Block 5 W1

Question 1

What are the advantages and disadvantage of bipedalism?

Answer 1

+ frees our hand (increased manual dexterity)
+ elevates our head
+ walk on challenging terrain
- poses biomechanical challenge

Question 2

Why has the supporting rectangle of humans become smaller than quadrupedal primates?

Answer 2

In standing upright, essential that body’s centre of gravity remains directly over the supporting rectangle.

Question 3

Where did morphological changes necessary for bipedalism occur?

Answer 3

Vertebral column and lower limb.

Question 4

How do chimpanzees move bipedally?

Answer 4

Bent knee bent hip gait. Centre of mass = too anterior to base -> energetically costly.

Question 5

What is the role of the iliofemoral ligament?

Answer 5

The tension of the iliofemoral ligament prevents the truck rotating backwards at the hip joint.

Question 6

What is the role of the cruciate ligament?

Answer 6

Keeps upper body and thigh from falling forwards at the knee.

Question 7

What is the role of the vertebral curves?

Answer 7

Cancel out, passing weight directly to the lower limb. Cervical and lumbar lordosis balances body weight over the feet. Shock absorbers.

Question 8

Why is the human ilium wider than it is high?

Answer 8

Reduced height brings the sacroiliac joint closer to the hip joint, reducing stress on the ilium.

Question 9

Why is the iliac blade curved?

Answer 9

It is curved and medially-orientated, which brings the small gluteal muscles into a position where they can act as abductors of the thigh.

Question 10

What is the role of the abductors of the thigh?

Answer 10

Supports the pelvis when the body weight is on one leg and prevents side-to-side swaying of the trunk -> pelvis is kept stable.

Question 11

Why is the femoral head of humans different?

Answer 11

It is larger - adaptation to load bearing.

Question 12

What does the diagonal position of the femur achieve?

Answer 12

It re-centres support directly inferior to the trunk to make bipedal standing more efficient and to enable bipedal walking -> more stable.

Question 13

Why are the joint surfaces of the knee larger?

Answer 13

Load bearing.

Question 14

How is the knee joint stabilised?

Answer 14

By posterior + anterior cruciate ligament and medial + lateral collateral ligaments.

Question 15

Why does the knee have a locking mechanism?

Answer 15

For stability in a fully extended position.

Question 16

Describe the foot of primates and humans.

Answer 16

Primate - transverse arch running mediolaterally.
Humans - two part longitudinal arch to permit medial weight transfer during mid stance, acts as shock absorber and distributes body weight over the sole.

Question 17

What is torque?

Answer 17

When most skeletal muscle contracts, the bones to which they are attached rotate around a joint - rotational force.

Question 18

What is a lever?

Answer 18

A muscle level (moment) arm is the perpendicular distance to the point of rotation from the line of muscle action.

• force requires long ‘in’ lever and short ‘out’ lever (badger)
• speed requires short ‘in’ lever and long ‘out’ lever (cheetah).

Question 19

What are the challenges to bipedal locomotion?

Answer 19

• gravity and efficiency -> gravity acts at CoM of each body segment and may cause gravitational moments depending on how the limb is positioned.
• stability -> humans CoM = pelvis in midline, anterior to S2. Stability = BoS & CoM.
  So body is technically unstable but won’t fall due to ankle and hip strategy.

Question 20

What is the gait cycle?

Answer 20

Period from heel strike of one limb until the next time that heel hits the ground.

Question 21

What is the stance phase?

Answer 21

First 60% of the cycle from the time the heel strikes until the toe of the same foot begins to lift off the ground.

Question 22

What is the swing phase?

Answer 22

Remaining 40%, limb has lost contact with the ground. Toe off -> heel strike.

Question 23

Define concentric muscles?

Answer 23

Muscle length shortens

Question 24

Define eccentric muscles?

Answer 24

Muscle length increases.

Question 25

Define step vs. stride.

Answer 25

Step - distance from one heel to another (diff feet)

Stride - distance from same heel at the beginning and end of swing phase (same foot).

