Bone and Cartilage

Question 1

Endochondral ossification make up the bonesof ?

Answer 1

• axial skeleton
• appendicular skeleton
• base of skull

Question 2

Process of bone formation in endochondral ossification?

Answer 2

• Cartilaginous model of bone is first made by chondrocytes
• Osteoclasts and osteoblasts later replace this with woven bone—>
• then remodel to lamellar bone

Question 3

Membranous ossification make up which bones?

Answer 3

Calvarium and facial bones (skull).

Question 4

Process of bone formation in membranous ossification?

Answer 4

• Woven bone is formed directly without cartilage.
• Later is remodeled to lamellar bone

Question 5

• Osteoblasts function?
• Osteoblasts differentiate from?

Answer 5

• Builds bone by secreting collagen and catalyzing mineralization in alkaline environment via ALP
• Differentiates from mesenchymal stem cells in periosteum

Question 6

• Osteoclasts function?
• Osteoclasts differentiate from?

Answer 6

• Dissolves bone by secreting H+ and collagenases
• Differentiate from a fusion of monocyte/macrophage precursors

Question 7

Organic matrix is important to strength of bone. What is matrix made up of?

Answer 7

• Over 90% collagen fibers
• ground substance
  
  • mainly proteoglycans, chrondroitin sulfate and hyaluronic acid

Question 8

Bone composition is 30%__ and 70%__?

Answer 8

• 30% matrix
  
  • cells maintain and produce matrix
  • extracellular component of bone
    
    • 35% osteoid (organic)
    • 65% mineral (inorganic)- hydroxyapatite
• 70% salts

Question 9

What is the major component of bone salts?

Answer 9

• Hydroxyapatite (form of calcium phosphate)
• inorganic
• important in deposition of Ca

Question 10

• Collagen in bong is along lines of?
• Important for?

Answer 10

• Along lines of tensional force
• Important to tensile strength
• Has high compression strength so bone resists both tension and compression

Question 11

• Extracellular matrix forms most of what kind of tissue
• What is important to density and deformability of matrix?

Answer 11

• Forms bulk of connective tissue
• Hydration is important!

Question 12

What are the functions of ECM?

Answer 12

• Provides structure and support
  
  • (holds cells and tissues together)
• Limit movement and migration
• barrier to microorganisms and large molecules

Question 13

• What is the most abundant type of protein in the body, especially which form?
• Found in?

Answer 13

• Collagen 1
• found in:
  
  • loose connective tissue,
  • bone
  • tendons,
  • skin
  • blood vessels

Question 14

Structure of collagen? What does it need to stabilize it?

Answer 14

• Triple helix with repetitive nature
• needs vitamin C to stabilize

Question 15

• Lack of Vitamin C means less stability of __?
• Symptoms of Scurvy?

Answer 15

• Less stability of collagen and tissues where it is important
• Skin less stable, blood vessels easily injured, gums less stable so teeth are loose

Question 16

• Collagen IV makes a __ rather than fibrils.
• Important in which structures?

Answer 16

• Makes a mesh
• important in basement membranes and basal lamina

Question 17

• Glycosaminoglycans (GAG) are repeating __ units with?
• Which glycosaminoglycan is the backbone of the matrix?

Answer 17

• Repeating disaccharide units
• Hyaluronic acid (just disaccharide units)
  
  • bind HA to proteoglycans
  • Negative charges bind positive ions,
  • H+ bonds to water to form hydrated gel
  • matrix is flexible and acts a filter

Question 18

How is cartilage able to be compressed and deformable/regain shape after pressure is released?

Answer 18

• High number of negative charges attract cations,
• create high osmotic pressure water drawn in,
• tension balances at swelling equilibrium

Question 19

Function of fibronectin in the matrix?

Answer 19

• Proteoglycans bind to fibronectin (besides HA)
• Fibronectin binds to integrins in cell membranes
  
  • collagen fibrils cells attached to all matrix components

Question 20

How is bone matrix degraded?

