TOB L7

Question 1

Describe cartilage and where it is commonly found

Answer 1

Form of connective tissue
Found at most joints
Strong + deformable structures

Question 2

State adaptations of cartilage

Answer 2

Pliant (flexible)
resists compression
Avascular
Not innervated

Question 3

State the 2 types of cartilage cells

Answer 3

Chondroblasts
Chondrocytes

Question 4

Which cells produce ECM in cartilage

Answer 4

Chondroblasts
Chondrocytes

Question 5

Histology showing hyaline cartilage of the trachea

Answer 5

Isogenous (nest) cells
Perichondrium
Chondroblasts

Question 6

State the 3 types of cartilage

Answer 6

1. Hyaline cartilage -
2. Elastic cartilage - contains lots of elastic fibres, difference from hyaline cartilage
3. Fibrocartilage - ECM as lots of Type I collagen - difference from hyaline cartilage

Question 7

Describe the composition of hyaline cartilage

Answer 7

ECM contains proteoglycans, hyalaronic acid, type II collagen

Question 8

State a difference between hyaline and elastic cartilage

Answer 8

Elastic cartilage contains elastic fibres

Question 9

State a difference between hyaline and fibrocartilage cartilage

Answer 9

ECM of fibrocartilage contains type I collagen fibres

Question 10

State locations of hyaline cartilage

Answer 10

1. Articular cartilage - found at ends of bones + moveable joints
2. Costal cartilages - connect ribs to sternum
3. Larynx and trachea

Question 11

Describe the features of hyaline cartilage

Answer 11

1. Covered by fibrous perichondrium (except for articular surface of synovial joints)

Question 12

Describe the composition of abundant ECM in hyaline cartilage

Answer 12

1. Type II collagen - collagen in hyaline cartilage forms fibrils but does not assemble into fibres (contributes to unique properties of hyaline cartilage) - STRUCTURAL SUPPORT
2. Hyaluronic acid - molecule which holds lots of water. Keeps hyaline cartilage well hydrated, provides resilience to tissue under pressure. Makes it pliable (flex + absorb mechanical forces)
3. GROUND SUBSTANCE : NON CELLULAR COMPONENT OF ECM: Glycosaminoglycans (GAGs, including hyaluronic acid + proteoglycans) to Collagen Ratio: Large ratio of GAGs to collagen in ECM. Facilitates diffusion of substances between chondrocytes (cartilage cells) and blood vessels surrounding cartilage

• Type II collagen
• Water
• Ground substance

Question 13

State key properties of hyaline cartilage ECM

Answer 13

1. Hyaluronate Proteoglycan Aggregates:
   molecular complexes formed by binding of hyaluronic acid + proteoglycans.
   Contribute to resistance to deformation of hyaline cartilage.
   Allows hyaline cartilage to withstand compressive forces + maintain structure, providing support to joints
2. Negative gel + hydrated gel formation

GAGs (hyaluronic acid)/ carries negative charges on surface.
Negative charges strongly attract polarized water (H2O)
Attraction leads to formation of hydrated gel within cartilage
Hydrated gel contributes to ability to absorb + distribute mechanical forces, allowing to cushion joints

Question 14

Describe the growth process of hyaline cartilage

Answer 14

1. Perichondrium + appositional growth (hyaline cartilage increasing in size by adding new layers to its surface): chondroblasts in perichondrium add new cartilage to outer surface of existing cartilage to increase size by adding new layers
2. Dividing cells + isogenous groups
   Dividing cells within cartilage form isogenous groups (clusters of cells derived from the same parent cell). Cells contribute to territorial + inter-territorial matrix production
3. Territorial + inter-territorial matrix
   matrix produced by chondrocytes can be categorised into territorial + inter-territorial matrix. Territorial matrix surrounds individual lacunae (spaces where chondrocytes reside). Inter-territorial matrix lies between lacunae.

