Cardiovascular Flashcards

Question 1

Q

Define atherosclerosis.

Answer

A

A hardened plaque in the intima of an artery. It is an inflammatory process.

Question 2

Q

What can an atherosclerotic plaque cause?

Answer

A

Heart attack.
Stroke.
Gangrene.

Question 3

Q

What are the constituents of an atheromatous plaque?

Answer

A

Lipid core.
Necrotic debris.
Connective tissue.
Fibrous cap.
Lymphocytes.

Question 4

Q

Give 5 risk factors for atherosclerosis.

Answer

A

Family history.
Increasing age.
Smoking.
High levels of LDL’s.
Obesity.
Diabetes.
Hypertension.

Question 5

Q

In which arteries would you be most likely to find atheromatous plaques?

Answer

A

In the peripheral and coronary arteries.

Question 6

Q

Which histological layer of the artery may be thinned by an atheromatous plaque?

Answer

A

The media.

Question 7

Q

What is the precursor for atherosclerosis.

Answer

A

Fatty streaks.

Question 8

Q

What can cause chemoattractant release?

Answer

A

A stimulus such as endothelial cell injury.

Question 9

Q

What are the functions of chemoattractants?

Answer

A

Chemoattractants signal to leukocytes. Leukocytes accumulate and migrate into vessel walls -> cytokine release e.g. IL-1, IL-6 -> inflammation!

Question 10

Q

Describe the process of leukocyte recruitment.

Answer

A

Capture.
Rolling.
Slow rolling.
Adhesion.
Trans-migration.

Question 11

Q

Describe in 5 steps the progression of atherosclerosis.

Answer

A

Fatty streaks.
Intermediate lesions.
Fibrous plaque.
Plaque rupture.
Plaque erosion.

Question 12

Q

Progression of atherosclerosis: what are the constituents of fatty streaks?

Answer

A

Foam cells and T-lymphocytes. Fatty streaks can develop in anyone from about 10 years old.

Question 13

Q

Progression of atherosclerosis: what are constituents of intermediate lesions?

Answer

A

Foam cells.
Smooth muscle cells.
T lymphocytes.
Platelet adhesion.
Extracellular lipid pools.

Question 14

Q

Progression of atherosclerosis: what are the constituents of fibrous plaques?

Answer

A

Fibrous cap overlies lipid core and necrotic debris.
Smooth muscle cells.
Macrophages.
Foam cells.
T lymphocytes.

Fibrous plaques can impede blood flow and are prone to rupture.

Question 15

Q

Progression of atherosclerosis: why might plaque rupture occur?

Answer

A

Fibrous plaques are constantly growing and receding. The fibrous cap has to be resorbed and redeposited in order to be maintained. If balance shifted in favour of inflammatory conditions, the cap becomes weak and the plaque ruptures. Thrombus formation and vessel occlusion.

Question 16

Q

What is the treatment for atherosclerosis?

Answer

A

Percutaneous coronary intervention (PCI).

Question 17

Q

What is the major limitation of PCI?

Answer

A

Restenosis.

Question 18

Q

How can restenosis be avoided following PCI?

Answer

A

Drug eluting stents: anti-proliferative and drugs that inhibit healing.

Question 19

Q

What is the key principle behind the pathogenesis of atherosclerosis?

Answer

A

It is an inflammatory process!

Question 20

Q

Define atherogenesis.

Answer

A

The development of an atherosclerotic plaque.

Question 21

Q

Define angina.

Answer

A

Angina is a type of IHD. It is a symptom of O2 supply/demand mismatch to the heart experienced on exertion.

Question 22

Q

What is the most common cause of angina?

Answer

A

Narrowing of the coronary arteries due to atherosclerosis.

Question 23

Q

Give 5 possible causes of angina.

Answer

A

Narrowed coronary artery = impairment of blood flow e.g. atherosclerosis.
Increased distal resistance = LV hypertrophy.
Reduced O2 carrying capacity e.g. anaemia.
Coronary artery spasm.
Thrombosis.

Question 24

Q

Give 5 modifiable risk factors for angina.

Answer

A

Smoking.
Diabetes.
High cholesterol (LDL).
Obesity/sedentary lifestyle.
Hypertension.

Question 25

Q

Give 3 non-modifiable risk factors for angina.

Answer

A

Increasing age.
Gender, male bias.
Family history/genetics.

Question 26

Q

Briefly describe the pathophysiology of angina that results from atherosclerosis.

Answer

A

On exertion there is increased O2 demand. Coronary blood flow is obstructed by an atherosclerotic plaque -> myocardial ischaemia -> angina.

Question 27

Q

Briefly describe the pathophysiology of angina that results from anaemia.

Answer

A

On exertion there is increased O2 demand. In someone with anaemia there is reduced O2 transport -> myocardial ischaemia -> angina.

Question 28

Q

How do blood vessels try and compensate for increased myocardial demand during exercise.

Answer

A

When myocardial demand increases e.g. during exercise, microvascular resistance drops and flow increases!

Question 29

Q

Why are blood vessels unable to compensate for increased myocardial demand in someone with CV disease?

Answer

A

In CV disease, epicardial resistance is high meaning microvascular resistance has to fall at rest to supply myocardial demand at rest. When this person exercises, the microvascular resistance can’t drop anymore and flow can’t increase to meet metabolic demand = angina!

Question 30

Q

How can angina be reversed?

Answer

A

Resting - reducing myocardial demand.

Question 31

Q

How would you describe the chest pain in angina?

Answer

A

Crushing central chest pain. Heavy and tight. The patient will often make a fist shape to describe the pain.

Question 32

Q

Give 5 symptoms of angina.

Answer

A

Crushing central chest pain.
The pain is relieved with rest or using a GTN spray.
The pain is provoked by physical exertion.
The pain might radiate to the arms, neck or jaw.
Breathlessness.

Question 33

Q

What tool can you use to determine the best investigations and treatment in someone you suspect to have angina?

Answer

A

Pre-test probability of CAD. It takes into account gender, age and typicality of pain.

Question 34

Q

What investigations might you do in someone you suspect to have angina?

Answer

A

ECG - usually normal, there are no markers of angina.
Echocardiography.
CT angiography - has a high NPV and is good at excluding the disease.
Exercise tolerance test - induces ischaemia.
Invasive angiogram - tells you FFR (pressure gradient across stenosis).

Question 35

Q

A young, healthy, female patient presents to you with what appears to be the signs and symptoms of angina. Would it be good to do CT angiography on this patient?

Answer

A

Yes. CT angiography has a high NPV and so is ideal for excluding CAD in
younger, low risk individuals.

