Elevated troponin I and its prognostic significance in acute liver failure

Troponin I was analysed using Trop I ultra reagent supplied by Siemens Healthcare Diagnostics (Siemens AG, Munich, Germany). The ADVIA Centaur TnI-Ultra assay is a three-site sandwich immunoassay using direct chemiluminometric technology. The European Society of Cardiology and the American College of Cardiology recommend using the 99th percentile as a cutoff value for troponin assays, above which any value is considered abnormal. For the ADVIA Centaur assay, troponin levels > 0.4 μg/L are taken to represent myocardial damage, levels > 1.5 μg/L are suggestive of acute myocardial infarction. The minimum detectable concentration for this assay is 0.006 μg/L [10]. The coefficient of variation was 0.05. Patients with abnormal cTnI were divided into troponin-positive (> 0.05) or troponin-negative (< 0.05), cTnI-high (> 0.7) or cTnI-low groups (< 0.21) based on the tertiales of the distribution of cTnI results to further assess the impact of cTnI on echocardiographically derived ventricular function given that all patients with a positive troponin underwent echocardiographic examination.

Assuming an effect size of 0.1, alpha of 0.05 and power of 80% to detect predictor independence from a model using 15 predictors, 200 sets of patient data were required. Data is reported as mean (SD) and median (range) and statistical testing utilised Student's t test/Mann Whitney U test/ANOVA/Kruskal-Wallis as appropriate following normality testing. Categorical data were compared using the χ2 test. Logistic regression and area under the receiver operating characteristic curve (AUROC) was performed to assess the effect of measured variables on outcome. Statistical significance was defined at the 95% level. Statistical analysis was performed within the Statistics Package for the Social Sciences (SPSS, version 17.0 SPSS Inc., Chicago, IL, USA) and MedCalc version 11.4.4 (MedCalc Software, Mariakerke, Belgium).

Patients in both the acetaminophen and non-acetaminophen-induced ALF presented with a wide range of abnormal troponin I levels ranging from 0.05 to 50, very high levels were more frequently observed in individuals with recreational drug-induced liver injury. Individuals with positive cTnI were older and had more severe organ failure. The median organ failure scores found in patients with positive cTnI were: APACHE II (19.5 (3 to 51) vs 14 (2 to 51), P = 0.001), SOFA (15 (4 to 20) vs 13 (2 to 21), P = 0.027). Patients with positive cTnI had higher median serum creatinine levels (192 (38 to 550) μmol/l vs 117 (46 to 929) μmol/l, P < 0.001, MWU test) and more frequently required renal replacement therapy (49% vs 22%, P = 0.006 χ² test). Troponin I elevation correlated significantly with pH (-0.21, P = 0.002) (r values), hepatic encephalopathy grade (0.25, P < 0.001) and arterial lactate (0.25, P < 0.001).

No difference in haemodynamic parameters were noted between the cTnI-negative and -positive groups for mean arterial pressure ((MAP) 70 (50 to 124) vs 70 (45 to 180); P = 0.221] or cardiac index (4.3 (2.0 to 6.5) vs 4.2 (2.9 to 6.9); P = 0.511). However patients with elevated cTnI required more vasopressor support-norepinephrine (45% vs 19%, P = < 0.008) Table 1. Subjects with elevated cTnI had higher creatinine kinase levels (CK) (292 (6 to 37840) IU/L vs 81 (14 to 1417) IU/L (P = < 0.001)) Table 1.

One hundred and forty-four patients underwent echocardiography; 100 in the cTnI-positive group (TI-pos) and 44 in the cTnI-negative group (TI-neg). Thirteen patients were diagnosed with a small not haemodynamically significant pericardial effusion Table 2.

LVD was observed in 15% of patients with a positive cTnI (15/100). Left ventricular dysfunction in the cTnI-positive group was more pronounced in those individuals with pre-existing cardiac disease such as ischaemic heart disease, cardiomyopathy and post cardiac arrest when compared to the cTnI-negative group (2%, 1/43). A borderline statistical association was noted between cTnI positivity and LVD (15/85 vs 1/43, P = 0.053, χ² test).

Median cTnI levels measured 0.08 μg/L (0 to 50) in those who survived and 0.18 μg/L (0 to 50) in those who either died or were transplanted; P = 0.046 (Mann Whitney U test). There was no difference in troponin positivity between the ALF (116/178) and SALF (20/40) cohort (P = 0.107, χ2 test), cTnI was not associated with poor outcome on either univariate or multivariate analysis (Table 3).

Independent prognostic significance was neither found when patients were subgrouped into those with hypoxic aetiology (P = 0.341) nor with regards to the presence or absence of raised pulmonary artery pressures (P = 0.756).

Age, aetiology of liver disease, bilirubin, INR, lactate, hepatic encephalopathy, mean arterial blood pressure, continuous venovenous haemodiafiltration (CVVHF), vasopressor use and fraction of inspired oxygen (FiO2) requirements were found to be associated with poor outcome on univariate analysis. However, on multivariate analysis only bilirubin (odds ratio (OR) 1.003, confidence interval (CI) 1.000 to 1.006, P = 0.039), INR (OR 1.263, CI 1.096 to 1.455, P = 0.001), lactate (OR 1.547, CI 1.137 to 2.105, P = 0.005), and hepatic encephalopathy grade (OR 3.293, CI 1.895 to 5.723, P = < 0.001) along with organ failure scores were identified as independent predictors of poor outcome in this group (Table 4).

AUROC analysis demonstrated the composite multivariate model that is, bilirubin, lactate, INR and hepatic encephalopathy grade (AUROC 0.89 (0.83 to 0.94)) to be the best predictor of outcome in ALF group followed by model for end-stage liver disease (MELD) (0.76 (0.68 to 0.83)) in this mixed cohort of patients (acetaminophen and non-acetaminophen). Despite a close correlation with organ failure severity, AUROC analysis confirmed that cTnI did not predict poor outcome (AUROC 0.61 (0.52 to 0.68)) (Figure 1).