Phase 2 - Week 1 (Bones, Osteoporosis, Fractures)

Question 1

Diaphysis

Answer 1

Central shaft of a long bone

Question 2

Epiphysis

Answer 2

Regions at either end of a long bone

Question 3

Epiphyseal Plate

Answer 3

Between diaphysis + epiphysis (also called growth plate)

Question 4

Metaphysis

Answer 4

Area adjacent to epiphyseal plate, part of bone where growth occurs

Question 5

Describe how bones grow

Answer 5

• During growth, the metaphysis is made of cartilage - more cartilage is produced to increase length of bone
• After puberty (by age 21) - epiphyseal plate becomes fully mineralised, becomes the epiphyseal line
• Growth in length = deposition of new cartilage at metaphysis and subsequent mineralisation/calcification of cartilage into new bone material

Question 6

Periosteum

Answer 6

Covers surface of bones, consists of an outer layer of tough fibrous tissue and an inner layer of osteogenic tissue (bone-forming tissue consisting of osteoblast cells)

Question 7

List the types of bone marrow and describe their functions

Answer 7

1. Yellow Marrow - stores adipose tissue

2. Red Marrow - contains Haematopoietic tissue which produces red blood cells

Question 8

Where is yellow bone marrow found?

Answer 8

In the medullary cavity - space running through centre of bone. Lined by osteogenic tissue - endosteum.

Question 9

Where is red bone marrow found?

Answer 9

In the epiphysis of long bones and in small, flat + irregular bones

Question 10

Describe the components of the bone matrix

Answer 10

Organic and inorganic components

Question 11

Describe the organic components of bone

Answer 11

Organic = osteoid - produced by osteoblasts, maintained by osteocytes (type 1 collagen + ground substance)

Question 12

Describe the inorganic components of bone

Answer 12

Inorganic = 50% of bone, hydroxyapatite (inorganic mineral - mineral salts e.g. calcium phosphate, calcium carbonate)

Question 13

Describe the major blood supply of bones

Answer 13

• Main supply is through the nutrient artery (in long bones enters into shaft)
• Enters bone at nutrient foramen, spreads through bone, supplies trabecular, compact bone etc.
• Periosteal BV (on outside of bone) supplies outside of bone

Question 14

How are Osteons supplied with blood?

Answer 14

Via their central canals.

Question 15

Describe the function of Volkmann’s canals

Answer 15

Transfer blood from the periosteum to central canals

Question 16

Describe the function of canaliculi

Answer 16

Canals which link lacunae, provide routes for nutrients to reach osteocytes/waste products to leave them

Question 17

List the types of bone tissue

Answer 17

1. Compact (dense/cortical)

2. Spongey (trabecular/cancellous)

Question 18

Describe the structure of Compact bone

Answer 18

• Outer part of all bones
• All of flat bones
• Dense, few spaces - protection + support (reduces stress of weight bearing in long bones)
• Functional units = Haversian systems/Osteons

Question 19

Osteons

Answer 19

• Contain a central canal with blood vessels, lymphatics + nerves
• Surrounded by concentric rings of lamellae (compact bone tissue) w/ lacunae (spaces) between containing osteocytes
• Canaliculi radiate from lacunae forming branching network

Question 20

Describe the structure of Spongey bone

Answer 20

• In epiphysis of long bones + pelvis, ribs, vertebrae, skull
• Thin bony plates of spicules of bone called trabeculae, between which are large spaces filled w/ bone marrow
• Compressive + tensile trabeculae
• Trabeculae contain lacunae containing osteocytes - nourished by blood in marrow cavities from BV penetrating spongey bone from periosteum

Question 21

Compressive Trabeculae

Answer 21

Arranged along line of force (vertically) to carry weight

Question 22

Tensile Trabeculae

Answer 22

Arranged horizontally for support

Question 23

List the types of bone cells

Answer 23

1. Osteoprogenitor cells
2. Osteoblasts
3. Osteocytes
4. Osteoclasts

Question 24

Explain maturation of bone cells

Answer 24

Osteoprogenitor cells –> Osteoblasts –> Osteocytes

Mononuclear phagocytic cells –> Osteoclasts

Question 25

Osteoprogenitor cells

Answer 25

• On surface of bone
• Become activated if there is injury
• Differentiate into osteoblasts

Question 26

Osteoblasts

Answer 26

• On surface of bone + line internal marrow cavities
• Have many mitochondria + Golgi apparatus for protein synthesis
• Secrete constituents of osteoid (organic matrix of bone) - type 1 collagen, proteoglycans + glycoproteins - important in mineralisation (calcification) of matrix
• Have receptors for parathyroid hormone + calcitriol

