. Hyaline- articular cartilage (forming joints), costal cartilage, respiratory cartilage, nasal cartilage
2. Elastic- contains more elastic fibers- external ear, epiglottis (like a trap door closing over the trachea when you swallow).
3. Fibrocartilage- compressible, great tensile strength- can support a lot of weight without damage. Vertebral discs, knee, pubic symphysis

Question 66

What type of cartilage is most plentiful in the adult body?

Answer 66

Hyaline cartilage is the most plentiful in the human body. This is found in articular cartilage (forming joints), costal cartilage, respiratory cartilage, and nasal cartilage.

Question 67

What two body structures contain flexible elastic cartilage?

Answer 67

The epiglottis and external ear cartilages are flexible elastic cartilages

Question 68

Cartilage grows by interstitial growth. What does this mean?

Answer 68

Interstitial growth is growth from within and is associated with a growth in length. Occurs throughout tissue- cells divide and secrete matrix in pre-existing cartilage

Question 69

Appositional growth (cartilage)

Answer 69

Laying down new cartilage on old cartilage, associated with a growth in width. Occurs at surface- cells in perichondrium deposit new matrix on top of preexisting cartilage.

Question 70

What is the functional relationship between skeletal muscles and bones?

Answer 70

Skeletal muscles use bones as levers to move the body

Question 71

List two types of substances stored in bone and state where each is stored.

Answer 71

The bone matrix stores minerals (calcium and phosphate). This is what gives bone its hardness and makes it slow to degrade/break down. Bone marrow cavities store fat in adults

Question 72

What are the components of the axial skeleton?

Answer 72

Skull, vertebral column, and rib cage

Question 73

Contrast the general function of the axial skeleton to that of the appendicular skeleton.

Answer 73

The function of the axial skeleton is to establish the long axis of the body and to protect structures that is encloses. The function of the appendicular skeleton is to move the body to allow us to interact with the environment.

Question 74

What bone class do the ribs and skull bones fall into?

Answer 74

The ribs and skull bones are flat bones. Long bones are most limb bones (bones that are longer than they are wide), short bones are the carpals and tarsals, irregular bones are the vertebrae and os coxa.

Question 75

Diaphysis

Answer 75

Bone shaft. Makes up most of the length of the long bone and is the cylinder portion. Composed of compact bone “collar” with internal medullary cavity. Helps with bearing weight loads. The medullary cavity is filled with yellow marrow in adults

Question 76

Epiphysis

Answer 76

Bone ends covered with hyaline cartilage. Irregularly shaped because these are the locations of articulation (joint formation). Composed of compact bone externally, spongy bone internally

Question 77

Periosteum

Answer 77

Membrane that covers the bone surface, except at joints. Double layered- outermost layer is fibrous (tougher, helps protect bone, prevents periosteum from tearing when bone bends), inner layer composed of osteoprogenitor cells (these are stem cells- undifferentiated). Very well vascularized and innervated. If a bone is broken badly enough that it breaks the periosteum, the tear will contribute to the pain and bleeding experienced.

Question 78

Endosteum

Answer 78

Covers internal bone surfaces- trabeculae in spongy bone, canals in compact bone. Also contains osteoprogenitor cells- bone growth must occur on the inside of bone to balance out the growth occurring on the outside

Question 79

What would happen to a bone if you removed all of the inorganic components? Would it be able to resist compression or tension?

Answer 79

This would remove the mineral salts that make the bone rigid, so it would not be able to resist tension. However, its organic portion, like collagen, would still be present to help it resist tension.

Question 80

Which cell has a ruffled border and acts to break down bone matrix? Which organelle would be the likely source of enzymes that can digest bone matrix?

Answer 80

The osteoclast, and the lysosome would contain the matrix digesting enzymes.

Question 81

Organic components of bone

Answer 81

Cells and osteoid. Osteoid is the unmineralized matrix that forms hard bone tissue. There are multiple types of cells responsible for maintaining bone tissue. Sacrificial bonds in or between collagen molecules stretch and break easily when pressure is put on bone without damaging the bone- makes the bone more flexible

Question 82

Types of bone cells (5)

Answer 82

1. Osteoprogenitor
2. Osteoblasts
3. Osteocytes
4. Bone lining cells
5. Osteoclasts

Question 83

Osteoprogenitor (osteogenic) cells

Answer 83

Stem cells- mitotically active cells (constantly reproducing). Can remain as osteogenic cells or differentiate to form osteoblasts

Question 84

Osteoblasts

Answer 84

Immature bone forming cells (responsible for bone growth). Secrete unmineralized matrix (osteoid) that forms hard bone tissue. Activity of cell depends on shape (cube shaped cells secrete matrix, flattened cells are inactive). Once surrounded by matrix, osteoblasts will mature to form an osteocyte.

