Mechanism of atheroma and infarction

Question 1

Atheroma

Answer 1

Degeneration of the walls of the arteries caused by accumulated fatty deposits and scar tissue, leading to restriction of the circulation and a risk of thrombosis.

-weakened wall so risk of it rupturing

Question 2

Infarction

Answer 2

Obstruction of the blood supply to an organ or a region of a tissue, typically by a thrombus (blood clot) or embolus causing local death of the tissue

Question 3

so, what is a myocardial infarction?

Answer 3

infarction in the myocardium, local death of the tissue

Question 4

aneurysm

Answer 4

excessive localised swelling of the wall of an artery

Question 5

what can cause an infarction?

Answer 5

an aneurysm

Question 6

what the difference between arteries in the heart and other organs and the consequence of this?

Answer 6

cardiac arteries, are functional end arteries

with most tissues, if one artery gets blocked there’s another route - but not in the heart

if there is a thrombus or embolus in heart, the tissue can be starved of oxygen

Question 7

what is atherosclerosis?

Answer 7

A complex inflammatory process

• mediated by LDL and angiotensin II. An ongoing systemic inflammatory disease makes it all worse (eg. rheumatoid arthritis)
• LDL in blood get deposited in arteries but made a lot worse by ongoing inflammatory processes

Question 8

common sites for atherosclerosis

Answer 8

1. Carotid Arteries - aorta to brain. if blocked, starving big areas of the brain of oxygen. circle of willis is a network of arteries underneath the brain which supply diff parts of the brain with blood - a clot here means you can have a stroke and where the clot is determines which part of the brain is starved and what your symptoms are.
2. Coronary arteries - functional end arteries, so a clot or an atherosclerotic plaque in the coronary artery starves part of the heart because there is no other arterial route to get there
3. Iliac arteries - in pelvis about to go legs
4. Aorta

Question 9

initiation of atherosclerosis (1)

Answer 9

Low levels of inflammation, necrotic cell debris and free radicals in the endothelium cause oxidation of LDL’s

Endothelial cells start to become a little bit inflamed and activated and express cytokines and adhesion molecules as part of a normal inflammatory response.

Causes circulating monocytes, which are looking for infected cells, to bind to the activated endothelium. They do this by expressing adhesion molecules, undergo diapedesis move through the tissue into the intima layer.

Once monocytes are in the tissue they differentiate into tissue macrophages which release their own inflammatory mediators which attract more macrophages (appropriate immune response IF there was a virus)

Question 10

plaque formation (2)

Answer 10

macrophages begin to absorb LDL’s from the circulation and become foam cells

these activated foam cells release growth factors which affect the medial muscle layer: they cause smooth muscle cells to cross the internal elastic lamina into the intima

the activated smooth muscle cells once in the intimate release growth factors, collagen and elastin - not secreting collagen and elastin in the right place

Question 11

plaque maturation (3)

Answer 11

smooth muscle cells accumulate LDL and become smooth muscle foam cells. they continue to make extracellular matrix of elastin and collagen, which forms a fibrous plaque - this can weaken the wall of the vessel and can get bigger and bigger, narrowing the lumen

this plaque is underneath the endothelium and it means that foam and muscle cells in this region become hypoxic because of the poor oxygen supply.

the cells begin to undergo apoptosis and release their fat that accumulates in the intimacy underneath the fibrous cap - called the lipid core.

the dying cells also release matrix metalloproteases (and other enzymes) which can break down the fibrous matrix towards the edge of the fibrous plaque - may be vulnerable to enzymatic digestion

Question 12

calcification and instability (4)

Answer 12

calcium deposits may form around the atheroma - visible on a CT scan. affect arterial compliance and they make the vessel stiff and stop the vessel stretching - can be dangerous when the vessel can’t stretch a higher pressures

could be an advantage?

Question 13

why might a few calcium deposits around the plaque be advantageous?

Answer 13

prevents the fibrous plaque from breaking off, so it can’t expose the underlying collagen - would lead to a thrombus event and the formation of a blood clot

Question 14

when does atheroma begin?

Answer 14

when we are young

• macrophage foam cells develop between birth and 10 yrs old
• 65% of people have smooth muscle foam cells by puberty
• maturation of fibrous cap at 30-40 yrs

Question 15

plaque rupture (5)

Answer 15

plaque can rupture in 2 situations:

1) if the central core becomes too large
2) the dying cells succeed in releasing enzymes that digest the fibrous plaque

this results in the sub-endothelium being exposed (the endothelium is normally an anticoagulant surface) - collagen is exposed.

collagen forms very good bases for clotting, and this means there is a pro-coagulant surface in an artery - thrombus could form which may occlude the artery.

