Cardiovascular

Question 0

Which germ layer does the cardiovascular system originate from?

Answer 0

Haemangioblasts which form in ‘blood islands’ in the splanchnic mesoderm

Question 1

What embryological process puts the veins of the heart behind the arteries?

Answer 1

Looping of the primitive heart tube

Question 2

What primitive structures develop into the right atrium?

Answer 2

Most of the primitive atrium and the sinus venosus

Question 3

What primitive structures develop into the left atrium?

Answer 3

Sinus venosus and some of the primitive atrium.

Question 4

Where is the oblique pericardial sinus found?

Answer 4

The cul de sac of the pericardium underneath the heart formed by the process of looping.

Question 5

Where is the transverse pericardial sinus found and what is it useful for clinically?

Answer 5

Where the pericardial sac meets at the top of the heart, between the superior vena cava and the aorta/pulmonary artery.
Clamp to put the heart on bypass.

Question 6

What is the ductus arteriosus and where can it be found?

Answer 6

It is a fetal shunt that allows blood to bypass the lungs during gestation. It connects the pulmonary artery to the proximal descending aorta.

Question 7

Which embryological aortic arch develops into the mature aortic arch?

Answer 7

Arch 4

Question 8

Why does the laryngeal nerve descend further down on the left than the right?

Answer 8

Descends to t4/5 on the left and only t1/2 on the right because on the left it has to go around the ductus arteriosus but on the right apoptosis of the primitive aortic arches allows it to be shorter.

Question 9

Name the three types of artery and how you would identify them in a histological slide.

Answer 9

Elastic - thick Tunica media with lots of elastin
Muscular - thick tunica media with lots of smooth muscle
Arterioles - thin tunica media

Question 10

Name three types of capillary and give an example of where they can be found.

Answer 10

Continuous - skeletal muscle
Fenestrated - endocrine glands
Sinusoidal - liver, spleen

Question 11

What are the layers of a blood vessel from superficial to deep?

Answer 11

Tunica adventitia - connective tissue
Tunica media - extra cellular elastic
Tunica intima - 1 cell thick with internal elastic lamina

Question 12

Which type of blood vessels contain valves?

Answer 12

Veins and venules

Question 13

What are venae comitantes and give an example of where they can be found?

Answer 13

A pair of veins that follow an artery, encapsulated in a sheath of fascia eg brachial artery

Question 14

What are vasa vasorum?

Answer 14

Blood vessels that supply and drain other large vessels such as the aorta. Found in the tunica adventitia.

Question 15

What are the atrioventricular valves called?

Answer 15

Left - mitral, bicuspid valve

Right - tricuspid valve

Question 16

Describe the seven phases of the cardiac cycle.

Answer 16

1. Atrial contraction
SA node fires to AV node
2. Isovolumetric contraction
Septum, bundle of His, inner to outer surface of the ventricles contract
3. Rapid ejection
4. Reduced ejection
5. Isovolumetric relaxation
6. Rapid ventricular filling
7. Reduced ventricular filling

Question 17

Distinguish systole from diastole.

Answer 17

Systole - contraction

Diastole - relaxation

Question 18

During which phases are both the mitral valve and the aortic valve closed?

Answer 18

Isovolumetric contraction and isovolumetric relaxation.

Question 19

Why is a small amount of valve regurgitation normal?

Answer 19

A small amount of blood must regurgitate back to close the valve.

Question 20

At what stage of the cardiac cycle does the aortic valve open?

Answer 20

Rapid ejection

Question 21

At what stage of the cardiac cycle does the mitral valve open?

Answer 21

Rapid ventricular filling

Question 22

What is the first stage of septation in the development of the cvs and where does it occur?

Answer 22

Formation of emdocardial cushions in the atrioventricular canal

Question 23

Describe the process of septation of the atria.

Answer 23

1. Growth of septum primum and the hole underneath it - the ostium primum
2. Before this is complete, the ostium secundum forms within it by apoptosis.
3. The septum secundum forms behind it with a hole in it known as the foramen ovale

The process allows blood to constantly flow from right to left which is necessary for intrauterine life. After septation blood flows from the right atrium to through the foramen ovale to the left atrium through the ostium secundum

Question 24

Describe the process of septation of the ventricles.

