Transfusion/Coagulation Flashcards

Question 1

Q

What is oxyhemoglobin blood product made up of?

Answer

A

13 g/dl of polymerized bovine hemoglobin in LRS

Bovine hemoglobin depends on chloride instead of 2-3 DPG to determine oxygen affinity → great oxygen transport ability in the body

Question 2

Q

What are P50 in dogs and cats?

Answer

A

Dogs: 31.5 mmHg

Cats: 35.6 mmHg

Question 3

Q

Is oxyhemoglobin isoosmotic or hyperosmotic? hyperoncotic or normooncotic?

Answer

A

Isoosmotic (300 mOsm/L)
Hyperoncotic (COP = 43 mmHg)

Question 4

Q

What are common complications/side effects for oxyhemoglobin administration? Why?

Answer

A

Hypertension - nitric oxide scanvenging effect leads to vasoconstriction
Volume overload - hyperoncotic & vasoconstriction
Transient Yellow-orange color skin and urine

Question 5

Q

What is the dose for oxyhemoglobin administration and what is the half-life?

Answer

A

10-30 ml/kg
18-43 hr

Question 6

Q

What is the formula for albumin deficit?

Answer

A

Albumin deficit (g) = 10 x [Desired albumin - patient albumin] x body weight x 0.3

Question 7

Q

What are in frozen plasma?

Answer

A

Albumin, fibrinogen, globulin, Factor 2, 7, 9, 10,11, 12

Mainly lacking factor 5, 8

Question 8

Q

What are in cryoprecipitate?

Answer

A

von Willbrand factor, Factor 8, 13, fibrinogen

Question 9

Q

What are in cryo-poor plasma?

Answer

A

albumin, vit-K dependent factor, globulin

Question 10

Q

What is the FFP volume required to raise albumin by 0.5 g/dL

Answer

A

20-25 ml/kg

Question 11

Q

What is the canine albumin dose required to raise albumin by 0.5 g/dL?

Answer

A

450 mg/kg

Question 12

Q

True or False: Platelets contains nucleus.

Question 13

Q

List 7 structures in the platelet.

Answer

A

1) Actin
2) Myosin
3) Fibrin-stabilizing factors (fXIII)
4) Prostaglandins
5) Mitochondria → can form ATP and ADP
6) Endoplasmic reticulum
7) Golgi apparatus
8) Growth factors
9) Thrombosthesnin
10) 𝜶 granules
11) Dense granules
12) Lysosomal granules

Question 14

Q

What are in platelet 𝜶 granules (10) and dense granules (6)?

Answer

A

𝜶 granules:
- Fibrinogen
- von Willbrand factors
- P-selectin
- Factor V, VIII
- Thrombospondin
- Glycoprotein IIb/IIIa
- Platelet factor 4
- Insulin like growth factor
- Platelet derived growth factor
- Vascular endothelium growth factor

Dense granules:
- Ca2+, Mg2+, phosphate
- ATP, ADP
- Histamine
- Serotonin
- Polyphosphate
- Catecholamines

Question 15

Q

What the structure in the endothelium that store the vWF?

Answer

A

Weibel-Palade bodies

Question 16

Q

What composes the extrinsic tenase complex?

Answer

A

Tissue factor (fIII), factor VIIa, calcium

Question 17

Q

What composes the intrinsic tenase complex?

Answer

A

Factor VIIIa, Factor IXa, phospholipid, calcium

Question 18

Q

What composes the prothrombinase complex?

Answer

A

Factor Xa, Factor Va

Question 19

Q

What are the 7 G protein-coupled receptors on the platelet and what do them bind to?

Answer

A

ADP (P2Y1, P2Y12)
Thrombin (PAR1, PAR4)
Thromboxane (TP)
Epinephrine (𝜷2 receptors)
Serotonin (5-HT2A)

Question 20

Q

What are the two intergin receptors and what do they bind to?

Answer

A

Intergin 𝜶2𝜷1 → collagen
Intergin 𝜶II2𝜷3 (GP IIbIIIa) → fibrinogen

Question 21

Q

What dose GPIb/IX/V receptors bind to?

Answer

A

vVF, P-selectin, collagen

a member of the leucine-rich receptor class

Question 22

Q

What is GPVI activated by?

Question 23

Q

Where does the thrombopoietin mainly synthesized?

Question 24

Q

What is the threshold of platelet count when we can see clinical bleeding?

