Artificial neural network-based models used for predicting 28- and 90-day mortality of patients with hepatitis B-associated acute-on-chronic liver failure

From January 2008 to May 2016, a total of 2532 cases of patients with chronic HBV (CHB)-ACLF who were hospitalized for an acute deterioration of liver function at the Beijing Ditan Hospital, Capital Medical University (Beijing, China), First Hospital Affiliated to Hunan University of Chinese Medicine (Changsha, China), First Affiliated Hospital of Guangxi University of Chinese Medicine (Nanning, China), Affiliated Hospital of Shandong University of Traditional Chinese Medicine (Jinan, China), Beijing 302 Hospital (Beijing, China), Renmin Hospital Hospital of Wuhan University (Wuhan, China), Hubei Provincial Hospital of Traditional Chinese Medicine (Wuhan, China), and Xiamen Hospital of Traditional Chinese Medicine (Xiamen, China) were retrospective reviewed. All the above hospital were tertiary hospitals in China. Patients’ inclusion criteria were: 1) patients were diagnosed with HBV-ACLF, 2) patients received standard medical management (except liver transplantation), including absolute bed rest, energy and vitamin supplement, maintenance water, intravenous infusions of albumin, electrolyte and acid-base correction, and prevention and management of complications, 3) patients received antiviral therapy (i.e. administration of lamivudine, adefovir dipivoxil, entecavir, telbivudine and tenofovir) based on the HBV replication levels, and the financial condition and willingness of patients, and 4) patients were followed up from their diagnosis until either the end of the 28- or 90-day follow-up period or their death in hospital. Patients who had: 1) hepatocellular carcinoma or other liver malignancy, 2) other organ malignancies that might influence treatment outcomes, 3) infection of hepatitis A, C, D, or E virus, 4) other virus infection (such as cytomegalovirus and human immunodeficiency virus co-infection), 5) autoimmune liver disease, 6) liver decompensated cirrhosis, or 7) severe chronic extrahepatic diseases (such as cardiovascular diseases, diabetes, kidney diseases), were excluded. Patients who were pregnancy or failed to meet the Asia Pacific Association for the Study of the Liver (APASL) criteria for ACLF were also excluded. Eventually, 684 cases of patients who were diagnosed with HBV-ACLF at the admission day or within 90 days after admission were analyzed; 423 of them from the Beijing Ditan Hospital were used for training and constructing ANN-based models and the remaining 261 from other hospitals were for validating the established models. All the involved centers were tertiary hospitals, with reliable treatment conditions and levels. In addition, if there was any difference in the units, presentation meas, etc. of parameters among different hospitals, they would be uniformly transformed. All these could make data measured in different hospitals comparable.

To validate the constructed models, 261 cases, including 103 from the First Hospital Affiliated to Hunan University of Chinese Medicine, 42 from the First Affiliated Hospital of Guangxi University of Chinese Medicine, 14 from the Affiliated Hospital of Shandong University of Traditional Chinese Medicine, 30 from the Beijing 302 Hospital, 32 from the Renmin Hospital of Wuhan University, 25 from the Hubei Provincial Hospital of Traditional Chinese Medicine, and 15 from Xiamen Hospital of Traditional Chinese Medicine, were retrospectively reviewed. The study protocol was in accordance with the ethical guidelines of the Declaration of Helsinki, and was approved by the ethics committees of the above hospitals.

CHB was determined as the detection of hepatitis B surface antigen for over 6 months [17]. Cirrhosis was diagnosed on the basis of previous liver biopsy examinations or the following combined parameters [18, 19], including: 1) ultrasonography, computed tomography, and magnetic resonance imaging characteristics of a small liver with or without splenomegaly/ascites; 2) an aspartate aminotransferase (AST)-platelet ratio index score > 2; and 3) an albumin level < 35 g·L^− 1, without other definite reasons of hypoalbuminemia, such as renal and gastrointestinal loss. Organ failure was defined according to the CLIF-COF score [20], including liver failure with total bilirubin (TBIL) ≥ 12 mg·dL^− 1, renal failure with creatinine ≥2 mg·dL^− 1 or a requirement of renal support therapy, cerebral failure with hepatic encephalopathy (HE) grade III/IV, coagulation failure with an international normalized ratio (INR) ≥ 2.5, circulatory failure with a requirement of vasoconstrictors for maintenance of arterial pressure, and respiratory failure with SpO₂/FiO₂ ≤ 214 or PaO₂/FiO₂ ≤ 200.