Answer 24

1. Muscular growth of the primary inter ventricular foramen

2. Membranous growth of connective tissue, proliferating from the endocardial cushions to fill the gap.

Question 25

What is the name of the fetal shunt which bypasses the liver and what is the name of its remnant in the adult?

Answer 25

Ductus venosus - ligamentum venosum

Question 26

What is the name of the fetal shunt which bypasses the lungs to prevent deoxy blood missing with oxy. And what is the name of its remnant in the adult?

Answer 26

Ductus arteriosus - ligamentum arteriosum

Question 27

What is the name of the fetal shunt which allows blood flow between the atria in order to bypass the lungs, and what is the name of its remnant in the adult?

Answer 27

Foramen ovale - fossa ovalis

Question 28

What is the name of the fetal shunt which provides nutrients to the fetus and what is the name of its remnant in the adult?

Answer 28

Umbilical vein - ligamentum teres

Question 29

Which arteries originate at the aortic trunk?

Answer 29

Right to left
Brachiocephalic
Common carotid
Subclavian

Question 30

Describe the layout of the coronary arteries.

Answer 30

Right coronary - right marginal

Left coronary - left anterior descending, left marginal, left circumflex

Question 31

What are the names, locations and functions of the two vascular sinuses?

Answer 31

Aortic sinus
Opening in the aorta behind the aortic valve
Allows coronary arteries to fill during diastole

Coronary sinus
Drains to the right atrium on the posterior surface
Drainage of the coronary veins

Question 32

What embryological feature do the cardiac auricles originate from? What is their function in the adult?

Answer 32

Embryological atria

Can expand the capacity of the adult atria if required

Question 33

What causes heart looping to occur?

Answer 33

Continual growth of the heart tube in the pericardial cavity which does not stretch or grow.

Question 34

What is the embryological derivative of the left ventricle?

Answer 34

Primitive ventricle

Question 35

What is the embryological derivative of the right ventricle?

Answer 35

Bulbus cordis

Question 36

What does the process of septation achieve?

Answer 36

Divides right and left heart, keeping blood flowing right to left at all times.

Question 37

Describe the cardiac action potential.

Answer 37

1. Voltage gated Na channels open - depolarisation
2. Na channels start to inactivate - pointy bit on graph
3. Voltage gated Ca channels open, balanced with leak K channels - plateau
4. Ca channels inactivate, delayed voltage gated k channels open - hyperpolarisation

Question 38

Describe the action potential at the SA node.

Answer 38

1. Hyperpolarisation triggers HCN channels Na slow influx - depolarises to threshold
2. Voltage gated Ca channels open - full depolarisation
3. Voltage gated k open - hyperpolisation

Question 39

What causes the natural automacity of the SA node?

Answer 39

The funny current

Question 40

When the action potential reaches cardiac myocytes, what is the molecular process that causes contraction?

Answer 40

1. Ach release
2. Beta 1 adrenoceptors - Gs protein - camp pathway - pka activates ca channels - Ca release
3. Ca - Ca positive feedback via ryanodine receptor
4. Ca binds to troponin - moves tropomyosin
5. Myosin binds to actin heads

Question 41

When the action potential reaches blood vessel smooth muscle cells, what is the molecular process that causes vasoconstriction?

Answer 41

1. Ach release
2. Alpha 1 adrenoceptor - Gq protein - IP3 pathway - Ca release
3. Ca activates myosin light chain kinase
4. MLCK phosphorylates myosin
5. Myosin binds to actin heads

Question 42

Which type of heart defects are acyanotic? Which are cyanotic?

Answer 42

Acyanotic - left to right shunts

Cyanotic - right to left shunts

Question 43

Give three examples of congenital heart defects which cause a left to right shunt.

Answer 43

Just a hole-
Atrial septal defects - eg patent foramen ovale
Ventricular septal defects
Patent ductus arteriosus

Question 44

Give an example of a congenital heart defect which causes a right to left shunt.

