Coagulopathy in liver disease

Surgical approach (context: liver surgery / transplantation / bleeding procedures in cirrhosis)

Control source of bleeding early: direct pressure, packing, Pringle manoeuvre (temporary hepatic inflow occlusion), topical haemostats, suture/clip ligation
- Damage control strategy if unstable: pack, temporary closure, ICU resuscitation, return to theatre
Minimise blood loss: low CVP strategy during parenchymal transection (balanced against renal perfusion/air embolism risk), cell salvage where appropriate, meticulous haemostasis
- Consider portal hypertension: varices/collaterals increase bleeding risk; careful dissection
If liver transplantation: hepatectomy phase (often major bleeding), anhepatic phase (no hepatic clearance/synthesis), reperfusion phase (post-reperfusion syndrome, fibrinolysis, hyperkalaemia)
- Surgical vascular clamps/anastomoses; potential venovenous bypass depending on centre

Anaesthetic management (typical for major liver surgery / transplant / high-risk bleeding in cirrhosis)

Type of anaesthesia: General anaesthesia with invasive monitoring; regional techniques often limited by coagulopathy (consider only if coagulation status acceptable and benefits outweigh risks)
- Neuraxial blocks: avoid if INR/platelets abnormal or dynamic coagulopathy; follow national guidance and local policy; consider peripheral/field blocks with ultrasound if safe
Airway: ETT usually required (aspiration risk, long duration, major haemorrhage, need for controlled ventilation); SGA generally inappropriate
- RSI may be indicated (ascites, delayed gastric emptying, variceal bleed, encephalopathy)
Duration: variable—minor procedures 1–3 h; major hepatectomy 4–8 h; liver transplant often 6–12+ h
Analgesia: moderate–severe (major upper abdominal); multimodal opioid-sparing; consider TAP/rectus sheath/QL blocks if coagulation allows; epidural often avoided in significant coagulopathy
- Avoid NSAIDs if renal dysfunction/variceal bleed risk; paracetamol dose-reduce in severe liver disease
Monitoring/lines: arterial line, large-bore IV access; consider rapid infuser; central access for vasoactive drugs; temperature monitoring; urinary catheter; consider cardiac output monitoring
- Point-of-care coagulation testing (TEG/ROTEM) to guide targeted blood product therapy
Haemostasis strategy: treat bleeding patient not numbers; use goal-directed transfusion; early fibrinogen replacement; correct hypothermia, acidosis, hypocalcaemia
- Transfusion triggers depend on procedure/bleeding; avoid prophylactic over-correction (thrombosis/volume overload)

Why coagulopathy occurs in liver disease (mechanisms)

Reduced synthesis of procoagulant factors: II, V, VII, IX, X, XI; fibrinogen may be low or dysfunctional (dysfibrinogenaemia)
- Factor VII short half-life → PT/INR rises early
Reduced synthesis of anticoagulants: protein C, protein S, antithrombin → prothrombotic tendency despite raised INR
Thrombocytopenia: hypersplenism (portal HTN), reduced thrombopoietin, marrow suppression (alcohol/viral), consumption/sepsis
Platelet dysfunction: uraemia, sepsis, alcohol, endothelial dysfunction; abnormal vWF/ADAMTS13 balance may partially compensate
Fibrinolysis abnormalities: hyperfibrinolysis (reduced clearance of tPA, low α2-antiplasmin) or hypofibrinolysis; dynamic changes esp. during transplantation/reperfusion
Vitamin K deficiency (cholestasis, malnutrition, antibiotics) → reduced II, VII, IX, X (correctable)
DIC-like picture can occur with sepsis/acute liver failure; differentiate from primary liver-related changes

Key concept: rebalanced haemostasis

Cirrhosis produces simultaneous reductions in pro- and anticoagulant pathways → haemostasis may be “rebalanced” but fragile and easily tipped to bleeding or thrombosis
INR/PT and APTT reflect only procoagulant factor deficiency and do not measure anticoagulant deficits or platelet-endothelial interactions → poor predictors of bleeding risk in cirrhosis
- INR was designed for warfarin monitoring; in liver disease it does not equate to “auto-anticoagulation”
Patients remain at risk of thrombosis: portal vein thrombosis, DVT/PE, catheter thrombosis; consider VTE prophylaxis on individual risk/bleeding balance

