Cardiopulmonary Bypass

Question 1

Hemolysis on CPB: causes

Answer 1

Causes:
- mechanical shear stress and turbulence
- contact with non-endothelial surfaces and air
- pressure gradients for venous drainage (vacuum assist)
- cardiotomy suction use (pump suckers)

Question 2

CPB effect on WBCs

Answer 2

WBC activation by contact with non-endothelial surfaces
- Activation leads to pro-inflammatory and pro-coagulant states (but can also lead to coagulopathy)
- Activated neutrophils release cytotoxic enzymes and free radials; migrate outside vessels leading to tissue edema and cellular dysfunction
- Activated monocytes promote thrombin generation via tissue factor

Question 3

CPB effect on platelets

Answer 3

• Can decrease platelet count by 30-50% due to hemodilution, platelet adhesion to the circuit, mechanical disruption, shear stress, sequestration in tissues
• Qualitative defects: excessive activation leading to blunted response to stimulation
• Protamine can activate platelets leading to aggregation, sequestration, and thrombocytopenia

Question 4

CPB effect on endothelial cells

Answer 4

• Activated within minutes of going on CPB
• Up-regulate anticoagulant and fibrinolytic pathways
• Can cause a consumptive coagulopathy (this is why we give an antifibrinolytic)

Question 5

What causes fibrinolysis on CPB?

Answer 5

• release of tPA
• fibrin formation that is not fully suppressed by systemic heparinization

Question 6

What are the components of the contact system?

Answer 6

• Factor XII (activated by contact with non-endothelial surfaces in the CPB circuit) –> converted to FXIIa –> activates coagulation cascade, fibrinolysis, etc.
• Factor XI
• Kallikrein
• High-molecular weight kininogen

Question 7

What is the complement system and how is it activated during cardiac surgery?

Answer 7

Cytotoxic immune system that initiate and amplify the inflammatory response. Activates platelets and can contribute to CPB coagulopathy.

• During CPB: “alternate” (antigen-antibody independent) pathway
• Heparin-protamine complexes: “classic” pathway

Question 8

What is the end result of the coagulation cascade?

Answer 8

Fibrin clot formation

Question 9

What is the intrinsic pathway?

Answer 9

Blood exposed to foreign material in the CPB circuit –> activation of Factor XII –> formation of activated Factor Xa

Question 10

What is the extrinsic pathway?

Answer 10

Endothelial disruption exposes blood to tissue factor –> TF complexes with Factor VIIa to activate FXa.

Question 11

What is the common pathway?

Answer 11

The extrinsic and intrinsic pathways converge at FXa. Includes factors V, X, II and fibrinogen.

Question 12

What does PT and aPTT measure?

Answer 12

PT/INR: extrinsic pathway
- Factor VII + common pathway

aPTT: intrinsic pathway
- Factors XII, XI, IX, VIII + common pathway

Common pathway:
- Factors V, X, II, fibrinogen

Question 13

Risk factors for post-op myocardial dysfunction

Answer 13

• Pre-operative LV dysfunction
• Acute ischemia
• Advanced age
• X-clamp time
• Total CPB time
• Perioperative bleeding
• Dilated cardiac chambers

Question 14

Incidence of prolonged mechanical ventilation after cardiac surgery

Answer 14

7.5-10%

• Defined as intubation >72 hrs post-op
• Associated with increased mortality

Question 15

Pathophysiology of lung injury on CPB

Answer 15

• Neutrophils/pro-inflammatory mediators (neutrophils adhere to pulmonary endothelium and release proteolytic enzymes/ROS)
• Ischemic injury (lungs are only supplied by bronchial arteries during CPB; no PA blood flow)
• Reperfusion injury
• Atelectasis 2/2 prolonged apnea
• Pulmonary capillary membrane damage = edema

Question 16

Risk factors for intubation >72 hrs after cardiac surgery

Answer 16

• Preoperative renal failure *
• DM
• Female gender
• LVEF <30% *
• Type of surgery: double valve (prolonged X-clamp/CPB), active endocarditis (SIRS)
• Emergent surgery
• Age >70 years
• Prior MI
• CPB >180 minutes
• Large volume transfusion (>4 units pRBC)
• = most important factors in study (Filsoufi et. al. 2008)

Question 17

Most common pulmonary complications post-cardiac surgery

Answer 17

• Atelectasis
• Pleural effusions

Question 18

What is the most frequent perioperative complication of cardiac surgery? What is its incidence?