Answer 44

Tetralogy of Fallot

Question 45

What needs to go wrong in the heart for there to be a right to left shunt defect?

Answer 45

Hole + increased pressure from the right eg pulmonary stenosis or right sided hypertrophy in heart failure

Question 46

What are the consequences of a left to right shunt defect?

Answer 46

ASD - Blood goes to the lungs twice so increase in pulmonary pressure
Increased preload on right heart. Eventual right heart failure

VSD - (as above plus…) High pressure blood goes to the lungs twice so lung damage and the left heart’s effort is wasted. Cardiac output has to increase so left heart fails.

Question 47

Describe the 4 defects associated with tetralogy of fallot.

Answer 47

1. Ventricular septal defect
2. Aorta stems from both ventricles
3. Pulmonary artery squashed
4. Right ventricular hypertrophy

Question 48

Why do people with tetralogy of fallout tend to live for years without diagnosis?

Answer 48

Squashed pulmonary artery increases pressure on the right. This balances out the ventricular defect and prevents left to right shunt.

Question 49

What would be the prognosis for a patient with tetralogy of fallot left untreated? What is the treatment given to a baby?

Answer 49

Blood bypasses the lungs, so cyanotic, exercise intolerance, potential for hypoxia and sudden death

Prostaglandin e1 to keep the ductus arteriosus open

Question 50

Which arteries branch off the celiac trunk? Which vertebra is it level with? What does it supply?

Answer 50

Splenic artery
Left gastric artery
Common hepatic artery
At level of t12 to supply the foregut

Question 51

What is the main process which maintains the venous pressure?

Answer 51

Starling’s law - increase vp, increase Stoke volume. More in more out.

Question 52

What are the main processes which determine the arterial pressure.

Answer 52

Total peripheral resistance

Baroreceptors in carotid sinus

Question 53

Outline Starlings law of the heart.

Answer 53

Increase venous pressure, increase filling, increase stroke volume. More is removed from the veins each beat, regulating the venous pressure back down to normal.

Question 54

Define contractility of the heart.

Answer 54

The inherent ability to contract caused by the strength and stretch of bonds between actin and myosin fibres.
Increase contractility with the same venous pressure, increase stroke volume.
But only till the point where the ventricle has been stretched to its maximum.

Question 55

How do the baroreceptors in the carotid sinus work?

Answer 55

Carotid sinus is a weaker wider area of arterial wall that is sensitive to pressure.
Decrease pressure signals to the medulla - increase sympathetic to increase contractility (b1 adrenoceptors) and decrease parasympathetic to increase heart rate (m2 muscarinic)

Question 56

What is cardiac output made up of?

Answer 56

Stroke volume and heart rate

Question 57

Define total peripheral resistance. Which factors can influence it?

Answer 57

Total force opposing blood flow in the vasculature. Mainly produced in the arterioles.
Viscosity of blood, diameter of vessel, turbulent flow.

Question 58

If my heart rate (only) was artificially increased, how would my body return it to normal?

Answer 58

Increase cardiac output, decrease venous pressure, decrease stroke volume, decrease heart rate (starlings law that in equals out)

Question 59

How does the body regulate against postural hypotension (normally)?

Answer 59

Decrease venous pressure, decrease cardiac output, decrease arterial pressure, baroreceptors increase heart rate and increase resistance by vasoconstriction.

Question 60

Give an example of a situation when the baroreceptors reflex is not beneficial. How does the body deal with that situation?

Answer 60

Haemorrhage. Decrease arterial pressure makes the baroreceptors increase hr and vasoconstrict so there is an increase in blood loss.

Instead auto transfusion (shunted out of capacitance vessels) from nearby tissue and veno constriction can help temporarily.

Question 61

How does the body self regulate blood pressure after light activity or digestion which increase local vasodilation?

Answer 61

Increase in local vasodilation, decrease in total peripheral resistance, increase venous pressure and decrease arterial pressure
Increase cardiac output
Decrease venous pressure and increase arterial pressure

Question 62

How would an increase in total peripheral resistance affect venous and arterial blood pressures?

