Week 8 Cardiovascular 1

Question 1

Define Ischaemic heart disease.

Answer 1

Inadequate blood supply to the myocardium

Question 2

What causes ischaemic heart disease?

Answer 2

Most comminly due to reduced coronary blood flow, almost always due to atheroma +/- thrombus.

Less common cause are due to amyloid accumulation or due to surgical problems

Question 3

what additional complications can occur with ischeamic heart disease?

Answer 3

myocardial hypertrophy, usually due to systemic hypertension–> mainly left ventricular hypertrophy

Question 4

What is the pathogenesis of ischaemic heart disease?

Answer 4

Autoregulation of coronary blood flow breaks down if > 75% occlusion

> 90% stenosis may be insufficient at rest

low diastolic flow especially subendocardial

myocyte dysfunction/death from ischaemia

Active aerobic metabolism of cardiac muscle

Question 5

What are the different type of angina pectoris?

Answer 5

typical/stable –. fixed obstruction, predictable relationship to exertion

crescendo/unstable –> often due to plaque disruption

variant/Prinzmetal –> coronary artery spasm

Question 6

What type of angina pectoris is the most dangerous?

Answer 6

Unstable angina as the angina increasingly gets worse

Question 7

What are the ischaemic heart disease syndromes?

Answer 7

angina pectoris

acute coronary syndrome

sudden cardiac death

chronic ischaemic heart disease

Question 8

What is acute coronary syndrome?

Answer 8

It refers to a group of conditions due to decreased blood flow in the coronary arteries such that part of the heart muscle is unable to function properly or dies.

Question 9

Give examples of acute coronary syndrome

Answer 9

acute myocardial infarction (+/- ecg ST elevation)

crescendo/unstable angina

Question 10

What occurs in subendocardial myocardial infarction?

Answer 10

The subendocardial myocardium is relatively poorly perfused under normal conditions

Question 11

How can the subendocardial myocardium infarct without any acute cornary occlusion?

Answer 11

If there is:
Stable athermanous occlusion of the coronary circulation

An acute hypotensive episode

Question 12

Where is it common to get coronary atheroma and thrombus?

Answer 12

Occur in bifurcation, junctions of the coronary arteries or if there is any abnormalitis.

Due to the shear pressures at the time

Question 13

What is the morphology of heart after MI within the fisrt 24 hours? Explain both gross and microscopic appearance

Answer 13

Gross appearance –> Normal/dark

Microscopic appearance –> necrosis and neutrophils

Question 14

What is the morphology of heart after MI within post 1-2 days? Explain both gross and microscopic appearance

Answer 14

Gross appearance – more necrosis and neutrophils

Question 15

What is the morphology of heart after MI within post 3-7 days? Explain both gross and microscopic appearance

Answer 15

Gross appearance –> hyperaemic borderm, yellow centre

Microscopic appearance –> macrophages

Question 16

What is the morphology of heart after MI within post 1-3 weeks? Explain both gross and microscopic appearance

Answer 16

Gross appearance –> red/grey

Microscopic appearance–> granulation tissue

Question 17

What is the morphology of heart after MI within post 3-6 weeks? Explain both gross and microscopic appearance

Answer 17

Gross –> scar

Microscopic –> collagen scar

Question 18

What are the different blood markers of cardiac myocyte damage? When can they be detected?

Answer 18

Troponins T & I
detectable 2 – 3h, peaks at 12h, detectable to 7 days
raised post MI but also in pulmonary embolism, heart failure, & myocarditis.

Creatine kinase MB
detectable 2 – 3h, peaks at 10-24h, detectable to 3 days

Myoglobin
peak at 2h but also released from damaged skeletal muscle

Lactate dehydrogenase isoenzyme 1
peaks at 3days, detectable to 14days

Aspartate transaminase
Also present in liver so less useful as a marker of myocardial damage

Question 19

Why is creatine kinase not the best marker for MI?

Answer 19

Because creatine kinase is seen in muscles all around the body and not just in the heart.

CK Mb which is mainly found in cardiac is also found in skeletal

Question 20

What is the prognosis of MI?