Question 26

Describe the walking pattern.

Answer 26

One foot is on the ground at all time.

Question 27

Describe the running pattern.

Answer 27

At some point, both feet are off the ground. Absorbing and releasing energy stored in tendons biomechanically makes running a series of controlled leaps.

Question 28

Describe the nervous system control of locomotion.

Answer 28

Receptors in muscles and joints provide info on body position and movement.
Cerebellum - motor correction and adjustments due to sensory and proprioceptive inputs.
Motor learning - improving performance of motor seq. with repitition.
Balance - coordinating muscle systems across the body.

Question 29

Describe the gait cycle in order.

Answer 29

1. Heel strike
2. Loading response
3. Midstance
4. Terminal stance
5. Preswing
6. Terminal swing
   7 Heel strike

Question 30

Describe heel strike (stance phase).

Answer 30

• Tibalis anterior lowers forefoot to the ground.
• Gluteus maximus continues deceleration.
• Intrinsic muscles of foot and long tendons of foot preserve the longitudinal arch of the foot.

Question 31

Describe loading response (stance phase).

Answer 31

• quadriceps accept the weight
• triceps surae decelerate mass
• gluteus medius and minimus + tensor of the fascia lata stabilise the pelvis.
• intrinsic muscle of foot + long tendons of foot preserve the longitudinal arch of foot.

Question 32

Describe the midstance (stance phase).

Answer 32

• quadriceps stabilise the knee
• triceps surae controls dorsiflexion
• gluteus medius and minimus + tensor of the fascia lata stabilise pelvis.
• intrinsic muscle + long tendons of foot preserve longitudinal arch of foot.

Question 33

Describe the terminal stance (stance phase).

Answer 33

• triceps surae accelerates mass
• gluteus medius and minimus + tensor of the fascia lata stabilise pelvis.
• intrinsic muscle + long tendons of foot preserve longitudinal arch of foot and fixes the forefoot.

Question 34

Describe the pre-swing (swing phase).

Answer 34

• hip flexors (rectus femoris) decelerate thigh and prepares for swing.
• long flexors of digits (flexor hallucis longus) accelerate mass.
• intrinsic muscle + long tendons of foot preserve longitudinal arch of foot and fixes the forefoot.

Question 35

Describe the initial swing (swing phase).

Answer 35

• hip flexors (rectus femoris) accelerate thigh and varies cadence.
• tibialis anterior clears the foot.

Question 36

Describe the mid-swing (swing phase).

Answer 36

• tibialis anterior clears foot.

Question 37

Describe the terminal swing (swing phase).

Answer 37

• hip extensors (gluteus maximus) decelerates thigh
• knee flexors (hamstrings) decelerate leg
• tibialis anterior positions the foot
• quadriceps extend knee to place foot and prepares for contact.

Question 38

How does ageing alter gait?

Answer 38

Ageing = decreased muscle bulk and stability.

Reduced stride length.

Question 39

How does arthritis or other degenerative conditions alter gait?

Answer 39

Reduces mobility of joint and causes pain -> limp.

Question 40

How does flip-flops alter gait?

Answer 40

• shorter steps
• heel hits ground with less force
• larger ankle angle
• shorter stride length

Question 41

How does high heels alter gait?

Answer 41

Shortens achilles tendon and shortens calf.

Question 42

What is antalgic gait?

Answer 42

Any gait that reduces loading on the affected extremity by decreasing stance phase time or joint forces as to avoid pain.
On painful side, shortened stance phase time, lengthened swing phase time and lengthened step length.
e.g. stone in the shoe, diabetic foot.

Question 43

What is ataxic (cerebellar) gait?

Answer 43

Unsteady, uncoordinated, wide base and feet thrown out - can’t stay steady, double tap.
e.g. MS, cerebellar disease.

Question 44

What is parkinsonian gait?

Answer 44

Involuntary short, accelerating steps, tiptoe, trunk forward and legs stiff.
e.g. Parkinson’s disease and conditions affect BG

Question 45

What is myopathic (waddling) gait?