Question 36

Q

Describe the primary prevention of angina.

Answer

A

Risk factor modification.
Low dose aspirin.

Question 37

Q

Describe the secondary prevention of angina.

Answer

A

Risk factor modification.
Pharmacological therapies for symptom relief and to reduce the risk of CV events.
Interventional therapies e.g. PCI.

Question 38

Q

Name 3 symptom relieving pharmacological therapies that might be used in someone with angina.

Answer

A

Beta blockers.
Nitrates e.g. GTN spray.
Calcium channel blockers.

Question 39

Q

Describe the action of beta blockers.

Answer

A

Beta blockers are beta 1 specific. They antagonise sympathetic activation and so are negatively chronotropic and inotropic. Myocardial work is reduced and so is myocardial demand = symptom relief.

Question 40

Q

Give 3 side effects of beta blockers.

Answer

A

Bradycardia.
Tiredness.
Erectile dysfunction.
Cold peripheries.

Question 41

Q

When might beta blockers be contraindicated?

Answer

A

They might be contraindicated in someone with asthma or in someone who is bradycardic.

Question 42

Q

Describe the action of nitrates.

Answer

A

Nitrates e.g. GTN spray are venodilators. Venodilators -> reduced venous return -> reduced pre-load -> reduced myocardial work and myocardial demand.

Question 43

Q

Describe the action of Ca2+ channel blockers.

Answer

A

Ca2+ blockers are arterodilators -> reduced BP -> reduced afterload -> reduced myocardial demand.

Question 44

Q

Name 2 drugs that might be used in someone with angina or in someone at risk of angina to improve prognosis.

Answer

A

Aspirin.
Statins.

Question 45

Q

How does aspirin work?

Answer

A

Aspirin irreversibly inhibits COX. You get reduced TXA2 synthesis and so platelet aggregation is reduced.
Caution: Gastric ulcers!

Question 46

Q

What are statins used for?

Answer

A

They reduce the amount of LDL in the blood.

Question 47

Q

What is revascularisation?

Answer

A

Revascularisation might be used in someone with angina. It restores the patent coronary artery and increases blood flow.

Question 48

Q

Name 2 types of revascularisation.

Answer

A

PCI.
CABG.

Question 49

Q

Give 2 advantages and 1 disadvantage of PCI.

Answer

A

Less invasive.
Convenient and acceptable.
High risk of restenosis.

Question 50

Q

Give 1 advantage and 2 disadvantages of CABG.

Answer

A

Good prognosis after surgery.
Very invasive.
Long recovery time.

Question 51

Q

What are acute coronary syndromes (ACS)?

Answer

A

ACS encompasses a spectrum of acute cardiac conditions including unstable angina, NSTEMI and STEMI.

Question 52

Q

What is the common cause of ACS?

Answer

A

Rupture of an atherosclerotic plaque and subsequent arterial thrombosis.

Question 53

Q

What are uncommon causes of ACS?

Answer

A

Coronary vasospasm.
Drug abuse.
Coronary artery dissection.

Question 54

Q

Briefly describe the pathophysiology of ACS?

Answer

A

Atherosclerosis -> plaque rupture -> platelet aggregation -> thrombosis formation -> ischaemia and infarction -> necrosis of cells -> permanent heart muscle damage and ACS.

Question 55

Q

Describe type 1 MI.

Answer

A

Spontaneous MI with ischaemia due to plaque rupture.

Question 56

Q

Describe type 2 MI.

Answer

A

MI secondary to ischaemia due to increased O2 demand.

Question 57

Q

Why do you see increased serum troponin in NSTEMI and STEMI?

Answer

A

The occluding thrombus causes necrosis of cells and so myocardial damage. Troponin is a sensitive marker for cardiac muscle injury and so is significantly raised in reflection to this.

Question 58

Q

Give 3 signs of unstable angina.

Answer

A

Cardiac chest pain at rest.
Cardiac chest pain with crescendo patterns; pain becomes more frequent and easier provoked.
No significant rise in troponin.

Question 59

Q

Give 6 signs/symptoms of MI.

Answer

A

Unremitting and usually severe central cardiac chest pain.
Pain occurs at rest.
Sweating
Breathlessness.
Nausea/vomiting.
1/3 occur in bed at night.

Question 60

Q

Give 5 potential complications of MI.

Answer

A

Heart failure.
Rupture of infarcted ventricle.
Rupture of interventricular septum.
Mitral regurgitation.
Arrhythmias.
Heart block.
Pericarditis.

Question 61

Q

What investigations would you do on someone you suspect to have ACS?

Answer

A

ECG.
Blood tests; look at serum troponin.
Coronary angiography.
Cardiac monitoring for arrhythmias.

Question 62

Q

What might the ECG of someone with unstable angina show?

Answer

A

The ECG from someone with unstable angina may be normal or might show T wave inversion and ST depression.

Question 63

Q

What might the ECG of someone with NSTEMI show?

Answer

A

The ECG from someone with NSTEMI may be normal or might show T wave inversion and ST depression. There also might be R wave regression, ST elevation and biphasic T wave in lead V3.

Question 64

Q

What might the ECG of someone with STEMI show?

Answer

A

The ECG from someone with STEMI will show ST elevation in the anterolateral leads. After a few hours, T waves invert and deep, broad, pathological Q waves develop.

Answer 65

A

Significantly raised.

Answer 66

A

Gram negative sepsis.
Pulmonary embolism.
Myocarditis.
Heart failure.
Arrhythmias.

Answer 67

A

Get into hospital ASAP - call 999.
If STEMI, paramedics should call PCI centre for transfer.
Aspirin 300mg.
Pain relief e.g. morphine.
Oxygen if hypoxic.
Nitrates.

Answer 68

A

It amplifies platelet activation.

Answer 69

A

Bleeding.
Rash.
GI disturbances.

Answer 70

A

Aspirin.
Clopidogrel (P2Y12 inhibitor).
Statins.
Metoprolol (beta blocker).
ACE inhibitor.
Modification of risk factors.

Answer 71

A

Where the QRS complex becomes the ST segment.

Answer 72

A

-30° -> +90°

Answer 73

A

Atrial depolarisation.

Answer 74

A

120 - 200ms.

Answer 75

A

Heart block.

Answer 76

A

0.35 - 0.45s.

Answer 77

A

Ventricular depolarisation.

Answer 78

A

Ventricular repolarisation.

Answer 79

A

From the right arm to the left arm with the positive electrode being at the left arm. At 0°.

Answer 80

A

From the right arm to the left leg with the positive electrode being at the left leg. At 60°.