Assessment and investigations (preop and periop)

History: previous procedural bleeding, variceal bleed, easy bruising, menorrhagia, family history, anticoagulants/antiplatelets, alcohol, sepsis, renal failure
Examination: stigmata of chronic liver disease, ascites, encephalopathy, sepsis, signs of portal hypertension/splenomegaly
Baseline labs: FBC (platelets), PT/INR, APTT, fibrinogen, LFTs, U&E/creatinine, calcium, lactate/ABG; group & screen/crossmatch
Viscoelastic testing (TEG/ROTEM): assesses clot initiation, strength, fibrinogen contribution, fibrinolysis; useful for targeted therapy in bleeding or high-risk surgery
- Interpret alongside clinical bleeding and surgical field; avoid treating traces in a non-bleeding patient
Risk stratification: Child–Pugh and MELD predict perioperative mortality; not direct bleeding scores but correlate with severity and complications

When to correct coagulation abnormalities (principles)

Do not correct INR/platelets “to normal” routinely; correct for active bleeding, high-risk procedures, or before neuraxial techniques (if ever considered)
Optimise physiology first: temperature > 36°C, pH > 7.2, ionised calcium normal, Hb appropriate, avoid dilutional coagulopathy
- Hypocalcaemia from citrate in transfused blood impairs coagulation and contractility
Use goal-directed therapy guided by TEG/ROTEM where available; otherwise use fibrinogen/platelets and clinical bleeding

Blood products and haemostatic drugs (what to use, key points)

Packed red cells: maintain oxygen delivery; avoid excessive haemodilution; consider restrictive strategy unless massive bleeding/ACS/brain injury
Fibrinogen replacement: cryoprecipitate or fibrinogen concentrate; often early target in liver-related bleeding (low fibrinogen predicts bleeding better than INR)
- Practical targets vary by context; commonly aim fibrinogen > 1.5–2.0 g/L in major bleeding/high-risk surgery (local protocol)
Platelets: consider if active bleeding or high-risk procedure with thrombocytopenia; platelet function may be impaired even with adequate count
- Common procedural thresholds used clinically: >50 x10^9/L for many major procedures; higher for neurosurgery/critical sites (institution-dependent)
FFP: replaces multiple factors but requires large volumes; limited effect on INR in cirrhosis; risks include TACO/TRALI; consider in active bleeding with prolonged PT/APTT or guided by viscoelastic tests
Prothrombin complex concentrate (PCC): concentrated vitamin K–dependent factors; rapid effect with small volume; consider for urgent reversal of warfarin or severe bleeding with evidence of factor deficiency; thrombosis risk
- In liver disease without warfarin, use only with specialist input/TEG guidance due to thrombotic potential
Vitamin K: give if deficiency likely (cholestasis, malnutrition, prolonged antibiotics); effect takes hours; safe and often reasonable empirically
Tranexamic acid (TXA): consider if hyperfibrinolysis suspected/confirmed (TEG/ROTEM) or major haemorrhage; balance against thrombosis risk
- In liver transplantation, hyperfibrinolysis may occur around reperfusion; many centres use TXA selectively rather than routinely
Desmopressin (DDAVP): may improve platelet function (e.g., uraemia); limited evidence in cirrhosis; consider case-by-case
Recombinant factor VIIa: rescue therapy for life-threatening bleeding refractory to conventional measures; high thrombotic risk; specialist decision

Regional/neuraxial anaesthesia considerations

Neuraxial techniques carry risk of spinal/epidural haematoma; liver disease coagulopathy is dynamic and poorly captured by INR alone
If considering neuraxial: require stable coagulation, adequate platelets, no active bleeding, no sepsis, and a clear plan for postoperative monitoring and catheter removal timing
- Catheter removal can be higher risk than insertion if coagulation worsens postoperatively
Prefer alternatives: multimodal systemic analgesia, wound infiltration, TAP/QL blocks (still consider bleeding risk with deep blocks), IV lidocaine/ketamine where appropriate

