Bone Structure, Formation, Growth & Repair

Question 1

What are the constitutes of connective tissue?

Answer 1

1. Cells: fibroblasts (secrete ECM), adipocytes, osteoblasts/osteocytes (bones), chrondroblasts/chrondrocytes (cartilage) + immune cells
2. ECM: fibrous proteins (e.g. collagen/elastin) + ground substance (proteoglycans, glycoproteins + water) - composition determines tissues physical properties

Question 2

What is bone?

Answer 2

A specialised type of connective tissue

Question 3

What is the function of proteoglycans?

Answer 3

Consist of repeat dissacharide units called GAGs bound to core of protein that are hydrophilic and attract water so tissue can resist compressive forces

Question 4

What is the function of glycoproteins?

Answer 4

Allows cells to adhere to underlying ECM

Question 5

What are the 2 main features of bone and what gives it these properties?

Answer 5

Need a BALANCE of:

1. Rigidity: deals with force via mineralised ECM (hydroxyapatite)
2. Resilience: absorb energy from impact, change slightly then return to original form via type I collagen fibres

Question 6

What are the functions of bone?

Answer 6

Movement
Mineral homeostasis
Support
Protection
Site of haematopoiesis

Question 7

What is periosteum?

Answer 7

Non-calcified dense irregular connective tissue layer covering bone helping bones to grow in thickness (as it contains osteoprogenitor cells and osteoblasts), protects bone, assists fracture repair, helps nourish bone tissue and is attachment point for tendons and ligaments

Question 8

What are the 2 layers of periosteum?

Answer 8

1. Outer fibrous layer

2. Inner cellular layer

Question 9

What are the 2 different microscopic types of bone?

Answer 9

1. Woven: immature primary weak bone formed at any site during development (also sites of fracture healing) where collage fibres are arranged randomly and quickly
2. Lamellar: mature bone formed by remodelling of collagen fibres from woven bone into an orderly arrangement increasing strength

Question 10

What are the 2 different types of lamellar bone structure?

Answer 10

Need a BALANCE of:

1. Cortical: dense, strong and heavy giving rigidity
2. Trabecular/spongy bone: less dense with holes like a sponge giving resilience

Question 11

What are the different types of cortical (compact) bone?

Answer 11

1. Outer circumferential lamellae
2. Haversian systems (osteons)
3. Interstitial lamellae (result of bone remodelling + formation of new Haversian systems)
4. Inner circumferential lamellae

Question 12

Define lamellae.

Answer 12

Bony plates made up of irregularly arranged collagen fibres in parallel

Question 13

What are Haversian systems (osteons)?

Answer 13

Concentric lamellae around a central Haversian canal which contains blood vessels, lymphatic vessels and nerves

Question 14

What is the function of Volkmann’s canals?

Answer 14

Run transversely or obliquely to Haversian canals allowing communication between Harversian canals, periosteum, the marrow cavity and itself

Question 15

What is trabecular/cancellous/spongy bone?

Answer 15

3D network of beams and struts of lamellar bone orientated along lines of stress (more likely to be remodelled in stress) making up large areas of interconnecting marrow spaces for haematopoiesis

Question 16

Why do bones need a good vascular supply? Why is this clinically relevant?

Answer 16

Because a lot of remodelling occurs regularly - fractures can break blood vessels causing bleed and access can be gained to these vessels to give drugs in emergencies

Question 17

What types of arteries supply bone?

Answer 17

Epiphyseal
Metaphyseal
Periosteal
Nutrient

Question 18

How are bone cells formed?

Answer 18

From mesenchymal stem cells which form osteoprogenitor cells which become osteoblasts then osteocytes

Question 19

What do osteoblasts do?

Answer 19

Line the surface of bones synthesizing and secreting organic bone matrix (osteoid)/ECM which is subsequently mineralised outside of the cell - once surrounded by matrix they become OSTEOCYTES

Question 20

What does osteoid contain?

Answer 20

Type I collagen 
Proteoglycans
Glycoproteins
ALK P (forms hydroxyapatite)
Osteocalcin (Ca2+ binding)
Osteopontin

Question 21

What are periosteal cells?

