Pathophysiology of Ischaemia and Infarction

Question 1

What is meant by hypoxia?

Answer 1

•Relative lack of blood supply to tissue/organ leading to inadequate O2 supply to meet needs of tissue/organ: hypoxia

Question 2

What is hypoxic hypoxia?

Answer 2

(a) Low inspired O2 level
(b) Normal inspired O2 but low PaO2 – impairment of diffusion.

Question 3

What is anaemic hypoxia?

Answer 3

•Normal inspired O2 but blood abnormal

Question 4

What is stagnant hypoxia?

Answer 4

•Normal inspired O2 but abnormal delivery

(a) Local e.g. occlusion of vessel
(b) Systemic e.g. shock

Question 5

What is cytotoxic hypoxia?

Answer 5

•Normal inspired O2 but abnormal at tissue level – Something not working with oxygen delivery to the cells

Question 6

What are the factors afecting oxygen supply?

Answer 6

1. Inspired O2
2. Pulmonary function
3. Blood constituents (haemoglobin)
4. Blood flow (hypotension impairs supply)
5. Integrity of vasculature (atheroma, thrombus/embolus)
6. Tissue mechanisms – deliver oxygen to respiring organelles

Question 7

What are the factors affecting oxygen demand?

Answer 7

Tissue itself - different tissues have different requirements – fat, bone, connective tissue have lower demand than brain and heart

Activity of tissue above baseline value

Question 8

What are the two mechanisms for heart ischaemia?

Answer 8

Supply malfunction

Demand Malfunction

Question 9

Describe supply issues that can cause heart ischaemia

Answer 9

Coronary artery atheroma

Cardiac failure

Pulmonary function - disease and pulmonary oedema

Anaemia

Previous MI

Question 10

Where is the localised accumulation of lipid and fibrous tissue in atheroma?

Answer 10

In the intima of the arteries

Question 11

What is the link between atheroma and:

• Stable angina
• Unstable angina
• Thrombosis
  
  • Aneurysm

Answer 11

Stable angina - established atheroma in the coronary artery - pain on excertion

Unstable angina - complicated atheroma in coronary artery

Thrombosis - Ulcerated/fissured plaques - thrombosis - ischaemia and infarction

Aneurysm - Atheroma in aorta - walls of aorta become weakened and dilate

Question 12

What are the clinical consequences of atheroma?

Answer 12

MI

Transient ischaemic attack

Cerebral infarction

Abdominal aortic aneurysm

Peripheral vascular disease

Cardiac failure

Coronary artery disease - MI - Cardiac failure

Question 13

What are the

• Functional
• General
• Biochemical
• Cellular
• Clinical

Effects of Ischaemia?

Answer 13

Functional - Blood/O2 supply fails to meet demands of tissue - (can be because of a reduction in supply or an increase in demand)

General

• Acute
• Chronic - claudication
• Acute-on-chronic – sudden worsening of an already chronic condition

Biochemical

Results in Lactate production -

Lactate to pyruvate takes energy

Lactate can cause death of the cell

Cellular

Variable susceptibility to O2 depending on tissue type and the metabolic rate

Clinical

Dysfunction

Pain

Physical damage to specialised cells

Question 14

What are the outcomes of Ischaemia?

Answer 14

No clinical effect

Resolution / therapeutic intervention

Infarction

Question 15

What is meant by infarction?

Answer 15

•Ischaemic necrosis within a tissue/organ in living body produced by occlusion of either the arterial supply or venous drainage

Question 16

What are the possible aetiologies for infarction?

Answer 16

1. Thrombosis
2. Embolism
3. Strangulation e.g. gut
4. Trauma - cut/ruptured vessel

Question 17

What does the scale of damage of ischamia/infarction depend on?

Answer 17

1. Time period
2. Tissue/organ
3. Pattern of blood supply (consider collateral circulation – whereby one branch can still supply cells if one is blocked)
4. Previous disease

Question 18

What is the mechanism of tissue breakdown caused by infarction?

Answer 18

Anaerobic metabolism - cell death - liberation of enzymes

Question 19

What are the two types of necrosis?

Answer 19

Coagulative

Colliquitive

Question 20

Where do you find coagulative necrosis?

Answer 20

Heart, lung (most organs)

Question 21

What is coagulative ischaemia?

Answer 21

Typically caused by ischaemia or infarction

Architecture of the dead tissue is preserved for at least a coupls of days.

Injury denatures structural proteins and lysosomal enzymes - blocks proteolysis of damaged cells - maintains coagulated morphology.

Question 22

What is liquefactive necrosis/colliquitive necrosis?

Answer 22

Necrosis which results in a transformation of the tissue into a liquid viscous mass. Affected cell is completely digested by hydrolytic enzymes - circumscribed lesion of pus and fluid remains of necrotic tissue - debris is removed by white blood cells and a fluid space is left

Question 23

How does myocyte death occur as a result of infarction?

