Hemostasis

Question 1

4 Stages of Normal Hemostasis

Answer 1

• 1- endothelial injury —> transient vasoconstriction to dec blood flow to site
• 2- primary homeostasis- exposed sub endothelial matrix —> platelet adhesion, activation and aggregation
• 3- secondary homeostasis - tissue factor —> coagulation cascade —> forming fibrin clot
• 4- fibrinolysis - counter-regaultion to dissolve clot/ restrict it to only site of injury

Question 2

2 Types of Thrombi

Answer 2

• White: mainly platelets forming platelet plaque; arteries

- Red: mainly RBCs forming thrombin; veins

Question 3

How are endothelial cells pro-thrombiotic?

Answer 3

• Sub endothelial cells express von Willebrand factor once exposed (glue b/n thrombogenic vessel wall and Gp1b receptors of platelets) platelet adhesion
• Activated endothelial cells make tissue factor —> extrinsic cascade AND secrete plasminogen activator inhibitor —> promotes thrombosis/dec fibrinolysis

Question 4

How are endothelial cells anti-thrombiotic?

Answer 4

• Endothelial prostacyclin (PG12) and NO —> vasodilation, muscle relax, inhibit platelet aggregation
• Adenosine disphosphatase degrades ADP (ADP normally inc aggregation)
• Heparin-like molecules which interact w/ antithrombin III to enhance it
• Thrombomodulin - activates protein C which cleaves factors 5a and 8a
• Tissue Factor Pathway Inhibitor - (TFPI) inactivates factor Xa and tissues factor 7a complex
• tPA- activates plasminogen —> plasmin (major fibrinolytic agent)

Question 5

2 Types of Platelet Granules

Answer 5

• Alpha granules - fibrinogen, vWF, clotting factors V and VIII, platelet factor 4, PDGF and p-selectin
• Delta granules - ADP, ATP, Ca++, serotonin, epi

Question 6

Primary Hemostasis

Answer 6

• Adhesion —> shape change —> platelets secrete granules (platelet activation) —> activated platelets now secrete TxA2 (vasoconstrictor that stimulates platelet aggregation) and delta granules secrete ADP (mediator of aggregation)
• Platelets (aggregates) held together by fibrinogen and GpIIb/IIIa receptors on platelets (cross links); GpIIb/IIIa inhibitors used as anticoagulants

Concomitant activation of thrombin stabilizes the platelet plug

Question 7

Closure Time

Answer 7

• Meas time required for platelet sample to plug a tube
• ID low platelet function if prolonged but does not tell cause
• Could be low platelet count, anti-platelet meds, reduction of proteins needed for platelet function, etc
• Can screen for Von Willebrand Disease but not all platelet function disorders AND cannot predict risk of preoperative bleeding

Question 8

Secondary Hemostasis

Answer 8

**Coag Cascade

• Series of amplifying enzymatic reactions that ends in thrombin (2A) activation —> fibrin (1a) formation
• Each factor starts as a proenzyme (inactive form) then activated and can go on to act as enzyme in subsequent reactions
• Each reaction requires activated enzyme, cofactor, proenzyme and phospholipid surface as scaffold
• Also use Ca++ ions (from delta granules)

Question 9

Extrinsic Path of Coag Cascade

Answer 9

Tissue injury —> tissue factor + 7a —> activates 10 —> activates prothrombin to thrombin (2) —> converts fibrinogen to fibrin (1a) AND activates factor 8 which helps in intrinsic path AND activates factor 13 which stabilizes fibrin polymers

Question 10

PT

Answer 10

• Screens extrinsic path; add tissue factor and phospholipids to plasma; prolonged PT and normal aPTT suggest factor VII deficiency (affected by warfarin)
• INR- international std ratio to compare PT b/n labs