ACLF was defined on the basis the APASL criteria as follows (3): 1) acute hepatic damage manifesting as jaundice, TBIL ≥5 mg·dL^− 1 (85 μM) and coagulopathy, 2) with INR ≥ 1.5 or prothrombin activity (PTA) < 40%, 3) complicated with clinical ascites and/or HE within 4 weeks in patients who were previously diagnosed or undiagnosed chronic liver disease. Chronic Liver Failure-ACLF (CLIF-ACLF), MELD, MELD-Na, and Child-Turcotte-Pugh (CTP) scores were calculated on the basis of previously published criteria, respectively. All scores and definitions were applied upon the enrollment in this study.

Patients’ demographics, laboratory parameters, clinical variables (HBV reactivation, bacterial infection, gastrointestinal hemorrhage, hepatotoxic drugs, active alcoholism, and surgery), complications (HE, hepatorenal syndrome, hyponatremia, and spontaneous bacterial peritonitis), and organ (liver, renal, brain, coagulation, circulatory, and respiratory) failure were collected from patients’ medical records and the hospitals’ databases upon the HBV-ACLF diagnosis and during hospitalization. Four scoring systems related to clinical prognosis, including MELD, MELD-Na, CLIF-ACLF and CTP scores, were assessed at baseline. Patients receiving liver transplantation were taken as lost to follow-up, and mortality rate was estimated as transplant-free rate. Mortality at 28 and 90 days after enrollment was confirmed from patients’ medical records or through direct contact with their families, and mortality rates were thus calculated accordingly.

ANN comprises highly complicated and interconnected processing units (neurones) related to weighted connections, with an input, an output, and one or more hidden layers [21‐24]. The advantages of ANN include self-learning, self-adapting and inference processes. By learning from examples, ANN connect each input with the corresponding output through changing the weight of the connections within neurones. When applied, an input will be propagated from the first layer of neurones via each upper layer till an output is generated, followed by a self-adapting process. The value of the produced output is compared with that of the desired one. If there is a discrepancy between these two values, an error signal will then be produced and accordingly, a back propagation (BP) method should be used to modify the weight of the interneurone connections to reduce the total error of the network. During the learning process, the error between the values of the produced and desired outputs is decreasing until a minimum is reached (i.e. convergence of the network). Thereafter, inference process is performed, where the outputs (prognosis) can be produced from new input data on the basis of the knowledge accumulated during training process. Therefore, the ANN can accurately carry out predictions on data sets [21‐24].

In this study, 28- and 90-day mortality in the 423 HBV-ACLF input layers contained neurones that imported the data available, including various clinical, demographic and laboratory data, and the output layers comprised neurones that exported the corresponding predictive outcomes. The hidden layers were applied to make complicated interactions between the input and output neurones. Variables significantly associated with prognosis of HBV-ACLF patients were included to construct ANNs by using Mathematica 11.1.1 for Microsoft windows (64-bit) (April 18, 2017), a graphical neural network development tool. Six hundred and eight-four eligible patients were allocated to a training cohort (n = 423, 61.8%) or validation cohort (n = 261, 38.2%).

The learning process of this ANN was carried out by BP through assessing the errors between the values of the generated and desired outputs. The interneurone connections was adjusted the weight to reduce the overall errors of the network. Learning (training) would be stopped if the total of square errors reached minimum in comparison with the cross-validation data set. Eventually, the final form provided the 28- and 90-day mortality risks in each patient.

Six hundred and eight-four cases of patients diagnosed with HBV-ACLF were eventually reviewed in the study, with a mean age of 43.9 ± 11.7 years and a male proportion of 85.1%. The basic characteristics, biochemical parameters and some scoring systems (such as MELD) of patients were shown in Table 1. One hundred and seventy-five patients (25.6%) died during a 28-day follow-up and 251 patients (36.7%) died during a 90-day follow-up. The mean MELD, MELD-Na, CTP and CLIF-ACLF scores of the total study population were 22.9 (20.0, 26.5), 22.3 (18.1, 28.0), 11 (10, 12), and 38.6 ± 8.1, respectively.