Answer

A

25000-50000/ul

Question 25

Q

List 4 tick-borne diseases that can cause thrombocytopenia.

Answer

A

Ehrlichiosis
Babesiosis
Rocky Mountain Spotted Fever (Rickettsia rickettsii)
Anaplasmosis

Question 26

Q

What are the three proposed mechanisms of drugs causing immune-mediated destruction of platelets and an example for each one of them?

Answer

A

1) hapten-dependent antibody formation: drugs bind covalently with the platelet membrane proteins → antibody production
- Penicillin, cephalosporins

2) drugs induce antibodies to bind to platelet membrane proteins in the presence of drugs (e.g. GPIIbIIIa)
- quinine, vancomycin, sulfonamides, rifampin, fluoroquinolones

3) drugs induce antibodies to bind to platelet membrane proteins without the presence of drugs
- sulfonamides

Question 27

Q

List 5 drugs that can cause bone narrow suppression.

Answer

A

1) Chemotherapeutic drug
2) Methimazole
3) Phenobarbitals
4) Penicillins
5) Azathioprine
6) Esteogen

Question 28

Q

What is the MOA of using vincristine to treat ITP?

Answer

A

1) stimulate thrombopoiesis
2) accelerate fragmentation of megakaryocytes
3) impairment of the phagocytosis of platelets by macrophages
4) interference with antiplatelet antibody formation and binding

Question 29

Q

True or False: lyophilized platelets have shorter half-life than PRP.

Question 30

Q

What is the max platelet increase when giving one unit of fresh whole blood derived PRP (80K/uL)/10kg ?

Question 31

Q

True or False: Extrinsic thrombocytopathies are more common than intrinsic thrombocytopathies in small animals.

Answer

A

False

Intrinsic is more common!

Question 32

Q

What is the most common extrinsic thrombocytopathy?

Answer

A

von Willebrand’s disease

Question 33

Q

List 3 places where von Willebrand factors are stored.

Answer

A

1) Platelet 𝜶 granules
2) Weibel-Palade bodies in the endothelial cells (richest!)
3) plasma (bind with fVIII)

Question 34

Q

Describe three types of VWD in dogs

Answer

A

Type I: quantitative reduction of von Willebrand factors
Type II: qualitative reduction of von Willebrand factors
Type III: absolute lack of von Willebrand factors

Question 35

Q

What is normal BMBT in dogs and cats?

Question 36

Q

List 4 differential for prolonged BMBT.

Answer

A

1) vWD
2) Thrombocytopenia
3) Thrombocytopathia
4) Vascular wall abnormalities

Question 37

Q

List two treatments for vWD.

Answer

A

1) Cryoprecipitate (1 unit/10kg)
2) DDAVP (Desmopressin acetate)

Question 38

Q

What is the MOA of DDAVP administration in vWD?

Answer

A

Stimulate endothelial V2 receptors to release intracellular von Willebrand factors.

Type I has the best response compared to Type II and Type III

Question 39

Q

For vWD patient that needs surgery, when should you give DDAVP, the dose and how long does it last?

Answer

A

Give 1 ug/kg SC/IV 30min - 1hr before surgery
Last about 2 hours

Question 40

Q

How to perform clot retraction assay? What does it used for?

Answer

A

Clot retraction is determined by the placement of 5 ml of whole blood into a sterile glass tube (without any anticoagulant). A wooden applicator is inserted into the tube and blood. The tube then is sealed with plastic paraffin film before incubation at 37°C. The assessment of clot formation and clot retraction is noted over 8 to 24 hours. Within 2 to 4 hours a normal clot retracts markedly.
* Used in patient with normal platelet count

Abnormal result → thrombocytopathia, low fibrinogen or coagulopathy

Question 41

Q

What is the breed that can have idiopathic asymptomatic macrothrombocytopenia?

Answer

A

Cavalier King Charles Spaniels (CKCS)

mutation in β1-tubulin

Question 42

Q

List 3 causes of acquired vWD.

Answer

A

1) Immune-mediated disease
2) Hypothyroidism
3) Hydroxyethyl starch administration
4) High shear stress (e.g. mitral regurgitation, aortic stenosis)

Question 43

Q

What is the proposed major cause of uremia causing bleeding?

Answer

A

defects in vWD functions

Other mechanisms: increased NO and prostacyclin → inhibit platelet activation; direct platelet inhibition by uremix toxin

Question 44

Q

What is Virchow’s triad?

