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A Novel Algorithm for Streamlining Diagnosis of Advanced Liver Fibrosis in CHB Patients with Concurrent Hepatic Steatosis

  • Xiaoming Xu1,#,
  • Fajuan Rui1,#,
  • Wenjing Ni1,
  • Chao Wu1,2,
  • Junping Shi3,*  and
  • Jie Li1,2,* 
 Author information
Journal of Clinical and Translational Hepatology 2024;12(2):222-226

DOI: 10.14218/JCTH.2023.00362

Abstract

Keywords

Chronic hepatitis B (CHB) with concurrent hepatic steatosis (HS) is a growing challenge for public health globally. As the prevalence of HS increases in Asia where CHB is endemic,1 the combined prevalence of HS and CHB is estimated to be 32.8%.2 Furthermore, the co-existence of these diseases is associated with more frequent and severe adverse clinical events such as liver fibrosis than HS or CHB alone.3 There is a need for reliable diagnostic methods to detect and manage this condition in affected individuals. It should be noted that histologic evaluation via liver biopsy remains the gold standard to diagnose advanced fibrosis in patients with chronic liver diseases. Despite its effectiveness, many patients are hesitant to undergo a liver biopsy due to its invasive nature and the potential risks involved. Some of the most well-known complications associated with liver biopsy include bleeding, infection, and damage to nearby organs. Hence, alternative non-invasive tests (NITs), including the aspartate aminotransferase to platelet ratio index (APRI), fibrosis index based on the four factors (FIB-4), and nonalcoholic fatty liver disease fibrosis score (NFS) have been proposed.4–6 However, the diagnostic accuracy of these tests in CHB patients with concurrent HS is not yet clear. In this retrospective study, we aimed to evaluate the performance of APRI, FIB-4, and NFS for predicting advanced fibrosis in patients with both CHB and HS. Furthermore, we introduced the combined models that call for improvements in the current diagnostic workflow.

We consecutively enrolled untreated CHB patients with concurrent HS who underwent liver biopsy from nine medical centers in China between April 2004 and September 2021 (Clinical Trials. gov identifier: NCT05766449). The liver biopsy was performed to evaluate the extent of steatosis, inflammation, and fibrosis, and to determine if patients required antiviral therapy initiation.7,8 Patients who were hepatitis B virus surface antigen positive for more than 6 months, and had hepatic steatosis of more than 5% as confirmed by liver biopsy, were included in the study. Patients with alcoholic fatty liver or other causes of liver disease, diagnosed with hepatocellular carcinoma, or other malignancies were excluded. The study was approved by ethics committees at all participating centers. The stage of fibrosis was assessed by Scheuer’s score. Based on Scheuer’s classification, the stages of fibrosis were determined based on the degree of portal/periportal and lobular activity. In this system, S3 represents severe fibrosis with bridging fibrosis, and we defined ≥S3 as advanced fibrosis.9 Clinical and laboratory data, including demographic characteristics, routine blood tests, and liver biochemistry data, were systematically extracted into standardized forms. During the data analysis process, the Kolmogorov-Smirnov test was used to determine if the data followed a normal distribution. Continuous variables were presented as the mean and standard deviation if the variables showed a normal distribution, or as the median (interquartile range). Categorical variables were expressed as numbers (percentages). Statistical analysis was performed using MedCalc software (version 19.8). The area under the receiver operating characteristic, sensitivity, specificity, positive and negative predicted values were calculated for the two estimated cut-off points for each score (the lower and higher cut-offs for ruling out and ruling in advanced fibrosis, respectively). Subsequently, we computed the proportion of patients with the correct classification (the sum of true positives and negatives) for different combinations of NITs.

We retrospectively enrolled 926 eligible patients over the study period. The patients had a median age of 38.00 years, 697 (75.27%) were male, and the median body mass index was 25.47, with 80 patients (8.64%) having diabetes. In terms of steatosis classification, 752 (81.21%) patients were categorized as grade 1, 126 (13.61%) as grade 2, and 48 (5.18%) as grade 3 (Table 1). Among them, 180 (19.44%) patients had advanced fibrosis (≥S3). The scores of FIB-4, APRI, and NFS were calculated based on obtainable laboratory parameters. At the lower cut-off values (FIB-4 <1.3, APRI ≤0.5, NFS <1.455), APRI had the highest sensitivity at 65.56%, followed by 53.89% for FIB-4 and 41.11% for NFS. At the higher cut-off values (FIB-4 >2.67, APRI >1.5, NFS >0.676), NFS had the highest specificity of 97.99%, followed by FIB-4 (94.77%) and APRI (94.1%).