Patients were assigned to survivor and non-survivor groups, respectively at 28 and 90 days during the follow-up. PTA (OR = 0.908, 95% CI: 0.891–0.926, p < 0.001), TBIL (OR = 1.003, 95% CI: 1.002–1.004, p < 0.001), age (OR = 1.037, 95% CI: 1.022–1.053, p < 0.001), serum sodium (OR = 0.923, 95% CI: 0.892–0.955, p < 0.001), alkaline phosphatase (ALP) (OR = 0.995, 95% CI: 0.991–0.999, p = 0.009), gamma-glutamyl transpeptidase (GGT) (OR = 0.996, 95% CI: 0.993–0.999, p = 0.006), HE (OR = 5.623, 95% CI: 2.358–10.891, p < 0.001) and hepatitis B e antigen (HBeAg) positive rate (OR = 0.616, 95% CI: 0.429–0.884, p = 0.009) were significantly associated with 28-day mortality (Table 2). All these variables were included to build an ANN model.

In addition, PTA (OR = 0.922, 95% CI: 0.907–0.937, p < 0.001), TBIL (OR = 1.003, 95% CI: 1.003–1.004, p < 0.001), age (OR = 1.040, 95% CI: 1.026–1.054, p < 0.001), sodium (OR = 1.379, 95% CI: 1.113–1.708, p = 0.003), ALP (OR = 0.997, 95% CI: 0.993–1.000, p = 0.034), GGT (OR = 0.997, 95% CI: 0.994–0.999, p = 0.005), HE (OR = 2.235, 95% CI: 1.883–4.837, p < 0.001) and HBeAg positive rate (OR = 1.005, 95% CI: 1.003–1.006, p < 0.001) were significantly associated with 90-day mortality. Similarly, these variables were also included to build an ANN model.

As one of the most recognized ANN architectures, multilayer perceptron (MLP) including the input, output and hidden layers were used to establish ANN models. Neurones were shown linkage with weighted connections (Figs. 1 and 2). Generally, the numbers of input and output variables were respectively consistent with those of demographic, biochemical and clinical parameters and those of the set prognosis. As shown in Figs. 1 and 2, the MLP comprises eight input neurones and one output neurone. Following many times of debugging and testing, two hidden neurones were included in the hidden layers in order to increase the performance of MLP. The ANN models for 28- and 90-day mortality of HBV-ACLF patients were shown in Figs. 1 and 2, respectively.

For 28-day mortality in the training cohort, the ANN model’s predictive accuracy (AUR 0.948, 95% CI 0.925–0.970) was significantly higher than that of MELD (AUR 0.777, 95% CI: 0.735–0.820, p < 0.001), MELD-Na (AUR 0.758, 95% CI: 0.711–0.805, p < 0.001), CTP (AUR 0.697, 95% CI: 0.650–0.744, P < 0.001), and CLIF-ACLF (AUR 0.813, 95% CI: 0.772–0.853, p < 0.001) (Fig. 3a). In the validation cohorts, the AUR of ANN model for 28-day mortality was 0.748 (95% CI: 0.673–0.822), which was still higher than that of MELD (AUR 0.619, 95% CI: 0.536–0.701, p = 0.0099), MELD-Na (AUR 0.720, 95% CI: 0.642–0.799, p = 0.424), CTP (AUR 0.713, 95% CI: 0.634–0.792, p = 0.303), and CLIF-ACLF (AUR 0.696, 95% CI: 0.615–0.777, p = 0.2004) (Fig. 3b).

For 90-day mortality in the training cohort, the ANN model’s prediction accuracy (AUR 0.913, 95% CI 0.887–0.938) was significantly higher than that of MELD (AUR 0.765, 95% CI: 0.726–0.805, p < 0.001), MELD-Na (AUR 0.775, 95% CI: 0.733–0.817, p < 0.001), CTP (AUR 0.712, 95% CI: 0.669–0.755, p < 0.001), and CLIF-ACLF (AUR 0.818, 95% CI: 0.782–0.854, p < 0.001) (Fig. 4a). In the validation cohorts, the AUR of ANN model was 0.754 (95% CI: 0.697–0.812), which was still higher than that of MELD (AUR 0.626, 95% CI: 0.560–0.691, p = 0.019), MELD-Na (AUR 0.669, 95% CI: 0.604–0.733, p = 0.133), CTP (AUR 0.656, 95% CI: 0.591–0.720, P = 0.076), and CLIF-ACLF (AUR 0.632, 95% CI: 0.565–0.698, p = 0.264) (Fig. 4b).