Perioperative plan for a bleeding cirrhotic patient (structured approach)

Call for help early: senior anaesthetist, haematology, blood bank; activate major haemorrhage protocol if needed
Resuscitation priorities: ABC, haemorrhage control, permissive hypotension only if appropriate and short-lived; maintain end-organ perfusion
Laboratory and point-of-care: repeat Hb, fibrinogen, PT/APTT, platelets, ABG (pH, lactate), ionised Ca; use TEG/ROTEM to target therapy
Transfusion strategy: early fibrinogen + platelets as indicated; PRBC to maintain oxygen delivery; avoid large-volume FFP unless indicated; correct Ca/temperature/acidosis
Consider TXA if hyperfibrinolysis; consider PCC in selected scenarios; avoid overcorrection (thrombosis/portal vein thrombosis)
Postop: HDU/ICU, ongoing bleeding surveillance, repeat coagulation, VTE prophylaxis decision, manage encephalopathy/renal dysfunction, careful fluid balance

Explain the concept of “rebalanced haemostasis” in cirrhosis and why INR is a poor predictor of bleeding.

FRCA viva expects you to challenge the assumption that raised INR = bleeding risk.

Cirrhosis reduces procoagulant factors (II, V, VII, IX, X, XI) but also reduces anticoagulants (protein C/S, antithrombin) → net balance may be near-normal but unstable
INR/PT measures only the procoagulant arm (extrinsic pathway) and ignores anticoagulant deficiency and platelet/endothelial contributions
Therefore patients can bleed or clot; INR does not equate to “auto-anticoagulation”
Better approach: clinical bleeding history, procedural risk, platelet count/function, fibrinogen, and viscoelastic tests to guide targeted therapy

You are asked to ‘correct the INR’ before an urgent laparotomy in a cirrhotic patient who is not bleeding. How do you respond?

Demonstrate risk-based decision-making and avoid reflex FFP.

Clarify urgency and bleeding risk of the procedure; assess for active bleeding and obtain bleeding history
Explain that INR in cirrhosis poorly predicts bleeding and FFP often fails to normalise INR, requires large volumes, and risks TACO/TRALI
Check fibrinogen and platelets; correct reversible causes (vitamin K deficiency, hypothermia, acidosis, hypocalcaemia)
If high-risk surgery: plan for blood availability, point-of-care coagulation (TEG/ROTEM), and targeted replacement if bleeding occurs or if tests indicate poor clot strength

Describe how TEG/ROTEM can guide management of coagulopathy in liver disease.

Focus on what each component suggests and how it changes therapy.

Assesses clot initiation, propagation, maximum clot strength, and fibrinolysis in whole blood
Prolonged clotting time/low R-time: suggests factor deficiency → consider FFP (or PCC in selected cases) if bleeding
Low clot amplitude/MCF: suggests low fibrinogen and/or platelets → give cryo/fibrinogen concentrate and/or platelets depending on pattern
Evidence of hyperfibrinolysis (rapid clot lysis): consider TXA
Avoids empiric large-volume transfusion; reduces exposure and complications

A cirrhotic patient has platelets 45 x10^9/L and INR 2.0. They need an urgent endoscopy for variceal bleeding. Outline your haemostatic plan.

Prioritise resuscitation, source control, and targeted products.

Resuscitate: airway protection (often ETT), large-bore access, arterial line, activate haemorrhage protocol if unstable; correct hypothermia/acidosis/hypocalcaemia
Bloods: Hb, fibrinogen, PT/APTT, platelets; consider TEG/ROTEM if available; crossmatch
Transfuse PRBC as needed; consider platelets given count <50 with active bleeding/procedure; prioritise fibrinogen replacement if low
FFP only if ongoing bleeding with evidence of factor deficiency and/or viscoelastic indication; avoid chasing INR alone
Adjuncts: vitamin K if deficiency possible; TXA if hyperfibrinolysis suspected/confirmed (case-by-case); coordinate with endoscopist for banding/sclerotherapy

List the haemostatic abnormalities seen in chronic liver disease and give one clinical consequence of each.