Question 85

Osteocytes

Answer 85

Mature bone cell that monitors and maintains the bone matrix. Respond to mechanical stress and calcium levels. Often have several slender projections- extend through the matrix and make immediate contact with neighboring bone cells (osteoblasts/osteoclasts). This allows these cells to communicate. If the osteocyte is monitoring and decides the matrix is too thin, it will send a message to the osteoblast to stimulate it to create more matrix and vice versa.

Question 86

Bone lining cells

Answer 86

Maintain a matrix at the bone surface. These cells have a very specific location, unlike the osteocyte.

Question 87

Osteoclasts

Answer 87

Has a ruffled edge of the cell that contacts bone directly. Maintains, repairs, and remodels bones- breaks down old tissue- don’t want the bone to be too dense. Bone will also need to be remodeled after going through stress so it can continue to withstand stress. Important function in blood calcium homeostasis- osteoclasts will be stimulated to break down bone and get calcium

Question 88

Inorganic components of bone

Answer 88

Mineral salts- mostly calcium phosphate packed around collagen fibers. This is what gives bone its hardness and makes it slow to degrade/break down. This is why the bones are the last to break down after death.

Question 89

Bones don’t begin with bone tissue. What do they begin with?

Answer 89

Bones begin as fibrous membranes or hyaline cartilage. Hyaline cartilage is used as a “blueprint” to form ossified bone in bones below the skull. In the skull and clavicles, bone formation begins from a fibrous membrane

Question 90

When describing endochondral ossification, some say “bone chases cartilage”. What does that mean?

Answer 90

The cartilage model grows, then breaks down and is replaced by bone.

Question 91

Where is the primary ossification center located in a long bone? Where are the secondary ossification centers located?

Answer 91

The primary ossification center in a long bone is located in the center of the shaft (diaphysis). The secondary ossification centers are in the epiphyses (bone ends). Secondary ossification begins in adolescence- steps are similar to primary ossification, but the spongy bone is retained in bone ends. No medullary cavity is formed.

Question 92

As a long bone grows in length, what is happening in the hypertrophic zone of the epiphyseal plate?

Answer 92

The chondrocytes are enlarging and their lacunae are breaking down and leaving holes in the cartilage matrix.

Question 93

Intramembranous ossification steps (4)

Answer 93

1. Mesenchymal cells differentiate into osteoblasts- form a primary ossification center (clump of osteoblasts)
2. Matrix is secreted by the osteoblasts, then calcified
3. Formation of periosteum and immature spongy bone
4. Compact bone replaces some spongy bone, red marrow develops

Question 94

Bone growth zones (4)

Answer 94

Bone growth is accomplished by interstitial growth, occurs at the epiphyseal plate.

1. Proliferation
2. Hypertrophic
3. Calcification
4. Ossification

Question 95

Endochondral ossification steps (5)

Answer 95

1. Formation of a bone collar (week 9 in embryonic development)
2. Cavity formation in diaphysis center
3. Formation of spongy bone (month 3)
4. Formation of medullary (marrow) cavity, elongation of diaphysis
5. Secondary ossification begins in epiphyses (childhood to adolescence)

Question 96

Which stimulus is more important in maintaining homeostatic blood calcium levels- PTH or mechanical forces?

Answer 96

Parathyroid hormone maintains blood calcium levels

Question 97

How do bone growth and remodeling differ?

Answer 97

Bone growth increases bone mass, like during childhood or when a lot of stress is placed on the bone. Bone remodeling follows bone growth to maintain the proper proportions of the bone considering the stresses placed on it.

Question 98

Despite daily exercise, the bones of astronauts in the International Space Station get thinner and weaker during their time in space. Why does this occur?

Answer 98

The bones get thinner and weaker because they are deprived of the normal loading forces placed on the bones by gravity. Exercise can help to some extent but is not a substitute for gravity.

Question 99

What are 3 measures that may help to maintain healthy bone density?