Answer 18

AKI

Incidence of 5-42%; associated with increased mortality which is worse in patients who require renal replacement therapy

Question 19

Pathophysiology of renal injury on CPB

Answer 19

• Increased renal vascular resistance to maintain renal blood flow while on CPB
• Non-pulsatile blood flow inhibits vascular autoregulation
• Decreased O2 delivery (hemodilution)
• Increased renal O2 requirement during rewarming (supply-demand mismatch)
• Emboli
• Free Hgb scavenging of NO
• Oxidative stress/inflammation

Question 20

Preoperative risk factors for AKI with cardiac surgery

Answer 20

• Age >70
• Female
• Cr >2.5
• Anemia
• LVEF <35%
• High dose contrast

Question 21

Intraoperative risk factors for AKI with cardiac surgery

Answer 21

• Hypotension
• DO2 <272 mL/min/mm2
• Prolonged CPB
• Hemodilution (has a large effect)
• Non-pulsatile blood flow
• Hemolysis
• Inflammation

Question 22

Postoperative risk factors for AKI

Answer 22

• Hypotension
• Nephrotoxins
• Atheroemboli
• Sepsis
• Cardiogenic shock

Question 23

What is the KDIGO bundle?

Answer 23

“Kidney Disease Improving Global Outcomes” guidelines

• Optimize of hemodynamics and volume
• Functional hemodynamic monitoring
• Avoid nephrotoxic drugs
• Prevent hyperglycemia

Question 24

Most effective measures at preventing AKI after cardiac surgyer

Answer 24

• KDIGO bundle
• maintain renal DO2 >280mL/min/mm2

Question 25

Decrease in cerebral metabolism per degree Celsius of cooling

Answer 25

6-7% decrease in CMRO2 per 1 degree Celsius of cooling

Question 26

Potential CNS benefits of hypotermia

Answer 26

• Decrease CMRO2 (6-7% per 1 C)
• Preserve high-energy phosphate stores
• Reduce excitatory neurotransmitter release
• Quicker recovery of protein synthesis
• Decreased membrane-bound protein kinase C activity
• delayed onset of depolarization
• reduced formation of ROS
• reduced nitric oxide synthase activity

Question 27

Areas of body with greatest decrease in blood flow during hypothermia

Answer 27

Skeletal muscle and extremities

Question 28

Renal effects of hypothermia

Answer 28

• Increased renal vascular resistance –> decreased blood and O2 delivery
• Impaired ability to concentrate urine
• Decreased tubular reabsorption
• Glycosuria (2/2 decreased ability to handle glucose)

Question 29

Effects of hypothermia on the circulatory system

Answer 29

• Increased tissue water content
• Cell swelling and edema
• Increased SVR and PVR (T<26C)
• Increased Hct
• Increased blood viscosity
• Thrombocytopenia (reversible sequestration of platelets in splanchnic circulation)
• Complement activation/neutrophil activation
• Increased circulating bradykinin

Question 30

Effects of hypothermia on the endocrine system

Answer 30

• Hyperglycemia
• Insulin resistance
• Catecholamine release/sympathetic response
• Suppression of corticosteroid release with prolonged T<28C

Question 31

What happens to the acid-base balance during hypothermia?

Answer 31

Alkaline drift

• Decreased dissociation of weak acids and bases
• Increased gas solubility

Question 32

Class I Recommendations for rewarming during CPB

Answer 32

• Oxygenator arterial outlet temp should be used as a surrogate for cerebral temp
• Assume that oxygenator arterial outlet blood temp underestimates cerebral perfusate temp
• Limit arterial outlet blood temp to <37 C to avoid cerebral hyperthermia

Question 33

Effects of free Hgb and heme

Answer 33

Tissue hypoxia and oxidative damage

• Free Hgb scavenges nitric oxide –> reduced vasodilation –> impaired microcirculatory function –> tissue hypoxia
• Free heme combines with hydrogen peroxide to form free radicals –> oxidative damage