Bone Lecture 2

Question 1

Intramembranous Ossification is responsible for formation of bone for:

Answer 1

Bone healing
Growth of flat bones (i.e. skull, carpals, tarsals)
Thickening of long bones

Question 2

Intramembranous Ossification

Answer 2

Osteoblasts secrete organic matrix (osteoid)

Osteoblasts then directly mineralize the matrix with hydroxyapatite crystals

Once surrounded by calcified matrix, osteoblasts become osteocytes

Osteoblasts are formed by differentiation of cells of the periosteum and endosteum or bone marrow stem cells (mesenchyme)

Osteoblasts secrete an organic bone matrix and then calcify the matrix

Question 3

Endochondral Ossification

Answer 3

Chondrocytes produce cartilage matrix and calcify the matrix

Osteoblasts enter the area and deposit bone matrix (osteoid) over the calcified cartilage matrix

Osteoblasts/osteocytes – remove remnants of cartilage matrix resulting in typical bone matrix

Question 4

Process of endochondral ossification is responsible for:

Answer 4

Growth of long bones (epiphyseal plate)

Bone healing

Question 5

Epiphyseal Plate: Resting Zone

Answer 5

Resting zone

area of normal hyaline cartilage and chondrocytes

Question 6

Epiphyseal Plate: Proliferative zone

Answer 6

Proliferative zone

area of intense mitosis (proliferation) of chondrocytes

Question 7

Epiphyseal Plate: Hypertrophic zone

Answer 7

Hypertrophic zone
area of chondrocyte hypertrophy due to glycogen uptake

Cartilage ECM is partially resorbed

Remnants appear as septa of matrix material between hypertrophic chondrocytes

Question 8

Epiphyseal Plate: Calcified cartilage zone

Answer 8

Calcified cartilage zone
Thin septa of cartilage matrix become calcified
Chondrocytes in this zone die after matrix calcification

Question 9

Epiphyseal Plate: Ossification zone

Answer 9

Osteoprogenitor cells from the bone marrow are delivered to the calcified cartilage
Osteoprogenitor cells differentiate into osteoblasts

Osteoblasts deposit bone matrix over the calcified cartilage matrix = ossification

Question 10

Endochondral ossification during fetal development is a similar process:

Answer 10

Osteoid deposition over cartilage matrix

Question 11

Basics of Bone remodeling

Answer 11

Bone undergoes constant remodeling throughout life

Bone remodeling is dependent on stresses (forces) placed on bones

Bone matrix is deposited and resorbed in accordance with the stresses placed upon it

Question 12

Wolff’s Law

Answer 12

Every change in form and function of bone, or in its function alone, is followed by certain, definite changes in its internal architecture and external form

Bone models and remodels [its internal architecture] in response to the mechanical stresses it experiences, so as to produce a minimal-weight structure that is ‘adapted’ to its applied stresses

Question 13

Bones response to fx

Answer 13

Bone matrix/cells are destroyed

Damaged blood vessels produce a localized clot

Clot material is later removed by macrophages

Periosteum and endosteum respond with intense proliferation of cells

Question 14

Bone response to fx and repair

Answer 14

Periosteal/endosteal fibroblasts differentiate into chondroblasts and form hyaline cartilage model = soft callus

Mesenchyme cells differentiate into osteoblasts and form osteoid

Endochondral and intramembranous ossification occur to form primary (woven) bone = hard callus
Hard callus (woven bone) is replaced by lamellar bone

Question 15

Healing time table

Answer 15

Soft Callus – 2wks
Hard Callus – 4wks
Lamellar Bone – 6wks

Healing bone is influenced by stresses placed upon it during healing

Question 16

Effects on bone with inactivity

Answer 16

Inactivity or decreased loading of bone results in reduced osteoblast activity

Inactivity/decreased loading do not affect osteoclast activity
Osteoclast activity remains at/near normal levels

The overall result of inactivity is increased degradation of bone matrix and increase in serum Ca++ levels
(urine calcium levels increase since calcium is excreted by kidneys)

Question 17

Exercise training: effects on bone

Answer 17

Increased loading (mechanical stress) results in improved bone qualities:

Hypertrophy of bone

↑ bone mass/density

↑ load to failure (strength)