Answer 45

Proximal pelvic girdle muscles weak - pelvis not stabilised thus tilts towards non-weight bearing leg.

Question 46

What is neuropathic (high stepping) gait?

Answer 46

Distal lower extremity affected due to foot dorsiflexors weak - lifts whole leg to avoid toe dragging.

Question 47

What is trendelenburg gait?

Answer 47

Hip paralysis prevents small gluteals functioning - pelvis drops.
To prevent fall, lumbar spine flexes forwards to bring centre of gravity over the foot.

Question 48

What is cox vara?

Answer 48

Decreased angle (< 120) of the femoral head -> mild shortening of lower limb = duck waddle gait.

Question 49

What is cox valga?

Answer 49

Increased angle (> 140) resulting from weakness of abductor muscle. Occurs in cerebral palsy and poliomyelitis.

Question 50

How does anterior cruciate ligament damage occur?

Answer 50

Deceleration or rational forces acting on weight-bearing limb may tear the ligament.

Question 51

What is pes planus?

Answer 51

Flat footed due to overweight.

Question 52

What are the functions of bone?

Answer 52

• protect organs
• provide support and rigidity in limbs
• haematopoiesis in marrow

Question 53

What is the origin of the skeleton?

Answer 53

Derived from neural crest (head) and mesoderm = somites (body).
Neural crest gives rise to bones of head through intramembranous ossification.
Bones of body form though endochondral ossification.

Question 54

What is neural crest?

Answer 54

A membrane within which bones form directly = intramembranous ossification.
Skull bone formed by radiating calcification.

Question 55

What is the role of somites bone development?

Answer 55

Vertebra and base of skull develop from somites.

Question 56

What are HOX genes?

Answer 56

Patterning genes that specify the identity of vertebra.

Question 57

Describe limb development.

Answer 57

• limb buds develop at 4-5 weeks.
• patterning genes guide morphogenesis
• gene on progress zone determine shape and length of the finger and what kind of finger
• hands develop then cells die from apoptosis between the fingers to form the finger

Question 58

What is ossification?

Answer 58

Cartilage and membrane formed genetically - they are converted to bone -> functional formation.

Question 59

Describe cartilage formation.

Answer 59

Chondroblasts make cartilage by forming chondrocytes by secreting ECM and trapping itself.
Chondrocyte maintains the secretion.
ECM is formed of fibres and ground substance.
Avascular so requires diffusion.

Question 60

Define lacunae.

Answer 60

Cavity within which the chondrocytes reside.

Question 61

Define interstitial and appositional growth.

Answer 61

Interstitial - growth in length

Appositional - growth in diameter.

Question 62

What is the epiphyseal growth plate?

Answer 62

Flow of cartilage cells from epiphysis to metaphysis - cartilage then ossified. Active site of endochondral ossification.

Question 63

List the different zones of cartilage.

Answer 63

1. zone of resting cartilage
2. zone of proliferating cartilage
3. zone of hypertrophic cartilage
4. zone of calcified cartilage

Question 64

Describe long bone morphology (compact).

Answer 64

Compact -> Haversian/central canal (blood vessels), Volkmann’s canal (vessels), lamellae, lacunae.

Question 65

What is a bone?

Answer 65

Bone is a connective tissue comprised of cells, fibres and mineralised ground substance.

Question 66

What are osteoblasts?

Answer 66

Deposit bone.
A osteoblasts surround themselves in ECM -> osteocytes.
When mineralised forms osteon.

Question 67

What are osteocytes?

Answer 67

Maintain bone and fluid flow between osteocytes.
Signals depending on stress to osteoblasts and osteoclasts for bone growth or removal.
Secretes collagen fibres.

Question 68

What are osteoclasts?

Answer 68

• removes bone
• multi-nucleated cells
• ruffled border
• creates trabeculae based on loading
• 50 monocyte derived
• released lysosomal enzymes and acids to digest bone

Question 69

What is a osteon?

Answer 69

Circular arrangement of collagen fibres and mineral.