Reduced clotting factors (II, V, VII, IX, X, XI) → prolonged PT/INR and potential bleeding with major haemostatic challenge
Reduced anticoagulants (protein C/S, antithrombin) → thrombosis risk (e.g., portal vein thrombosis, VTE)
Thrombocytopenia (hypersplenism, low TPO) → mucosal/procedural bleeding risk
Platelet dysfunction → oozing, poor primary haemostasis
Dysfibrinogenaemia/low fibrinogen → reduced clot strength and surgical bleeding
Hyperfibrinolysis → diffuse oozing, clot breakdown (notably around transplant reperfusion)

How would you differentiate liver-related coagulopathy from DIC in a septic cirrhotic patient?

Expect a pragmatic answer: both can coexist; look for trends and clinical context.

Clinical context: sepsis, shock, microvascular thrombosis/organ failure suggests DIC; chronic stable cirrhosis suggests baseline rebalanced haemostasis
Trends: rapidly falling platelets and fibrinogen, rising D-dimer, worsening PT/APTT support DIC
Factor VIII: often normal/high in cirrhosis but can be low in DIC (not definitive); viscoelastic tests may show consumption and hyperfibrinolysis
Management: treat underlying cause (sepsis), support haemostasis if bleeding/procedure, avoid indiscriminate correction

Outline your approach to VTE prophylaxis in a patient with cirrhosis and an elevated INR postoperatively.

Key point: elevated INR does not protect from thrombosis.

Assess bleeding risk (active bleeding, recent variceal bleed, severe thrombocytopenia, planned procedures) and thrombosis risk (immobility, cancer, surgery type, prior VTE, portal vein thrombosis)
Do not assume INR is protective; cirrhotics can be prothrombotic
Use mechanical prophylaxis early; consider pharmacological prophylaxis (e.g., LMWH) if bleeding risk acceptable and platelets/clinical picture allow; involve hepatology/haematology for complex cases
Monitor for bleeding and thrombosis; reassess daily as coagulation status changes

Previous FRCA-style question: ‘Discuss the management of coagulopathy during liver transplantation.’

Structure by phases + targeted haemostatic therapy.

Preop: optimise Hb, fibrinogen/platelets if indicated, treat infection, plan massive transfusion, ensure rapid infuser/cell salvage, baseline TEG/ROTEM
Dissection phase: major bleeding from collaterals; maintain temperature, calcium; use goal-directed transfusion; early fibrinogen replacement if low clot strength
Anhepatic phase: no hepatic synthesis/clearance; citrate accumulation and hypocalcaemia; acidosis; manage with calcium, ventilation, perfusion
Reperfusion: post-reperfusion syndrome; hyperkalaemia; potential hyperfibrinolysis—consider TXA if confirmed; reassess TEG/ROTEM frequently
Avoid overtransfusion: risk of thrombosis (hepatic artery thrombosis), TRALI/TACO; consider PCC/rFVIIa only as rescue with specialist agreement

Previous FRCA-style question: ‘What are the risks and benefits of FFP in liver disease?’

Benefits: replaces multiple clotting factors; may help in active bleeding with factor deficiency; can be part of massive haemorrhage protocols
Limitations: large volumes needed; often minimal INR correction in cirrhosis; effect short-lived; does not address platelet dysfunction or fibrinogen well
Risks: TACO, TRALI, allergic reactions, infection (low), increased portal pressures/bleeding from volume load
Practical: reserve for bleeding/high-risk procedures with evidence of factor-related coagulopathy; prefer targeted therapy (fibrinogen/platelets) and viscoelastic guidance

Previous FRCA-style question: ‘How would you manage a patient with obstructive jaundice and a prolonged PT?’

This tests vitamin K deficiency and perioperative planning.

Mechanism: fat malabsorption → vitamin K deficiency → reduced II, VII, IX, X → prolonged PT
Management: give vitamin K (parenteral if needed); reassess PT/INR; plan blood products if urgent surgery/bleeding
Consider additional issues: sepsis/cholangitis, renal dysfunction, cardiovascular risk, pruritus, malnutrition; optimise before surgery where possible