Answer 21

Resting osteoclasts lining bone with important role in fracture healing

Question 22

What are osteocytes?

Answer 22

Mature bone cells (do not divide) occupying lacunae and surrounded by bone matrix - their dendritic processes pass through canaliculi which radiate from lacunae and anastamose with those from other lacunae where gap junctions allow transfer of ions and nutrients so there main functions are matrix maintenance/Ca2+ homeostasis and mechanotransduction (detection of force/stress + laying down of new bone in response)

Question 23

What are osteoclasts?

Answer 23

Large multinucleated cells with ruffled border derived from monocyte-macrophage system (haemtopoietic origin) that function in resorption of bone matrix via synthesis and secretion of enzymes and acid (form Howship’s lacunae) but also, remodelling, growth and repair

Question 24

What is bone remodelling?

Answer 24

Continual process throughout life in response to changing mechanical stress or microfractures of bone whereby there is coupling and balance of bone resorption (osteoclasts) and formation (osteoblasts)

Question 25

How is bone remodelled?

Answer 25

1. Osteoclasts form cone-shaped tunnels into compact bone (Howship’s lacunae)
2. Tunnel is invaded by blood vessels, osteoblasts + osteoprogenitor cells
3. Osteoblasts lay down new bone in concentric lamellae around blood vessels forming new Haversian systems closing the cone

Question 26

How is bone remodelling regulated?

Answer 26

Osteoblasts secrete:

1. RANKL which binds to RANK receptor on osteoclasts activating bone resorption
2. OPG is a non-signalling decoy receptor of RANKL mopping it up and decreasing bone resorption

RANKL:OPG important in determining degree of resorption along with cytokines, hormones + drugs

Question 27

What hormone favours bone formation?

Answer 27

Oestrogen via increasing OPG levels

Question 28

What hormones favour bone resorption?

Answer 28

Calcitriol + PTH via stimulation of osteoblasts to release RANKL which acts on RANK receptor on osteoclasts to activate bone resorption

Question 29

What are the 2 ways in which bones can develop?

Answer 29

1. Intramembranous ossification: direct replacement of mesenchyme by bone tissue with NO cartilage precursor (e.g. flat skull bones, clavicle + mandible)
2. Endochrondral ossification: bone develops from mesenchyme but with a cartilage precursor in weight-bearing bones (e.g. long bones, vertebrae + pelvis)

Question 30

What are the steps of intramembranous ossification?

Answer 30

1. Primary ossification centre: mesenchyme membrane differentiates directly into osteoprogenitor cells then osteoblasts then osteocytes
2. Osteoblast secrete osteoid which is then calcified
3. Blood vessels invade and trabecula of woven bone is formed whilst mesenchyme condenses to form fibrous periosteum
4. Bone collar is formed (compact bone) and spongy bone cavities (diploe) now contain red marrow

Question 31

What are the steps of endochrondral ossification of the diaphysis?

Answer 31

Primary (diaphyseal) ossification centre:

1. Mesenchyme develops into chondroblasts which form a mini hyaline cartilage model
2. Cartilage cells in centre of diaphysis hypertrophy die and become calcified leaving large open spaces in cartilage (future marrow cavity)
3. Osteoblasts secrete matrix and form subperiosteal bony collar around edge of diaphysis
4. Vascularisation of perichondrium transforms it to periosteum
5. Blood vessels invade cartilage model with osteoprogenitor cells which differentiate into osteoblasts
6. Osteoblasts secrete bone matrix on surface of calcified cartilage scaffold

Question 32

How does endochondral ossification occur in the epiphysis?

Answer 32

Similar process forming secondary ossification centres but there is no bony collar and bone is not laid down at articular surface or epiphyseal plate

Question 33

When do different ossification centres appear?

Answer 33

1. Primary ossification centres in diaphysis develop in foetal life (14 weeks)
2. Secondary ossification centres in epiphyses develop after birth in an ordered way related to age (X-rays can determine if a child’s skeleton is developing appropriately with age as a result)

Question 34

What are the 2 different types of bone growth?