Answer

A

It describes the three factors that predispose a patient to vascular thormbosis.

Endothelial injury
Hypercoagulability
Blood stasis

Question 45

Q

How many deoxygenated Hb need to be present in the vessels for the cyanosis to be clinically appreciable?

Question 46

Q

“Serious bleeding concerns arise when there are ___ platelets or less per high-power field.”

What is the number in the blank?

Question 47

Q

What are the two heavy metal that can induce hemolysis?

Answer

A

Zinc, copper

Question 48

Q

List 5 substances that can cause methemoglobinemia.

Answer

A

1) Acetaminophen
2) Nitrates
3) Skunk musk
4) Nitrites
5) topical benzocaine formulations
6) hydroxycarbamide
7) phenazopyridine

Question 49

Q

List 5 RBC’s self-protective mechanisms for oxidative injury.

Answer

A

1) superoxide dismutase
2) catalase
3) glutathion peroxidase
4) glutathion
5) metHb reductase

Question 50

Q

Why is feline Hb more susceptible to oxidative injury?

Answer

A

Because feline Hb has 8 SH-group (sulfhydryl) on the globin part; dogs’ only have 4.

Question 51

Q

True or False: Heinz bodies can be seen in normal feline erythrocytes.

Question 52

Q

What are the three major components of glutathione?

Answer

A

Glutamic acid
Cysteine
Glycine

Question 53

Q

What is the process of vitamin K dependent coagulation factors systhesis called?

Answer

A

𝛄-carboxylation (vitamin K is the cofactor)

Question 54

Q

There are two ADP receptors on the platelets, what are their functions?

Answer

A

P2Y1: platelet shape change and mild aggregation
P2Y12: activation of intergrin and platelet granule release, induction of thromboxane production

** Both ADP receptors need to be activated for full ADP-induced platelet aggregation

Question 55

Q

True or False: Clopidogrel is a prodrug and require hepatic cytochrome p450 system transformation to be effective.

Question 56

Q

True or False: Is clopidogrel irreversible or reversible antagonist when it binds to P2Y12 ADP receptors?

Answer

A

Irreversible antagonist

Question 57

Q

What is the MOA of aspirin in anti-platelet aggregation?

Answer

A

It irreversibly blocks COX-1 in the platelets → inhibit thromboxane (TXA2) production → inhibit TXA2 induced platelet aggregation

Question 58

Q

What is the MOA of Abciximab?

Answer

A

Non-competitive GPIIbIIIa inhibitor → inhibit fibrinogen induced platelet aggregation

Question 59

Q

What is extrinsic factor pathway also called? What about intrinsic factor pathway?

Answer

A

Extrinsic factor pathway: tissue factor pathway
Intrinsic factor pathway: contact activation pathway

Question 60

Q

Where are the tissue factor located?

Answer

A

Extravascular cells
Monocytes, macrophages, neoplastic cells, microparticles released from endothelial cells, platelets

Question 61

Q

List 10 functions of thrombin.

Answer

A

1) Platelet activation
2) Convert fibrinogen to fibrin
3) Activate FXI & FV (11 & 5)
4) Release FVIII from von Willebrand factors
5) Activate FVIII (8)
5) Activate thrombin-activatable fibrinolysis inhibitor (TAFI)
6) Induce inflammation
7) Combine with thrombomodulin → activate protein C
8) Increase endothelial cell microparticle release
9) Activate fXIII (13)
10) Activate protein C (alone, slow)

Question 62

Q

What is INR and what is it used for?

Answer

A

It is an abbreviation of International Normalized Ratio. It is a type of calculation based on PT result, and is used to monitor patients’ on anticoagulant.

INR = [Patient PT/Control PT]^ISI

*ISI = international sensitivity index; the relative strength of the thromboplastin reagent

Question 63

Q

Why is the benefit of INR compared to PT test result? What is normal INR?

Answer

A

INR takes into account of the variation of different machines, different reagents used and sensitivity difference in the TF activators.

Normal INR: ≤ 1.1

Question 64

Q

Why at the beginning of warfarin treatment, patient may be in hypercoagulable state instead of hypocoagulable state?

Answer

A

Because warfarin also inhibit the activation of protein C and protein S, both of which are anticoagulant.