Answer 81

A

From the left arm to the left leg with the positive electrode being at the left leg. At 120°.

Answer 82

A

From halfway between the left arm and right arm to the left leg with the positive electrode being at the left leg. At 90°.

Answer 83

A

From halfway between the right arm and left leg to the left arm with the positive electrode being at the left arm. At -30°.

Answer 84

A

From halfway between the left arm and left leg to the right arm with the positive electrode being at the right arm. At -150°.

Answer 85

A

The SA node. 60-100 beats/min.

Answer 86

A

a) 0.04s.
b) 0.2s.

Answer 87

A

Less than 110 ms.

Answer 88

A

Leads 1 and 2.

Answer 89

A

From chest leads V1 to V4.

Answer 90

A

From chest leads V1 to V3. It must also disappear in V6.

Answer 91

A

Leads 1, 2, V2 -> V6.

Answer 92

A

Right atrial enlargement.

Answer 93

A

Left atrial enlargement.

Answer 94

A

Symmetrical.
Tall and peaked.
Biphasic or inverted.

Answer 95

A

The QT interval decreases.

Answer 96

A

QT interval.

Answer 97

A

Non-specific symptoms, pain and swelling. Tenderness, warmth and slight discolouration.

Answer 98

A

D-dimer; looks for fibrin breakdown products. If normal, you can exclude DVT. Abnormal does not confirm diagnosis however.
Ultrasound compression scan; if you can’t squash the vein = clot.

Answer 99

A

LMWH.
Oral warfarin or DOAC.
Compression stockings.
Treat the underlying cause e.g. malignancy or thrombophilia.

Answer 100

A

Surgery, immobility, leg fracture.
OCP, HRT.
Long haul flights.
Genetic predisposition.
Pregnancy.

Answer 101

A

Hydration.
Mobilisation.
Compression stockings.
Low does LMWH.

Answer 102

A

Pulmonary embolism.

Answer 103

A

Platelet rich - a ‘white thrombosis’.

Answer 104

A

Fibrin rich - a ‘red thrombosis’.

Answer 105

A

MI.
Stroke.
Peripheral vascular disease e.g. gangrene

Answer 106

A

Pulmonary embolism.

Answer 107

A

Aspirin.
LMWH.
Thrombolytic therapy.

Answer 108

A

It produces NON-functional clotting factors 2, 7, 9 and 10.

Answer 109

A

Vitamin K.

Answer 110

A

Lots of interactions!
Teratogenic.
Needs almost constant monitoring.

Answer 111

A

Infection of the heart valves.

Answer 112

A

BP ≥ 140/90mmHg.

Answer 113

A

Lifestyle modification e.g. reduce salt intake.
Anti-hypertensive drugs.

Answer 114

A

BP = CO X TPR.

Answer 115

A

RAAS.
Sympathetic nervous system (NAd).

Answer 116

A

Potent vasoconstrictor.
Activates sympathetic nervous system; increased NAd.
Activates aldosterone = Na+ retention.
Vascular growth, hyperplasia and hypertrophy.

Answer 117

A

Noradrenaline is a vasoconstrictor = increased TPR.
NAd has positive chronotropic and inotropic effects.
It can cause increased renin release.

Answer 118

A

Ramapril.
Enalapril.
Perindopril.

Answer 119

A

Hypertension.
Heart failure.
Diabetic nephropathy.

Answer 120

A

Hypotension.
Hyperkalaemia.
Acute renal failure.
Teratogenic.

Answer 121

A

ACE also converts bradykinin to inactive peptides. Therefore ACE inhibitors lead to a build up of kinin.

Answer 122

A

Dry chronic cough.
Rash.
Anaphylactoid reaction.

Answer 123

A

ACE inhibitors lead to a build up of kinin. One of the side effects of this is a dry and chronic cough.

Answer 124

A

Angiotensin 2 receptor blockers.

Answer 125

A

AT-1 receptor.

Answer 126

A

Candesartan.
Valsartan.
Losartan.

Answer 127

A

Hypertension.
Heart failure.
Diabetic nephropathy.

Answer 128

A

An ARB e.g. candesartan.

Answer 129

A

ARBs have similar side effects to ACEi:
1. Hypotension.
2. Hyperkalaemia.
3. Renal dysfunction.
4. Rash.

Contraindicated in pregnancy.

Answer 130

A

Amlodipine.
Felodipine.
Diltiazem.
Verapamil.

Answer 131

A

Dihydropyridines are a class of calcium channel blockers. Amlodipine and felodipine are examples of dihydropyridines. They are arterial vasodilators.

Answer 132

A

Verapamil - it is negatively chronotropic and inotropic.

Answer 133

A

Diltiazem - acts on the heart and the vasculature.

Answer 134

A

Hypertension.
IHD.
Arrhythmia.

Answer 135

A

L type Ca2+ channels.

Answer 136

A

Flushing.
Headache.
Oedema.

Answer 137

A

Worsening caridac failure.

Answer 138

A

Bradycardia.
Atrioventricular block.

Answer 139

A

Worsening cardiac failure (-ve inotrope).
Bradycardia (-ve chronotrope).
Atrioventricular block (-ve chronotrope).
Constipation!

Answer 140

A

Verapamil.

Answer 141

A

Bisoprolol (beta 1 selective).
Atenolol.
Propanolol (beta 1/2 non selective).

Answer 142

A

IHD.
Heart failure.
Arrhythmia.
Hypertension.

Answer 143

A

Fatigue.
Headache.
Nightmares.
Bradycardia.
Hypotension.
Cold peripheries.
Erectile dysfunction.
Bronchospasm.

Answer 144

A

The distal tubule.

Answer 145

A

Bendroflumethiazide.

Answer 146

A

Furosemide.
Bumetanide.

Answer 147

A

Spironolactone.

Answer 148

A

They have anti-aldosterone effects too.

Answer 149

A

Heart failure.
Hypertension.

Answer 150

A

Hypovolemia.
Hypotension.
Reduced serum Na+/K+/Mg+/Ca2+.
Increased uric acid -> gout.
Erectile dysfunction.
Impaired glucose tolerance.

Answer 151

A

ACE inhibitors e.g. ramapril or ARB e.g. candesartan.

Answer 152

A

Calcium channel blockers (as this patient is over 55) e.g. amlodipine.

Answer 153

A

You would combine ACE inhibitors or ARB with calcium channel blockers.

Answer 154

A

You would combine the ACEi/ARB and calcium channel blockers with a thiazide diuretic e.g. bendroflumethiazide.