Answer 34

1. Longitudinal: at epiphyseal growth plate of weight bearing long bones where there is proliferation of cartilage cells followed by endochondral ossification
2. Appositional: growth in width where new bone is formed under periosteum

Question 35

What are the different zones of the epiphyseal growth plate?

Answer 35

1. Resting (quiescent): cartilage cells resting + ready to be used
2. Growth (proliferation): cartilage cells proliferate under influence of ILGF produced by hepatocytes in response to GH (epiphyseal aspect)
3. Hypertrophic: chrondocytes stacked in columns like coins, mature + hypertrophy
4. Calcification: hypertrophied chrondrocytes die + cartilage matrix is calcified which is removed by osteoclasts
5. Ossification (osteogenic): osteoblasts form new bone (diaphyseal aspect) and epiphyseal growth plate closes

Question 36

When does the epiphyseal growth plate close? What can be left in its place?

Answer 36

18-25 years when rate of proliferation zone decreases and ossification zone overtake other zones - may be marked by an epiphyseal line where the marrow cavity of the epiphysis and diaphysis have joined up = no growth in length is possible at this point

Question 37

What is growth plate activity and closure influenced by?

Answer 37

A range of hormones e.g. GH and oestrogen

Question 38

Why does the thickness of growth plates remain the same?

Answer 38

The rate of proliferation of cartilage cells is the same as the rate of new bone production at the opposite end of the growth plate

Question 39

What is the clinical significance on growth plates?

Answer 39

Weak point particularly if subject to shearing forces which can cause:

• Salter-Harris fractures of growth plates causing deformities in developing bone (e.g. shortening/angulation)
• Disorders of bone mineralisation (e.g. Rickets can affect size/shape of growth plates)

Question 40

What is a fracture?

Answer 40

Breach in the integrity of part OR the whole of a bone

Question 41

What are the stages of fracture healing for long bone?

Answer 41

1. Haematoma
2. Granulation tissue
3. Callus
4. Woven bone
5. Lamellar bone
6. Remodelling

Question 42

What is the difference in fracture healing of other bones?

Answer 42

Bones with more trabecular bone have a better blood supply so there is usually less necrosis and callus formation

Question 43

What occurs in the haematoma stage of fracture healing?

Answer 43

Rupture of vessels in region of fracture site forming a haematoma so there is necrosis of bone fragments - this initiates an inflammatory reaction where phagocytes migrate to the area to remove necrotic tissue

Question 44

What occurs in the granulation tissue stage of fracture healing?

Answer 44

Blood clot is invaded by small capillaries and fibroblasts from surrounding connective tissue to form granulation tissue - cytokines, signalling molecules and GFs induce subperiosteal/endosteal cellular proliferation as they attract cells to the site

Question 45

What occurs in the callus stage of fracture healing?

Answer 45

Bridge formed between fractured bone ends to form a soft fibrocartilaginous callous made up of fibrous tissue, inflammatory cells and cartilage

Question 46

What occurs in the woven bone stage of fracture healing?

Answer 46

Osteoprogenitor cells proliferate and differentiate into osteoblasts to form woven bone which strengthens the callus giving it rigidity forming a bony callus - when it is sufficiently firm that movement no longer takes place at fracture site it is clinically united

Question 47

What occurs in the lamellar bone stage of fracture healing?

Answer 47

Osteoclasts remove woven bone and osteoblasts gradually replace it with lamellar bone although its laid down quick so it is not that strong

Question 48

What occurs in the remodelling stage of fracture healing?

Answer 48

Osteoclasts and osteoblasts remodel lamellar bone in response to stresses and excessive callus is reabsorbed also re-establishing the marrow cavity

Question 49

What factors aid fracture healing?

Answer 49

Stability of fracture (can be clinically enhanced by fixations)

Apposition of bone ends (dont want foreign material/tissue between bone ends - want bones to be as close as possible)

Adequate blood supply

Question 50

What factors delay fracture healing?

Answer 50

Excessive movement of bone ends
Poor blood supply
Infection
Foreign bodies

Question 51

What can happen if fracture healing goes wrong?

Answer 51

1. Malunion: healing in unsatisfactory position
2. Delayed union: takes longer than expect to unite
3. Non-union: can lead to fibrous union of pseudoarthrosis (fake joint)