Answer 99

Sufficient vitamin D, calcium, and weight bearing exercise

Question 100

What name is given to “adult rickets”?

Answer 100

Osteomalacia. Osteomalacia only occurs in adults- calcium salts are not deposited to the tissue, so the bone bends really easily and pushes on the nerves, causing pain. This can be reversed with normal calcium intake.

Question 101

Rickets

Answer 101

Rickets only occurs in children but tends to be more severe as children are still growing. Can result in permanent bone deformities and cause skull deformities (dents), misshapen pelvis due to weight of the body and visceral organs, rib cage can be deformed (problematic, it’s very important for breathing). Caused by insufficient calcium in diet, low vitamin D. Mineral salts are deposited in bone in much lesser amounts- bone is weak/soft

Question 102

Osteon

Answer 102

Structural unit of compact bone. A single osteon is composed of several layers (lamella) packed closely together- the walls of one lamella with be in contact with the other in a concentric manner. Fibers always run in opposite direction to adjacent lamella. Function- helps the bone to withstand pressure and stress. Allows the bone to bend/twist without breaking.

Question 103

Canals

Answer 103

Run through the center of each osteon (haversion canal). Central (haversion) canal contains nerves and blood vessels (artery and vein). Perforating canals connect nerve/blood supply of marrow cavity to central canal. Allows the marrow cavity to be supplied with blood and nervous fibers.

Question 104

Interstitial lamellae

Answer 104

Incomplete lamellae found in between complete osteons. Fill gaps between osteons- osteons are circular and there are no corners, so there will be spaces in between- you don’t want air pockets in bone

Question 105

Circumferential lamellae

Answer 105

Found just deep to periosteum, complete layer. Extend completely around the circumference of diaphysis (outermost lamellae of compact bone). Resists twisting of long bone, bundle the osteons together

Question 106

Growth hormone

Answer 106

Controls (increases) activity at the epiphyseal plate- cartilage cells divide faster or divide more, increasing bone length. Hypersecretion results in gigantism, hyposecretion results in dwarfism.

Question 107

What 3 factors control bone deposition and resorption?

Answer 107

1. Parathyroid hormone (PTH) released in response to decreasing Ca+ blood levels
2. Calcitonin decreases blood calcium levels
3. Mechanical stress- bones are strongest where they are subject to high pressure (Wolff’s Law), or where they are most likely to break

Question 108

How are joint mobility and stability related?

Answer 108

The more stable a joint is, the less mobile it is

Question 109

Functional categories of joints (3)

Answer 109

1. Synarthroses- not movable
2. Amphiarthroses- slightly movable
3. Diarthroses- freely movable

Question 110

Structural categories (3)

Answer 110

1. Fibrous- joints composed of collagen fibers of connective tissue
2. Cartilaginous- bones joined by cartilage
3. Synovial- contain a synovial cavity

Question 111

Types of fibrous joints (3)

Answer 111

1. Gomphoses- joins teeth to the bony alveolar sockets
2. Syndesmoses- bones are connected to each other only by ligaments
3. Sutures- found only between bones of the skull

Question 112

Types of cartilaginous joints (2)

Answer 112

1. Symphyses- fibrocartilage joins bone- pubic symphysis

2. Synchondroses- bones united with a plate of hyaline cartilage- costal cartilage

Question 113

Evan is 25 years old. Would you expect to find synchondroses at the ends of his femur?

Answer 113

No. By age 25, his epiphyseal plates have fused and become syntoses.

Question 114

Nick bent over to pick up a dime. What movement was occurring at his hip joint, at his knees, and between his index finger and thumb?

Answer 114

Nick’s hip joint was flexed, his knees were extended, and his thumb was in opposition to his index finger

Question 115

Structures associated with synovial joints (6)

Answer 115

1. Articular cartilage- hyaline cartilage covering bone ends
2. Joint cavity- extremely small space between articulating bones
3. Articular capsule- two layered capsule that encloses the joint cavity- forms the walls of the joint cavity.
4. Synovial fluid- stored in articular cartilages when the joint isn’t active
5. Reinforcing ligaments- bandlike ligaments that join articulating bones.
6. Innervation (sensory nerve fibers) and rich vascularization

Question 116

Bursae

Answer 116

Flattened sacs that contain a small amount of synovial fluid. Found where ligaments, muscles, skin, tendons, and/or bone would rub together. Function- reduce friction between adjacent structures