Answer 20

• Components (GAG) enter cells by endocytosis and fuse with lysosomes
• lysosomal hydrolase break these down into sugars and amino acids
  
  • lack of any enzyme will prevent degradation and accumulation of partially degraded material in lysosome

Question 21

• Stem cells in bone respond to ___ from osteoblasts?
• These precursors then become osteoclasts that respond to__ and __?

Answer 21

• M-CSF from osteoblasts
• precursors become osteoclasts
  
  • responding to IL-6 and RANKL;
  • important in osteoclast regulation and bone remodeling/resorption

Question 22

• Osteoclasts are regulated by __ and __?
• What do osteoclasts release against bone surface?

Answer 22

• Cytokine receptors (stimulate resorption)
• Calcitonin (inhibit resorption)

Release H+ ions, phosphotases (TRAP) and lysosomal enzymes

Question 23

• Integrins are?
• What type of signals to they transmit?

Answer 23

• Transmembrane proteins (alpha-beta dimers)
• connect to matrix and cytoskeleton
• Pass physical signals across cell membrane

Question 24

Role of matrix maetalloproteinasees (MMPs) in degradation of ECM proteins?

Answer 24

• MMP degrade all ECM proteins (locally)
  
  • Important for migration and remodeling

Question 25

Regulation of MMPs in degredatin of ECM proteins?

Answer 25

• Synthesized with propeptide that must be cleaved to activate
• TIMP (Tissue Inhibitors of Malloproteinases)

Question 26

On which cells in the bone are the RANK receptor and ligand located?

Answer 26

• RANK ligand on osteoblast/stromal cell
• RANK receptor on osteoclast precursor
  
  • Need RANK and M-CSF (always floating around) to differentiate into osteoclast

Question 27

What binds to the RANK ligand on osteoblast/stromal cells and inhibits it’s interaction with RANK receptor on osteoclast precursor cells?

Answer 27

• Osteoprotein (OPG) prevents differentiation into osteoclast
  
  • acts as a decoy for RANKL

Question 28

What are other ECM proteins that are not important in bone but are important in skin and other tissue?

Answer 28

• Laminin
  
  • Binds collagen to ECM molecules and cell integrins to provide stability
• Elastin
  
  • allows blood vessels to deform, lungs to expand and contract without energy

Question 29

Where is elastin found?

Answer 29

Abundant elastic fibers found in:

• smooth muscle endothelium near chondrocytes and fibroblast

Question 30

• Chrondroblasts form from which cells?
• Where are they abundant?

Answer 30

• Form from mesenchymal cells
• Abundant in the perichondrium

Question 31

• Chondrocyte is defined when?
• What do chondrocytes secrete?
• Abundant in?

Answer 31

• Defined when chondroblasts are surrounded by the “matrix” they produce
  
  • Sit in lacunae
• Secrete Type II collagen and extracellular matrix
• Abudant lipids, glycogen and RER

Question 32

Extracellular matrix (“ground substance”) consits of?

Answer 32

• Hyaluronic acid
• glycosaminoglycans
  
  • chondroitin sulfate
  • keratin sulfate

It is extremely hydrated

Question 33

• Pericellular matrix has the highest concentration of?
• What type of collagen surrounds each chondrocyte?

Answer 33

• highest [] of sulfated proteoglycans, hyaluronic acid and glycoproteins
• Type VI collagen surrounds each chondrocyte

Question 34

What does territorial matrix consist of?

Answer 34

Type II collagen and proteoglycans

Question 35

• What parts of the body is comprised of hyaline cartilage?
• What does it serve as?

Answer 35

• Nasal, laryngeal, costal and tracheal cartilage
• Articular cartilage
• Fetal skeleton

Serves as shock abosorber

Question 36

What is hyaline cartilage composed of?

Answer 36

• Cells (chondrocytes and chondroblasts)
• Type II collagen fibers (mostly)
• Extracellular matrix
  
  • hyaluronic acid, proteoglycans and water

Question 37

Chondrogenesis:

• Appositional growth?
• Interstitial growth?

Answer 37

• Appositional growth:
  
  • new cartilage formed from inner surface of perichondrium
• Intersitial growth:
  
  • new cartilage formed from within cartilage

Question 38

• Where is fibrocartilage found?
• Characterized by?