Answer 155

A

A complex clinical syndrome of signs and symptoms that suggest the efficiency of the heart as a pump is impaired.

Answer 156

A

Ischaemic heart disease.

Answer 157

A

ANP and BNP.

Answer 158

A

NEP metabolises ANP and BNP. NEP inhibitors can therefore increase levels of ANP and BNP in the serum.

Answer 159

A

Increased renal excretion of Na+ and therefore water.
Vasodilators.
Inhibit aldosterone release.

Answer 160

A

ANP/BNP hormones.

Answer 161

A

Isosorbide mononitrate.
GTN spray.

Answer 162

A

They are venodilators. They reduce preload and so BP.

Answer 163

A

Headache.
Syncope.
Tolerance.

Answer 164

A

Vaughan Williams classification.

Answer 165

A

Class 1 are Na+ channel blockers. There are 3 sub-divisions in this group.
1a: disopyramide.
1b: lidocaine.
1c: flecainide.

Answer 166

A

Class 2 are beta blockers:
1. Propranolol.
2. Atenolol.
3. Bisoprolol.

Answer 167

A

Class 3 drugs prolong the action potential. E.g. amiodarone. Side effects are very likely with these drugs.

Answer 168

A

Class 4 drugs are calcium channel blockers but NOT dihydropyridines as these don’t effect the heart.
1. Verapamil.
2. Diltiazem.

Answer 169

A

It inhibits the Na+/K+ pump therefore making the action potential more positive and ACh is released from parasympathetic nerves.

Answer 170

A

Bradycardia.
Reduced atrioventricular conduction.
Increased force of contraction (positive inotrope).

Answer 171

A

Nausea.
Vomiting.
Diarrhoea.
Confusion.

Answer 172

A

Atrial fibrillation and severe heart failure.

Answer 173

A

Sotalol.
Amiodarone.

Answer 174

A

Pro-arrythmic effects.
Interstitial pneumonitis.
Abnormal liver function.
Hyper/hypothyroidism.
Sun sensitivity.
Grey skin discolouration.
Corneal micro-deposits.
Optic neuropathy.

Answer 175

A

They block the inactivation gate of the sodium channel.

Answer 176

A

It can also block sodium channels.

Answer 177

A

The Na+/K+/2Cl- transporter.

Answer 178

A

They block reflex sympathetic responses which stress the failing heart.

Answer 179

A

It is an alpha 1 receptor antagonist.

Answer 180

A

They reduce O2 demand by slowing heart rate (negative chronotrope).
They reduce O2 demand by reducing myocardial contractility (negative inotrope).
They increase O2 distribution by slowing heart rate.

Answer 181

A

Amlodipine.

Answer 182

A

When the cardiovascular system is unable to provide adequate substrate for aerobic cellular respiration.

Answer 183

A

Pale.
Sweaty.
Cold.
Pulse is weak and rapid.
Reduced urine output.
Confusion.
Weakness/collapse.

Answer 184

A

Loss of blood e.g. acute GI bleeding, trauma, post-op, splenic rupture.
Loss of fluid e.g. dehydration, burns, vomiting, pancreatitis.

Answer 185

A

15% blood loss.
Pulse < 100 bpm.
Blood pressure - normal.
Pulse pressure - normal.
Respiratory rate: 14 - 20.
Urine output > 30ml/h.

Answer 186

A

15-30% blood loss.
Pulse > 100 bpm.
Blood pressure - normal.
Pulse pressure - decreased.
Respiratory rate: 20 - 30.
Urine output: 20 - 30ml/h.

Answer 187

A

30-40% blood loss.
Pulse > 120 bpm.
Blood pressure - decreased.
Pulse pressure - decreased.
Respiratory rate: 30 - 40.
Urine output: 5 - 15ml/h.

Answer 188

A

Cardiac tamponade.
Pulmonary embolism.
Acute MI.
Fluid overload.

Answer 189

A

A systemic inflammatory response associated with an infection (bacterial endotoxins).

Answer 190

A

An intense allergic reaction associated with massive histamine release = haemodynamic collapse. The patient may be breathless, wheezy and have a rash.

Answer 191

A

Adrenaline and supportive therapy e.g. O2 delivery, fluid replacement.

Answer 192

A

Impaired oxygenation.
Bilateral pulmonary infiltrates.
No cardiac failure.

Answer 193

A

Exudative phase: increased vascular permeability leads to a platelet, fibrin and clotting factor rich exudate.
Proliferative phase: fibroblast proliferation.
Fibrotic phase.

Answer 194

A

SEPSIS!
Trauma.
Shock.
Drug reaction.
Pancreatitis.

Answer 195

A

Pneumonia.
Smoke inhalation.
Near drowning.

Answer 196

A

It acts as a lubricant and so allows smooth movement of the heart inside the pericardium.

Answer 197

A

It restrains the filling volume of the heart.

Answer 198

A

Viral (common) e.g. enteroviruses.
Bacterial e.g. mycobacterium tuberculosis.
Autoimmune e.g. RA, sjögren syndrome.
Neoplastic.
Metabolic e.g. uraemia.
Traumatic and iatrogenic.
80-90% are idiopathic.

Answer 199

A

An inflammatory pericardial syndrome with or without effusion.

Answer 200

A

Acute pericarditis can be clinically diagnosed if the patient has at least 2 of the following:
1. Chest pain.
2. Friction rub.
3. ECG changes.
4. Pericardial effusion.

Answer 201

A

Chest pain! Described as severe, sharp and pleuritic. Rapid onset. Pain can radiate to the arm.
Dyspnoea.
Cough.
Hiccups.
Skin rash.

Answer 202

A

Because of irritation to the phrenic nerve.

Answer 203

A

ECG.
CXR.
Bloods.
Echocardiogram.

Answer 204

A

PR depression seen in most leads.
‘Saddle shaped’ concave ST elevation.

Answer 205

A

MI - it is important to rule this out ASAP!

Answer 206

A

Patients are advised to avoid strenuous activity until symptom resolution.
NSAID or aspirin - high doses.
Colchicine (anti-inflammatory).

Answer 207

A

The parietal pericardium is able to adapt when effusions accumulate slowly and so tamponade is prevented.

Answer 208

A

Direct bleeding from vasculature through the ventricular wall following MI.

Answer 209

A

Viral infection.

Answer 210

A

Hypertrophic (HCM).
Dilated (DCM).
Arrhythmogenic right/left ventricular (ARVC/ALVC).

Answer 211

A

Sarcomeric gene mutations e.g. beta myosin, troponin T mutations. About 1 in 500 people are affected.