Question 11

Intrinsic Path of Coag Cascade

Answer 11

Factor 12 (Hageman Factor) is activated by HMWK collagen —> activates 11 —> activates 9 —> w/ help from factor 8 they activated factor 10 —> activates prothrombin to thrombin (2) —> converts fibrinogen to fibrin (1a) AND activates factor 13 which stabilizes fibrin polymers

Question 12

aPTT

Answer 12

Screens intrinsic path (12, 11, 9, 8); prolonged if deficiency in one of these factors; Von Will Disease; lupus anticoagulant disorder; heparin use

Question 13

4 Roles of Thrombin

Answer 13

• Converts fibrinogen to fibrin
  
  • Activates factors 11, 5 and 8
  • Platelet activation through PARs
  • Pro-inflammatory

Question 14

2 Inhibitors of Coagulation Prod by Liver

Answer 14

• Antithrombin III - inactivates thrombin (2) and inhibits 9a-12a (heparin potentiates antithrombin III)
• Activated protein C - inhibits factors 5a and 8a; requires protein S co-factor and both require Vit K (so inhibited by warfarin)

Question 15

Fibrinolysis

Answer 15

• Fibrinolytic cascase is mainly carried out by plasmin (breaks down fibrin —> D-dimers)
• Plasminogen —> plasmin activated by tPA, urokinase-like plasminogen activator and streptokinase (bacterial product)

Question 16

von Willebrand Disease

Answer 16

deficiency in VWF - bleeding disorder

Question 17

Bernard Soulier Disease

Answer 17

• deficiency in Gpb1 receptor; defective platelet adhesion to endo wall

Question 18

Glanzmann Thrombasthenia

Answer 18

• deficiency in GpIIb/IIIa receptor; bleeding disorder b/c cannot aggregate

Question 19

4 Types of Hemorrhage

Answer 19

Hematoma- more of a solid lump; accumulation of blood enclosed in tissue or brain

• Petechiae - tiny (1-2 mm); usually due to platelet dysfunction/deficiency or loss of vascular wall support
• Purpura - medium (3-5 mm); similar causes to petechiae but also vasculitis (infection compromises vessel wall)
• Ecchymoses- larger (> 1 cm); subcutaneous bruises that change from red/blue —> blue/green —> gold/brown as Hb broken down to hemosiderin

Question 20

Virchow’s Triad

Answer 20

• 1- Endothelial Injury
  
  • Ulcerated atherosclerotic plaques, trauma, inflammation/vasculitis, stress of hypertension, toxic hypercholesterolemia, smoking toxins
  • Previous MI
• 2- Abnormal Blood Flow
  
  • Turbulence from plaques
  • Stasis from a fib (decreased contractions), aneurisms, arterial dilations,
• 3- Hypercoagulability
  
  • Genetic
    
    • Factor V Leiden mutation
    • Prothrombin gene mutation
    • Rare - deficiencies in antithrombin III, protein C or protein S
  • Acquired
    
    • Antiphospholipid Antibody Syndrome
    • Heparin Induced Thrombocytopenia-
  • Secondary hypercoagulable conditions: immobility, oral contraceptives, hormone replacement therapy, obesity, pregnancy, trauma, post-partum period

Question 21

Types of Shock

Answer 21

• Cardiogenic - low cardiac output due to pump failure
• Hypovolemic - low cardiac output due to loss of blood or plasma volume (usually must lose 20%)
• Septic - systemic vasodilation, blood pooling, systemic immune rxn, microvascular thrombosis and end organ damage
• Others - neurogenic (SC injury) or anaphylactic (systemic allergic reaction)

Question 22

Cardiogenic Shock

Answer 22

• Causes: MI, cardiac tamponade, pulmonary embolus, ventricular arrhythmia
• Treatment: Ionotropes to increase contractility or pressers; surgical bypass or percutaneous coronary intervention

Question 23

Hypovolemic Shock

Answer 23

• Causes: burns, trauma, exsanguination, insanguination
• Treatment: fluids and blood (if respond to this then confirms diagnosis of this type of shock); surgery to stop bleeding