Sometimes patients can be treated with heparin at the first few days of warfarin therapy

Answer 55

A

2.0 - 4.0

Answer 56

A

Factor II, X
Factor IX, XI, XII

Answer 57

A

UFH
- saturable pathway: cleared by reticuloendothelial system and endothelial cells
- non-saturable pathway: excreted via kidneys

LMWH
- mainly excreted via kidneys

Answer 58

A

UFH: 60-90 min
MNWH: 3-6 hours

Answer 59

A

Because of more extensive fibrin polymerization

Answer 60

A

renal tubular epithelium

Answer 61

A

Reperfusion injury

Answer 62

A

Both drugs reversibly bind to lysine-binding site on the plasminogen → inhibit plasminogen to bind to fibrin → inhibit plasminogen activation → inhibit fibrinolysis

Answer 63

A

Fibrin
Fibrinogen
TPA

Answer 64

A

Prothrombotic

Answer 65

A

TXA is 6-10x more potent than EACA

Answer 66

A

Mainly excreted via kidneys

Answer 67

A

TXA: 1-2 hours
EACA: 2-3 hours

Answer 68

A

In Desmopression, the L-arginine is switched to D-arginine → no effect on V1 receptor (vasoconstriction) but more effective on V2 (antidiuretic & release vWF and fVIII from endothelium)

Answer 69

A

hemophilia A: fVIII (8)
hemophilia B: fIX (9)
hemophilia C: fXII (11)

Answer 70

A

1) Hypotension
2) Anaphylaxis reaction
3) Pulmonary hypertension
4) Delayed noncardiogenic pulmonary edema
5) Paradoxical bleeding (e.g. thrombocytopenia, thrombocytopathia, heparin-rebound effect)

Heparin-rebound effect: protein-bound heparin that is incompletely bound by protamine. After the protamine-heparin complexes are cleared from the circulation, remaining protein-bound heparin dissociates slowly and binds to antithrombin to produce an anticoagulant effect

Answer 71

A

Increased vWF, fVII and fXII

Often used in uremic patients

Answer 72

A

Arterial thrombus
- White clot; platelets + fibrins

Venous thrombus
- Red clot; fibrins + red blood cells

Answer 73

A

1.5 - 2.5x prolongation of aPTT

Answer 74

A

Pallor (i.e. purple or pale toes)
Polar (i.e. cold extremities)
Pulselessness
Paralysis
Pain

Answer 75

A

Presence of motor function
Only one limb is affected

Answer 76

A

1) Neoplasia
2) Hyperadrenocorticism
3) PLN
4) PLE
5) Hypothyroidism
6) IMHA
7) Infective endocarditis

Answer 77

A

Non-immunogenic: direct interaction between heparin and platelets causing platelets clumping or sequestration

Immunogenic: Heparin bids to platelet factor 4 (released from alpha granules) → becomes immunogenic and cause release of IgG targeting at heparin-PF4 complex → The heparin–PF4–IgG multimolecular immune complex activates platelets via their FcγIIa receptors → release of prothrombotic platelet‐derived microparticles, platelet consumption, thrombocytopenia

*Thrombosis

Answer 78

A

False

uPA does not require the presence of fibrin

Answer 79

A

Fibrin degradation products (FDPs): degradation of fibrin, fibrinogen and cross-linked fibrin

D-dimers: degradation of fibrin that are cross-linked by fXIII

Answer 80

A

𝜶-2-antiplasmin
𝜶-2-macroglobin

Answer 81

A

Plasminogen activator inhibitor-1 (PAI-1)
Protease nexin

Answer 82

A

Thrombin-thrombomodulin complex
Plasmin

Answer 83

A

It eliminates carboxyl-terminal lysine residues from fibrin → reduces the ability of plasminogen to bind fibrin

Answer 84

A

LPS
IL-1
TNF-𝜶
TGH-𝜷

Answer 85

A

False

Increase D-Dimer can be a result of increase fibrinolysis or increase thrombosis → cannot identify hypo or hyper-fibrinolysis!

Answer 86

A

INTEM: ellagic acid
EXTEM: tissue factor
APTEM: aprotinin

Answer 87

A

Factor XII deficiency (Hageman trait)

Answer 88

A

1-4 mcg/kg SC

Answer 89

A

1) Decreased hepatic clearance of tPA
2) Decreased levels of PAI-1, 𝜶-2-antiplasmin, and TAFI.