Question 27

Osteocytes

Answer 27

• Mature bone cells derived from osteoblasts
• In lacunae
• Adjacent osteocytes linked by cytoplasmic processes through canaliculi

Question 28

Osteoclasts

Answer 28

• Large multinucleated cells derived from fusion of several precursor cells - contain many mitochondria/lysosomes - Very mobile
• Responsible for resorption of bone - skeletal remodelling
• Abundant at surfaces undergoing erosion
• At site of contact with bone, microvilli that infiltrate disintegrating bone surface
• Calcium, phosphate + bone matrix constituents released into extracellular fluid
• Activity controlled by hormones - parathyroid hormone, calcitonin, thyroxine, oestrogens + metabolites of Vit. D

Question 29

Describe the main functions of bone

Answer 29

1. Protection/structural support
2. Attachment for muscles, tendons, ligaments allowing movement through articulation
3. Homeostasis of minerals (calcium + phosphate)
4. Haematopoiesis - red bone marrow
5. Storage of triglycerides

Question 30

Describe the functions of calcium in bone

Answer 30

• Calcification of bones gives strength, structural support and rigidity to bones
• Bone acts as a metabolic reservoir of calcium for extracellular homostasis
• Makes up most of inorganic ECM of bone as calcium hydroxyapatite, which gives bone rigidity

Question 31

Describe why calcium is needed throughout the body

Answer 31

1. Muscle contraction
2. Nerve excitability
3. Intracellular messenger
4. Blood coagulation

Question 32

Describe calcium in serum

Answer 32

• Either free (unbound/unionised), bound to albumin or complexed
• Free calcium is what regulates feedback mechanisms
• 50% of total serum calcium is bound to albumin

Question 33

How is serum calcium level measured

Answer 33

• Total = bound + free calcium

- Adjusted calcium = total adjusted to normal albumin level

Question 34

Hypercalcaemia

Answer 34

Serum calcium is too high

Question 35

Hypocalcaemia

Answer 35

Serum calcium is too low

Question 36

Normal serum calcium level

Answer 36

2.2-2.6mmol/l

Question 37

List the organs involved in calcium homeostasis

Answer 37

1. Gut - absorption of dietary calcium
2. Kidney - filtration + reabsorption of calcium
3. Bone - storage of calcium
4. Parathyroid glands - secrete PTH
5. Liver - helps production of calcitriol

Question 38

Where does the calcium in the body come from?

Answer 38

All calcium comes from diet (25 mmol/day)

Question 39

Describe how dietary calcium is absorbed

Answer 39

Absorbed by the gut - mainly duodenum + jejunum

• cell-mediated active transport pathway - controlled by calcitriol
• passive diffusion dependent on luminal calcium concentration

Question 40

Explain how calcium absorption in the gut is mediated

Answer 40

Proportion of calcium absorbed by active transport depends on calcitriol - can range from 20-60%. Calcitriol increases fractional absorption if dietary intake falls, during growth, pregnancy and lactation.

Question 41

Where will calcium absorbed from the gut be transported?

Answer 41

It is absorbed into the bloodstream - into plasma.

Question 42

Describe the role of the kidneys in calcium homeostasis

Answer 42

• Plasma is filtered by the kidneys
• 65% of calcium reabsorbed in PCT (coupled to bulk transport of solutes e.g. Na + water)
• 20% reabsorbed in thick ascending Loop of Henle
• 15% reabsorbed in DCT
• Reabsorption in Loop + DCT increased by effect of PTH
• Remainder excreted in urine

Question 43

Describe the mechanism of action of Parathyroid Hormone

Answer 43

Acts to vary the amount of calcium reabsorbed in kidneys and absorbed into bones + stimulates formation of calcitriol in kidneys to increase calcium absorption from gut.

Question 44

Where and why is PTH produced?

Answer 44

Produced in the parathyroid glands in response to low levels of free calcium

Question 45

How do the Parathyroid glands detect a change in free calcium levels?

Answer 45

Have calcium sensing receptors (G-protein coupled receptors) which sense levels of free calcium - main physiological ligand is calcium.