Question 16

what are the consequences of atheroma?

Answer 16

1. Occlusive Thrombosis
2. Thromboembolism
3. Aneurysm due to wall weakness

Question 17

occlusive thrombosis - consequence of atheroma

Answer 17

• e.g. myocardial infarction, coronary artery blocked

- commonly known as a heart attack, occurs when blood flow decreases to a part of the heart, damaging the heart muscle

Question 18

thromboembolism - consequence of atheroma

Answer 18

• e.g. ischaemic stroke, thrombus in the carotid or circle of willis, causing severe symptoms
• in this case, there is an obstruction due to an embolus from elsewhere in the body (usually carotid artery)
• blocks the blood supply to the brain

Question 19

aneurysm due to wall weakness - consequence of atheroma

Answer 19

• e.g. aortic aneurysm
• causes weakness in the wall of the aorta and increases the risk of an aortic rupture
• rupture occurs - massive internal bleeding, unless it’s treated immediately, you get shock and ultimately death

Question 20

Is Atherosclerosis Inevitable?

Answer 20

-you have to look at lifestyle choices, genetic or environmental influences, vulnerability depending on ethnicity

Question 21

what does systemic inflammation promote?

Answer 21

atheroma formation

Question 22

rheumatoid arthritis can cause?

Answer 22

systemic inflammation, and atherosclerosis

Question 23

parasitic infections can cause what?

Answer 23

chronic inflammation, and therefore atherosclerosis

Question 24

what can a plaque cause?

Answer 24

1. arterial occlusion
2. venous occlusion
3. myocardial infarction

Question 25

arterial occlusion - consequence of plaque

Answer 25

• in cardiac and carotid arteries
• anything downstream from arterial occlusion becomes starved of oxygen (ischaemia)
• reduced BF can cause angina during exercise
• thrombus can become detached, blocking the cardiac arteries causing serious damage/death

Question 26

venous occlusion - consequence of plaque

Answer 26

• this occlusion doesn’t cut off the blood supply, but will cause pain and swelling because hydraulic pressure causes oedema
• a thrombus may detach and return to RHS of the heart, enter the pulmonary circulation and cause a pulmonary embolism

Question 27

what is a haemorrhagic myocardium?

Answer 27

the artery has burst and bled into the tissue, reducing blood supply

Question 28

angina and MI

Answer 28

even if you have angina, you might not necessarily get an MI

Question 29

what is the difference between stable and unstable angina?

Answer 29

Stable Cardiac Angina

• Due to permanent flow limitation
• Not necessarily infarction

Unstable Cardiac Angina

• Due to transient thrombosis
• Not necessarily infarction
• Can get sudden pain

Question 30

MI

Answer 30

• Due to complete occlusion of a vessel
• all the tissue downstream of the thrombus will die
• heart attack

Question 31

how can you identify MI from an ECG scan?

Answer 31

• Damaged heart tissue doesn’t depolarise properly so this section is elevated above the baseline (“ST ELEVATED Myocardial Infarction”)
• Recognising the STEMI is one of the most fundamental things in interpreting ECG

Question 32

Complications of MI

Answer 32

• Acute cardiac failure
• Conduction problems – arrhythmia
• Papillary damage – valve dysfunction
• Mural thrombosis – stroke
• Wall rupture
• Chronic heart failure – myocardial scarring

Question 33

is a stroke always caused by a thromboembolism?

Answer 33

no, a stroke can have a non-thromboembolic cause

Question 34

how can a thromboembolism cause a stroke?

Answer 34

• Thrombus at carotid plaque rupture travels into smaller cerebral vessels
• 85% of strokes from carotid atheroma rupture
• 15% of strokes from stasis of blood in left atrium due to arrhythmia

Question 35

how does a non-thromboembolic stroke occur?

Answer 35

• Due to hypo-perfusion, loss of BP ( e.g. heart failure, haemorrhage, shock)
• Or aneurysm rupture and bleeding in the brain

Question 36

difference between a thrombus and an embolus?

Answer 36

embolus is a piece of blood clot that is unattached and is capable of travelling along the vessels

thrombus is a clot formed due to the blood coagulation process, and it doesn’t travel along the vessels