Answer 90

A

𝜷-hemolytic streptococci

Answer 91

A

TIC: ATC + resuscitation-associated coagulopathy (RAC)

ATC: endogenous coagulation abnormality

Answer 92

A

Hypocoagulable state
Hyperfibrinolysis

Answer 93

A

Hypothermia
Metabolic acidosis
Hemodilution

Answer 94

A

During severe trauma, there is lots of catecholamine release & extensive endothelial damage → extensive activation of coagulation cascade; extensive release of thrombomodulin → many thrombins are formed; clotting factors and platelets are consumed → eventually hypocoagulable state

Many thrombins bind to thrombomodulin → activates protein C → protein C inactivates fVa, fVIIIa, and PAI, TAFI → hyperfibrinolysis

Thrombomodulin inhibits thrombin formation → tips the scales a bit over hypocoagulability

Endothelial shedding lots of heparin & tPA → hypocoagulability & hyperfibrinolysis

Answer 95

A

Severe tissue injury
Hemorrhagic shock

Answer 96

A

Many different types of cells

Answer 97

A

Weibel-Palade bodies!

Answer 98

A

Dogs: if patient has a transfusion more than 4 days ago

Cats: always do a crossmatch due to possible anti-mik antibodies

Answer 99

A

False

It can only prevent acute hemolytic transfusion reaction.

Answer 100

A

Citrate
Phosphate
Dextrose
Adenine

Answer 101

A

Optisol solution contains adenine, dextrose, NaCl and mannitol. It is a RBC additive solution that can provide RBCs nutrition and prolong the storage life. It needs to be used with anticoagulant (usually CPD).

Answer 102

A

Dog: 20 ml/kg
Cat: 10 ml/kg

Answer 103

A

Major crossmatch: Donor’s RBCs + Recipient’s plasma

Minor crossmatch: Recipient’s RBCs + Donor’s plasma

Answer 104

A

True

That’s why type B is so rare!

Answer 105

A

Dog: 23kg; 450ml
Cat: 4kg; 40ml

Answer 106

A

1) Cause hypotension
2) Interfere with platelet function

Answer 107

A

Open collection system: the blood can be in contact with the environment and increase the risk of contamination
- needle + Three-way stopcock + syringe + blood bag

Closed collection system: the blood is not exposed to the environment at any time point during the collection or separation into blood components.
- commercial blood bag with needle

Answer 108

A

PRP: 200ml
PC: 50ml

1 unit FWB = 450ml

Answer 109

A

cryoprecipitate: 1-2 ml/kg
cryo-poor: 6-10 ml/kg

Answer 110

A

1) NO scavenging → vasoconstriction
2) Increase oxidative stress and cause oxidative injury
3) Pro-inflammatory
4) Endothelial damage
5) Increase risk of AKI
6) Increase pulmonary arterial pressure

Answer 111

A

No more than 5 x 10^6 of leukocytes should be present per unit of human pRBC

Answer 112

A

1) Mechanical filtration
2) Cell adhesion (to the filter)

Answer 113

A

about 51-52 ml

Answer 114

A

Pre-storage leukoreduction is superior

It reduces the accumulation of the metabolites produced by WBCs and platelets

Answer 115

A

1) Biochemical changes
- Decreased ATP
- Increased potassium
- Decreased 2,3-DPG
- Dysfunction of NO
- Accumulation of ammonia
- Oxidative injury
- Accumulation of cell free hemoglobin

2) Biomechanical changes
- Decreased RBC deformability
- Accumulation of microparticles
- RBC shape changes
- Adhesion to endothelial cells

3) Immunological changes
- Leukocyte contamination
- Transfusion-related immunomodulation

Answer 116

A

Erythrocytes do not have mitochondria → they generate ATP via anaerobic glycolysis → generate pyruvate, hydrogen ion → accumulate of hydrogen ions inhibit PFK function (key enzyme in glycolysis) → decrease ATP

Answer 117

A

Pro-inflammatory and also pro-thrombotic

Answer 118

A

1) Receive 1 whole blood volume within 24 hours
2) Receive half of the blood volume within 3-4 hours
3) Receive 1.5 times of the blood volume regardless of time
4) Receive blood at 1.5 ml/kg/min for 20 minutes

Answer 119

A

1) Hypocalcemia
2) Hypomagnesemia
3) Hyperkalemia

Answer 120

A

1) Hypothermia
2) Metabolic acidosis
3) Coagulopathy
4) Immunosuppression
5) TRALI

Answer 121

A

1) vWf
2) fVIII
3) tPA
4) P-selectin
5) IL-8

Answer 122

A

It is a von Willebrand factor-cleaving protease. It cleaves vWf into smaller multimers → preventing accumulation of ultra large multimers of vWf which can lead to diffuse microvascular thrombosis