Question 24

Septic Shock

Answer 24

• Causes: bacterial or fungal infections

- Treatments: ANTIBIOTICS; fluids, insulin, corticosteroids for adrenal damage; treat DIC

Question 25

4 Main Events of Septic Shock

Answer 25

• 1- Vascular
  
  • Vasodilation and inc permeability due to cytokines, dec perfusion (esp at micro vessels —> contributes to clot formation)
• 2- Thrombotic
  
  • Complement activated and activates endothelial cells, microvascular thrombosis (DIC); endotoxins from bacteria —> pro-clot
  • DIC - clot formation and fibrinolysis at same time so both clots and bleeding in arterioles and capillaries deep in tissues
• 3- Immunosuppressive
  
  • Hyper immune state then causes counter regulatory measures
• 4- Metabolic
  
  • Insulin resistance, hyperglycemia, gluconeogenesis
  • Waterhouse-Friderichsen Syndrome- adrenal gland necrosis or hemorrhage into adrenal gland

Question 26

ARDS

Answer 26

• ARDS (Adult Resp Distress Syndrome) - sometimes seen due to dec cardiac output, vascular permeability and endothelial damage in lungs —> pulmonary edema and acute damage (SEE HYALINE MEMBRANE FORMATION)
  
  • Edema damages alveoli so covered in membranous coating and no O2 gets to the area

Question 27

3 Stages of Shock

Answer 27

• 1- Nonprogressive
  
  • Redistribution to conserve vital organs; so less flow to extremities (cold and pale) as well as inc in cardiac output to compensate
• 2- Progressive
  
  • Lactic acidosis due to anaerobic metabolism; sign of hypoxia/anoxia (tissues not getting oxygen)
  • Lactic acidosis —> lower pH which blunts vasomotor response and worsens hypoxia and CO
• 3- Irreversible
  
  • Organs start to shut down and stop functioning
  • Free radicals and NO accumulate —> dec contractility of heart
  • Ischemic bowel —> further bacteremia
  • Renal shut down as tubular necrosis starts

Question 28

SIRS

Sepsis

Severe Sepsis

Multi-Organ Failure

Answer 28

• SIRS- systemic inflammatory response syndrome - non-specific response to infection or non-infectious inflammatory response; Must have 2+ of following:
  - Fever more than 38 deg C or less than 36 deg C
  - HR > 90 bpm
  - Resp rate > 20/min or PaCO2 < 32 mmHg
  - WBC > 12,000 or <4,000
• Sepsis - SIRS + source of infection
• Severe Sepsis - sepsis w/ organ dysfunction, hypotension or hypoperfusion
• Multi-organ dysfunction syndrome (multi-organ failure) - septic shock w/ 2+ organs failing

Question 29

Active v Passive Congestion

Answer 29

• Hypermia - active congestion - engorged w/ blood due to arterial dilation
• Passive congestion - reduction in blood flowing out of the tissue due to back up
  • Ex) Nutmeg liver due to upstream L heart failure and pulmonary edema
  • Ex) Back up in spleen and liver “congestive hepatosplenomegaly

Question 30

5 Causes of Edema

Answer 30

• 1- Inc hydrostatic pressure (too much pressure inside vessel forces fluid out)
  
  • Ex - deep vein thrombosis causing blockage
  • Results in transudate (protein poor)
• 2- Dec plasma osmotic pressure
  
  • Dec in albumin in plasma —> can no longer keep fluid from leaking out
  • Dec b/c less synthesized by liver or protein lost in urine if nephrotic syndrome
  • Results in transudate (protein poor)
• 3- Sodium Retention
  
  • Dec in renal blood flow causes kidney to retain Na+ and water via renin-angiotensin
• 4- Inflammation (inc blood vessel permeability) - local or generalized
  
  • Results in exudate - protein rich pus
• 5- Lymphatic Obstruction
  
  • Due to tumor, inflammation, surgery, radiation or scar; also parasitic infection
  • Also results in exudate