Answer 212

A

Desmosome gene mutations.

Answer 213

A

Autosomal dominant; off-spring have a 50% chance of being affected.

Answer 214

A

Systole is normal but diastole is affected; the heart is unable to relax properly due to thickening of the ventricular walls.

Answer 215

A

Ventricular dilation and dysfunction = poor contractility.

Answer 216

A

Desmosomes attach cells via their intermediate filaments. Desmosome mutations lead to myocytes being pulled apart and ventricles are replaced with fatty fibrous tissue. Gap junctions are affected too.

Answer 217

A

Angina.
Dyspnoea.
Syncope.

Answer 218

A

DCM usually presents with symptoms similar to those seen in heart failure:
1. Breathlessness.
2. Tiredness.
3. Oedema.

Answer 219

A

Ventricular tachycardia.

Answer 220

A

Large QRS complexes.
Large inverted T waves.

Answer 221

A

Epsilon waves.

Answer 222

A

Poor dilation of the heart restricts diastole.

Answer 223

A

Amyloidosis (extra-cellular deposition of an insoluble fibrillar protein - amyloid).

Answer 224

A

Mutations in genes coding for ion channels.

Answer 225

A

Long QT syndrome.
Short QT syndrome.
Brugada.
CPVT.

Answer 226

A

Sodium channel.

Answer 227

A

Recurrent syncope.

Answer 228

A

Characteristic ST elevation in chest leads.

Answer 229

A

A channelopathy caused by a mutation in sodium channels.

Answer 230

A

Ventricular septal defect.
Over-riding aorta.
RV hypertrophy.
Pulmonary stenosis.

Answer 231

A

YES! There is a greater pressure in the RV than the LV and so blood is shunted into the LV -> CYANOSIS!

Answer 232

A

An abnormal connection between the two ventricles.

Answer 233

A

No. There is a higher pressure in the LV than the RV and so blood is shunted from the left to right meaning there is an increased amount of blood going to the lungs; not cyanotic.

Answer 234

A

High pulmonary blood flow.
Breathless, poor feeding, failure to thrive.
Increased respiratory rate,
Tachycardia.
Requires surgical repair.

Answer 235

A

Eisenmengers syndrome.

Answer 236

A

High pressure pulmonary blood flow damages pulmonary vasculature -> there is increased resistance to blood flow (pulmonary hypertension) -> RV pressure increases -> shunt direction reverses (RV to LV) -> CYANOSIS!

Answer 237

A

Risk of death.
Endocarditis.
Stroke.

Answer 238

A

An abnormal connection between the two atria; it is fairly common.

Answer 239

A

No. There is a higher pressure in the LA than the RA and so blood is shunted from the left to right, therefore not cyanotic.

Answer 240

A

Significant increase in blood flow through the right heart and lungs - pulmonary flow murmur.
Enlarged pulmonary arteries.
Right heart dilatation.
SOBOE.
Increased chest infection.

Answer 241

A

Atrio-ventricular septal defects. Basically a hole in the very centre of the heart.

Answer 242

A

Breathless.
Poor feeding and poor weight gain.

Answer 243

A

Patent ductus arteriosus.

Answer 244

A

Torrential flow from the aorta to the pulmonary arteries can lead to pulmonary hypertension and RHF.
Breathless.
Poor feeding, failure to thrive.
Risk of endocarditis.

Answer 245

A

Excessive sclerosing that normally closes the ductus arteriosus extends into the aortic wall leading to narrowing.

Answer 246

A

Narrowing of the RV outflow tract.

Answer 247

A

VSD.
ASD.
PDA.

Left to right shunt! This is okay but a bit insufficient and there is a risk of Eisenmengers syndrome.

Answer 248

A

Tetralogy of Fallot.

Right to left shunt.

Answer 249

A

A complex clinical syndrome of signs/symptoms that suggest the efficiency of the heart as a pump is impaired; the heart is unable to deliver blood at a rate that meets the metabolic demands.

Answer 250

A

Systolic failure: the ability of the heart to pump blood around the body is impaired.
Diastolic failure: the heart is pumping blood effectively but is relaxing and filling abnormally.

Answer 251

A

Commonest cause: IHD.
Hypertension.
Cardiomyopathy.
Excessive alcohol.
Obesity.

Answer 252

A

Women have ‘protective hormones’ meaning they are less at risk of developing heart failure.

Answer 253

A

When the heart fails, compensatory mechanisms attempt to maintain CO. As HF progresses, these mechanisms are exhausted and become pathophysiological.

Answer 254

A

Sympathetic system.
RAAS.
Natriuretic peptides.
Ventricular dilation.
Ventricular hypertrophy.

Answer 255

A

The sympathetic system improves ventricular function by increasing HR and contractility = CO maintained.

BUT it also causes arteriolar constriction which increases after load and so myocardial work.

Answer 256

A

Reduced CO leads to reduced renal perfusion; this activates RAAS. There is increased fluid retention and so increased preload.

BUT it also causes arteriolar constriction which increases after load and so myocardial work.

Answer 257

A

Diuretic.
Hypotensive.
Vasodilators.

Answer 258

A

Shortness of breath.
Fatigue.
Peripheral oedema.

Answer 259

A

Pulmonary crackles.
Added heart sounds (3rd and 4th) and murmurs.
Displaced apex beat.
Tachycardia.

Answer 260

A

ECG.
CXR - might show cardiac enlargement.
Natriuretic peptide levels - raised indicate heart failure.

Answer 261

A

An echocardiogram.

Answer 262

A

Vasodilator therapy (ACEi, beta blockers) via the neurohumoral blockade (RAAS-SNS).

Answer 263

A

Perindopril.

Answer 264

A

Metoprolol.
Bisoprolol.
Carvedilol.
Nebivolol.

Answer 265

A

Diuretics: thiazides (bendroflumethiazide) and loop diuretics (furosemide). They promote Na and so H2O excretion.

Answer 266

A

RV hypertrophy and dilation due to pulmonary hypertension.

Answer 267

A

140/90mmHg.

Answer 268

A

7 years. Although this depends on onset and severity.

Answer 269

A

Kidney disease.
Genetics and family history.
Lifestyle factors e.g. high salt diet, excess alcohol, obesity, stress, caffeine.
Recreational drug use e.g. cocaine.
Drugs such as OCP and NSAIDS.
Hyperaldosteronism.

Answer 270

A

Conn’s syndrome - hyperaldosteronism.
Cushing’s syndrome - prolonged cortisol exposure -> raised BP.
Phaeochromocytoma - adrenal gland tumour, excess NAd and Ad release -> high BP.