Question 15

Describe the effect of pressure and stress on hyaline cartilage

Answer 15

Creates mechanical + electrical signals
This increases chondrocyte activity

Question 16

Osteoarthritis

Answer 16

Most common form of arthritis
Prevalence increasing with age
Results from focal (centre) + progressive hyaline articular cartilage loss with changes to underlying bone
Soft tissue structures in + around joint affected

CAUSES:
-severe joint injury (fractures of articular surfaces, tears of menisci
-obesity

Osteoarthritis leads to patients having total knee + total hip replacements

Question 17

Describe the prevalence and age of osteoarthritis

Answer 17

Most common form of arthritis
Prevalence increases with age

Question 18

Describe characteristics of osteoarthritis

Answer 18

1. Focal (localised) + progressive loss of hyaline articular cartilage (covers ends of bones with joint)
2. Changes in underlying bone structure as result of cartilage loss
3. Soft tissue structures in + around joint also affected

Question 19

Describe causes + risk factors osteoarthritis

Answer 19

CAUSES:
1. Severe joint injuries including fractures of articular surfaces + tears of menisci (cartilage discs in knee joint)
2. Obesity

RISK FACTORS
1. Total knee replacement
2. Total hip replacement

X-Ray shows arthritis of knee joint

Question 20

State locations of elastic cartilage

Answer 20

1. External ear pinna
2. External acoustic meatus
3. Auditory tube
4. Epiglottis

Question 21

Histology showing elastic cartilage from the epiglottis

Answer 21

Elastic fibres lying in ECM
Provide elasticity + increased resilience
(more than hyaline cartilage)

Question 22

State locations of Fibrocartilage

Answer 22

1.I ntervertebral discs
2. Articular discs of 3.sternoclavicular and temporomandibular joints
4. Menisci of knee
5. Pubic symphysis
6. Entheses (between tendon and bone)

FIBROCARTILAGE HAS NO PERICHONDRIUM

Question 23

Histology of fibrocartilage in intervertebral discs

Answer 23

In the annulus fibrosus,
chondrocyes in lacunae
are embedded in large
bundles of type I collagen
fibres.
This provides a tough,
shock absorbing structure.
In some regions, e.g. the
pubic symphysis or menisci
of the knees, more
cartilaginous matrix can be seen

Question 24

Describe how fibrocartilage in intervertebral discs provides a tough shock absorbing structure

Answer 24

1. In annulus fibrosus, chondrocytes in lacunae embedded in large bundles of type I collagen fibres
2. This provides a tough, shock absorbing structure

Question 25

Meniscal damage

Answer 25

1.

Question 26

Describe the composition of fibrocartilage

Answer 26

Dense regular connective tissue
Hyaline cartilage (therefore, contains fibroblasts + chondrocytes)

Question 27

State properties of fibrocartilage

Answer 27

resilience to act
as a shock absorber and to resist
shearing forces.

FIBROCARTILAGE HAS NO PERICHONDRIUM - we can use this to recognise it

Question 28

State the role of fibrocartilage in the menisci of the knee

Answer 28

Menisci of knee formed of fibrocartilage discs separating femur and tibia

Menisci Prevent degeneration of articular cartilage underneath

Question 29

State a common cause of meniscal lesions in young people

Answer 29

Sport related injury
includes trauma, twisting or direct impact on knee leading to damage of menisci

Question 30

State a common cause of meniscal lesions in middle aged people

Answer 30

Long term degeneration of articular cartilage underneath

overtime, wear and tear of menisci, due to repetitive movements, ageing

Question 32

Describe the position of the menisci

Answer 32

Between femur (thigh bone)
and tibia (shinbone) in knee joint

Question 33

State the functions of menisci

Answer 33

Fibrocartilage
Cushions knee joint
Stabilises knee during movement
By distributing weight
Also by acting as shock absorber
Prevents degeneration of articular cartilage (covering ends of femur + tibia joint)

Act as cushions + stabilisers in knee joint

Help distribute weight, absorb shock, provide stability during movements

Prevents degeneration of articular cartilage that covers ends of femur and tibia in joint