Answer 123

A

1) consumption
2) eliminated by neutrophil elastase
3) decrease production (negative acute phase protein)

Answer 124

A

Endothelial cells
Platelets
Mononuclear cells
Fibroblasts
Vascular smooth muscles

Answer 125

A

1) Hemodilution
2) Hepatic dysfunction
3) DIC
4) Sepsis
5) After thrombolytic therapy

Answer 126

A

It tests functional fibrinogen, via measure of the time taken for a standardized thrombin solution to convert fibrinogen to fibrin

Answer 127

A

False

Dal is present in most dogs but is lacking in some Dalmatians.

Answer 128

A

DEA 1.1, 1.2, 3, 5, and 7 negative but positive for DEA 4

Answer 129

A

30 min

Longer → hypercoagulable

Answer 130

A

TEG: cup oscillates around the stationary pin

ROTEM: Pin oscillates while the cup is stationary

Answer 131

A

All the samples need to add calcium

Kaolin: stimulate intrinsic pathway
Tissue factor: stimulate extrinsic pathway
T-PA: used to assess fibrinolysis

Answer 132

A

INREM
- Activator: ellagic acid
EXTEM
- Activator: tissue factor
FibTEM
- Activator: tissue factor
- Modification: cytochalasin D is added to inhibit the platelet contribution to the clot → assess fibrinogen
ApTEM
- Activator: tissue factor
- Modification: aprotinin is added to inhibit fibirnolysis → assess the impact of hyperfibrinolysis

Answer 133

A

it involves a vertically oscillating probe immersed in a cuvette of whole blood in which glass beads activate coagulation.

It tests ACT, clot rate, and platelet function

Answer 134

A

aPTT

Both test the intrinsic and common pathway

Answer 135

A

TEG: K
ROTEM: Clot forming time (CFT)

Answer 136

A

TEG: R
ROTEM: Clot time (CT)
VCM: Clot time (CT)

Answer 137

A

Lower (more residual clot being lysed)

Answer 138

A

False

Unless other risk factor exists

Answer 139

A

Dogs: IMHA, PLN
Cat: Cardiac disease

For canine pancreatitis, only acute necrotizing pancreatitis is indicated

Answer 140

A

1) Dogs with IMHA or PLN
2) Cats with cardiomyopathy and associated risk factors (history of ATE, LA enlargement, spontaneous echo contrast, reduced LA appendage flow velocity)
3) Dogs or cats with > 1 disease/risk factor for thrombosis (e.g. pancreatitis with sepsis)

Answer 141

A

Arterial clot

Answer 142

A

Arterial clot: ATE from HCM

Venous clot: IMHA, PLN, PTE

Answer 143

A

LMWH in both dogs and cats
(positive safety profile, reliable bioavailability)

Answer 144

A

Direct Xa inhibitor in both dogs and cats
(efficacy, reliable pharmacokinetics, ease of oral dosing)

Answer 145

A

Either one is reasonable

Answer 146

A

Dog: aspirin/clopidogrel in addition to LMWH or individually adjusted UFH therapy may be considered in dogs at high risk of VTE

Cat: insufficient data; combination therapy may be considered where there is a high risk of thrombosis

Answer 147

A

Dog:
- Loading dose: 4-10 mg/kg
- Daily dose: 1.1-3 mg/kg q24h

Cat:
- Loading dose: 37.5mg
- Daily dose: 18.75mg q24h

Answer 148

A

IV
- 100 U/kg IV
- CRI 480-900 U/kg/24hr

SC
- 150-300 U/kg SC q6h

Answer 149

A

250 U/kg SC q6h

Answer 150

A

Dog: 1-2 mg/kg/d PO
Cat: 0.5-1 mg/kg/d PO

Answer 151

A

Dog: Anti-Xa activity (target: 0.35-0.7 U/ml)
Cat: insufficient data

Answer 152

A

insufficient evidence to make strong recommendations for therapeutic monitoring

targeting anti-Xa levels of 0.5–1.0 U/mL 2–4 hours postdose can be considered (dog)

Answer 153

A

True

Doesn’t matter anti-platelet or heparin

Answer 154

A

If underlying causative conditions have resolved → d/c
Unknown or unsolved underlying cause → continue

Answer 155

A

If underlying causative conditions have resolved → d/c
o Unknown or unsolved underlying cause → continue