Question 46

Describe what happens to the level of PTH when calcium levels:

a) Increase
b) Decrease

Answer 46

a) PTH decreases
b) PTH increases
Small change in calcium produces large change in PTH

Question 47

Describe the series of events which occur when ionised calcium decreases

Answer 47

PTH -

• stimulates calcium reabsorption in renal tubules
• stimulates formation of calcitriol in kidney, which enhances calcium absorption from gut
• Promotes bone resorption - increase in number + activity of osteoclasts in bones, releasing calcium into blood
• Rise in iCa back to normal

Question 48

Explain how bone resorption affects calcium homeostasis

Answer 48

Bone resorption by osteoclasts releases calcium into the bloodstream, so if bone resorption is increased (by PTH) calcium level will be increased and if bone resorption is decreased (by calcitonin) calcium level will be decreased.

Question 49

Describe the series of events which occur when ionised calcium increases

Answer 49

• The parafolicular cells of the Thyroid gland secrete increased levels of Calcitonin
• Calcitonin stimulates an increase in number and activity of osteoblast cells in bone, preventing calcium release into blood
• Calcitonin also decreases the level of calcium reabsorption in the kidneys
• Decrease in ionised calcium levels back to normal

Question 50

Define Osteoporosis

Answer 50

Clinical condition characterised by compromised bone strength meaning there is an increased risk of fracture

Question 51

Explain the cause of Osteoporosis

Answer 51

• Imbalance between bone resorption + formation (resorption higher than formation)
• Decrease in oestrogen - increased RANK ligand as less OPG to block it
• Decrease in Oestrogen causes increase in bone resorption so bones become thinner + weaker
• Genetic predisposition

Question 52

Describe how bone density changes throughout a person’s lifetime

Answer 52

• Bone mineral acquisition occurs mainly during puberty - bones increase in length/diameter/trabecular thickness
• Peak bone density - age 21
• Consolidation of bone density - up to age 40
• Decline in bone density - age 40 onwards, much more dramatic in women (due to oestrogen)

Question 53

Describe the factors which affect peak bone density

Answer 53

1. Lifestyle - smoking, physical activity, alcohol intake
2. Nutrition - calcium intake
3. Hormones (growth hormones, oestrogen)
4. Genetic predisposition
5. Gender

Question 54

What is the affect of a drop in bone density?

Answer 54

Makes bones more susceptible to fractures - common fracture sites = distal radius, vertebrae and pelvis

Question 55

List the risk factors for osteoporosis

Answer 55

1. > 65 years old
2. Vertebral compression fracture
3. Fragility fracture after age 40
4. Family history of osteoporotic fracture (especially maternal hip fracture)
5. Malabsorption syndrome
6. Primary hyperthyroidism
7. Propensity to fall
8. Osteopenia
9. Early menopause
10. Rheumatoid arthritis
11. Low dietary calcium intake
12. Smoking
13. Excessive alcohol/caffeine
14. Weight <57kg/significant weight loss at 25 y/o
15. Long term heparin therapy

Question 56

List the complications of bone fractures due to Osteoporosis

Answer 56

1. Permanent disability
2. Pain
3. Deformity
4. Physical deconditioning
5. Loss of height
6. Kyphosis
7. Increased mortality
8. More likely to fracture again

Question 57

How is the risk of fractures determined?

Answer 57

Bone strength + extraskeletal conditions (propensity to fall + fall conditions)

Question 58

Describe how Osteoporosis is diagnosed

Answer 58

Based on T-score.

Question 59

Define T-Score

Answer 59

Number of standard deviations above/below mean for a healthy adult population of the same sex/ethnicity as the patient

Question 60

List the T-score range for:

a) Normal
b) Osteopenia
c) Osteoporosis
d) Established Osteoporosis

Answer 60

a) > -1
b) -1 to -2.5
c) < -2.5
d) < -2.5 + presence of one or more fractures

Question 61

What is the aim of treatment of Osteoporosis?

Answer 61

Reduction in fracture risk/number of fractures occurring

Question 62

Describe the non-pharmacological treatments for Osteoporosis

Answer 62

• Lifestyle changes - intake of dietary calcium, exercise, stop smoking, drink alcohol safely
• Minimise risk of falls - avoid drugs w/ risk of fall, identify + treat sensory deficits etc.
• Exercise increases bone density

Question 63

Describe the Pharmacological treatments for Osteoporosis

Answer 63

• Only used if non-pharmacological is ineffective
• ## Calcium + Vitamin D stop fracturesBisphosphonate is most common treatment - leads to bone remodelling - anti-resorptive, increases bone density + strength
• E.g. Alendronate/Alendronic Acid, Zolendronate, Risendronate, Etidronate
• Denosumab - monoclonal antibody, binds RANK ligand and inhibits osteoclast formation, function + survival, no longer have high bone resorption

Question 64

Define Fracture

Answer 64

Break in continuity of bone

Question 65

How are fractures classified?