Question 70

How does primary osteon become secondary?

Answer 70

Primary osteon is immature -> fracture/death -> secondary osteon.

Question 71

Define trabeculae.

Answer 71

Sections of cancellous bone - carved out of the bone.

Maintains strength and stops bone bending.

Question 72

Why is mechanical adaptation of bones necessary?

Answer 72

Helps prevent osteoporosis and allows bone healing.

Question 73

Describe the stages of fracture healing.

Answer 73

1. fracture haematoma
2. subperiosteal and endosteal cell proliferation
3. callus - woven bone
4. consolidation - woven to lamellar bone
5. remodelling by osteoclasts

Question 74

How is bone remodelled?

Answer 74

Osteoblasts and osteoclasts remodel bone.
First bone is woven -> collagen fibres random.
Replaced by lamellar bone -> collagen fibres arranged in parallel layers.

Question 75

What is surface remodelling?

Answer 75

This adapts the form of bones e.g. skull thus different shapes and sizes.

Question 76

Define osteoporosis.

Answer 76

Bone resorption > deposition.
Bone thinning and loss of mechanical integrity.
Trabeculae thinner -> increased risk of fracture

Question 77

What is the nervous system?

Answer 77

System of cells, tissues and organs that regulate the body’s response to internal and external stimuli.
Communication via electrochemical impulses.
Responds via action potential and NTs.

Question 78

What is the endocrine system?

Answer 78

Responds to stimuli by secreting hormones into circulatory system.
Slow - synthesis of hormone, release and effect.
Long lasting response.

Question 79

How is nervous system divided?

Answer 79

CNS - brain and spinal cord

PNS - sensory & motor divisions -> Somatic (voluntary) nervous system + ANS (SympNS + ParaNS)

Question 80

What is the main function of sensory part of nervous system?

Answer 80

Responsible for collecting info from internal and external environ.
Integrating, interpreting and assessing.
Creates, encodes and lays down memory.

Question 81

What is the main function of motor part of nervous system?

Answer 81

Responsible for producing effects in response to stimuli for homeostasis and modifying behaviour.

Question 82

What are somatic afferents and efferents?

Answer 82

External stimuli and voluntary skeletal muscle.

Question 83

What are visceral afferents and efferents?

Answer 83

Internal stimuli and involuntary, smooth and cardiac muscles + glands.

Question 84

Define neurone?

Answer 84

Functional unit of the nervous system, comprised of cell body (soma), multiple dendrites (input) and axons.

Question 85

Differentiate between cell bodies and axons in CNS and PNS.

Answer 85

CNS - cell bodies -> gray matter found in nuclei and cortex. Axons -> white matter and tracts (lemniscus, fasciculus, peduncles).
PNS - cell bodies -> ganglia. Axons -> nerves.

Question 86

Describe the cranial meninges.

Answer 86

3 layers of connective tissue:

• dura mata -> dense, very tough outer layer
• arachnoid mata -> delicate fibrous layer
• pia mata -> innermost layer

Question 87

What is meningitis?

Answer 87

Cranial meninges inflamed.
Pachymeningitis -> dura mata
Leptomeningitis -> arachnoid mata and pia mata.

Question 88

What are the meningeal spaces?

Answer 88

Extradural, subdural and subpial potential spaces.

Subarachnoid space filled with CSF.

Question 89

What is the telencephalon?

Answer 89

Cerebral cortex, subcortical white matter, basal ganglia.

Question 90

What is the diencephalon?

Answer 90

Thalamus, hypothalamus.

Question 91

What are the ventricles?

Answer 91

Cavity where CSF flows though.

Question 92

What does the cerebellum consist of?

Answer 92

2 lateral lobes + vermis.

Receives info from spinal cord about touch and proprioception.

Question 93

What does the brainstem consist of?

Answer 93

Midbrain
Pons
Medulla

Question 94

At what level does the spinal cord end?

Answer 94

L1-L2

Question 95

Describe the difference in white and grey matter in SC vs. brain?