Question 31

Vegetations

Answer 31

non-bacterial but can become infected; can also be autoimmune or seen in cancer patients w/ inc hypercoagualbility

Question 32

4 Fates of Thrombus

Answer 32

• 1- Dissolution - rapid shrinkage and dissolution due to fibrinolysis
• 2- Propagation - further accumulation of fibrin and platelets
• 3- Embolization - parts of clot break-off and dislodge —> end up in another part of vasculature
• 4- Organization - recanalization; ingrowth of fibroblasts, smooth muscle cells, endothelial cells; form new lumen; flattens into a scar-like clump that narrows vessel

Question 33

5 Types of Emboli

Answer 33

• Thromboemboli - most common; systemic thromboembolic most commonly travel from heart to legs or brain
• Fat embolism - commonly from long bone fractures/trauma; clinically silent OR sudden dyspnea, tachypnea, tachycardia, restlessness, irritability, anemia, thrombocytopenia
• Air embolism - air in IV infusion, scuba diving, sudden change in atmospheric pressure, chest wall injury, back surgery in prone position (need 100 mL for effect)
• Amniotic fluid embolism - tears in placental membrane; squamous cells, lanuga hair, mucin or vernix cases fat travels from uterus —> lung (dyspnea, cyanosis, shock)
• Paradoxical embolism - when clot travels from venous to arterial circulation thru patent foramen ovale, arterial septal defect, patent ductus arteriosus

Question 34

4 Determinants of Likelihood of Infarction

Answer 34

• Organ’s vulnerability to hypoxia (ex- neurons very vulnerable- die after 4 min ischemia)
• Rate of development of vascular occlusion (faster the occlusion occurs = less time to compensate)
• Does organ have dual blood supply
• Oxygen content of blood (may have co-morbidity hat dec O2 content - inc chance of infarct)

Question 35

2 Types of Infarction & Which Organs?

Answer 35

• White- pale/anemic; normally if organ only has one source of blood flow (brain)
• Red- hemorrhagic; if organ still gets blood from other sources (lung, liver, transverse colon, intestine)

Question 36

6 Types of Necrosis

Answer 36

• Coagulative
  
  • Most common; architecture of dead tissue initially preserved; usual elicits acute inflammatory response (neutrophilic response peaks in 1-2 days then macrophages and fibroblasts)
• Liquefactive
  
  • Dead tissue is digested and transformed into liquid mass (usually pus); lose architecture; common in brain
• Gangrenous
  
  • Distinct form of coagulative; shrinkage and blackening; usually extremity or gallbladder; if infection on top of it then dry gangrene —> wet gangrene; if Chlostridium infection —> gas gangrene; treat w. surgical removal
• Saponification
  
  • Fat necrosis; breakdown —> fatty acids which react w/ calcium to form chalky white soap-like material; appears bright white on histo image; usually in fat of extremities, pancreas (pancreatitis) and omentum
  • Can occur as a result of direct injury; usually accompanied by hemorrhage and destruction of surrounding its; may also get fat embolism (usually MVAs or pedestrian struck by motor vehicle)
• Caseous
  
  • Associated w/ tuberculosis infection; granuloma look like cheese (necrotic centers and inflammatory borders)
• Fibrnoid
  
  • In autoimmune reactions when antigen-antibody complexes build up in blood vessel walls

Question 37

Hemosiderin

Answer 37

• By-product of iron metabolism; seen normally in certain cell types OR if iron overload
  
  • Normal circumstances- normal red cell breakdown; seen in mono-nuclear phagocytes of bone marrow, liver (Kipper cells) and spleen
  • Pathological - localized iron overload (seen in hemorrhage in form of bruises) OR systemic iron overload (ex- hereditary hemochromatosis)
• Left behind by dead cells (not broken down by macrophages)
• Gold/brown granular pigment (seen in images) OR can stain iron and it appears blue