Answer 20

20% 1-2h mortality – sudden cardiac death

Question 21

What are the complications of MI?

Answer 21

Mural thrombus and emboli
arrhythmias, ventricular fibrillation (75-95%) & sudden death

ischaemic pain

left ventricular failure (60%) & shock (10-15%)

Pericarditis

deep leg vein thrombosis & pulmonary embolus (15-40%)

ventricular aneurysm

autoimmune pericarditis (Dressler’s syndrome

Contractile dysfunction and chronic cardiac failure

Infarct expansion

Question 22

What can be the possible cause of chronic ischaemic heart disease?

Answer 22

coronary artery atheroma produces relative myocardial ischaemia & angina pectoris on exertion

risk of sudden death or MI

possible previous occult MIs

crescendo or unstable angina - evolving plaque

variant angina - coronary arterial spasm

Question 23

What is familial hypercholesterolaemia?

Answer 23

A genetic disorder characterized by high cholesterol levels, specifically very high levels of low-density lipoprotein

Question 24

What are the common type of mutation in familial hypercholesterolaemia?

Answer 24

Low density lipoprotein receptor gene (1 in 500)

Apolipoprotein B (1 in 1000)

Question 25

What are the possible consequence of heterozygote familial hypwecholesterolaemia?

Answer 25

develop xanthomas – tendons, perioccular, corneal arcus – and early atherosclerosis

Question 26

What is the cause of familial hypercholesterolaemia?

Answer 26

Mutation in genes involved in cholesterol metabolism

Autosomal dominant but variant in penetrance

Question 27

What is the treatment for heterozygote familial hypercholesterolaemia?

Answer 27

Early primary treatment with statins (hydroxymethyglutaryl CoA reductase inhibitors) is effective

Question 28

Why is blood pressure physiologically regulated?

Answer 28

To ensure the perfusion of organs sufficient to maintain function

Prevents higher flow that exceeds metabolic demands, increases damage to blood vessels and thus to organs

Question 29

When is blood pressure high?

Answer 29

Normal = 120/80mmHg”

Abnormal: Sustained diastolic of 90mmHg

Abnormal: Sustained systolic of 140mmHg

95% of cases are “primary”
aka “idiopathic”, “benign”, “essential”,

Question 30

Dysfunction over a long period of time of what physiological systems cause primary hypertension?

Answer 30

Cardiac baroreceptors

Renin-angiotensin- aldosterone system

Kinin-kallikrekin system

Naturetic peptides

Adrenergic receptor system

Autocrine factors produced by blood vessels

Autonomic nervous system

Question 31

What is the pathway that net set balance causes increase in BP?

Answer 31

Increased intravascular volume and volume delivery to the heart augment cardiac output and therefore blood pressur.

Results in tissue perfusion exceeding metabolic demand –> autoregulation of blood flow which increases vascoconstriction to reduce blood flow.

This results in a steady-state hemodynamic pattern of elevated blood pressure with increased systemic vascular resistance and normal cardiac output.

Question 32

What are the possible effect of hypertension?

Answer 32

Cardiovascular –> hypertensive heart disease

Renal failure

Cerebrovascular accident

Question 33

What occurs in hypertensive heart disease?

Answer 33

Systemic hypertension leads to increased left ventricular blood pressure

Left ventricle hypertrophy without dilatation initially in response to increased work needed to pump blood

When the pressure is too great the left ventricle fails to pump blood at a normal rate and dilates

Question 34

Whattypes of arterial rupture are consequence of hypertensive cerebrovascular disease?

Answer 34

atheromatous (intracerebral haemorrhage) –> weak vessels with atheroma can rupture

berry aneurysm of the Circle of Willis (subarachnoid haemorrhage)

Question 35

What is the BP of malignant hypertension?

Answer 35

BP > 180/120 mmhg

Question 36

What are the signs and symptoms of malignant hypertension?

Answer 36

acute hypertensive encephalopathy

renal failure

retinal haemorrhages

Question 37

What are the complications of acute hypertensive encephalopathy?

Answer 37

Diffuse cerebral dysfunction:

Confusion, vomiting, convulsions, coma and death

Question 38

What are the causes pulmonary hypertension?