Answer 156

A

UFH: need to wean (from IV to SC)
* “rebound” hypercoagulation phenomenon following discontinuation of heparin therapy may be observed

LMWH: no need to wean
direct-Xa inhibitor: weaning is recommended

Answer 157

A

1) Volume (ml) = PCV rise desired % x body weight x 1.5

2) Volume (ml) = Body weight x blood volume x (Desired PCV - Patient PCV)/Donor PCV

*Blood volume: dog 90 ml/kg; cat 60 ml/kg

Answer 158

A

Inside: PS, PE

Outside: Phosphatidylcholine (PC), Sphingomyelin, Sugar-linked sphingolipids

Answer 159

A

The functions of flippase and floppase are to maintain the resting state
- Flippase: flip PS in
- Floppase: flip PC out

The function of scramblase is to facilitate the activation state
- Scramblase: transpot PS, PE out

Answer 160

A

1) cytokines (e.g. TNF-𝜶)
2) thrombin
3) hypoxia
4) shear stress

Answer 161

A

1) Heparan sulfate proteoglycans
2) NO
3) Tissue factor pathway inhibitor
4) Thrombomodulin
5) Protein C & Protein S
6) Prostacyclin
7) Physical barrier
8) Ecto-adenosine diphosphatase
9) Antithrombin

Answer 162

A

1) Cleaves fV and fVIII
2) Inhibits PAI-1
3) Shut down thrombin formation
4) Inhibit TAFI

Answer 163

A

fVII (about 1% is active form)

Answer 164

A

True

fXa will be degraded by TFPI and AT once it leaves the cell surface

Answer 165

A

fV, fVIII, fXI

5,8,11

Answer 166

A

Cryoprecipitate
- Fibrinogen, vWf, fVIII,fXIII, fibronectin

Cryo-poor plasm
- Vitamin K dependent factors, albumin

Answer 167

A

Glutamic acid (Gla)

Need 𝛄-carboxylation to be able to bind to membrane surface

Answer 168

A

1) Heparin
2) Activated platelets

Answer 169

A

TFPI has three domains - K1, K2, and K3. The K2 domain binds to fXa and inhibit it (reversible, no Ca needed). The K1 domain then binds to fVII-TF complex (irreversible, need Ca).

K3 domain binds to protein S

Answer 170

A

True

AT can inhibit 2, 9, 10, 11, 12 without heparin (slow)
AT NEEDS heparin to inactivate factor 7

Answer 171

A

Protein S
Calcium
Phospholipid

Answer 172

A

1) Sodium binding site
2) Active site
3) Exosite I
4) Exosite II

Answer 173

A

Procoagulant

Answer 174

A

Exosite I: hirudin (from leech!), fibrinogen
Exosite II: heparin, thrombomodulin, AT

Anticoagulant

Answer 175

A

The complexes of 10-5 and 9-8 are more resistant to AT inactivation than 10 or 9 are alone.
Activation of the APC pathway leads to the reduced production of 5 and 8 → decreases 10-5 and 9-8 complex formation

Answer 176

A

Thrombocytopenia
Prolong aPTT/PT
Hypofibrinogenemia
Decreased AT
Elevated FDPs or D-dimer
Erythrocyte fragmentation on a blood smear (schistocytes, keratocytes, acanthocytes)

Answer 177

A

The major difference: whether there is an ARDS risk factor or the presence of mild ARDS

Type 1
- Patients who have no risk factor of ARDS and meet the following criteria
1) Acute onset
2) Hypoxemia: P/F ≤ 300 or SPO2 < 90% on room air
3) No evidence of left atrial hypertension (LAH) on echo (if LAH is present, it is judged not to be the main cause)
4) Clear evidence of bilateral pulmonary edema on imaging (chest radiographs, chest CT or ultrasound)
5) Onset of pulmonary signs within 6 hours of transfusion
6) No temporal relationship to an alternative risk factor for ARDS

Type 2
- Patients who have risk factors for ARDS or who have existing mild ARDS (P/F 200–300), but whose respiratory status deteriorates and is judged to be due to transfusion based on
1) Findings as described in the type 1 (1) to (5)
2) Stable respiratory status in the 12 hr before transfusion

Answer 178

A

In human medicine, it has been hypothesized that TRALI is the result of two clinical insults,
which is also call the “Two-hit model,” or “Two-event model.”

