1. Chapter 6 Cartilage and Bone

2. Functions of cartilage
Support soft tissue
keep trachea open
cushions vertebrae
Provide soft, gliding surface at articulations (joints)
Provides model for formation of new bone
Comes in 3 types
hyaline cartilage
fibrocartilage
elastic cartilage

3. Supporting connective tissue
Cartilage and bone are considered connective tissue
protect and support soft body tissues
Cartilage has firm, gel-like extracellular matrix
protein fibers and ground substance
chondrocytes are mature cartilage cells
sit in spaces called lacunae (sing. lacuna)
collagen fibers give strength; stronger than other connective tissue
elastic fibers give resilience
avascular (nutrients absorbed by diffusion)

4. Hyaline cartilage
Table 4.11a-1
Chondrocytes (cartilage cells) sit in lacunae (sing. lacuna)
Think of the lacuna as a pocket. The chondrocyte sits in the pocket.
Dividing chondrocytes often seen sharing lacuna
Extracellular matrix surrounds cells
Collagen fibers are very fine; can’t be seen in microscope
Lacuna
Chondrocyte
Extracellular matrix
LM 250x

5. Growth of cartilage Interstitial growth happens within cartilage
chondrocyte in lacuna undergoes mitosis
now two cells in one lacuna
cells called chondroblasts
chondroblasts secrete cartilage matrix, get pushed apart
lacuna forms around each cell, now called a chondrocyte
Happens widely during embryonic development, less as cartilage matures

6. © The McGraw-Hill Companies, Inc./Photos by Dr. Alvin Telser
Fig. 6.2a
Interstitial Growth
Chondrocyte
in lacuna
Hyaline cartilage
LM 320x
1. Chondrocyte starts to undergo mitosis
Lacuna
Chondrocyte
Cartilage matrix
2. Two chondroblasts occupy one lacuna.
Chondroblast
Chondroblast
Lacuna
© The McGraw-Hill Companies, Inc./Photos by Dr. Alvin Telser 6

7. © The McGraw-Hill Companies, Inc./Photos by Dr. Alvin Telser
Fig. 6.2a
3. Chondroblasts produce new matrix, begin to separate. Separate cells called chondrocytes
Interstitial Growth
Hyaline cartilage
New matrix
Lacuna
Lacuna
1. Chondrocyte starts to undergo mitosis
Chondrocyte
Chondrocyte
Lacuna
4. Cartilage continues to grow internally;
chondrocytes produce matrix.
Chondrocyte
Cartilage matrix
New matrix
Chondrocyte
2. Two chondroblasts occupy one lacuna.
Chondroblast
Chondroblast
Lacuna
© The McGraw-Hill Companies, Inc./Photos by Dr. Alvin Telser 7

8. Growth of cartilage Appositional growth happens at edges of cartilage
stem cells in perichondrium divide, create chondroblasts
new chondroblasts start to secrete cartilage matrix
new cells push apart, each forms own lacuna

9. Appositional Growth Perichondrium Matrix Hyaline cartilage Chondrocyte
Fig. 6.2b
Appositional Growth
Matrix
Hyaline cartilage
Chondrocyte
in lacuna
LM 320x 1
Stem cells within perichondrium do mitosis
Mesenchymal
cells
Dividing
undifferentiated
stem cell
Perichondrium
New cartilage
matrix
Older cartilage 9

10. Perichondrium
Fig. 6.2b
Matrix
Hyaline cartilage
Appositional Growth
Chondrocyte
in lacuna
LM 320x
New undifferentiated stem cells and committed cells that differentiate into chondroblasts are formed. New matrix formed at periphery 2
Undifferentiated stem cells
Committed cells differentiating into
chondroblasts
New cartilage matrix
Chondroblast secreting new matrix
Older cartilage matrix 10

11. Perichondrium
Fig. 6.2b
Matrix
Chondrocyte
in lacuna
Hyaline cartilage
Appositional Growth 3
Chondroblasts push apart and become chondrocytes,
produce more matrix at periphery
Perichondrium
Undifferentiated
stem cells
Chondrocyte
secreting new
matrix
New cartilage matrix
Mature
chondrocyte
Older cartilage matrix 11