Answer 38

• Found in:
  
  • intervertebral disk
  • menisci of knees
  • TMJ
  • sternoclavicular joints
  • pubic symphis
• Characterized by great tensil strength

Question 39

Fibrocartilage is comprised of?

Answer 39

• Chondrocytes and firbroblasts
• Type I and Type II collagen
  
  • less water and proteoglycans than hyaline cartilage

Question 40

Annulus fibrosis and Nucleus pulposus (intervertebral disk) are made of?

Answer 40

• Annulus fibrosis
  
  • fibrocartilage
• Nucleus pulposes
  
  • Physaliphorous cells and extracellular matrix of ground substance (squishy)

Question 41

• Where is elastic cartilage found?
• Abundant in?
• Characteristics?

Answer 41

• In external ear, epiglottis and auditory tube
• Abudant type II collagen and elastic fibers in ECM
• Elastic and pliable

Question 42

What makes articular cartilage different from general hyaline cartilage?

Answer 42

• No perichondrium (contacts bone directly)
• Obliquely oriented collage matrix in transition zone
• Longitudinally oriented collage fibrils in the deep zone

Question 43

T/F:

• Cartilage repairs easily

Answer 43

• False!
  
  • cartilage is not very capable of repair
  • avascular

Question 44

• What does perichondrium have that relates to repair?
• When damage is repaired what happens to hyaline cartilage?

Answer 44

• Perichondrium has pluripotent stem cells
  
  • but type II collage is very stable
• When damage is repaired, hyaline cartilage is converted to mixture of hyaline and fibrous cartilage
  
  • mix of type I and II cartilage
• Damaged cartilage may even be converted to bone (normal with aging)

Question 45

Lamellar bone

Answer 45

Mature bone with lamellae (overlapping folds)

Question 46

Woven bone?

• Common in?

Answer 46

Developing or immature bone

• Fetus or fracture

Question 47

• Compact bone is defined by?
• Where is it found?

Answer 47

• Defined by osteons (Haversion system)
• Solid bone found in outer protions of shaft of long bones

Question 48

• Spongy/Cancellous bone found toward?
• Lamellated but no?

Answer 48

• Bony spicules and trabeculae found toward the marrow space and in the metaphyses
• Lamellated but NO Haversion system

Question 49

Bone matrix is composed of:

• Organic
• Inorganic

What is in each?

Answer 49

Organic:

• Type I collagen, proteoglycans, chondroitin sulfate, keratin sulfate, hyaluronic acid
• Multiadhesive glycoproteins

Inorganic

• Hydroxyapatite (caclium phosphate)

Question 50

Long bone is composed of:

• Periosteum: inner and outer layer
• Sharpey’s Fibers
• Lamallae

Answer 50

• Periosteum
  
  • _Outer laye_r: collagen fibers and blood vessels
  • I_nner laye_r: osteoprogenitor cells and osteoblasts
• Sharpey’s fibers:
  
  • collagen fibers to the outer circumferential lamellae
• Lamallae

Question 51

• In corticol (compact) bone which way do each run? What are they surrounded by?
  
  • Haversian canals
  • Volkmann canals

Answer 51

• Haversion canals run longitudinal
  
  • ​surrounded by concentric lamellae
• Volkmann canal runs transverse
  
  • transversely connect to Haversion system and to the periosteum

Question 52

• In compact bone where is Endosteum vs. Periosteum?
• What does it contain?

Answer 52

• Osteoprogenitor cells
• osteoblasts
• reticular fibers

Question 53

Where do osteocytes sit?

Answer 53

In lacunae (trapped osteoblasts)

Question 54

Osteoid contain?

Answer 54

Type I collagen and proteoglycans

Question 55

Osteoblasts contain abundant RER to produce?

Answer 55

• Osteocalcin
  
  • mediates bone mineralization via Ca2+ binding
• Osteonectin
  
  • brindges collages and minerals (hydroxyapetite)
• Alkaline phosphotase
• Osteoid
  
  • ​secrete Type 1 collagen
• pyrophosphatase

Question 56

Where are osteoclasts multinucleated?