Answer 62

Arterial pressure increase

Venous pressure decrease

Question 63

How would an increase in cardiac output affect venous and arterial blood pressures?

Answer 63

Increase arterial pressure

Decrease venous pressure

Question 64

Why can the body not self regulate long term hypertension?

Answer 64

Increase venous pressure, increase cardiac output, increase arterial pressure, increase total peripheral resistance, increase arterial pressure, self perpetuating.

Question 65

What is a normal bp in the aorta?

Answer 65

120/80

Question 66

What is a normal bp in the right atrium?

Answer 66

5 (no systolic pressure)

Question 67

What is a normal bp in the right ventricle?

Answer 67

20/5

Question 68

What is a normal bp in the pulmonary artery?

Answer 68

20/10

Question 69

What is a normal bp in the left atrium?

Answer 69

5 (no systolic)

Question 70

What is a normal bp in the left ventricle?

Answer 70

120/5

Question 71

What is a normal bp in the right ventricle ?

Answer 71

20/5

Question 72

Why does the diastolic remain higher in the blood vessels than the ventricles?

Answer 72

Elastic recoil in the blood vessels maintains the pressure between beats

Question 73

Define the mean arterial pressure. What does it represent? How is it calculated? What is a normal value?

Answer 73

Average pressure for a single cardiac cycle. Represents perfusion to tissues.
=2/3diastolic pressure+1/3systolic pressure
=70-110

Question 74

What is the pressure and resistance like in the pulmonary circulation? How is this achieved?

Answer 74

Pressure and resistance are low created by lots of capillaries in parallel providing a high surface area.

Question 75

What is hypoxic pulmonary vasoconstriction? Give an example of a causal factor.

Answer 75

Physiological process in which less well ventilated alveoli are vasoconstricted so that the blood is redirected to well ventilated alveoli.

Caused by poor ventilated alveoli by eg mucus or infection

Question 76

What is the optimum ventilation/ perfusion ratio?

Answer 76

0.8

Question 77

How does an increase in venous pressure cause oedema?

Answer 77

Increase venous pressure, increase hydrostatic force out of the capillary so that it is greater than the oncotic force into the capillary.

Question 78

What is the pressure and resistance like in the cerebral circulation? How is this achieved?

Answer 78

Pressure and resistance are low created by lots of capillaries in parallel providing a high surface area.

Question 79

What happens if neurones are without oxygen for a small amount of time? Why does this happen?

Answer 79

Faint - very sensitive to hypoxia because they constantly need to do oxidative phosphorylation. No glycogen stores, no creatine phosphate stores and can’t use fatty acids as they don’t cross the barrier. Can use ketones.

Question 80

What is myogenic autoregulation?

Answer 80

Auto regulation of the pressure in the arterioles without any cvs involvement. Smooth muscle stretches, opens Ca channels, muscle depolarises and contracts.

Question 81

What is distinctive about a true capillary?

Answer 81

No smooth muscle

Question 82

What is the function of a precapillary sphincter? Give an example.

Answer 82

Block blood from entering the whole capillary bed, saving it for a more urgent purpose.
Eg, in a fight or flight response, pre capillary sphincters in the mesentery block the blood from the intestine so it can go to the muscles.

Question 83

What is cushings reflex seen in response to raised intracranial pressure?

Answer 83

Raised intracranial pressure raises pressure of cerebrospinal fluid higher than mean arterial pressure, compressing the arterioles. The reflex attempts to restore blood flow to the ischaemic brain.

1. Increased sympathetic - increased force of contraction and blood pressure and tachycardia
2. Baroreceptors respond with an increased parasympathetic - leading to bradycardia but pressure remains high to push into brain
3. Pressure on brain stem leads to irregular breathing

Question 84

How do the coronary arteries fill?

Answer 84

Through the aortic sinus during diastole

Question 85

What causes angina?

Answer 85

Hypoxia in the coronary arteries causes pain. It only occurs on exercise because this is when diastole is shortened so the coronary arteries aren’t given long enough to fill.

Question 86

Give three possible mechanisms of arrhythmia.