The first insult is that the pulmonary vascular endothelium is activated (pro-inflammatory) resulting in priming (adherence) and sequestration of neutrophils by one or more endogenous stimuli (i.e. sepsis, surgery)

The second insult is the blood product transfusion. The antibodies in the blood products, such as antibodies to human leucocyte antigen (HLA) class I and II, and various neutrophil antigens (HNA), can cause compliment activation and result in a full activation of those sequestrated neutrophils and released of cytotoxic agents, which eventually lead to endothelial injury and pulmonary edema

Answer 179

A

Acute non-immunologic or immunologic reaction
Temperature > 39C (102.5 F) AND an increase in temperature of > 1C (1.8 F) from the pre-transfusion body temperature during or within 4 hrs of the end of a transfusion
External warming, underlying patient infection, AHTR, TRALI, and TTI have been ruled out.

Answer 180

A

Secondary to donor WBCs or platelet antigen-antibody reactions or due to transfer of pro-inflammatory mediators in stored blood products.

Answer 181

A

1) TRALI
2) TACO
3) FNHTR
4) TAD (transfusion associated dyspnea)
5) allergy reaction

Answer 182

A

acute
development of acute respiratory distress during or within 24 hours of the end of a transfusion
TACO, TRALI, allergic reaction, and underlying pulmonary disease have been ruled out

Answer 183

A

Dog 4.7%
Cat 3%

Answer 184

A

acute, non-immunologic reaction secondary to an increase in blood volume mediated by blood transfusion
acute respiratory distress and hydrostatic pulmonary
edema within 6 hours of transfusion
Evidences of LA hypertension or volume overload
These patients typically have a positive response to diuretic therapy.

Answer 185

A

The neutrophils need to be primed/activated by either substances in the donor blood or by the recipient’s condition (e.g. surgery, sepsis). For TRALI reaction to happen, the primed/activated neutrophils need to overcome a threshold.

Answer 186

A

Type I hypersensitivity

Answer 187

A

False

Non-immunogenic: mechanical, chemical, osmotic, thermal

Answer 188

A

24 hours to 28 days after transfusion

Answer 189

A

2-4 days

compared to feline RBCs 30 days

Answer 190

A

A hypotensive transfusion reaction is an acute, non-immunologic reaction.
There is usually a decrease in systolic blood pressure of at least 30 mmHg from baseline.
Activation of coagulation factor XII → high-molecular-weight kininogen to bradykinin → vasodilation and increased vascular permeability
Bradykinin is metabolized via ACE, and the use of ACE inhibitors before or during a transfusion has been associated with the development of HyTRs.

Answer 191

A

Dog: standard 170–260 micron in-line blood administration set with gravity flow
* Peristaltic and rotary infusion pumps should be avoided!!!

Cat: syringe pump + 18-micron microaggregate filter works

Answer 192

A

1) Phagocytosis
2) Degranulation
3) Neutrophil Extracellular Traps (NETs)

Answer 193

A

1) Cell free DNA
2) Histone
3) Neutrophil granule proteins & peptides
- Myeloperoxidase (MPO), Lactoferrin, Cathepsin G, Neutrophil elastase (NE), Defensins

Answer 194

A

Neutrophils expose to PAMPs, DAMPs, cytokines, pathogens, autoantibodies, immune complexes → citrullination of histone, disassembly of the nuclear envelope, chromatin decondensation → release of NETs.

Answer 195

A

Prothrombogenic

Answer 196

A

Adhesive interaction
Soluble interaction

Answer 197

A

citrullinated histone

Answer 198

A

Transfusion volume (ml) = (PCVdesire - PCVcurrent)/PCVdonor x body weight x blood volume

Answer 199

A

Histamine
Acetylcholine
Bradykinin
Platelet activating factor
𝜶 adrenergic agonist

Answer 200

A

Thrombin-thrombomodulin complex
Plasmin

Answer 201

A

It inhibits platelet activation via thromboxane A2-dependent, COX-1-mediated effect

Answer 202

A

It is used to evaluate the severity of bleeding

9 categories
0-2 → the higher the worse

Answer 203

A

2-6C for 14 days

Answer 204

A

FFP
- Frozen with 24 hours after being made
- Last 1 year in -30C
- Contains all the clotting factors, vWf, fibrinogen, Albumin

FP
- FFP stored in -30C for more than 1 year
- Last 5 years in -30C
- Contains everything minus fV and fVIII

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Transfusion/Coagulation Flashcards

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