Post-bypass vasoplegia

Surgical approach (context: cardiac surgery with CPB)

Median sternotomy (or minimally invasive approach), systemic heparinisation, aortic + venous cannulation, initiation of CPB
- Myocardial protection with cardioplegia, temperature management (mild hypothermia common)
- Surgical correction (e.g. CABG, valve surgery, aortic surgery) then rewarming and separation from CPB
Protamine reversal of heparin, haemostasis, pacing wires and drains, chest closure
- Surgeon will exclude surgical bleeding/tamponade if hypotension persists post-bypass

Anaesthetic management (context: cardiac surgery with CPB, vasoplegia occurs peri-separation/post-CPB)

Type of anaesthesia: General anaesthesia with invasive monitoring
- Airway: ETT (almost always), lung isolation only if specific indication
- Duration: typically 3–6+ hours depending on procedure complexity
- Pain: moderate–severe (sternotomy), multimodal analgesia + regional options (e.g. parasternal blocks) as per local practice
Key monitoring: arterial line, central access, temperature, urine output, TOE commonly used, consider pulmonary artery catheter in high-risk cases
- Haemodynamic targets post-CPB: adequate MAP for coronary/cerebral perfusion, individualise (often MAP ≥ 65–75 mmHg, higher if chronic HTN/carotid disease)
Vasoplegia management is primarily haemodynamic + pharmacological, exclude bleeding/tamponade/ventricular dysfunction first (TOE + surgical field)
- Early vasopressors (noradrenaline first-line) and vasopressin, consider methylene blue/hydroxocobalamin/angiotensin II in refractory cases

Definition and diagnostic features

Post-bypass vasoplegia (vasoplegic syndrome): distributive shock occurring during/after separation from CPB characterised by low SVR with normal/high cardiac output and hypotension requiring vasopressors
Typical haemodynamics (guide): MAP &lt, 65 mmHg despite adequate preload, SVR low (e.g. &lt, 800 dyn·s·cm−5), CI normal/high (e.g. &gt, 2.2–2.5 L·min−1·m−2), low filling pressures may or may not be present
Clinical clues: warm peripheries, wide pulse pressure, low diastolic pressure, high vasopressor requirement, rising lactate if prolonged
Timing: commonly immediately post-CPB or early ICU period, can be precipitated/worsened by protamine reaction or systemic inflammatory response

Epidemiology and risk factors

Incidence varies (commonly quoted ~5–25% depending on definition and population), associated with increased ICU stay, AKI, and mortality when severe/refractory
Patient factors: pre-op ACE inhibitor/ARB use, beta-blockers (less consistent), chronic heart failure/low EF, vasodilatory states, liver disease, chronic renal impairment, diabetes, obesity
Surgical/CPB factors: prolonged CPB time, complex procedures, re-do surgery, aortic surgery, deep hypothermia, large transfusion/inflammation
Drug/biochemical factors: heparin–protamine effects, relative vasopressin deficiency post-CPB, catecholamine receptor desensitisation

Pathophysiology (high-yield mechanisms)

Systemic inflammatory response to CPB: cytokines/complement activation → endothelial dysfunction, vasodilatation, capillary leak
Excess nitric oxide (NO) production (iNOS upregulation) → increased cGMP → vascular smooth muscle relaxation and catecholamine hyporesponsiveness
Relative vasopressin deficiency after CPB (depleted stores) → reduced V1-mediated vasoconstriction, contributes to noradrenaline-refractory hypotension
KATP channel activation and acidosis/hypothermia → reduced vascular tone and reduced response to catecholamines
Microcirculatory dysfunction and capillary leak → intravascular hypovolaemia despite total body fluid excess

Differential diagnosis of hypotension post-CPB (must-exclude list)

Bleeding/hypovolaemia (surgical field, drains, Hb, coagulation, TOE: small ventricles)
Cardiogenic causes: LV/RV dysfunction, ischaemia, graft/valve problem, air embolism, TOE essential
Mechanical: tamponade (clotted drains), tension pneumothorax, dynamic LVOT obstruction (esp. post-mitral repair), aortic dissection
Arrhythmia/pacing issues: AF, junctional rhythm, heart block, loss of AV synchrony, check pacing wires and electrolytes
Protamine reaction: hypotension, pulmonary hypertension, RV failure, anaphylactoid features, timing around protamine administration
Sepsis (less immediate), adrenal insufficiency (rare but consider in refractory shock), anaphylaxis to drugs/latex

Immediate assessment and investigations (peri-separation/post-CPB)