Answer 86

1. Ectopic pacemaker activity - ischaemic area spontaneously depolarises
2. After depolarisations - extra depolarisation during the action potential. Can be early or late.
3. Re entry loops - conduction damage leads to abnormal route of excitation.

Question 87

What increases the risk of delayed after polarisations?

Answer 87

High cellular calcium

Question 88

What increases the risk of early after polarisations?

Answer 88

A long action potential - eg long qt syndrome

Question 89

What type of arrhythmia can be caused by ectopic pacemaker activity?

Answer 89

Ectopic beats

Question 90

What type of arrhythmia can be caused by delayed afterpolarisations?

Answer 90

Ectopic beats

Question 91

What type of arrhythmia can be caused by early depolarisations?

Answer 91

Flutter/fibrillation

Question 92

What type of arrhythmia can be caused by re entry loops?

Answer 92

Flutter/fibrillation

Question 93

Define heart failure.

Answer 93

Chronic failure of the heart to provide sufficient output to keep the body perfused due to muscle weakness/stenosis

Question 94

How do beta blockers work? What do they treat?

Answer 94

Antagonists of beta 1 adrenoceptors. Decrease ionotropy in the AV node. Decrease the rate of activation of the funny current at the SA node, decrease heart rate and therefore cardiac output.

Treat hypertension and supra ventricular tachycardia.

Question 95

How do Calcium channel blockers work? What do they treat?

Answer 95

Decrease the calcium in the cell, Decrease the slope at the SA node, decrease heart rate and cardiac output.
Also decreases force of contraction by decreasing the ryanodine positive feedback loop.
Treat hypertension and angina. Also diastolic heart failure

Question 96

How would K channel blockers work? Why are they not used?

Answer 96

Theoretically Lengthen the refractory period of the action potential, preventing any extra depolarisations.
But increase length of the action potential increases risk of early depolarisation so pro arrhythmic.
(Except amiodarone)

Question 97

How would Na channel blockers work? Why are they not used?

Answer 97

Blocks inactive Na channels so that the refractory period is maintained and there are no mistake depolarisations. Eg lidocaine.
Too many side effects

Question 98

How do cardiac glycosides work? What do they treat? What is a better option?

Answer 98

Eg digoxin. Block Na K ATPase so that the driving force for Na ca exchange is decreased and there is a build up of Ca which is perpetuated by the ryanodine loop - increase force of contraction.

Treat heart failure but don’t flog a dying horse - better to decrease the afterload with ace inhibitors

Question 99

How do ace inhibitors work? What do they treat?

Answer 99

Prevent angiotensin 1 to 2
Decrease Na and water reabsorption and vasodilation
Treat heart failure by reducing the load on the heart

Question 100

How do organic nitrates work? What do they treat?

Answer 100

Increase veno dilation to treat angina

Question 101

What is the relationship between blood pressure, cardiac output and total peripheral resistance?

Answer 101

Bp = co x tpr

Question 102

How do loop diuretics work? What do they treat?

Answer 102

Block NaKCl co transporter in the loop of Henle. Stops reuptake of these salts so stops water following. Increases water content of urine. Treats Hypertension.

Question 103

How would you interpret an ecg?

Answer 103

1. Rate
2. Rhythm
3. Axis
4. P wave - missing?
   - related to QRS?
5. PR segment length - 3-5 small squares
6. QRS length - 1-3 small squares
7. QT length - less than half r-r
8. T wave - elevation?
   - depression

Question 104

What do movements in the heart do the ecg letters PQRS and T refer to?

Answer 104

P - SA node, atria contract
Q - septum, ventricular endocardium contracts
R - main ventricular contraction
S - contraction spreads up the ventricle
T - relaxation of ventricles

Question 105

What is the pathophysiology of atrial fibrillation?

Answer 105

SA node starts to fire randomly (caused by ectopic pacemaker activity, after depolarisation, re entry loops), random contractions. So sometimes AV node takes over ventricular contractions.

Question 106

How would you identify atrial fibrillation on an ecg?

Answer 106

Absent p wave

Irregular rhythm

Question 107

What is the difference between 1st, 2nd and 3rd degree heart block?