Answer 56

merging of monocytes and macrophage progenitor cells in BM

Question 57

What do osteoclasts secrete?

Answer 57

• Acid
  
  • degrade minerals in bone
• Lysosomal proteins
  
  • degrade collagen and non collagen proteins
• Metalloproteinases (MMP)
  
  • degrade collagen and non collagen

Question 58

Osteoclasts are regulated by?

Answer 58

• PTH:
  
  • stimulates RANKL on surface of osteoblasts
  • RANKL interacts with receptors on surface of osteoclasts and encourage bone resorption

Question 59

Role of pyrophosphate and alkaline phosphate in bone?

Answer 59

• Pyrophosphate:
  
  • controls (inhibits) mineralization
• Alkaline phosphotase:
  
  • neutralizes pyrophosphate

Question 60

• Intramembranous ossification is important for the development of which bones?
• What does bone arise from?

Answer 60

• Development of frontal, parietal, occipital and temporal bone (skull) as well as mandible and maxilla
• Bone arises from primitive mesenchymal connective tissue (NOT from cartilage)
  
  • mesenchymal cells give rise to osteoblast
  • bone formed within a “blastemal” lined by osteoblasts

Question 61

Endochondral ossification is important for the development of which bones?

Answer 61

• Extremities
• Vertebral column
• Pelvis

Question 62

• MOA of Endochondral ossification?
• Primary vs. Secondary ossification center?

Answer 62

• Chondroblasts lay down Type II collagen initially but then Type X cartilage
• Primary ossification center:
  
  • form a periosteal collar of bone after apoptosis and calcification of matrix at the diaphysis
• Secondary ossification center
  
  • forms at the epiphysis

Vascularization helps promote entrance of osteoprogenitor and hematopoietic cells

Question 63

In bone what is happening in:

• zone of reserved cartilage
• zone of proliferation

Answer 63

• Zone of proliferation:
  
  • reserve of chondrocytes
• Zone of proliferation:
  
  • continuous cell division
  • chondrocytes align as vertical and parallel columns

Question 64

In bone, what is happening in:

• zone of hypertrophy
• zone of calcified cartilage
• zone of resorption

Answer 64

• zone of hypertrophy
  
  • chondrocytes swell up with collagen
  • are hypertrophic chondrocytes because of glycogen
    
    • secrete more Type X collagen as well as VEGF
• Zone of Calcified Cartilage:
  
  • _​_Chondrocytes become calcified
    
    • promote apoptosis because diffusion of nutrients to cell is diminished
• Zone of resorption:
  
  • _​_proliferation of osteogenic cells and vascular invasion

Question 65

• Mechanism of fracture repair and bone healing?

Answer 65

• Begins with deposition of highly vascular collagenous granulation tisssue
• Chondroblasts develop to replace granulation tissue with hyaline cartilage
  
  • provisional soft callus
• Osteoprogenitor cells from endosteum and periosteum go to work to create woven bone (hard)
• Woven bone gradually replaced with lamellar bone via remodeling

Question 66

• Articular cartilage at the bony end plate has no?
• What is it separated from cartilage by?

Answer 66

• NO Haversion systems and canaliculi
• Separated from cartilage by a glycoprotein rich substance
  
  • similar to cement lines

Question 67

• What is the synoviam?
• What does it contain?

Answer 67

• Outer layer of dense connective tissue (in joint capsule)
• Inner synovial membrane with 1-2 layers of synovial cells
  
  • NO basement membrane
  • NO tight junctions
  • Fenestrated capillaries

Question 68

• Tendons are composed of?
• Where tendons insert into bones there is no?

Answer 68

• Composed of dense regular connective tissue
  
  • regularly oreinted parallel bundels of collagen fibers separated by rows of fibroblasts
• NOTE:
  
  • ligaments secure bones and joints but have a less orderly arrangement of collagen fibers
• Where tendon inserts into bone there is no periosteum

Question 69

• Osteoid, the organic component of bone matrix is made of?