Question 117

Tendon sheath

Answer 117

Elongated bursa that wraps completely around a tendon subjected to frequent friction. Found in “crowded” tendon areas (example- tendons in the wrist and ankle). Functions- prevents excessive friction for a particular tendon

Question 118

Factors that influence joint stability (3)

Answer 118

1. Articular surfaces- the better 2 bones fit together, the more stable the joint in general
2. Ligaments- generally, the more ligaments that surround the joint, the stronger the joint (unless ligaments are the only supportive structure
3. Muscle tone- if the muscles are always slightly contracted, they pull slightly on tendons. This braces the joint

Question 119

Temporomandibular joint

Answer 119

Modified hinge joint. Articular disc divides the synovial cavity into superior and inferior portions. 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. This is why you can move your jaw up and down. Both of these movements occur during chewing.

Question 120

Glenohumeral joint

Answer 120

Ball and socket joint. Features:

1. Reinforcing ligaments are very thin and loose. Coracohumeral ligament and glenohumeral ligaments (3)- wrap around joint to provide stability
2. Rotator cuff- muscles and tendons encircle the joint- easily torn by excessive movements, like circumduction
3. Glenoid labrum- rim of fibrocartilage around glenoid fossa- provides some stability

Question 121

Elbow joint

Answer 121

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

Question 122

Coxal joint

Answer 122

Ball and socket joint. Reinforced by a deep socket and strong ligaments. Acetabulum of os coxa has acetabular labrum to further deepen the socket. Ligamentum teres- ligament of the head of the femur. This is not found in the glenohumeral joint. Serves as a joint stabilizer and provides blood and nerve supply to the head of the femur

Question 123

Knee joint

Answer 123

Single joint cavity shared by 3 separate joints- femoropatellar and 2 tibiofemoral joints. Anterior surface of the knee has no it is capsule, is enclosed with ligaments. Important structures are the menisci and ligaments.

Question 124

Menisci

Answer 124

Forms ridges laterally and medially. Help with absorbing shock.
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

Question 125

Intracapsular ligaments (cruciate ligaments) of the knee

Answer 125

Secure articulating bones, prevent displacement. Anterior cruciate ligament (ACL) prevents forward sliding of tibia, prevents hyperextension. This is also a very common sports injury caused by sudden changes in direction. The ACL is smaller and thinner and therefore tears more easily, so it’s more of a problem than the PCL. Posterior cruciate ligament (PCL) prevents backward sliding of tibia and forward sliding of femur.

Question 126

Cartilage tears

Answer 126

Joint cartilage (usually menisci) is overstretched, can snap and break. Compression (pushing together) and shear stress (rubbing against each other) occur simultaneously. This will rip cartilage if it occurs at the same time. Healing (if any) takes time. Thick cartilage will probably have too much damage and not be able to heal through diffusion (cartilage is avascular). Joint is less stable after injury.

Question 127

Sprains

Answer 127

Ligaments reinforcing joint are damaged. Completely torn ligament- more difficult to repair. Treatments: time/immobilization, sew ends of the ligament together (basically like trying to sew spaghetti together- very difficult), or grafting- taking a piece of tendon and using it to replace the torn ligament.

Question 128

Why are dislocated joints more likely to dislocate in the future?

Answer 128

This is because the ligaments have been overstretched and will remain overstretched when the joint is put back in place.

Question 129

Osteoarthritis

Answer 129

Most common form of chronic arthritis- progresses slowly and is irreversible. Poorly aligned and/or overused joints are most likely to exhibit OA- more articular cartilage is destroyed than can be replaced by the body. Exposed bone tissue rubs together, and can form bone spurs- deforms bone ends (excessive growth of bone in strange places), restricts movement at joint because it gets in the way.

Question 130

Rheumatoid arthritis

Answer 130

Autoimmune chronic inflammatory disorder (immune system is attacking your joints). More women affected than men, typically diagnosed between ages 30-50. Bilateral degenerative condition (occurs in the same joints on both sides)- joints of fingers, wrist, ankles, feet most likely to be affected. 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.

Question 131

What can rheumatoid arthritis result in over time?

Answer 131

Accumulation of synovial fluid and formation of a pannus- a pannus is a thickened portion of the synovial membrane- breaks down cartilage tissue over time. Ankylosis can occur- scar tissue forms where the hyaline cartilage tissue once was, fusing bones together