Answer 107

1. SA struggles to transmit to AV but no AV takeover - prolonged PR
2. SA sometimes fails, AV sometimes takes over, regularly irregular - erratic PR, missed QRS
3. SA never transmits to AV, AV takes over completely - no relationship between P and QRS.

Question 108

How would you identify heart block on an ecg?

Answer 108

Prolonged PR interval or lack of relationship between P and the rest of the wave.

Question 109

What is the difference between heart block and bundle branch block?

Answer 109

Heart block is a block in conduction between the SA and AV nodes so is noted at the p wave. Bundle branch block occurs at the septum so it noted at the q wave.

Question 110

How would you identify bundle branch block on an ecg?

Answer 110

Rabbit ear QRS because two attempts made at getting through the block in the septum.

Question 111

How would you identify angina/ myocardial ischaemia on an ecg?

Answer 111

ST depression because the block is during diastole.

Question 112

How would you identify MI on an ecg?

Answer 112

ST elevation
Rabbit ear Q wave
Inverted T

Question 113

What is the common cause of left axis deviation?

Answer 113

Defects of the conduction system

Question 114

What is the common cause of right axis deviation?

Answer 114

Right ventricular hypertrophy

Question 115

If a patient had an abnormally short PR interval what would be a likely cause?

Answer 115

Wolf Parkinson White - an extra pathway known as the bundle of Kent is present.

Question 116

If there was ST elevation in leads II III and aVF where would the MI be?

Answer 116

Inferior

Question 117

If there was ST elevation in leads V3 and V4 where would the MI be?

Answer 117

Anterior

Question 118

If there was ST elevation in leads V1 and V2 where would the MI be?

Answer 118

Septal

Question 119

If there was ST elevation in leads I, aVL, V5, V6 where would the MI be?

Answer 119

Lateral

Question 120

What is sinus rhythm?

Answer 120

A p wave precedes every QRS complex

Question 121

What is the difference between Mobitz type 1 and type 2 second degree heart block?

Answer 121

Type 1 - delay gets longer and longer till there is a skipped QRS
Type 2 - irregular pattern

Question 122

What does it mean if there are tall peaked T waves?

Answer 122

If seen in all leads it is hyperkalaemia. Can be an early sign of MI.

Question 123

Give three possible cvs causes of chest pain

Answer 123

Ischaemic heart disease
Pericarditis
Aortic dissection

Question 124

What is ischaemic heart disease?

Answer 124

Occurs when 02 supply cannot meet demand of coronary arteries and they can become ischaemic.

Question 125

Give four causes/precipitants of ischaemic heart disease. Identify the most common one.

Answer 125

Decreased supply:
1. Tachycardia - shortened diastole
2. Anaemia
Increased demand:
1. Atheroma MOST COMMON
2. Aortic stenosis

Question 126

Which area of the heart is most vulnerable to ischaemia?

Answer 126

Endocardium, because it is the last area the blood flow of the coronary arteries reaches.

Question 127

What are the four types of ischaemic heart disease caused by atheroma?

Answer 127

Stable angina
Unstable angina
NSTEMI
STEMI

Question 128

What is crescendo angina?

Answer 128

Stable angina that becomes unstable.

Pain no longer transient
Increasing severity
More often, longer duration

Question 129

What is the difference between stable and unstable angina?

Answer 129

Severe: Occlusion more severe, can no longer cope at rest.

Question 130

What is the difference between unstable angina and an NSTEMI?

Answer 130

NSTEMI develops necrosis so biomarkers become positive.

Question 131

What is the difference between an NSTEMI and a STEMI?

Answer 131

Occlusion of the artery becomes complete so there is full thickness infarction.

Question 132

What are the classic ecg markers for a STEMI?

Answer 132

St elevation
Q enlarges
T inverts

Question 133

What are the classic ecg markers for stable angina?

Answer 133

Normal ecg at rest

ST depression during stress test

Question 134

What are the classic ecg markers for unstable angina?

Answer 134

ST depression

Question 135

What are the classic ecg markers for an NSTEMI?