Table 1

Demographic and clinical characteristics of chronic hepatitis B patients with concurrent hepatic steatosis

CharacteristicsOutcome
Male, n/total (%)697/926 (75.27)
Age (years)38.00 (31.00–46.00)
Body mass index (kg/m2)25.47 (23.38–27.74)
Diabetes mellitus, n/total (%)80/926 (8.64)
Hypertension, n/total (%)103/926 (11.12)
White blood cell (109/L)5.57 (4.69–6.60)
Neutrophils (109/L)3.05 (2.46–3.87)
Red blood cell (1012/L)4.99 (4.62–5.28)
Hemoglobin (g/L)151.00(140.00–160.00)
Platelet (109/L)195.00 (160.00–236.00)
Total bilirubin (umol/L)14.10 (11.10–18.25)
Albumin (g/L)44.50 (41.60–47.30)
Globulin (g/L)27.50 (25.10–30.50)
Alanine transaminase (U/L)44.75 (28.00–85.85)
Aspartate transaminase (U/L)30.00 (23.00–49.25)
Alkaline phosphatase (U/L)71.05 (58.00–90.00)
Gamma-glutamyl transferase (U/L)34.00 (22.00–55.00)
Lactate dehydrogenase (U/L)179.50 (160.00–204.25)
Creatinine (umol/L)66.96±13.94
Urea (umol/L)345.72 ± 87.22
Total Cholesterol (mmol/L)4.58 (4.02–5.13)
Triglycerides (mmol/L)1.23 (0.91–1.77)
Glucose (mmol/L)5.25 (4.77–5.83)
High density lipoprotein cholesterol (mmol/L)1.17 (0.97–1.39)
Low density lipoprotein cholesterol (mmol/L)2.70 ± 0.75
Prothrombin time (s)12.40 (11.10–13.20)
International normalized ratio1.00 (0.94–1.04)
Steatosis grade, n/total (%)
  1752/926 (81.21)
  2126/926 (13.61)
  348/926 (5.18)
Fibrosis grade, n/total (%)
  029/926 (3.13)
  1464/926 (50.11)
  2253/926 (27.32)
  3129/926 (13.93)
  451/926 (5.51)

A total of 649 patients with CHB concurrent with HS, with a FIB-4 cutoff <1.3 were classified as non-advanced fibrosis, and 566 (61.12%) of the patients coincided with the biopsy results. Of the 695 patients with an NFS cutoff <−1.455, classified as non-advanced fibrosis, 589 (63.61%) had results consistent with the biopsy results of non-advanced fibrosis. Notably, APRI displayed the highest indeterminate rate of 30.99% compared to the other NITs. The proportions of patients who were correctly classified according to a single test were 64.7% for NFS, 64.1% for FIB-4, and 57.6% for APRI (Fig. 1).

Comparison of different non-invasive tests and combined model for predicting advanced fibrosis in chronic hepatitis B patients with concurrent hepatic steatosis.
Fig. 1  Comparison of different non-invasive tests and combined model for predicting advanced fibrosis in chronic hepatitis B patients with concurrent hepatic steatosis.

APRI, aspartate aminotransferase to platelet ratio index; AUROC, area under receiver operating characteristic; FIB-4, fibrosis index based on the four factors; FN, false negative; FP, false positive; NFS, nonalcoholic fatty liver disease fibrosis score; NITs, non-invasive tests; NPV, negative predicted values; PPV, positive predicted values; TN, true negative; TP, true positive; SE, sensitivities; SP, specificities.

To further improve the performance of the diagnostic model and reduce the indeterminate rate, we combined the three NITs pairwise. The algorithm, including NFS followed by APRI, allowed most patients to be correctly classified (73.7%), compared to FIB-4-NFS (71.3%), NFS-FIB-4 (71.8%), FIB-4-APRI (71.0%), APRI-FIB-4 (70.5%), APRI-NFS (71.8%), which were better than the three NITs used alone. In addition, as shown in Figure 1, the model which combined APRI and NFS achieved the lowest percentage of indeterminate cases at 10.04%.

