Haemodynamic disorders thrombosis and shock

Question 1

What are the 5 causes of oedema

Answer 1

1. Increased hydrostatic pressure
2. Reduced plasma oncotic pressure
3. Lymphatic obstruction
4. Salt retention
5. Leaky endothelium

Question 2

Give examples of scenarios that result in increased hydrostatic pressure

Answer 2

1. Impaired venous return
   - CHF
   - Constrictive pericarditis
   - Ascites (liver cirrhosis)
   - Venous obstruction or compression (thrombosis or external pressure e.g mass)
   - Lower extremity inactivity with prolonged dependency
2. Arteriolar dilation
   - Heat
   - Neurohumoral dysregulation

Question 3

Give examples of scenarios that reduce plasma oncotic pressure

Answer 3

• malnutrition
• liver cirrhosis (ascites)
• Protein losing glomerulopathies (nephrotic syndrome)
• Protein losing gastroenteropathy

Question 4

Give examples of clinical scenarios that result in lymphatic obstruction

Answer 4

inflammatory
neoplastic
postsurgical
post-irradiation

Question 5

Give examples of clinical scenarios that cause salt retention

Answer 5

• Excessive salt intake with renal insufficiency
• Increased tubular reabsorption of Na > renal hypoperfusion, increased renin-angiotensin-aldosterone secretion

Question 6

Increased endothelial permeability is the pathogenesis of oedema occurring in…

Answer 6

1. local anaphylaxis
2. adult respiratory distress syndrome

Question 7

Development of generalised oedema in chronic liver failure involves

Answer 7

1. increased renal Na retention
2. increased renal renin secretion
3. reduced plasma colloid osmotic pressure

Question 8

Intact endothelium synthesizes and secrete or ‘presents’

Answer 8

1. thrombomodulin
2. adenosine diphosphatase (ADP-ase)
3. prostacyclin (PGI2)
4. plasminogen activator
5. NO
6. Heparin like molecules

Question 9

What is an exudate

Answer 9

Protein rich fluid that accumulates due to increase in vascular permeability caused by inflammatory mediators.

Protein rich, cloudy due to presence of white cells.

Question 10

What is a transudate

Answer 10

Non inflammatory and protein poor effusions (e.g heart failure etc)

Normally translucent, straw coloured with the exception of peritoneal effusions caused by lymphatic blockage (chylous effusion), can be milky due to presence of lipid.

Question 11

Compare and contrast hyperemia and congestion

Answer 11

Both stem from increased blood volumes in tissues.

Hyperemia - active process, active arteriolar dilation (e.g sites of inflammation or muscle during exercise). Leads to increased blood flow and oxygen delivery. RED TISSUE

Congestion - passive process due to reduced venous outflow, can be systemic (CHF) or localised (DVT). CYANOTIC. Can lead to scarring.

Question 12

Outline the general sequence of events leading to haemostasis at the site of vascular injury

Answer 12

1. Arteriolar vasoconstriction
   - Occurs immediately, due to neurogenic mechanisms and release of endothelin.
   - Transient effect.
2. Primary haemostasis
   - Formation of the platelet plug
   - Disrupted endothelium exposes subendothelial vWF and collagen which promotes platelet adherence and activation.
   - Activated platelets release secretory granules and change their shape (spiky increasing their surface area)
   - Secretion promotes more platelets and aggregation = primary haemostatic plug.
3. Secondary haemostasis
   - Tissue factor is exposed by vasular injury.
   - A membrane bound glycoprotein (found in subendothelial cells).
   - Tissue factor binds to factor 7, kicks off coagulation cascade. Thrombin cleaves fibrinogen to fibrin = mesh network + potent activator of platelets = more platelets = consolidation of plug.
4. Clot stabilisation and resorption.
   - Fibrin and platelet contract = solid permanent plug.
   - Counter-regulatory mechanisms e.g TPA limit clotting to site of injury and eventually lead to clot resorption and repair.

Question 13

What cells are the central regulators of haemostasis

Answer 13

Endothelial cells, balance between the antithrombic/prothrombotic activites determine if thrombus formation, propogation or dissolution occur.

Question 14

What shape are platelets are where are they found

Answer 14

• Anucleate disc shaped cell shed from megakaryocytes in bone barrow and float in circulation.

Question 15

What critical role do platelets play in haemostasis

Answer 15

Formation of primary plug
Provide a surface that binds and concentrates activated coagulation factors.

Question 16

What two granules do platelets release

Answer 16

• Alpha granules: Have the adhesion molecule P-selectin in their membrane. Contain proteins involved in coagulation (vWF, V, fibrinogen), as well as factors involved in healing like PDGF).
• Dense bodies/delta granules: Contain ADP, ATP, calcium, serotonin, adrenaline.

Question 17

4 steps involved in formation of primary plug

Answer 17

1. Platelet adhesion
2. Platelet shape change
3. Secretion of granules
4. Aggregation

Question 18

Outline how platelet adhesion works (first step in plug formation)

Answer 18

Mediated by interactions between Gp1b (platelet receptor) and vWF.
Gp1a/IIa also invovled

Question 19

Outline how platelets change shape (second step in plug formation)

Answer 19

• Go from smooth discs to spiky sea urchins that increase SA.
• Results in a conformational change in cell surface glycoprotein (iib/iiia) which increases affinity for fibrinogen AND translocation of negatively charged phospholipids (bind calcium and acts as sites for assembly of coag complexes)

Question 20

Outline the secretory step of platelet plug formation

Answer 20

Occurs alongside the change in shape (these two steps are often referred together as platelet activation).
Triggered by multiple factors including thrombin and ADP.
Thrombin activates platelets by GPCR (protease activated receptor).
ADP is a component of dense granules. It acts as mediator for further platelet activation (i.e recruitment).
Activated platelets produce TXA2 which induces platelet aggregation.