Answer 95

SC - grey matter in centre and white matter surrounds.

Brain - grey matter outside forms the cortex and white matter inside.

Question 96

What are plexuses?

Answer 96

Network of nerves made of spinal/cranial nerves.
e.g. brachial plexus formed by C6-8 + T1 nerves.
Plexuses receive ventral roots.

Question 97

What does the dorsal and ventral rami supply?

Answer 97

Dorsal rami - strip of back

Ventral rami - everything else

Question 98

How are somites divided?

Answer 98

Myotomes and dermatomes - areas innervated by a single spinal nerve.
Can work out spinal segment lesion by which particular dermatome.

Question 99

If there is a lesion, why is their mixed sensory and motor problem?

Answer 99

Most nerve carry both sensory and motor components.

Question 100

How can peripheral nerve lesions be localised?

Answer 100

Pain -> motor, sensory and reflex loss in specific nerve distribution.

Question 101

How can spinal nerve root lesions be localised?

Answer 101

Radicular (shooting) pain - motor, sensory and reflex loss in specific root distribution.

Question 102

How can cerebral cortex lesions be localised?

Answer 102

Hemiplegia (paralysis), hemisensory loss, aphasia, neglect, hemianopia (loss of vision), dementia, seizure.

Question 103

How can dorsal root ganglion lesions be localised?

Answer 103

Sensory loss and reflex loss.

Question 104

How can spinal cord lesion be localised?

Answer 104

Neurogenic bladder.

Question 105

What is neuroectoderm?

Answer 105

The part of ectoderm that go on to form the nervous system.

Question 106

How does the neural tube form?

Answer 106

Boundaries between ectoderm rise and forms neural plate, the boundaries come together and zip up -> neural tube underneath the ectoderm.
Tube has fluid within.

Question 107

What does neural crest cells do?

Answer 107

Migrate to other regions e.g. hindbrain into pharyngeal arches. These form:
- bone, muscle, dentine, cranial nerves.

Question 108

What do cranial neural crest cells form?

Answer 108

• neurons and glia of cranial ganglia
• cartilage and bone
• connective tissue

Question 109

What do trunk neural crest cells form?

Answer 109

• pigment cells
• sensory neurons and glia
• sympathy-adrenal cells

Question 110

What does the neural tube form?

Answer 110

Brain and spinal cord

Question 111

What are somites and what do they form?

Answer 111

Specialised mesoderm - forms early vertebrae (MSK structures)

Question 112

What does endoderm form?

Answer 112

Gut

Question 113

What does notochord form?

Answer 113

Precursor to vertebral column.

Question 114

What does the prosencephalon (forebrain) divided into?

Answer 114

Telencephalon and diencephalon.

Question 115

What does the mesencephalon go on to form?

Answer 115

Midbrain and aquaduct

Question 116

What does the rhombencephalon (hindbrain) divide into?

Answer 116

Metencephalon and myelencephalon.

Question 117

What does the telencephalon go on to form?

Answer 117

Cerebral hemispheres and lateral ventricles.

Question 118

What does the diencephalon go on to form?

Answer 118

Thalami and third ventricles.

Question 119

What does the metencephalon go on to form?

Answer 119

Pons, cerebellum and upper part of 4th ventricle

Question 120

What does the myelencephalon go on to form?

Answer 120

Medulla and lower part of 4th ventricle

Question 121

What are the flexures of the developing brain?

Answer 121

• cranial flexure -> midbrain bends bringing hindbrain over top of forebrain.
• cervical flexure -> hindbrain also bends
• pontine flexure -> hindbrain folds again further pulling midbrain over the forebrain.

Question 122

Describe the growth of the telencephalon.

Answer 122

Telencephalon continues to grow over the diencephalon and midbrain. The flexures continue to grow, resulting in the formation of brainstem.
Sulci/gyri forms and telencephalon completely surrounds the diencephalon and midbrain, leaving only the hindbrain.

Question 123

Describe the ventricular system.