In this study, we found that the combined models overall showed better performance than the individual NITs in CHB patients with concurrent HS. Moreover, the NFS-APRI model achieved the lowest indeterminate zone among the six combined models. Although FIB-4, APRI, and NFS have been widely utilized for detecting advanced fibrosis,10 none of these NITs were completely suitable for CHB patients with concurrent HS. Additionally, the accuracy of these scoring systems might be affected by factors such as age, sex, ethnicity, and comorbidities. FIB-4, the most commonly used test for fibrosis stratification in HS patients had a relatively lower positive predictive value and a higher indeterminate rate.11 Furthermore, a population-based study12 reported that FIB-4 and NFS misclassified more than 30% of patients, leading to a non-negligible percentage of false-negatives and false-positives, especially in patients with risk factors for chronic liver disease (such as obesity and diabetes). Lin KM et al.13 investigated the diagnostic accuracy of FIB-4, NFS and APRI for identifying advanced fibrosis in CHB patients with concurrent HS, and demonstrated that these NITs were better at excluding rather than including advanced fibrosis, which is consistent with our results. A previous study showed that a simple serum-based score may fall into the given test’s indeterminate zone (a high uncertainty area ranging from 40% for FIB-4 to 55.8% for NFS).14 Thus, considering the suboptimal performance of individual NITs, researchers have started using a sequential strategy to screen for fibrosis. For instance, a Danish cohort study combined FIB-4 with the Enhanced Liver Fibrosis test, to achieve a correct classification rate of 88% and reduced indeterminate zones.15 Our study also provided evidence supporting the utilization of a sequential strategy. Given the easily-available laboratory parameters used in NITs, a sequential strategy could promote diagnostic accuracy and optimize referral pathways. Additionally, the combination of models developed during our study can be of great assistance in primary care settings. With the ability to provide targeted screening for liver fibrosis, the findings from this study will enable healthcare professionals to make informed decisions regarding treatment options and predict potential clinical outcomes. Identifying patients who may be at risk of developing liver fibrosis is a crucial step in the early detection and treatment of this condition. By implementing these models, we can ensure that patients receive the care they need and deserve. The potential benefits of utilizing these models are vast, from improving patient outcomes to reducing the burden on healthcare systems. Overall, the use of our combined models has the potential to revolutionize the way in which liver fibrosis is diagnosed and treated in primary care settings.

Our study cohort involving multiple centers provides well characterized clinical data, including liver histology information representing the current gold standard reference for comparison to the NITs. However, some limitations should be acknowledged. First, as this was a retrospective study, we did not have imaging test data for some of our subjects. Second, all the patients were recruited from tertiary centers and may not be fully representative of community-dwelling patients, which limits the generalizability of our findings to other populations.

In conclusion, the combined model of NFS-APRI developed in our study showed better performance than individual NITs. The model could reduce indeterminate zones and optimize referral pathways, highlighting it as a useful tool for targeted screening for liver fibrosis in patients afflicted with both CHB and HS. Additional research is needed to validate our study findings and extend our understanding of the clinical utility of combined NITs models, particularly in cases of CHB with concurrent HS. Further studies are needed to provide valuable insights into the efficacy of this approach, and pave the way for more widespread adoption of these models in clinical practice.

Abbreviations

APRI: 

aspartate aminotransferase to platelet ratio index

CHB: 

chronic hepatitis B

FIB-4: 

fibrosis index based on the four factors

HS: 

hepatic steatosis

NFS: 

nonalcoholic fatty liver disease fibrosis score

NITs: 

non-invasive tests

Declarations

Ethical statement

This study has received approval from the Institutional Ethics Review Board of all the involved hospitals, with document numbers of 2008022 and NCT05766449. This study was carried out in accordance with the Declaration of Helsinki. As this was a retrospective study, the requirement for informed consent was waived.

Data sharing statement

We are unable to provide access to our dataset for privacy reasons. The protocol and statistical analysis methods used in the study can be requested directly from the corresponding author after approval.

Funding

This research was supported by the National Natural Science Fund (No. 82170609, 81970545), the Natural Science Foundation of Jiangsu Province (No. BK20231118), the Natural Science Foundation of Shandong Province (Major Project), (No. ZR2020KH006).

Conflict of interest

JL has been an Editorial Board Member of Journal of Clinical and Translational Hepatology since 2024. The other authors have no conflict of interests related to this publication.

Authors’ contributions

All authors contributed to this study at different levels. Study concept and design: JL and JS. Acquisition of data: XX, FR, and WN. Statistical analysis and interpretation of data: XX, FR, and WN. Drafting of the manuscript: XX and FR. Critical revision of the manuscript for important intellectual content: JL, JS and CW.

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