12. Endosteum Osteoprogenitor cell is stem cell
Fig. 6.5
(b) Endosteum
Osteoprogenitor cell
Osteoprogenitor cell is stem cell
mitosis creates another stem cell and “committed cell”
Osteoblasts secrete osteoid
bone matrix
later calcium deposits harden osteoid
osteoblasts become trapped in bone matrix, become osteocytes
Periosteum
Osteoblasts
Endosteum
Compact bone
Endosteum
Osteoclast
Nuclei
Bone matrix
Canaliculi
Osteocyte
in lacuna
Osteoid
Copyright © McGraw-Hill Education. Permission required for reproduction or display. 12

13. Endosteum Osteoclasts reabsorb bone matrix
Fig. 6.5
(b) Endosteum
Osteoprogenitor cell
Osteoclasts reabsorb bone matrix
derived from marrow cells
usually located in pit or depression called resorption lacuna
free calcium and potassium for use elsewhere in the body (osteolysis)
clean up damaged bone
Osteoclasts remove bone, osteoblasts replace it
Periosteum
Osteoblasts
Endosteum
Compact bone
Endosteum
Osteoclast
Nuclei
Bone matrix
Canaliculi
Osteocyte
in lacuna
Osteoid
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14. Page 154 Paget’s disease of bone
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
Paget’s disease of bone
Excessive osteoclast activity
osteoclasts are too large and too active, remove too much bone
Osteoblasts replace lost bone
New bone structurally unstable
more susceptible to deformation and fractures
X-ray of a skull with osteitis deformans. White arrows indicate areas of excessive bone deposition.
© Science Source 14

15. Osteocytes Osteocytes in lacunae in matrix maintain bone matrix
send information about stress on bone
communicate with each other through canaliculi
in spongy bone, osteocytes not in osteons

16. Parts of long bones outside of bone lined with periosteum
Fig. 6.4
Parts of long bones
Proximal
epiphysis
Metaphysis
outside of bone lined with periosteum
dense irregular connective tissue
same tissue found where else?
outer layer is fibrous
inner layer is cellular
perforating fibers anchor periosteum to bone
Periosteum
Perforating fibers
Diaphysis
Metaphysis
Distal
epiphysis 16

17. Periosteum Protects bone
(a) Periosteum
Periosteum
Fig. 6.5
Circumferential lamellae
Perforating fibers
Periosteum
Fibrous layer
Protects bone
provides stem cells for bone width growth and fracture repair
Cellular layer
Canaliculi
Osteocyte
in lacuna
Periosteum
Compact bone
Endosteum
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18. Case Study: Achondroplasia
Matt is a toddler who does not appear to be developing normally
Mentally he is normal, but he is very small. His head size is normal, but his arms and legs are very short and don’t appear to be growing normally

19. Ossification AKA osteogenesis formation and development of bone
Intramembranous ossification
produces flat bones of skull, some facial bones, part of clavicle
osteoid from osteoblasts becomes calcified
bone slowly becomes more organized, osteoblasts captured in matrix

20. Fig. 6.10 Intramembrous Ossification
Flat bone
of skull
1. Ossification centers form within thickened regions of mesenchyme.
Collagen
fiber
Ossification
center
Osteoblast
Osteoid
Mesenchymal
cell 20

21. Fig. 6.10 Intramembrane Ossification
Osteoid
Osteocyte
Osteoblast
Newly calcified
bone matrix
2. Osteoid undergoes
calcification. 21

22. Fig. 6.10 Intramembrous Ossification
Mesenchyme
condensing to
form the
periosteum
Blood vessel
Trabecula of
woven bone
3. Woven bone and surrounding
periosteum form. 22

23. Fig. 6.10 Intramembrous Ossification
4. Lamellar bone replaces woven bone, as compact and spongy bone form.
Periosteum
Compact
bone
Lamellar
bone
Spongy
bone 23

24. Spongy
bone
Periosteum
Flat bone of skull
Compact bone
Fig. 6.7 24

25. Ossification Endochondral ossification produces most bones of skeleton
chondroblasts secrete cartilage matrix
chondrocytes trapped within matrix die, leaves holes in matrix
cartilage matrix is calcified
osteoblasts lay down calcium phosphate matrix, get trapped in matrix, etc.
process continues until growth is complete (teenage years)