Question 21

Outline the steps in platelet aggregation.

Answer 21

Platelet activation is followed by platelet aggregation.
Conformational change of GPIIa/IIIa allows fibrinogen to bind, which forms a bridge between adjacent platelets.
Initial wave of aggregation is reversible.
Thrombin is then activated, promotes more platelet aggregation + irreversible platelet contraction.
Thrombin also converts fibrinogen into the insoluble fibrin = secondary haemostatic plug.

Question 22

Following injury to a small artery, the formation of a temporary platelet plug is… (4 things)

Answer 22

1. unaffected by therapeutic doses of heparin
2. unaffected by therapeutic doses of dicoumarol
3. associated with local vasoconstriction
4. is not followed by the conversion of insoluble plasma fibrinogen to insoluble fibrin

Question 23

What does the PT asssess

Answer 23

extrinsic pathway

Question 24

What does PTT assay scree for

Answer 24

Intrinsic pathway

Question 25

Coagulation cascade ####

Answer 25

###

Question 26

Anti-thrombotic properties of intact endothelium that are directed at platletets

Answer 26

PGI2 (COX1)
NO (eNOS)
ADPase (inhibits ADP)

Question 27

Anti-thrombotic properties of intact endothelium that are directed at coagulation

Answer 27

• Thrombomodulin activation of Protein C/S
  (thrombomodulin protein C receptor bind thrombin and protein C, this activates protein C/ S complex that inhibits coagulation via Va and VIIIa).
• Alpha macroglobulin
• Heparin like molecules activate Antithrombin III (inhibits thrombin and factors 9,10,11,12)

Question 28

Anti-thrombotic properties of intact endothelium that are directed at fibrinolysis.

Answer 28

tPA

Question 29

Prothrombotic properties of the injured endothelium that are directed at platelets

Answer 29

vWF
pAF

Question 30

Prothrombotic properties of the injured endothelium that are directed at coagulation

Answer 30

Tissue facor
binding factors 9a, 10a
Factor V

Question 31

Pro-thrombotic properties of the injured endothelium that are directed fibrinolysis

Answer 31

t-pA inhibitor

Question 32

What is virkows triad

Answer 32

Abnormalities that lead to thrombosis
1. Endothelial injury
2. Stasis or turbulent blood flow
3. Hyper-coagulability of blood

Question 33

How does abnormal blood flow contribute to thrombosis

Answer 33

Normally flow is laminar, and platelets travel in centre of the lumen. Disruption to laminar flow leads to
- Platelets touching endothelium inappropriately
- Promotion of endothelial activation (changes expression of pro-inflammatory factors)
- Prevents washout and dilution of activated clotting factors (i.e clots remain and clotting factor inhibitors cant get in)

Question 34

How does endothelial injury contribute to thrombosis

Answer 34

Exposed vwf and TF
activated endothelial cells secrete PAI’s which limit fibronolysis and down regular t-PA
Activated endothelial cells also downregulate thrommbomodulin

Question 35

How does a hypercoagulable state pre-dispose to thrombosis (give a genetic example)

Answer 35

Alterations in coagulation factors can be genetic or acquired.
V gene mutations
- 2-15% of white population
- 60% with recurrent DVT
carry a mutation call the Leiden mutation, renders factor V resistant to cleavage by activated protein C (counter regulatory pathway is lost)

Question 36

What conditions pre-dispose to thrombosis

Answer 36

1. Polyarteritis nodosa
2. Giant cell arteritis
3. Buerger’s disease
4. T akayasu’ s disease

Question 37

What 4 things might a PE cause

Answer 37

1. pulmonary artery atherosclerosis
2. chronic pulmonary hypertension 3. no clinical effect
3. cardiogenic shock

Question 38

What 4 things might a fat emboli cause

Answer 38

1. result from severe soft tissue trauma
2. results from abdominal trauma in the alcoholic 3. cause DIC
3. cause the ARDS

Question 39

Relationship between mitral stenosis, PE and infarction.

Answer 39

if a patient with mitral stenosis has a pulmonary embolus, infarction is esp. likely to occur BECAUSE
The bronchial arterial supply is reduced in mitral stenosis

Question 40

What is the fate of a thrombus

Answer 40

Fate of a thrombus
1. Propogate: causing progressive complete vessel obstruction (by accumulation of additional platelets and fibrin)
2. Embolism > Dislodge and travel to other sites (PE)
3. Dissolution by fibrinolytic activity
- Only in recent thrombi, once established they become resistant to lysis (i.e this is why you cant give t-pa too late)
4. Organization & recanalization (small amount of lumen re-established, clot becomes part of the wall)

Question 41

What is a fat embolisation characterised by

Answer 41

Pulmonary insufficiency
Neurologic symptoms
Anaemia
Thrombocytopenia
Death (in 5-15%)

1. result from severe soft tissue trauma
2. results from abdominal trauma in the alcoholic
3. cause DIC
4. cause the ARDS

Question 42

4 things about PE

Answer 42

1. fatal PE is usually due to impaction of a large embolus in the main pulmonary artery and its branches, or in the RV
2. to do this > the embolus must be large, and has to come from the leg, normally
3. thrombi can occur in both pelvic and leg veins
4. but in fatal pulmonary embolus > the cause is rarely from the pelvis