Answer 123

• Lateral ventricles occur on each side of hemisphere.
• Connect in midline and forms 3rd ventricle (in middle of 2 thalami).
• Connected to 4th ventricle via aqueduct around midbrain.
• 4th brain occurs around cerebellum/hindbrain.
• Continues into SC via central canal.

Question 124

What are the structures around the ventricles?

Answer 124

Basal ganglia/thalamus has lateral ventricle circling around it.
Caudate nucleus forms flow of lateral ventricle.
Hippocampus and fornix form around top of lateral ventricle.

Question 125

What is the internal capsule?

Answer 125

Major tract of fibres passing through diencephalon and basal ganglia and passes through gap between caudate nucleus and putamen.

Question 126

From what does the posterior (dorsal) horn derive from?

Answer 126

Alar plate (sensory)

Question 127

From what does the anterior (ventral) horn derive from?

Answer 127

Basal plate (motor)

Question 128

Which area does the ANS pass through?

Answer 128

Lateral horn

Question 129

Where does the efferent axons develop from?

Answer 129

Anterior horn cell bodies and grow out.

Question 130

Where does the afferent axons develop from?

Answer 130

Neural crest cells migrate and penetrate into posterior horn.

Question 131

Where do the parasympathetic and sympathetic nerves originate from?

Answer 131

P - cranial/sacral

S - thorax/lumbar

Question 132

Where do the cranial nerves originate?

Answer 132

Olfactory and optic - extensions of brain
Hypoglossal, oculomotor, tochlear, abducens - ventral root nerves (motor nerves).
Pharyngeal arch: 1 - trigeminal 2 - facial 3 - glossopharyngeal 4 - vagus

Question 133

Describe the components of cancellous bone.

Answer 133

40% organic -> type 1 collagen + non-collagenous proteins.

60% inorganic -> calcium hydroxyapatite

Question 134

Describe the bone remodelling cycle.

Answer 134

Quiescence -> resorption (osteoclasts release calcium phosphate ions into circulation) -> reversal -> formation (osteoblasts lay down unmineralised osteoid) -> mineralisation -> quiescence.

Question 135

What is the role of bone metabolism?

Answer 135

Drives bone remodelling

Maintains level of ionised ca2+ in blood within defined range.

Question 136

What are the signalling mechanisms involved in bone remodelling?

Answer 136

• parathyroid hormone
• vitamin D
• calcitonin
• growth hormone
• growth factors
• oestrogen
• cytokines

Question 137

Describe calcium metabolism.

Answer 137

Occurs for bone remodelling and physiological reasons e.g. muscle contractions.
1000g -> 99% skeleton 1% extracellular fluids and soft tissues.

Serum concentration - 2.25-2.6 mmol/L

Question 138

What are the 3 definable fractions of Ca2+?

Answer 138

• ionised Ca2+ -> 50%
• protein bound Ca2+ -> 40%
• complexed Ca2+ -> 10%
  Ca2+ levels maintained by PTH, VitD and calcitonin.

Question 139

Describe protein metabolism.

Answer 139

600g -> 85% skeleton 15% extracellular fluids as inorganic ions (HPO42-).
Concentrations vary widely by age, diet, pH, hormones.

Serum concentration - 0.9-1.3 mmol/L

Question 140

What are the 3 definable fractions of phosphate?

Answer 140

• ionised phosphate -> 55%
• protein bound -> 10%
• complexed phosphates -> 35%

Question 141

Describe the hydroxylation steps of VitD activation.

Answer 141

• synthesised in skin from 7-dehydrocholesterol by UV.
• 25-hydroxylation in liver makes 25(OH)D3 (main circulating form).
• 1-hydroxylation in kidney makes 1,25 (OH)2 vitamin D3 (active).

Cholecalciferol

Question 142

What is 1,25 (OH)2 vitamin D3?

Answer 142

Principle hormonal form of VitD.

Production is tightly regulated and stimulated by PTH and inhibited by elevated Ca and P.

Question 143

What is the action of 1,25 (OH)2 vitamin D3?