Answer 135

ST depression

Question 136

What would be the diagnosis for a positive result for creatine kinase or troponin?

Answer 136

STEMI or NSTEMI

Question 137

How would you treat angina?

Answer 137

Aspirin

GTN spray
Statins
Beta/Ca channel blockers
Re vascularise

Question 138

How would you treat a STEMI?

Answer 138

Streptokinase
Emergency re vascularisation

GTN spray
Statins
Beta/Ca channel blockers

Question 139

How would you treat an NSTEMI?

Answer 139

Heparin

GTN spray
Statins
Beta/Ca channel blockers
Re vascularise

Question 140

What is a bruit? Where might they be found?

Answer 140

Audible turbulent flow of blood in an artery due to obstruction eg:

Aneurism
Thrombus

Question 141

What is the relationship between blood flow and radius of the vessel?

Answer 141

Flow is proportional to radius to the power of 4.

So decrease radius leads to massive decrease in flow.

Question 142

What are you worried about if the popliteal pulse is easily palpable?

Answer 142

Popliteal aneurism

Question 143

What is a cardiac catheter? Where would it be inserted?

Answer 143

Entry into heart via blood vessels for therapeutic or diagnostic purposes.

Right heart - femoral vein
Left heart - femoral artery

Question 144

What is venous insufficiency? What is it called when it occurs chronically, following a DVT?

Answer 144

Inability of veins to pump blood back efficiently. Leads to pooling in the legs and peripheries.

After DVT - postphlebotic syndrome

Question 145

What is the main difference between left and right heart failure?

Answer 145

Left causes lung oedema, right causes peripheral oedema

Question 146

What causes the oedema in heart failure?

Answer 146

Increased hydrostatic pressure in the veins

Question 147

Why does hypertension alone not cause oedema?

Answer 147

Hypertension refers to arteries. Oedema only released from slow moving veins.

Question 148

What is meant by cardiac asthma?

Answer 148

The cough that develops in left heart failure due to constriction of airways by pulmonary oedema.

Question 149

Which two physiological processes cause heart failure to deteriorate even faster?

Answer 149

Sympathetic overdrive

Up regulation of renin-angiotensin-aldosterone-system

Question 150

Why does sympathetic overdrive occur in heart failure?

Answer 150

Low perfusion to brain
Detected by baroreceptors as low bp
Increased sympathetic drive

Also affected by increased angiotensin from upRegulation of RAAS

Question 151

Why is RAAS (renin angiotensin aldosterone system) upregulated in heart failure?

Answer 151

Kidneys underperfused, think low bp
Upregulate RAAS to:
increase aldosterone - increase salt retention
Increase angiotensin 2 - increase water retention, vasoconstriction and sympathetic overdrive

Question 152

Why do increased sympathetic drive and upregulation of RAAS cause increased deterioration of heart failure?

Answer 152

Increase: HR, vasoconstriction, salt and water retention

Therefore increased afterload and increased oedema.

Question 153

What is the difference between diastolic and systolic heart failure?

Answer 153

Systolic is a failure to pump, diastolic is a failure to fill as well as pump

Question 154

Why is ejection fraction preserved in diastolic heart failure?

Answer 154

There is a decrease in both the amount of blood entering the heart and the amount leaving, so the proportion (ejection fraction) stays the same.

In systolic, just the amount leaving decreases, so the ejection fraction also decreases.

Question 155

What is a normal ejection fraction value?

Answer 155

Above 50%

Question 156

How would you treat increasingly serious heart failure?

Answer 156

1. Low salt diet
2. ACE inhibitor to decrease RAAS
3. Diuretics to decrease oedema
   Aldosterone antagonist to decrease salt retention
   Digoxin to increase contractility
4. Palliative opioids to ease breathlessness

Question 157

What is ejection fraction?

Answer 157

A measure of efficiency of the heart - end diastolic volume/stroke volume

Question 158

What is meant by shock?

Answer 158

Acute circulatory failure with inadequate or inappropriate tissue perfusion.

Question 159

Give 5 types of shock

Answer 159

Cardiogenic
Mechanical
Hypovolaemic
Anaphylactic
Septic

Question 160

What causes cardiogenic shock? What colour is the patient? What does their peripheral pulse feel like?