Answer 69

• Mostly Type I collagen
• Osteopontin/ Osteocalcin: only protein unique to bone
  
  • produced by osteoblasts
  • function in bone mineralization, Ca homeostasis
• Cytokine and growth factors
  
  • control bone cell proliferation, maturation and metabolism
• Glycosaminoglycans

Question 70

Osteoprogenitor cells are what kind of cells?

Answer 70

Pluripotent mesenchymal stem cells located at bone surface

Question 71

• When do osteoblasts become osteocytes?
• What is function of osteocytes?

Answer 71

• Osteoblasts become osteocytes when they are embedded within the matrix
• Osteocytes function to:
  
  • communicate with each other and other bone cells via cytoplasmic process tunnels (canaliculi)
  • control Ca and P levels in locally
  • Mechanotransduction

Question 72

How do osteoclasts perform bone resportion?

Answer 72

• Bone resorption:
  
  • attach to matrix with cell surface integrins to create a sealed extracellular trench (resorption pit)
  • secrete proteases into the pit to disolve matrix components

Question 73

Osteoclasts differentiate by cytokines and growth factors, produced by osteoblasts, including?

Answer 73

• M-CSF (macrophage colony stimulating factor)
• IL-1
• TNF

Question 74

• RANKL on osteoblast promote?
• OPG on osteoblast promote?

Answer 74

• RANKL promote bone resorption
  
  • ​bind to RANK of osteoclast precursor and promote differentiation
  • Enhanced by binding of M-CSF to receptor
• OPG (Osteoprotegrin) promote bone formation
  
  • acts as decoy receptor for RANKL
  • inhibit osteoclast differentiation and resorption

Question 75

Explain the process of paracrine cross talk between osteoblasts and osteoclasts?

Answer 75

• As bone is resorbed, factors are released (matrix proteins, GF, etc.) locally and stimulate osteoblast
  
  • initiate bone renewal
• Osteoprogenitor cells produce WNT and BMP
  
  • bind to receptors on osteoblasts and increase production of OPG
    
    • promote bone formation

Question 76

Senile osteoporosis is related to?

Answer 76

• Age related changes
  
  • decreased proliferative and biosynthetic potential
  • decrease response to GF
  • net result: diminished capacity to make bone

Question 77

Through what process does physical activity stimulate bone growth?

Answer 77

• Mechanical forces stimulate normal bone remodeling: Mechanotransduction
  
  • strain/pressure of muscle contraction is transmitted to osteocytes through fluid in canaliculi
  • mechanical signal stimulates secretion of factors that increase bone remodeling
    
    • stimulate osteoblast differentiation and activity
    • decrease osteoclast activity
  • result: positive bone balance

Question 78

How does a decrease in estrogen lead to postmenopausal osteoporosis?

Answer 78

• Decrease estrogen stimulates blood monocytes and bone marrow cells to secrete inflammatory cytokines
• Increase RANKL and decrease OPG
  
  • increase osteoclast recruitment and activity
  • decrease osteoclast apoptosis
• Resorption>formation

Question 79

MOA of Vitamin D hormone?

Answer 79

• Binds a nuclear receptor (vitamin D receptor, VDR) which associates with RXR to form a heterodimer
• Heterodimer binds to vitamin D response element (VDRE)

Question 80

What is the result of Vitamin D deficiency?

Answer 80

• Impaired mineralization and accumulation of unmineralized matrix
• Can cause Rickets (children) and Osteomalacia (adults)

Question 81

Compare Rickets and Osteomalacia to Osteoporosis

Answer 81

• Osteoporosis: mineral content is normal but total bone mass is decreased
• Rickets: decreased bone deposition in growth plate of developing bone
• Osteomalacia: bone formed during remodeling is undermineralized resulting in predisposition to fractures

Question 82

How can you differentiate between osteoporosis and osteomalacia?

Answer 82

• Abnormal blood levels of Vitamin D, calcium and phosphorus
• X-ray: slight cracks in bones
  
  • Looser transformation zones; characteristic in osteomalacia