Answer 65

1. Completeness of break
   - Complete or incomplete fracture
2. Break orientation
   - Transverse or linear
3. Bone position
   - Non-displaced or displaced
4. Severity of the break
   - Open or closed

Question 66

List some common fracture types

Answer 66

1. Open
2. Impacted
3. Comminuted
4. Compression
5. Greenstick
6. Spiral

Question 67

Open Fracture

Answer 67

• Also called a compound fracture
• Broken ends of the bone break through surface of skin
• Higher risk of infection
• Healing is much slower
• Commonly caused by high energy impacts e.g. falls/sports injuries

Question 68

Impacted Fracture

Answer 68

• One end of the fractured bone is forcefully driven into the other
• Similar to compression fractures, except force is applied to both ends of the bone
• Common in RTA/high falls

Question 69

Comminuted Fracture

Answer 69

• Bone breaks in a number of places - by splintering, crushing or breaking
• Pieces of the bone then lie between the two broken bone ends
• One of the most difficult fractures to treat
• More common in elderly patients - bones are more brittle

Question 70

Compression Fractures

Answer 70

• Almost exclusive to body of the vertebrae
• Commonly occur when porous vertebral body is crushed, usually from one direction
• Can affect more than one vertebra at one time
• Occur in elderly patients suffering from osteoporosis
• Also, healthy individuals after fall from a significant height

Question 71

Greenstick Fractures

Answer 71

• Occur in young, soft bone
• One side of the bone breaks and the other bends
• With age bones grow harder/more brittle - less likely to produce greenstick fracture
• Most during infancy/childhood when bones are soft + bend easily

Question 72

Spiral Fractures

Answer 72

• Also called torsion fracture
• Occurs when bone is twisted apart
• Result of excessive twisting force to bone
• Normally only detected by X-Ray + often mistaken for oblique fracture
• Tends to run parallel with the axis of the bone

Question 73

How is Vitamin D synthesised?

Answer 73

Vitamin D is made in the skin from 7-dehydrocholesterol under the influence of UV light.

Question 74

How is Vitamin D involved in calcium homeostasis?

Answer 74

Vitamin D is carried in the bloodstream to the liver, where it is hydroxylated to Calcifediol (25-hydroxycholecalciferol). Circulating Calcifediol may then be hydroxylated to Calcitriol (1,25-dihydroxycholecalciferol), the biologically active for of Vitamin D, in the kidneys

Question 75

Describe the action of RANK ligand

Answer 75

RANK ligand stimulates maturation of osteoclasts - binds to receptors, activation of osteoclasts, activated osteoclasts carry out bone resorption

Question 76

Describe the inhibition of RANK ligand

Answer 76

OPG is produced in response to oestrogen, it is a decoy receptor for RANK ligand - binds to RANK so it is not recognised by receptor so there is no bone resorption

Question 77

What is the function of OPG in a healthy person?

Answer 77

To stop constant bone resorption

Question 78

Define bone healing

Answer 78

Progressive process, body promotes the protection + repair of areas surrounding a fractured bone.

Question 79

How long does a fracture typically take to heal?

Answer 79

3-4 weeks for a simple fracture

Question 80

What factors affect the healing period of a fracture?

Answer 80

Location, severity, angle and type of fracture

Question 81

List the steps in bone repair

Answer 81

1. Fracture haematoma formation
2. Fibrocartilaginous callus formation
3. Bony callus formation
4. Bone remodelling

Question 82

Describe fracture haematoma formation after a fracture

Answer 82

• Blood vessels around bone are damaged when bone breaks - blood haemorrhages into surrounding area
• In 6-8hrs, pool of blood develops at site of fracture called fracture haematoma
• Formation of haematoma causes blood vessels to constrict and stop further bleeding
• In response to formation of haematoma - blood cells die causing inflammation + swelling around area of injury

Question 83

Describe fibrocartilaginous callus formation after a fracture

Answer 83

• Fibroblasts invade fracture site from periosteum
• Replicate, producing collagen fibres, intersperse w/ small BV and inflammatory cells to form granulation tissue
• Formation of granulation tissue leads to development of a fibrocartilaginous callus - islands of collagen fibres + cartilage
• Doesn’t provide structural rigidity - helps to bridge two ends of broken bone together

Question 84

Describe bone remodelling after a fracture

Answer 84

• FInal stage - remodelling of repaired portion of bone
• Osteoclast activity increases - removes dead/damaged cells around bony callus
• Spongey bone is replaced by strong, thick, stable area of bone where fracture was
• No complications + bones are correctly aligned = remodelling occurs successfully, injury heals completely

Question 85

Bone Remodelling in healthy bones.