Answer 160

Dysfunction of heart itself eg. MI, acute heart failure
Leads to decreased cardiac output, decreased bp
Pale, sweating, cold
Weak pulse

Question 161

What causes mechanical shock? What colour is the patient? What does their peripheral pulse feel like?

Answer 161

Restriction of the heart’s normal action
Eg. Pulmonary embolism or cardiac tamponade
Decreased filling (PE left only) decreased output, decreased bp
Baroreceptors compensate with HR and TPR
But while block still there, still no blood!
Pale, sweating, cold
Pulse weak
Like

Question 162

What causes hypovolaemic shock? What colour is the patient? What does their peripheral pulse feel like?

Answer 162

Blood loss decreases venous pressure. 
Decrease cardiac output, decrease arterial pressure. 
Baroreceptors compensate with HR and TPR
But this just exacerbates blood loss
Pale, cold, sweating
Weak pulse

Question 163

What causes anaphylactic shock? What colour is the patient? What does their peripheral pulse feel like?

Answer 163

Histamine, prostaglandins, bradykinin, leukotrines respond to allergen. 
( bronchoconstriction so can get blue)
Smooth muscle relaxes
Decrease TPR, decrease arterial pressure
Baroreceptors compensate with HR and TPR
But capillary leakage 
Puffy and red
Fast bounding pulse

Question 164

What causes septic shock? What colour is the patient? What does their peripheral pulse feel like?

Answer 164

Endotoxins from g neg bacteria
Or interleukin 1 from tumour
Relax smooth muscle decrease arterial pressure
Baroreceptors compensate with HR and TPR
But capillary leak 
Fast bounding pulse

Question 165

How would you treat shock in general?

Answer 165

High pressure oxygen
Fluid (crystalloid if capillary leak)
Adrenalin for anaphylaxis only

Question 166

Describe the conduction pathway of the heart.

Answer 166

SA node - atria contract - AV node - 120ms - septum contracts - ventricles contract endocardium to epicardium through purkinje fibres - ventricles relax

Question 167

What is a common side effect of ACE inhibitors? What is it caused by?

Answer 167

Bradykinin causes fatal stimulation - dry cough

Question 168

Why does aspirin cause stomach ulcers?

Answer 168

It is an NSAID. Blocks COX 1 which encourages mucus production.

Question 169

What is the difference between pulmonary oedema and pleural effusion?

Answer 169

Pulmonary oedema fill the lung interstitium and the alveoli

Pleural effusion fills the space between the pleura

Question 170

Why is oxygen not administered automatically after an MI?

Answer 170

If sats are not below 94 then no need. Can cause oxygen toxicity which is like reperfusion injury, causes increased production of reactive oxygen species.

Question 171

Name 3 modifiable risk factors of heart disease and 3 non modifiable factors.

Answer 171

Non Modifiable: increasing age, male sex, South Asian ethnicity, familial hyperlipidaemia

Modifiable: low exercise, high fat diet, type 2 diabetes, alcohol, smoking

Question 172

What is levine’s sign?

Answer 172

Clenched right fist over chest implies ischaemic chest pain.

Question 173

What is meant by compensation and decompensation of the heart?

Answer 173

If it is compensated, it can function in spite of stressors or defects. Eg baroreceptors and RAAS maintain fluid, and increase heart rate and bp.

It becomes decompensated when this is no longer able to maintain adequate circulation. Eg increased HR and bp lead to worse peripheral perfusion and shock.

Question 174

What is meant by a paradoxical embolism?

Answer 174

An embolus that crosses the heart via an ASD or a VSD. So venous can go to the brain/other arteries and arterial can go to the lungs.

Question 175

Describe the evolution of the ecg pattern in an MI.

Answer 175

Minutes - tall T waves
Hours - ST elevation
Days - pathological Q waves

Question 176

Describe the venous drainage of a drug travelling by first pass metabolism.

Answer 176

Superior mesenteric vein - portal vein
Or
Inferior mesenteric vein - splenic vein - smv - portal vein