Answer 23

•Coronary arterial obstruction leads to a decreased blood flow to region of myocardium. Results in ischaemia, rapid myocardial dysfunction and myocyte death

Question 24

What happens within seconds of myocardial ischaemia?

Answer 24

•Anaerobic metabolism, onset of ATP depletion

Question 25

What happens in under two minutes of myocardial ischaemia?

Answer 25

•Loss of myocardial contractility (heart failure)

Question 26

What happens within a few minutes of myocardial ischaemia?

Answer 26

•Ultrastructural changes (myofibrillar relaxation, glycogen depletion, cell and mitochondrial swelling) ?reversible

Question 27

How long does it take for ischaemia to cause irreversible damage to the heart?

Answer 27

20-30 minutes

• Myocyte necrosis (disruption of integrity of sarcolemmal membrane leading to the leakage of intracellular macromolecules: blood tests) - Troponin?
• Injury to the microvasculature - over 1 hour

Question 28

What do areas of infarction look like less than 24 hours after insult?

Answer 28

• No change on visual inspection
• A few hours to 12 hours post insult, see swollen mitochondria on Electron Microscopy

Question 29

What organs do you see a plae infarct between 24 and 48 hours?

Answer 29

•Myocardium, spleen, kidney, solid tissues

Question 30

What organs show a red infarct?

Answer 30

Lung and the liver

Loose tissues, previously congested tissue; second/continuing blood supply, venous occlusion

Question 31

What can you see microscopically between 24 and 48 hours after infarction?

Answer 31

•Acute inflammation initially at edge of infarct; loss of specialised cell features

Question 32

What changes do you see in a pale and a red infarct about 72 hours after infarction?

Answer 32

Pale - yellow/white and red rim periphery

Red infarct - little change

•Microscopically: chronic inflammation; macrophages remove debris; granulation tissue; fibrosis

Question 33

What is the end result of infarction?

Answer 33

• Scar replaces area of tissue damage
• Shape depends on territory of occluded vessel
• Reperfusion Injury – damage when blood supply is restored – after period of ischaemia – inflammation and damage from free radicals

Question 34

What is the reparative process of myocardial infarction?

Answer 34

• Cell death
• Acute inflammation
• Macrophage phagocytosis of dead cells
• Granulation tissue – new vessel formation
• Collagen deposition (fibrosis)
• Scar formation

Question 35

What happens after 4-12 hours of myocardial infarction?

Answer 35

•Early coagulation necrosis, oedema, haemorrhage

Question 36

What happens 12-24 hours after myocardial infarction?

Answer 36

•Ongoing coagulation necrosis, myocyte changes, early neutrophilic infiltrate

Question 37

What happens 1-3 days after myocardial infarction?

Answer 37

•Coagulation necrosis, loss of nuclei and striations, brisk neutrophilic infiltrate

Question 38

What happens between 3-7 days of myocardial infarction?

Answer 38

•Disintegration of dead myofibres, dying neutrophils, early phagocytosis

Question 39

What happens during 7-10 days of myocardial infarction?

Answer 39

•Well developed phagocytosis, granulation tissue at margins (red rim if pale infarct)

Question 40

What happens between days 10-14 of myocardial infarction?

Answer 40

Well established granulation tissue with new blood vessels and collagen

Question 41

What happens during weeks 2- 8 after myocardial infarction?

Answer 41

•Increased collagen deposition, decreased cellularity

Question 42

What happens over 2 months of myocardial infarction?

Answer 42

•Dense collagenous scar

Question 43

What is meant by a transmural infarction?

Answer 43

ischaemic necrosis affects full thickness of the myocardium

Question 44

What is meant by a subendocardial infarction?

Answer 44

•ischaemic necrosis mostly limited to a zone of myocardium under the endocardial lining of the heart – just under the endocardial surface

Question 45

What are the histological features of transmural and subendocardial infarction?

Answer 45

•Histological features are the same

(repair time - granulation tissue stage followed by fibrosis - in subendocardial infarct possibly slightly shortened compared to transmural infarct)

Question 46

How are acute infarcts clasified?

Answer 46

•according to whether there is elevation of the ST segment on the ECG

Question 47

What are the features of a NSTEMI?

Answer 47

(non st elevating myocardial infarction)

no ST segment elevation but a significantly elevated serum troponin level

Question 48

What does a non-stemi correlate with?

Answer 48

subendocardial infarct

Question 49

What do the effects of infarction depend?

Answer 49

Site

Size of infarct

Death and dysfunction (pain)

Contribution of previous disease and infarction

Question 50

What are the complications of myocardial infarction?

Answer 50

• Immediate; early; late
• Sudden death; arrhythmias; angina; cardiac failure; cardiac rupture - ventricular wall, septum, papillary muscle; reinfarction; pericarditis; pulmonary embolism secondary to DVT; papillary muscle dysfunction - necrosis/rupture leads to mitral incompetence; mural thrombosis; ventricular aneurysm; Dressler’s syndrome