Answer 143

• increases Ca2+ and phosphate absorption from intestine.
• mobilises Ca2+ and phosphate from bone
• induces marrow monocytes to differentiate into osteoclasts for bone resorption.

Question 144

What is parathyroid hormone?

Answer 144

84 AA polypetide
Half life 20mins
Secreted by parathyroid gland in response to low plasma Ca2+ levels.

Question 145

What are the actions of PTH?

Answer 145

• high levels stimulates osteoclastic bone resorption

- low levels stimulate osteoblastic bone formation

Question 146

What are the effects of PTH?

Answer 146

• decreases renal Ca2+ excretion
• increases renal production of active D3
• increased Ca2+ absorption from intestine via VitD
• increases blood Ca2+ levels.

Question 147

What is parathyroid hormone related protein (PTHrP) and its effects?

Answer 147

Product of normal and malignant cells (tumours).
Required for normal development, regulator of proliferator and mineralisation of chondrocytes.
Acts locally.
Acts systemically when secreted in excess.

Question 148

What is calcitonin and its effect?

Answer 148

32 AA sequence
Released from C cells in thyroid gland in response to high plasma Ca2+ levels.

Reduces bone resorption by activated calcitonin receptors expressed by osteoclasts.

Question 149

Describe the Ca2+ homeostasis.

Answer 149

Decrease

• induces PTH secretion
• mobilises Ca2+ from bones
• decreases renal Ca2+ excretion and increases renal synthesis of VitD
• enhances Ca2+ mobilisation and absorption.

Increase

• increases calcitonin levels by inhibiting resorption
• decreases VitD synthesis.

Question 150

What is the role of oestrogen in bone turnover?

Answer 150

Maintains bone mass

• reduces resorption by inhibiting osteoclastogenesis and function.
• oestrogen receptors expressed on osteoblasts and osteoclasts
• high oestrogen stimulates bone formation.

Question 151

What is the role of androgens in bone turnover?

Answer 151

Decreased androgen levels linked to lower bone density.

• correlation between hypogonadism and increased incidence of fractures
• decreases bone resorption by inhibiting osteoclasts.

Question 152

What are the causes of hypercalcaemia?

Answer 152

• primary hyperparathyroidism
• malignancy
• hyperthyroidism
• immobilisation
• VitD toxicity

Question 153

What causes hypocalcaemia?

Answer 153

• renal failure
• VitD deficiency
• prematurity (immature thyroid gland)

Question 154

What are primary hyperparathyroidism symptoms?

Answer 154

• excess PTH -> osteitis fibrosa cystica (replacement of bone with fibrous tissue)
• periosteal erosions, fracture, bone pain.
• kidney stones

Question 155

What is secondary hyperparathyroidism?

Answer 155

Physiological response to hypoglycaemia.

Question 156

What causes osteomalacia/rickets?

Answer 156

Type 1 collagen made but no mineralisation as less Ca2+.

• VitD deficiency
• malabsorption (surgery)
• renal disease
• lack of sunlight
• anticonvulsants inhibits 1,25 (OH)2 vitamin D3 synthesis

Inherited

• VitD-dependent rickets (VDDR) type 1 (1-hydroxylase deficiency)
• type 2 (resistance to 1,25 (OH)2 vitamin D3).

Question 157

What are the features of osteomalacia/rickets?

Answer 157

• Diffuse bone pain
• Muscle weakness
• Elevated alkaline phosphatase levels (osteoclasts)
• Decreased mineralisation
• Long bones -> bowing deformity.

Question 158

Define osteoporosis.

Answer 158

Net loss of bone mass due to resorption > formation.

Decreased bone mineral density and deterioration of bone microarchitecture -> increased susceptibility of fracture.

Question 159

What is the treatment of osteoporosis?

Answer 159

• calcium supplementation
• hormone replacement therapy
• bisphosphonates -> osteoclast inhibitors (alendronate, residronate)
• calcitonin
• selective oestrogen-receptor modulator (SERMs) -> ostrogen agonists (raloxifine)