Structured approach: confirm MAP/arterial trace, check for artefact, ensure adequate oxygenation/ventilation, anaesthetic depth, temperature, acid–base, ionised calcium
TOE: assess ventricular function, volume status, valvular/graft issues, tamponade, RV strain, LVOT obstruction, intracardiac air
Haemodynamic monitoring: CI/SVR if available (PAC or calibrated pulse contour), trend lactate, ScvO2/SvO2, urine output
Labs: ABG (lactate, Hb), electrolytes incl. Ca2+/K+/Mg2+, coagulation/TEG/ROTEM, glucose

Management principles (stepwise, exam-structured)

1) Optimise basics: oxygenation/ventilation, correct acidosis, rewarm, correct hypocalcaemia, treat arrhythmias, ensure adequate anaesthesia/analgesia
2) Ensure adequate preload but avoid indiscriminate fluid: small boluses guided by TOE/dynamic indices, consider capillary leak—albumin/crystalloid per local practice, early blood if bleeding
3) First-line vasopressor: noradrenaline titrated to MAP target, consider adrenaline if mixed vasoplegia + low output
- Aim: restore coronary perfusion pressure (diastolic pressure important) and maintain organ perfusion
4) Add vasopressin early if high NA requirement or suspected vasopressin deficiency (common post-CPB)
- Typical infusion: 0.01–0.04 units/min (institution dependent), avoid higher doses due to ischaemia risk
5) Refractory vasoplegia (despite NA + vasopressin and optimisation): consider methylene blue, hydroxocobalamin, angiotensin II, consider corticosteroids if adrenal insufficiency suspected
- Methylene blue: inhibits NO–cGMP pathway (guanylate cyclase inhibition), typical dose 1–2 mg/kg IV over 10–20 min (may follow with infusion per protocol)
- Hydroxocobalamin: NO scavenger, typical dose 5 g IV over 10–15 min (may repeat), causes red discolouration of skin/urine and interferes with some lab assays
- Angiotensin II: potent vasoconstrictor, consider in catecholamine-resistant shock with specialist input, monitor for thrombosis/ischaemia
- Steroids: e.g. hydrocortisone 50 mg IV q6h (or 100 mg bolus then infusion per local policy) if refractory shock/relative adrenal insufficiency considered
6) If haemodynamics unstable: return to CPB may be required while diagnosing/treating (e.g. tamponade, severe ventricular dysfunction, protamine reaction)
7) ICU management: ongoing vasopressor titration, fluid balance, lactate clearance, renal protection, early source identification if infection suspected, avoid excessive haemodilution

Drug notes and cautions (high-yield)

Noradrenaline: first-line, improves MAP primarily via α1, may increase afterload—ensure LV function adequate
Vasopressin: V1-mediated vasoconstriction, catecholamine-sparing, may reduce pulmonary vascular effects compared with high-dose catecholamines, risks: digital/mesenteric ischaemia, hyponatraemia (less relevant acutely)
Methylene blue cautions: contraindicated in G6PD deficiency (haemolysis risk), risk of serotonin syndrome with SSRIs/SNRIs/MAOIs, may cause pulmonary vasoconstriction, interferes with pulse oximetry readings
Hydroxocobalamin cautions: can cause hypertension, chromaturia and discoloration, may trigger false alarms in dialysis machines and affect co-oximetry/lab assays
Angiotensin II cautions: thromboembolic risk, ensure VTE prophylaxis and monitor limb/mesenteric perfusion, specialist/ICU-led use

Outcomes and prevention (what to mention in viva)

Consequences: prolonged vasopressor use, AKI, gut ischaemia, delirium, increased ICU/hospital length of stay, mortality increases with severity and refractory shock
Prevention/mitigation: identify high-risk patients (ACEi/ARB, long CPB), consider withholding ACEi/ARB pre-op per local policy, minimise CPB time/inflammation, maintain temperature and acid–base, early vasopressin in high NA requirement
Communication: early discussion with surgeon/perfusionist/ICU, agree MAP target (e.g. carotid disease, chronic HTN), document vasoplegia and therapies used

Test yourself…

You are separating from CPB and the patient is hypotensive. How will you approach this problem?

Demonstrate a structured differential and immediate actions, prioritise life-threatening and reversible causes.

Confirm the problem: check arterial trace, transducer level/zero, rhythm, pacing capture, surgical field, ensure adequate oxygenation/ventilation and anaesthetic depth
Rapid TOE assessment: LV/RV function, volume status, tamponade, intracardiac air, valvular/graft issues, LVOT obstruction
Treat likely causes in parallel: fluid/blood if hypovolaemia/bleeding, inotrope if low output, vasopressor if low SVR, correct Ca2+, acidosis, hypothermia
If unstable or unclear: consider returning to CPB while diagnosing and treating

Define post-bypass vasoplegia and describe the typical haemodynamic profile.

