1.3.2 Bone, Cartilage, and Joint Histology

Question 1

Osteoblasts synthesize RANK-L which?

Answer 1

Stimulates osteoclastogenesis

Question 2

What is the cellular action of bisphosphonates?

Answer 2

Encourage osteoclastic apoptosis

Question 3

What is osteopetrosis?

Answer 3

Absence of secondary marrow cavity

Question 4

What are some of the general aspects of osteogenesis?

Answer 4

Question 5

What are two types of arthritis?

Answer 5

Question 6

What are the two mechanisms for calcification?

Answer 6

Matrix vesicles and mineralization in adult bone

Question 7

What are the covered parts?

Answer 7

Question 8

What is the role of osteoblasts?

Answer 8

Osteoblasts synthesize type I collagen and the bone matrix and then synthesize alkaline phosphatase which increases the local Ca2/PO4- ratio resulting in calcification. When the osteoblasts become trapped in the calcified matrix they are called osteocytes.

Question 9

Deposition of lime salts, in the form of hydroxyapatite crystals prevents?

Answer 9

Diffusion of metabolites

Interstitial growth

Both of which occur in cartilage

Question 10

What are the three phases of charcot joints?

Answer 10

Question 11

What are the characteristics of endochondral ossification?

Answer 11

Mesenchymal cells differentiate into chondrocytes and form a hyaline cartilage model of the long bone.

In the center of the diaphysis:

–Cartilage cells enlarge (hypertrophy)

–Chondrocytes synthesize alkaline phosphatase

–The matrix becomes calcified and does not permit diffusion.

–A vascular/osteogenic bud forms.

–Ossification occurs as bone is deposited on cores of calcified cartilage.

Primary ossification center establishes itself across the width of the shaft and extends toward the epiphyses.

Zones of endochondral ossification:

–Reserve/quiescent zone

–Multiplication/proliferative zone

–Hypertrophic zone

–Calcification/Vascular Invasion

–Zone of cartilage removal and bone deposition

Question 12

Describe the growth of cartilage and what are the two types of growth?

Answer 12

Centers of chondrification consist of mesenchymal cell aggregates which differentiate into chondrocytes

Interstitial growth - growth from within, isogenous groups formed by mitosis

Appositional growth - Growth from the perichondrium

Question 13

Describe the ARF cycle

Answer 13

Question 14

Hyaline cartilage consists of?

Answer 14

Type II collagen and proteoglycans

Question 15

What is this an image of?

Answer 15

Hyaline cartilage

Question 16

What are osteoclasts?

Answer 16

Osteoclasts contain ruffled borders and are responsible for the enzymatic dissolution of the bone.

Question 17

What is the process of bone growth in width/ diameter?

Answer 17

Growth in width occurs by depostion of new membrane bone (intramembranous ossification) beneth the periosteum.

Question 18

An osteoprogenitor cell is?

Answer 18

Pluripotential stem cell (from the sclerotome in case of the vertebrae) capable of differentiating into osteoblasts. They are found in the periosteum and endosteum as bone lining cells in non-growing regions.

Question 19

Describe the vascular supply to a joint?

Answer 19

Articular arteries and veins provide an abundant supply of blood to the joints. Diffusion plays an important part in the movement of nutrients from the perichondrium to the cartilage. Th absence of a continuous basal lamina facilitates diffusion.

Question 20

What is the role of parathyroid hormone?

Answer 20

Causes bone release of Ca2+. Leads to increased osteoclast activity

Question 21

Understand this chart

Question 22

What are the characteristics of bone development?

Answer 22

Question 23

What are the type of cells that the arrow is pointing at?

Answer 23

Osteoclasts

Question 24

Explain endochondral ossification again

Answer 24

Question 25

What is this an image of?

Answer 25

Woven bone

Question 26

The joint (articular) cavity is filled with?

Answer 26

Synovial fluid, containing very few lymphocytes, macrophages, monocytes and neutrophils. The fluid is a plasma dialysate. The fluid also contains hyaluronan and lubricin.

Question 27

Osteoblasts synthesize osteopontin which?

Answer 27

Allows for formation of sealing zones

Question 28

What are Charcot Joints?

Answer 28

Question 29

What are joints?

Answer 29

Question 30

What is this an image of?

Answer 30

A groove becoming a tunnel in bone

Formation of Haversian systems and Volkmann’s canals and internal remodeling of long bones

Filling in of tunnels with lamellae of bone to form osteons

Question 31

What is this an image of?

Answer 31

Diathrosis

Question 32

Osteoblasts synthesize osteocalcin which?

Answer 32

Is required for mineralization

Question 33

What are some of the characteristics of bone?

Answer 33

Question 34

Intermittent PTH exposure leads to?

Answer 34

Osteoblast proliferation and increased bone mass

Question 35

What is the role of the V-type ATPase on the osteoclast?

Answer 35

The V-type H+ ATPase is an ATP-driven enzyme that transforms the energy of ATP hydrolysis to electrochemical potential differences of protons across diverse biological membranes via the primary active transport of H+. It is essential for the production of an acidic environment in the Howship’s lacuna.

Question 36

Describe the innervation of a joint.

Answer 36

Question 37

What are the characteristics of intramembranous ossification?

Answer 37

Question 38

What are the types of cells in the synovial membrane?

Answer 38

Marcrophages - involved in phagocytosis and antigen presentation

Fibroblasts - synthesize hyaluronan and lubrican

Question 39

What is the effect of continuous PTH exposure on bone?

Answer 39

Continuous PTH exposure results in RANKL upregulation and concomitant OPG suppression (OPG serves as a decoy receptor for RANKL and prevents its interaction with osteoclast RANK). The stimulated RANKL-RANK interaction leads to osteoclast proliferation and increased bone turnover. Calcitonin receptors are found on the osteoclasts, but calcitonin is not a strong antagonist to PTH.

PTH binding to osteoblast also increases M-CSF. This will increase monocyte activity which will lead to more osteoclast progenitor cells.