26. Endochondral Ossification
Epiphyseal
blood vessel
capillaries
Deteriorating
cartilage matrix
Developing
periosteum
Perichondrium
Epiphyseal plate
Articular
cartilage
Spongy
bone
Epiphyseal line
(remnant of
epiphyseal plate)
Compact
Medullary
cavity
Periosteum
compact
Secondary
ossification
centers
plate
Calcified cartilage
Blood
vessel of
periosteal
bud
Primary
center
Hyaline
Periosteal
bone collar
Spongy bone
Articular cartilage
Fig. 6.11 26

27. proliferating cartilage
Fig. 6.12
Epiphyseal
plates
(b) X-ray of a hand
Zone 1: Zone of
resting cartilage
Zone 2: Zone of
proliferating cartilage
Zone 3: Zone of
hypertrophic cartilage
Zone 4: Zone of
calcified cartilage
Zone 5: Zone of ossification
(a) Epiphyseal plate
Epiphyses
Diaphysis
Diaphyses
LM 70x 27

28. Page 160 Epiphyseal plates
When a person is growing, epiphysis and diaphysis are separate pieces
When bones stop growing longer, cartilage section calcifies, unites epiphysis and diaphysis
(Left) the epiphyses are partially fused; likely age 15 to 23
(Right) No fusion; likely younger than 15 years of age.
Copyright © McGraw-Hill Education. Permission required for reproduction or display.
© David Hunt/Smithsonian Institution 28

29. Long bone development Fig. 6.13
Bone deposited by osteoblasts
Bone resorbed by osteoclasts
Adult
Young adult
Child
Infant
Growth in length is interstitial growth
Growth in width is appositional growth
does not require cartilage matrix
osteoblasts created by cells in periosteum 29

30. Case Study: Achondroplasia
What if the body doesn’t produce cartilage correctly?
Flat bones of head develop normally
osteoprogenitor cells continue to produce osteoblasts, which make osteoid
Long bones don’t develop normally
endochondral ossification can’t happen
osteoblasts get made, but don’t have cartilage matrix to lay calcium phosphate onto
bones don’t grow

31. Roloff family (Little People, Big World) Parents Matt and Amy and one son are achondroplasic dwarfs Other 3 children are average height

32. Bone remodeling Happens throughout life
maintains levels of calcium and phosphate in blood
heals fractures
responds to stresses (including running, weight training)
increases size of bone attachment sites on bone
Osteoclasts remove bone, osteoblasts replace it
usually results in loss of bone density

33. Medullary cavity (contains yellow bone marrow)
Articular cartilage
Fig. 6.14
Epiphyseal artery
Metaphyseal artery
Epiphyseal line
Periosteal arteries
Periosteum
Cellular layer
Periosteum
Fibrous layer
Nutrient artery
(in nutrient
foramen)
Branch of
nutrient artery
Medullary cavity (contains yellow bone marrow)
Compact bone 33

34. Fractures Oblique Fig. 6.15 Greenstick Pott Transverse Comminuted
Spiral
Colles
Compound (open) 34

35. Fig. 6.16 Medullary cavity Hematoma Periosteum Compact bone 1
A fracture hematoma forms. 35

36. Fig. 6.16 Fibrocartilaginous (soft) callus Regenerating blood vessels
Medullary
cavity
Hematoma
Periosteum
Regenerating
blood vessels
Compact
bone 1
A fracture hematoma forms. 2
A fibrocartilaginous (soft)
callus forms. 36

37. Fig. 6.16 Hard callus Primary bone 3 A hard (bony) callus forms.
Medullary
cavity
Hematoma
Hard
callus
Periosteum
Compact
bone
Fibrocartilaginous
(soft) callus
Regenerating
blood vessels
Primary bone 1
A fracture hematoma forms. 2
A fibrocartilaginous (soft)
callus forms. 3
A hard (bony) callus forms. 37

38. Fig. 6.16 Compact bone at break site 4 The bone is remodeled.
Medullary
cavity
Hematoma
Hard
callus
Periosteum
Compact
bone
Fibrocartilaginous
(soft) callus
Regenerating
blood vessels
Primary bone 4 1
A fracture hematoma forms. 2
A fibrocartilaginous (soft)
callus forms. 3
A hard (bony) callus forms.
The bone is remodeled. 38