Distributive shock after CPB with hypotension requiring vasopressors due to low SVR, typically with normal/high cardiac output
Features: low MAP, low diastolic pressure/wide pulse pressure, warm peripheries, CI often &gt,2.2–2.5, SVR often &lt,800 (values vary by definition)
Diagnosis is clinical + haemodynamic and requires exclusion of bleeding, tamponade, and cardiogenic shock (TOE)

List risk factors for post-bypass vasoplegia.

Pre-op ACE inhibitor/ARB use, heart failure/low EF, renal impairment, diabetes/obesity, liver disease
Intra-op: prolonged CPB time, complex/re-do/aortic surgery, major inflammatory response, large transfusion, hypothermia
Physiology: relative vasopressin deficiency, NO upregulation, catecholamine receptor downregulation

Explain the pathophysiology of post-bypass vasoplegia.

CPB triggers systemic inflammatory response (cytokines/complement) → endothelial dysfunction, vasodilatation, capillary leak
Upregulation of iNOS → increased NO → increased cGMP → vascular smooth muscle relaxation and reduced catecholamine responsiveness
Relative vasopressin depletion post-CPB reduces endogenous vasoconstrictor tone, KATP channel activation and acidosis/hypothermia worsen vasodilatation

How do you distinguish vasoplegia from cardiogenic shock after CPB?

TOE: vasoplegia usually shows preserved ventricular systolic function (or not severely impaired) and no major mechanical cause, cardiogenic shock shows LV/RV dysfunction, regional wall motion abnormalities, valve/graft issues
Haemodynamics: vasoplegia = low SVR with normal/high CI, cardiogenic = low CI with higher SVR (unless mixed shock)
Clinical: vasoplegia often warm with wide pulse pressure, cardiogenic may be cool with pulmonary oedema and rising filling pressures

Outline your pharmacological management of post-bypass vasoplegia.

Noradrenaline as first-line to restore MAP/diastolic pressure, titrate to agreed target
Add vasopressin early if escalating NA requirement (typical 0.01–0.04 units/min)
If refractory: methylene blue 1–2 mg/kg IV, consider hydroxocobalamin 5 g IV, consider angiotensin II in ICU setting, consider hydrocortisone if refractory shock

Methylene blue: mechanism, dose, and key contraindications/complications.

Mechanism: inhibits NO pathway via guanylate cyclase inhibition → reduces cGMP-mediated vasodilatation, may improve catecholamine responsiveness
Dose: 1–2 mg/kg IV over 10–20 min (local protocols may add infusion)
Avoid/caution: G6PD deficiency (haemolysis), serotonergic drugs (serotonin syndrome), potential pulmonary vasoconstriction, interferes with SpO2 readings

Hydroxocobalamin in vasoplegia: why might it work and what practical problems does it cause?

NO scavenging effect → reduces vasodilatation, can be useful in refractory vasoplegia
Dose often 5 g IV over 10–15 min (may repeat per protocol)
Practical issues: red discoloration of skin/urine, interferes with some lab assays/co-oximetry, may affect dialysis machine sensors, can cause hypertension

What are the key differentials for profound hypotension immediately after protamine administration?

Protamine reaction: systemic hypotension (anaphylactoid), pulmonary vasoconstriction → acute RV failure, bronchospasm, urticaria
Acute bleeding/coagulopathy, tamponade (clot), myocardial dysfunction/ischaemia, arrhythmia, air embolism
Management includes stopping/slow protamine, vasopressors, treating anaphylaxis, considering return to CPB if severe

How would you set a blood pressure target in post-bypass vasoplegia?

Individualise: consider chronic hypertension (shifted autoregulation), carotid/cerebrovascular disease, coronary disease (diastolic pressure important), renal perfusion
Common pragmatic target: MAP ≥ 65–75 mmHg, higher targets may be appropriate in selected patients (e.g. severe carotid disease)
Use markers of perfusion: lactate trend, urine output, mental status (ICU), SvO2/ScvO2, peripheral perfusion

What complications can arise from high-dose vasopressors in vasoplegia and how do you mitigate them?

Complications: peripheral/digital ischaemia, mesenteric ischaemia, arrhythmias (catecholamines), increased afterload worsening LV function, metabolic effects (hyperlactataemia with adrenaline)
Mitigation: add non-catecholamine agents (vasopressin, methylene blue, hydroxocobalamin, angiotensin II) to reduce catecholamine dose, optimise volume status and cardiac output, frequent limb/gut perfusion assessment