Answer 85

Bone constantly undergoes remodelling - necessary for metabolic function in calcium/phosphorus storage.

Question 86

Describe the processes involved with bone remodelling

Answer 86

1. Bone resorption - loss of minerals + collagen fibres from bone under action of osteoclasts
2. Bone deposition - new layers of bone tissue formed under action of osteoblasts

Question 87

How is bone remodelling controlled?

Answer 87

Triggered by changes in mechanical forces or micro-damage and by hormonal responses to changes in calcium/phosphate

Question 88

Explain the role of the physiotherapist in bone fracture healing

Answer 88

• Muscle assessment - following fracture, muscles around fracture sight weaken. Physio prescribe safe exercise program to restore strength + prevent secondary complications
• Joint mobilisation - stop joint stiffness
• Heat + electrotherapy
• Gait education - e.g. crutches

Question 89

Describe the role of Physiotherapists in Osteoporosis treatment

Answer 89

• Can help strengthen bones + muscles
• Prevent bone thinning, reduce falls (improve balance), manage pain
• Weight bearing exercises (e.g. walking) can help to strengthen bones

Question 90

Extracellular Matrix (ECM)

Answer 90

• Complex network of proteins and polysaccharides

- Secreted locally by cells and remain closely associated with them

Question 91

Function of the ECM

Answer 91

Provides structural, adhesive and biochemical signalling signalling support

Question 92

Give examples of areas where there is an ECM

Answer 92

• Bone
• Tendon
• Cartilage
• BV walls
• Cornea
• Basement Membrane

Question 93

Describe the components of ECM

Answer 93

Fibres - e.g. collagen/elastin
and Ground Substances - e.g. Proteoglycans, Glycosaminoglycans
and Glycoproteins

Question 94

List some types of ECM

Answer 94

• Loose networks e.g. submucosa, allows movement
• Tightly woven 3D e.g. skin, resilient properties
• Unidirectional aligned e.g. Tendon, mechanical properties
• Calcified e.g. bone, mechanical properties

Question 95

Gives an example of ECM fibre synthesis

Answer 95

Collagen synthesised as procollagen, undergoes postranslational modifications (glycosylation, hydroxylation), assembled as a triple helix

Question 96

Describe how Proteoglycans are synthesised in the ECM

Answer 96

• Core protein synthesised on RER
• Addition of polysaccharide as disaccharide repeats in Golgi
• Delivered to extracellular compartment by exocytosis
• Assembly with other ECM components

Question 97

Describe ECM remodelling

Answer 97

Under action of Proteases, MMPs and Elastase, for wound repair, embryogenesis or angiogenesis.

Question 98

Describe Basement Membrane/Basal Lamina structure

Answer 98

• A thin, tough sheet of ECM
• 3 layers - lamina lucida, lamina densa + lamina fibroreticularis
• Composed of collagen, laminin (glycoprotein), perlecan (proteoglycan), entactin + fibronectin (glycoprotein)

Question 99

List some disorders of the Basement Membrane

Answer 99

1. Cancer - epithelial tumours are malignant once they breach the BM
2. Epidermolysis bullosa - failure in attachment of epidermis to BM

Question 100

Rickets

Answer 100

• If epiphysis has not fused (in children/adolescents)

- Newly formed bone of the growth plate does not mineralise, causing the growth plate to become thick, wide + irregular

Question 101

List the regions of the spine and number of vertebrae in each region

Answer 101

Cervical - 7 vertebrae
Thoracic - 12 vertebrae
Lumbar - 5 vertebrae
Sacrum - 5 fused vertebrae
Coccyx - 4 fused vertebrae

Question 102

Describe the curves of the spine

Answer 102

• Lordosis (concave anterior) in the cervical and lumbar regions
• Kyphosis (concave anterior) in the thoracic and sacral regions

Question 103

Describe the features of typical vertebrae

Answer 103

• Vertebral body
• Neural arch
• Vertebral foramen
• Pedicles
• Intervertebral foramina
• Laminae
• Transverse processes
• Inferior articular processes
• Superior articular processes
• Spinous process

Question 104

Describe the facet joints between vertebrae

Answer 104

Formed from the inferior articular process of the vertebra above and the superior articular process from the vertebra below

Question 105

Describe the structure of intervertebral discs

Answer 105

Centre is made of fluid filled, gelatinous Nucleus Pulposus which acts as a shock absorbed and is surrounded by the outer Annulus Fibrosis which is tougher and helps to contain the Nucleus Pulposus.