Answer 38

Loss of pulmonary vasculature
Secondary to left ventricular failure
Systemic to pulmonary artery shunting
Primary or idiopathic in children

Question 39

What pulmonary vasculature diseases can cause pulmonary hypertension?

Answer 39

Chronic obstructive lung disease

Pulmonary interstitial fibrosis (interstitial lung diseases)

Pulmonary emboli or thrombosis

Under ventilated alveoli

Question 40

What can be the consequence of pulmonary hypertension?

Answer 40

Increased right ventricular work to pump blood

Right ventricular myocardial hypertrophy initially without dilation

Later dilatation and systemic venous congestion as right ventricular failure develops

Question 41

What are cardiovascular risk factors?

Answer 41

Gender
Hypertension
Smoking
High blood cholesterol
Low blood high density lipoproteins
Diabetes
Sedentary lifestyle
Obesity – especially central obesity
High alcohol use
Ethnicity – south Asian

Question 42

What is the consequence of hypertension on the kidney?

Answer 42

Arterial intimal fibroelastosis

Hyaline arteriolosclerosis

Slow deterioration in renal function leading to chronic renal failure

Question 43

How does kidney produce aldosterone?

Answer 43

Renin Synthesized, stored in, and released from the juxtaglomerular apparatus in the wall of the afferent arterioles of the kidney

Cleaves angiotensinogen to angiotensin I

Angiotensin I is converted to active angiotensin II in many tissues

Angiotensin II stimulates adrenal cortex to produce aldosterone

Question 44

What are the effects of angiotensin 11 and aldosterone?

Answer 44

Angiotensin II
Potent natural vasoconstrictor
Very short half-life

Aldosterone
The physiological mineralocorticoid
Renal action causes sodium and thus water retention
Circulating blood volume increases

Question 45

What disease is caused by excess aldosterone secretion?

Answer 45

Conn’s syndrome

Question 46

What causes excess aldosterone secretion?

Answer 46

Usually due to adrenocortical adenoma
Possibly micronodular hyperplasia
Renal sodium and water retention
Hypertension
Elevated aldosterone, low renin
Potassium loss

Question 47

How is Conn’s syndrome diagnosed?

Answer 47

Diagnose by CT scan of adrenals in presence of these metabolic abnormalities

Question 48

What is phaechromocytoma?

Answer 48

Tumour of the adrenal medulla

Presents due to secretion of vasoconstrictive catecholamines – adrenaline and noradrenaline

Question 49

What is phaechromocytoma usually presented with?

Answer 49

Presents with:
Pallor
Headaches
Sweating
Nervousness
Hypertension

Question 50

How do you diagnose and treat phaeochromocytoma?

Answer 50

Diagnosed by 24hr urine collection for adrenaline metabolites

Surgical is the main treatment but usually bilateral so don’t want to take both of your adrenal glands

Question 51

What is Cushings disease?

Answer 51

Overproduction of cortisol by adrenal cortex

Question 52

What is the conseuqence of Cushings disease?

Answer 52

Cortisol has several metabolic effects including potentiating sympathetic nervous system activity and it has a mineralocorticoid (aldosterone-like) action on the kidneys, thus causing hypertension

Question 53

What causes Cushings disease?

Answer 53

An adrenocortical neoplasm usually an adenoma

A pituitary adenoma

A paraneoplastic effect of other neoplasms

Question 54

What is a common paraneoplastic effect of other neoplasm that causes Cushings disease?

Answer 54

Small cell lung carcinoma producing adrenocorticotrophic hormone that stimulates the zona fasciculata cells of the adrenal cortex to produce cortisol

Question 55

What is the consequence of renal artery stenosis?

Answer 55

Reduced blood pressure in kidney

Reduced blood pressure in renal afferent arterioles

Juxtaglomerular apparatus stimulated to produce renin

Renin-angiotensin system stimulates adrenal cortex zona glomerulosa cells to produce aldosterone

Question 56

What is the cause of hypertrophic cardiomyopathy?

Answer 56

Muscle contractile protein gene mutations