Question 35

State functions of bone

Answer 35

Strength + rigidity allows forceful muscle contractions to result in movement

Provides protection for internal structures

Highly vascular + innervated

Adapts to changing mechanical demands

Regenerates following injury

Mineral storage

Blood cell formation

Question 36

Bone divisions and classifications

Answer 36

Axial Skeleton:
- Skull
- Vertebral column
- Ribs
- Sternum
- Hyoid

Appendicular Skeleton
everything else

Shapes of bones

Long
Short
Flat
Irregular
Sesamoid
Pneumatic (bones containing air filled spaces / cavities)

Question 37

Describe the composition of bone

Answer 37

Inorganic component: Calcium Hydroxyapatite Crystals. contribute to strength + hardness of bones. Presence of minerals (esp calcium) provides bone with solid + rigid structure, resistant to compression

Organic component: Type I collagen
Collagen is a fibrous protein that imparts flexibility + resilience to bone. Provides elasticity + bone resist bending + twisting forces

Question 38

Describe the types of mature bone structure

Answer 38

2 types of mature bone structure:

1. Cancellous (spongy) Bone
   -spongy, porous structure with open spaces
   -lighter weight compared to compact bone
   -usually located in ends of long bones, within interior bones, areas where bone is not subjected to high mechanical stress
   -FUNCTION: FLEXIBILITY + CUSHIONS. CONTAINS SPACES THAT HOUSE BONE MARROW, WHERE BLOOD CELLS ARE PRODUCED
2. COMPACT (cortical) Bone: dense + solid with more homogenous structure.
   Heavier + stronger compared to cancellous bone
   LOCATION: compact bone forms outer layer of all bones + shafts of long bones
   FUNCTION: structural support, strength, protection of internal components incl bone marrow

Question 39

Describe the organisation of compact (cortical) bone

Answer 39

Osteon - basic structural unit of compact bone (cylindrical)

Haversian (Central) Canal:
central channels within osteon, carries blood vessels, lymph vessels, nerves

Volkmann’s Canal (perforating canals) - connect haversian canals. Allow for passage of blood vessels, lymph vessels + nerves from periosteum to haversian (central) canals

Lamellar Structure of Osteon:
osteon has a lamellaer (layered) structure, with concentric rings of mineralized matrix called lamellae. Lamellae surround Haversian canal + provide strength to the osteon

Slippage Panes:
The lameller structure of the osteon provides slimage planes. Allows deformation + flexibility within bone. While bone is rigid, flexibility important for adapting to mechanical stress

Cortical bone surrounded by layer of fibrous connective tissue called periosteum

Periosteum important for bone health, growth. Contains blood vessels, nerves, cells involved in bone formation + repair. Attachment point for tendons and ligaments

Question 40

Describe the role of canaliculi in an osteon

Answer 40

Canaliculi = channels extending from osteocytes
Connect neighbouring osteocytes, allowing communication between them

Question 41

State where osteocytes are found within an osteon

Answer 41

Mineralised matrix

Question 42

Explain the communication process between neighbouring osteocytes

Answer 42

1. Osteocytes have slender cytoplasmic processes - extensions
2. Reach out to adjacent osteocytes via canaliculi (tiny channels)
3. Allows osteocytes to maintain contact with each other, facilitate exchange of nutrients + signalling molecules
4. Slender Cytoplasmic processes connect with each other via gap junctions
5. Gap Junctions enable passage of nutrients between adjacent osteocytes
6. Slender Cytoplasmic processes connect to Haversian canals
7. This allows osteocytes to receive nutrients + signals from blood vessels in Haversian canal.

Question 43

Gap Junctions

Answer 43

Specialised protein channels
Allow direct communication between cells

Question 44

Describe the organisation of spongy (cancellous) bone

Answer 44

1. No Haversian / Volkmann’s canals
2. Osteocytes reside in lacuna (small spaces or cavities within the bone matrix) between lamellae (same as cortical)
3. Lamellae are more irregular than in cortical

Question 45

Which cells carry out bone remodelling in spongy bone?