Question 106

List the major ligaments which support the spine

Answer 106

1. Nuchal ligaments
2. Anterior longitudinal ligament
3. Posterior longitudinal ligament
4. Ligamenta Flava

Question 107

Why is the spine curved

Answer 107

Increases mobility and ability to bear axial load

Question 108

Which spinal curves are primary and which are secondary?

Answer 108

Thoracic and sacral kyphosis are primary curves, cervical and lumbar lordosis are secondary curves

Question 109

When and why do the secondary curves of the spine form?

Answer 109

Spine is C-shaped at birth. Cervical lordosis develops at 6 months to allow lifting of head/head control. Lumbar lordosis develops at 10-14 months to allow standing/walking.

Question 110

Scoliosis

Answer 110

Abnormal lateral curvature of the spine

Question 111

Why is abnormally increased kyphosis often seen in the thoracic spine of elderly people?

Answer 111

Due to osteoporotic compression fractures

Question 112

What parts of the spinal column are easily palpable?

Answer 112

The spinous processes of the vertebrae

Question 113

What is the easily palpable spinous process in the cervical spine?

Answer 113

C7 (vertebra prominens)

Question 114

What is the surface anatomy landmark for:

a) T3?
b) T7?
c) L4/5?

Answer 114

a) level of base of spines of scapulae
b) level of inferior angle of the scapula
c) level of iliac crests

Question 115

What is significant about L1/2?

Answer 115

The spinal cord terminates, forming the Cauda Equina below

Question 116

What is a dermatome?

Answer 116

An area of skin supplied by a specific spinal nerve root and spinal segment

Question 117

Describe the movements that occur in the spinal column and where they occur

Answer 117

1. Flexion/extension - cervical and lumbar (50% in cervical is at atlantoaxial joint).
2. Rotation - thoracic.
3. Lateral flexion - cervical, thoracic + lumbar

Question 118

Where do most vertebral fractures occur and why?

Answer 118

At the junction between cervical and thoracic regions and thoracic and lumbar regions as the thoracic region is relatively immobile - biomechanical increase in stress between a stiff and moveable segment

Question 119

What is a tendon reflex?

Answer 119

An involuntary muscle contraction response to the sudden stretch of its tendon. It can be used to test the integrity of a 2 neurone reflex arc innervated by a single segment of the spinal cord.

Question 120

Myotome

Answer 120

Group of muscles supplied by a specific spinal nerve root

Question 121

Describe which imaging modalities use ionising radiation

Answer 121

1. X-Rays
2. CT scans
3. Fluoroscopy
4. Nuclear Medicine

Question 122

Describe the structure of C1 (atlas)

Answer 122

• Flat, wide superior articular surfaces which articulate with the occipital condyles
• Large vertebral foramen for brain stem/top of spinal cord
• Transverse foramen for the vertebral arteries
• No vertebral body
• Articular facet for odontoid process of axis (C2)
• Anterior + posterior arches

Question 123

Describe the structure of C2 (axis)

Answer 123

• Odontoid process which articulates with C1 for movement of the head
• Transverse foramen for the vertebral arteries
• Vertebral body

Question 124

Explain how to describe a radiology image

Answer 124

1. Imaging Modality
2. Plane/view (if X-ray)
3. Area of body
4. Side of body (L/R)
5. Adult or child patient
6. T1 or T2 weighted if MRI

Question 125

Explain the difference between T1 and T2 weighted MRI scans

Answer 125

T1 - Fat shows up white, water (CSF) and air show up black

T2 - Water (CSF) shows up white, fat and air show up black

Question 126

Describe structural differences between vertebrae of the different regions of the spine

Answer 126

Cervical
- Small vertebral body
- One vertebral foramina, 2 transverse foramina for vertebral arteries
- Small, bifid spinous processes
- Articular facets - superior faces posterosuperior, inferior faces anteroinferior
Thoracic
- Larger vertebral body
- Long, fairly thick spinous processes that mostly project inferiorly
- Have articular facets for ribs
- Articular facets - superior faces posterolateral, inferior faces anteromedial
Lumbar
- Largest vertebral body
- Short and blunt spinous processes - project posteriorly rather than inferiorly
- Articular facets - superior faces medial, inferior faces lateral