Question 17

Exercise training: effects on bone

Answer 17

Increased loading (mechanical stress) results in improved bone qualities:

Hypertrophy of bone

↑ bone mass/density

↑ load to failure (strength)

Question 18

Flow for Effects on bone and exercise

Answer 18

Mechanical Stress–>Microscopic deformities
–>↑ blood flow & ↑ bioelectric potentials =
(Piezoelectric effect)
—>Increased osteoblast and osteoclast activity

Question 18

Flow for Effects on bone and exercise

Answer 18

Mechanical Stress–>Microscopic deformities
–>↑ blood flow & ↑ bioelectric potentials =
(Piezoelectric effect)
—>Increased osteoblast and osteoclast activity

Question 19

Stress Fx

Answer 19

Repetitive loading on bone creates microscopic deformities

Deformities are healed and bone repaired with rest

Stress fractures result when loading outpaces bone repair/remodeling

Question 19

Stress Fx

Answer 19

Repetitive loading on bone creates microscopic deformities

Deformities are healed and bone repaired with rest

Stress fractures result when loading outpaces bone repair/remodeling

Question 20

Osteopenia

Answer 20

reduction in bone mineral density below normal levels, results in decreased bone strength
Osteopenia is often a precursor to the development of osteoporosis

Question 20

Osteopenia

Answer 20

reduction in bone mineral density below normal levels, results in decreased bone strength
Osteopenia is often a precursor to the development of osteoporosis

Question 21

Osteopenia occurs as a result of

Answer 21

inactivity, aging, low intake of vitamin D and calcium, smoking

Question 21

Osteopenia occurs as a result of

Answer 21

inactivity, aging, low intake of vitamin D and calcium, smoking

Question 22

Osteoporosis

Answer 22

defined as ↓ bone density and ↓ in overall volume of bone

With osteoporosis, bone resorption > bone formation

Osteoporosis often results in pathologic fractures
Failure of bone in response to normal physiologic stress

Question 23

Bones serves as what reservoir

Answer 23

Ca++ reservoir
99% of total body calcium is in the skeleton

Ca++ levels are tightly controlled by the endocrine system

Question 24

Key regulators of calcium metabolism

Answer 24

Parathyroid hormone (parathyroid glands) 
Calcitonin (thyroid gland)
Vitamin D (absorbed thru intestines)

Question 25

Calcium levels in Blood

Answer 25

Hypercalcemia (↑ Ca++ level in serum) > 10.5 mg/dL of blood

Typical symptoms = mild to severe proximal weakness of the extremities

Hypocalcemica (↓ Ca++ level in serum ) < 8.5 mg/dL of blood

Typical symptoms = neuromuscular excitability and muscular tetany (especially UE flexion)

Question 26

Parathyroid Hormone (PTH)

Answer 26

Secreted from the parathyroid gland in response to low Ca++ levels in the plasma

PTH promotes osteoclast resorption of bone matrix and subsequent liberation of Ca++ into the blood

PTH binds to osteoblasts and stimulates osteoblasts to:
Stop producing bone
Secrete an osteoclast-stimulating factor

PTH also:
Enhances calcium absorption from intestines
Decreases calcium excretion by kidneys

Question 27

Calcitonin

Answer 27

Synthesized by the thyroid gland in response to elevated blood (plasma) Ca++ levels

Calcitonin
Inhibits matrix resorption by osteoclasts
Inhibits new osteoclast formation

Calcitonin has no effect on osteoblast activity, thus osteoblasts continue to produce bone matrix (and deposit excess the serum calcium onto new bone)

Question 28

Vitamin D metabolism

Answer 28

Vitamin D is necessary for intestinal absorption of Ca++ and PO4- from the small intestine

Vitamin D is necessary for active reabsorption of Ca++ and PO4- from the kidney

Vitamin D formation is stimulated by UV light; initial molecule is inactive

Question 29

VItamin D synthesis

Answer 29

Inactive Vit. D is “processed” in the liver and fully activated by the kidneys (hydroxylation)

Activated vitamin D enters the blood stream to assist with calcium absorption from the GI tract

A slight decrease in serum calcium below normal stimulates activation of “inactive” vitamin D