Answer 45

Bone remodelling - removal of old bone tissue, formation of new tissue
1. Osteoblasts
2. Osteoclasts

Question 46

State the location of osteoblasts and osteoclasts in spongy bone

Answer 46

Surface of trabeculae

Question 47

H&E photomicrograph of a section of
decalcified spongy (cancellous) bone

Answer 47

Question 47

Describe the process of bone remodelling

Answer 47

1. Process starts with CUTTING CONE, group of osteoclasts (specialist cells for breaking down + resorbing bone tissue). CUTTING CONE ACTIVELY REMOVES OLD DAMAGED BONE
2. REVERSAL ZONE: this region contains osteoprogenitor cells, undifferentiated cells, have potential to become osteoblasts. Osteoprogenitors involved in transition phase between bone resorption + bone formation
3. Closing cone: Osteoblasts (bone-forming cells) secrete organic components of bone (osteoid). Osteoid = unmineralised organic matrix of bone, provides framework for mineralization
4. Apiogenesis - formation of blood vessels. Important because supplies necessary nutrients + oxygen to the actively remodelling bone tissue

Question 48

State the role of an osteoclast

Answer 48

Break down bone during resorption phase

Question 49

State the role of an osteoblast

Answer 49

Lay down new bone during formation phase by secreting osteoid

Question 50

State the role of osteocytes

Answer 50

Mature osteoblasts
Become embedded in mineralised matrix
Metabolically active + maintain bone tissue

Question 51

Describe the bone remodelling unit

Answer 51

Consists of

1. Cutting zone
2. Reversal zone
3. Closing cone

Question 52

Photomicrograph of a cutting
cone (H&E)

Answer 52

Question 53

Describe which factors influence the pattern + extent of bone remodelling

Answer 53

1. Mechanical loading: forces + stresses experienced by bone during activities (weight bearing + movement). Osteoclasts are sensitive to mechanical loading - respond to mechanical forces applied to bone tissue
2. Reduced gravitational forces: Bone resorption increases when gravitational forces reduced. Eg situations incl: long period of bed rest, space travel, reduced weight bearing

Age: bone remodelling decreases with age. Increasing age = shift in balance between bone resorption + bone formation = changes in bone density + structure

Increased sport activity + bone hypertrophy - increase in physical activity can lead to bone hypertrophy (increase in bone size / mass - increased cortical bone thickness)

Question 54

Describe the process of bone repair after fracture

Answer 54

Bone has a balance between flexibility + rigidity. Balance allows ability to withstand forces + resist fractures

Lamellae able to slip relative to each other. Allows bone to disperse forces. When external force is applied to bone, lamellae can adjust positions, distributing forces + preventing concentrated stress points that could lead to fractures

Fractures occur when forces applied to bone are too strong for its structural integrity to withstand

If the forces exceed the bone’s ability to flex + redistribute stress through the slipping of lamellae, it results in fracture

Question 55

Describe the stages of bone fracture repair

Answer 55

1. Haematoma: when bone fractures, blood vessels around + within fractured area are torn + bleed = accumulation of blood to area
   leads to formation of blood clot (haematoma)
   Haematoma stabilises fractured bone fragments
2. Soft (fibrocartilage callus): Clot is removed by macrophages + replaced by mass of procallus tissue comprised of fibroblasts + collagen
3. Hard (bony) callus: Fibrocartilage callus formed in previous step further transformed into hard bony callus. Due to invasion of callus by blood vessels + osteoblasts

Callus is invaded by blood vessels + osteoblasts. Fibrocartilage is gradually replaced by woven bone (immature bone tissue, provisional structure, gives stability to fractured area)

4. Remodelling: Woven bone remodelled as compact + spongy bone

Question 56

X-Ray showing stages of fracture repair

Answer 56