Answer 271

A

Pallor.
Palpitations.
Chest pain.
Panic.

Answer 272

A

Very high BP can cause immediate damage to small vessels, this can be seen in the eyes where there are small exposed blood vessle.s

Answer 273

A

24h ambulatory blood pressure monitoring to confirm a diagnosis.
ECG and blood tests may be done to identify secondary causes of hypertension.

Answer 274

A

MI (IHD).
Stroke.
Heart failure.
Chronic renal disease.
Dementia.

Answer 275

A

1 tablet = 10mmHg reduction in BP.

Answer 276

A

a) High risk - 140/90mmHg.
b) Low risk - 160/100mmHg.

Answer 277

A

a) Below 140/90mmHg in those aged less than 80.
b) Below 150/90mmHg in those aged above 80.

Answer 278

A

Anti-hypertensives won’t necessarily make someone feel better as there are few symptoms associated with high BP although headache symptoms may improve.

Answer 279

A

Lifestyle modification: reduce salt intake, lose weight, reduce alcohol.
Drug therapy: ABCD.

Answer 280

A

A - ACEi e.g. rampiril or ARB e.g. candesartan.
B - beta blockers e.g. bisoprolol.
C - Calcium CB e.g. amlodipine, diltiazem or verapamil.
D - diuretics e.g. bendroflumethiazide or furosemide.

Answer 281

A

Side effects of ACE inhibitors:
1. Hypotension.
2. Acute renal failure.
3. Hyperkalaemia.
4. Teratogenic.
5. Cough, rash, anaphylactoid due to increased kinin production.

Answer 282

A

AT-1, prevents Ang 2 binding.

Answer 283

A

Side effects of valsartan:
1. Hypotension.
2. Renal dysfunction.
3. Hyperkalaemia.
4. Rash.
5. Contraindicated in pregnancy.

Answer 284

A

Side effects of beta blockers:
1. Hypotension.
2. Fatigue.
3. Headaches.
4. Nightmares.
5. Bradycardia.
6. Hypotension.
7. Erectile dysfunction.
8. Cold peripheries.

Answer 285

A

Side effects of dihydropyridines (CCB):
1. Flushing.
2. Headache.
3. Oedema.
4. Palpitations.

Answer 286

A

Side effects due to being negatively chronotropic:
1. Bradycardia.
2. AV block.
Side effects due to being negatively inotropic:
1. Worsening of cardiac failure.

Answer 287

A

Side effects of diuretics:
1. Hypovolemia.
2. Hypotension.
3. Reduced K, Na, Mg, Ca.
4. Hyperuricaemia -> gout.
5. Erectile dysfunction.

Answer 288

A

Aortic stenosis.
Mitral regurgitation.
Mitral stenosis.
Aortic regurgitation.

Answer 289

A

A disease where the aortic orifice is restricted and so the LV can’t eject blood properly in systole = pressure overload.

Answer 290

A

Congenital bicuspid valve.
Acquired e.g. age related degenerative calcification and rheumatic heart disease.

Answer 291

A

Aortic orifice is restricted e.g. by calcific deposits and so there is a pressure gradient between the LV and the aorta. LV function is initially maintained due to compensatory hypertrophy. Overtime this becomes exhausted = LV failure.

Answer 292

A

Exertional syncope.
Angina.
Exertional dyspnoea.

Onset of symptoms is associated with poor prognosis.

Answer 293

A

Slow rising carotid pulse and decreased pulse amplitude.
Soft or absent heart sounds.
Ejection systolic murmur: <> shape.

Answer 294

A

Echocardiography.

Answer 295

A

Ensure good dental hygiene.
Consider IE prophylaxis.
Aortic valve replacement or TAVI.

Answer 296

A

Symptomatic patients with aortic stenosis.
Any patient with decreasing ejection fraction.
Any patient undergoing CABG with moderate/severe aortic stenosis.

Answer 297

A

Back flow of blood from the LV to the LA during systole - LV volume overload.

Answer 298

A

Myxomatous degeneration.
Ischaemic mitral regurgitation.
Rheumatic heart disease.
IE.

Answer 299

A

LV volume overload! Compensatory mechanisms: LA enlargement and LVH and increased contractility. Progressive LV volume overload -> dilatation and progressive HF.

Answer 300

A

Dyspnoea on exertion.
HF.

Answer 301

A

Pansystolic murmur (always there).
Soft 1st heart sound.
3rd heart sound.

In chronic MR the intensity of the murmur correlates with disease severity.

Answer 302

A

ECG.
CXR.
Echocardiogram: estimates LA/LV size and function.

Answer 303

A

Rate control for AF e.g. beta blockers. Anticoagulation for AF. Diuretics for fluid overload. IE prophylaxis. If symptomatic = surgery.

Answer 304

A

A regurgitant aortic valve means blood leaks back into the LV during diastole due to ineffective aortic cusps.

Answer 305

A

Bicuspid aortic valve.
Rheumatic.
IE.

Answer 306

A

Pressure and volume overload. Compensatory mechanisms - LV dilatation, LVH. Progressive dilation -> HF.

Answer 307

A

Dyspnoea on exertion.
Orthopnea.
Palpitations.
Paroxysmal nocturnal dyspnea.

Answer 308

A

Wide pulse pressure.
Diastolic blowing murmur.
Systolic ejection murmur.

Answer 309

A

CXR and echocardiogram.

Answer 310

A

IE prophylaxis. Vasodilators e.g. ACEi. Regular echo’s to monitor progression. Surgery if symptomatic.

Answer 311

A

Obstruction to LV inflow that prevents proper filling during diastole.

Answer 312

A

Rheumatic heart disease.
IE.
Calcification.

Answer 313

A

LA dilation -> pulmonary congestion.
Increased trans-mitral pressures -> LA enlargement and AF.
Pulmonary venous hypertension causes RHF symptoms.

Answer 314

A

Dyspnea.
Haemoptysis.
RHF symptoms.

Answer 315

A

‘a’ wave in jugular venous pulsations.
Signs of RHF.
Pink patches on cheeks due to vasoconstriction.
Low pitched diastolic murmur.
Loud opening 1st heart sound snap.

Answer 316

A

ECG.
CXR.
Echocardiogram - gold standard.

Answer 317

A

If in AF rate control e.g. beta blockers/CCB. Anticoagulation if AF. Balloon valvuloplasty or valve replacement. IE prophylaxis.

Answer 318

A

The problem is mechanical and so medical therapy does not prevent progression.

Answer 319

A

Infection of the heart valves or other endocardial lined structure within the heart.

Answer 320

A

Left sided native IE.
Left sided prosthetic IE.
Right sided IE (rarely prosthetic).
Device related IE e.g. pacemakers, defibrillators.

Answer 321

A

Left sided IE - these are more likely to cause thrombo-emboli.
(Right side IE could spread to the lungs).

Answer 322

A

Having a regurgitant or prosthetic valve.
If infectious material is introduced into the blood stream or during surgery.

Answer 323

A

Staph aureus.
Staph epidermidis (coagulase negative staph).
Strep viridans (alpha haemolytic).

Answer 324

A

Elderly.
IVDU.
Those with prosthetic valves.
Those with rheumatic fever.

Answer 325

A

Microbial adherence (infection) -> vegetation on valve -> cardiac valve distortion -> cardiac failure and septic problems.

Answer 326

A

Vegetation - lumps of fibrin hanging off the heart valves.

Answer 327

A

Atrial surface of AV valves.
Ventricular surface of SL valves.

Answer 328

A

Signs of systemic infection e.g. fever, sweats.
Embolisation e.g. stroke, PE, MI.
Valve dysfunction e.g. HF, arrhythmia.

Answer 329

A

Splinter haemorrhages.
Osler’s nodes.
Janeway lesions.
Roth spots.
Heart murmurs.

Answer 330

A

Blood cultures are essential for diagnosis.
Echocardiogram shows endocardial involvement e.g. TTE or TOE.
Bloods - raised ESR/CRP.
ECG.

Answer 331

A

Safe.
Non-invasive, no discomfort.
Poor images.

Answer 332

A

Excellent images.
Discomfort.
Small risk of perforation or aspiration.

Answer 333

A

Antibiotics based on cultures.
Treat any complications.
Surgery.

Answer 334

A

Antibiotics not working.
Complications.
To remove infected devices.
To replace the valve.
to remove large vegetations before they embolise.

Answer 335

A

To prevent them embolising and causing a stroke, MI etc.

Answer 336

A

They may have previously received antibiotics.

Answer 337

A

A common type of vasculitis: localised, chronic and granulomatous inflammation of temporal arteries.

Answer 338

A

Thickened often palpable blood vessels.
Evidence of granulomatous inflammation.

Answer 339

A

Blindness if the occular artery is affected.

Answer 340

A

The duke criteria.

Answer 341

A

Hyperkalaemia.
Obesity.

Answer 342

A

Right atrial enlargement.

Answer 343

A

Left atrial enlargement.

Answer 344

A

The inferior aspect.

Answer 345

A

RCA blockage.
These leads show the activity of the inferior aspect of the heart and the RCA supplies the inferior aspect of the heart with blood.

Answer 346

A

Tall ‘tented’ T waves.
Flat P waves.
Broad QRS.

Answer 347

A

Flat T waves.
QT prolongation.
ST depression.
Prominent U waves.

Answer 348

A

QT prolongation.
T wave flattening.
Narrowed QRS.
Prominent U waves.

Answer 349

A

QT shortening.
Tall T waves.
No P waves.

Answer 350

A

The sinus node.

Answer 351

A

The autonomic nervous system.

Answer 352

A

Sinus rhythm - a P wave precedes each QRS complex.

Answer 353

A

Sudden death.
Syncope.
Dizziness.
Palpitations.
Can also be asymptomatic.

Answer 354

A

< 60 bpm.

Answer 355

A

> 100 bpm.

Answer 356

A

Supra-ventricular tachycardia’s.
Ventricular tachycardia’s.

Answer 357

A

They arise from the atria or atrio-ventricular junction.

Answer 358

A

Supraventricular tachycardias are often associated with narrow complexes.

Answer 359

A

The ventricles.

Answer 360

A

Ventricular tachycardias are often associated with broad complexes.

Answer 361

A

Atrial fibrillation.
Atrial flutter.
AV node re-entry tachycardia (AVNRT).
Accessory pathway.
Focal atrial tachycardia.

Answer 362

A

Physiological response to exercise.
Fever,
Anaemia.
Heart failure.
Hypovolemia.

Answer 363

A

Absent P waves.
Fine oscillation of the baseline.

Answer 364

A

The atria fire a lot, it is chaotic. The AV node and ventricles can’t keep up -> irregularly irregular pulse.

Answer 365

A

Palpitations.
Shortness of breath.
Fatigue.
Chest pain.
Increased risk of thromboembolism and therefore stroke.

Answer 366

A

CHADS2 VASc.

Answer 367

A

The CHADS2 VASc score is used to calculate the risk of stroke in patients with atrial fibrillation. It considers:
1. Age.
2. Hypertension.
3. Previous stroke/TIA.
4. Diabetes.
5. Female.

A score >2 indicates the need for anticoagulation.

Answer 368

A

Rate control - beta blockers, CCB and digoxin.
Rhythm control - electrical cardioversion or pharmacological cardioversion using flecainide.
Flecainide can be taken on a PRN basis in people with infrequent symptomatic paroxysms of AF.
Long term - catheter ablation and a pacemaker.

Answer 369

A

Beta blockers, CCB and digoxin.

Answer 370

A

Electrical cardioversion or pharmacological cardioversion using flecainide.

Answer 371

A

Catheter ablation - it targets the triggers of AF.

Answer 372

A

Narrow QRS.
‘sawtooth’ flutter waves.

Answer 373

A

Atrial flutter.

Answer 374

A

The re-entry mechanism - there is blockage of the normal circuit. Another pathway forms, takes a different course and re-enters the circuit -> tachycardia.

Answer 375

A

AV node re-entry tachycardia (AVNRT).

Answer 376

A

No - the P waves are within the QRS complex.

Answer 377

A

Sudden onset/offset palpitations.
Neck pulsation.
Chest pain.
Shortness of breath.

Answer 378

A

Acute treatment: vagal manoeuvre and adenosine.

Answer 379

A

Beta blockers, CCB, flecainide.

Answer 380

A

Congenital muscle strands connect the atria and ventricles - accessory pathway. This can result in pre-excitation of ventricles.

Answer 381

A

Delta wave.
Short PR interval.
Slurred QRS complex.

Answer 382

A

Wolff-Parkinson-White syndrome.

Answer 383

A

Another area of the atrium becomes more autonomic than the sinus node and so sinus node function is taken over -> focal atrial tachycardia.

Answer 384

A

Abnormal P waves appear before a normal QRS.

Answer 385

A

DC cardioversion.

Answer 386

A

Implantable defibrillator.

Answer 387

A

Very common, generally benign arrhythmias caused by premature discharge. The patient may complain of symptoms of ‘skipped beats’.

Answer 388

A

Congenital.
Electrolyte disturbances e.g. hypokalaemia and hypocalcaemia.
A variety of drugs.

Answer 389

A

Palpitations.
Syncope.

Answer 390

A

Ischaemia.
Fibrosis of the atrium.
Inflammation.
Drugs.

Answer 391

A

CAD.
Cardiomyopathy.
Fibrosis.

Answer 392

A

RBBB or LBBB.

Answer 393

A

Fixed prolongation of the PR interval due to delayed conduction to the ventricles.

Answer 394

A

There are more P waves to QRS complexes because some atrial impulses fail to reach the ventricles and so you don’t get a QRS complex.

Answer 395

A

PR interval gradually increases until AV node fails and no QRS is seen.

Answer 396

A

There is a sudden unpredictable loss of AV conduction and so loss of QRS. PR interval is constant but every nth QRS complex is missing.

Answer 397

A

Atrial activity fails to conduct to the ventricles. P waves and QRS complexes therefore occur independently.

Answer 398

A

A ‘W’ shape would be seen in the QRS complex of lead V1 and a ‘M’ shape in V6.

WiLLiaM.

Answer 399

A

A ‘M’ shape would be seen in the QRS complex of lead V1 and a ‘W’ shape in V6.

MaRRoW.

Answer 400

A

DC cardioversion.

Answer 401

A

Gangrene.

Answer 402

A

Exercise induced angina.
Intermittent claudication.

Answer 403

A

Critical limb ischaemia.
Vascular dementia.

Answer 404

A

Gangrene.

Answer 405

A

A symptom describing muscle pain that is caused by moderate ischaemia. Intermittent claudication occurs when exercising (stress induced) and is relieved with rest.

Answer 406

A

Critical ischaemia.

Answer 407

A

Normal. Intermittent claudication is stress induced so at rest and when you begin exercise O2 supply is able to meet demand.

Answer 408

A

Low. O2 supply is unable to meet demand -> anaerobic respiration -> lactic acid.

Answer 409

A

Low. It takes longer to recover as you’re getting rid of the lactic acid. After a long rest however it is normal.

Answer 410

A

Muscle cramps.

Answer 411

A

Blood supply is barely adequate for life. There is no reserve for an increase in demand. Very severe, cells are dying.
O2 supply is ALWAYS low, even at rest!

Answer 412

A

Rest pain.
Classically nocturnal.
Ulceration.
Gangrene.

Answer 413

A

Embolism/thrombosis.

Answer 414

A

Pain.
Pale.
Paralysis.
Paraesthesia.
Perishing cold.
Pulseless.

Answer 415

A

Stroke.
MI.

Answer 416

A

Hypertension.
Hyperlipidaemia.
Diabetes.
Smoking.
Obesity.

Answer 417

A

Risk factor modification.
Vein bypass for critical leg ischaemia.
Balloon angioplasty.
Stenting of occlusion.
Amuptation.

Answer 418

A

ABCDE.
Morphine.
Oxygen (if hypoxic).
Nitrates.
Aspirin.

Answer 419

A

Thrombolysis using streptokinase.

Answer 420

A

Streptokinase.

Answer 421

A

Mitral stenosis.

Answer 422

A

Mitral regurgitation.

Answer 423

A

Aortic stenosis.

Answer 424

A

Aortic regurgitation.

Answer 425

A

Duke’s criteria.

Answer 426

A

Positive blood culture with typical IE microorganism.
Positive echo showing endocardial involvement.

Answer 427

A

Group A strep e.g. s.pyogenes.

Answer 428

A

Aortic dissection!

Answer 429

A

Digoxin is a cardiac glycoside.

Answer 430

A

Fatty streaks.

Answer 431

A

mAP = DP + 1/3 PP.

Answer 432

A

When blood flow increases following occlusion to arterial flow.

Answer 433

A

BP = CO x TPR.

Answer 434

A

SV = EDV - ESV.

Answer 435

A

CO = SV x HR.

Answer 436

A

Fontaine classification.

Answer 437

A

There is increased LA pressure. This stretches the myocytes in the atria and irritates pacemaker cells -> AF.

Answer 438

A

Pulmonary congestion -> pulmonary hypertension causes a raised JVP.

Answer 439

A

Mitral stenosis means ventricles don’t fill completely -> reduced EDV -> reduced SV -> reduced CO and so breathlessness.

Answer 440

A

Sinus tachycardia.
Atrial fibrillation.

Answer 441

A

Angina.
Intermittent claudication.

Answer 442

A

Critical limb ischaemia.

Answer 443

A

Raised JVP.
Ascites.

Answer 444

A

Class 1: heart disease is present but there is no limitation.
Class 2: comfortable at rest but slight limitation on activity - mild HF.
Class 3: marked limitation - moderate HF.
Class 4: SOB at rest, all activity causes discomfort (moderate HF).

Answer 445

A

Pleural effusion.
Dilated pulmonary arteries.
Kerley B lines.
Bat’s wings.
Cardiomegaly.

Answer 446

A

Can develop 2-10 weeks after an MI.

Answer 447

A

Myocardial injury stimulates formation of autoantibodies against the heart. Cardiac tamponade may occur. Dressler’s is a secondary form of pericarditis.

Answer 448

A

Fever.
Chest pain.
Pericardial rub.

Occurs 2-10 week after MI.

Answer 449

A

MONA.
PCI or streptokinase.
Aspirin and clopidogrel.
LMWH.
Anti-anginals e.g. beta blockers, CCB, nitrates.
Preventing a secondary CV event: ACEi, aspirin, statins, RF modification.

Answer 450

A

It activates anti-thrombin, which then inhibits thrombin and factor 10a.

Answer 451

A

Reversible tissue damage as a result of impaired vascular perfusion depriving tissues of nutrients and oxygen.

Answer 452

A

Irreversible tissue death due to ischaemia.

Answer 453

A

Due to reduced CO.

Answer 454

A

Due to pulmonary oedema.

Answer 455

A

Due to activation of the sympathetic system.

Answer 456

A

Decreased venous pressure.
RAAS activation -> sodium and H2O retention.

Answer 457

A

Low blood pressure.
Rapid pulse.
Low urine output.
Pallor.
Sweating.

Answer 458

A

Breathlessness.
Wheeze.
Rash.
Swollen lips/tongue.
Low BP.
Chest tightness.

Answer 459

A

Vasodilation.
Increased vascular permeability.

Answer 460

A

Seafood.
Nuts.
Grains.

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Cardiovascular Flashcards

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