Noninvasive Techniques for the Evaluation and Monitoring of Patients With Chronic Liver Disease - CAM 332HB

Description
Noninvasive techniques to monitor liver fibrosis are being investigated as alternatives to liver biopsy in patients with chronic liver disease. Options for noninvasive monitoring include (1) multianalyte serum assays with algorithmic analysis of either direct or indirect biomarkers and (2) specialized radiologic methods, including magnetic resonance elastography (MRE), transient elastography, acoustic radiation force impulse imaging (ARFI), and real-time transient elastography (RTE).

For individuals who have chronic liver disease who receive transient elastography, the evidence includes many systematic reviews of more than 50 observational studies (> 10,000 patients). Relevant outcomes are test accuracy and validity, morbid events, and treatment-related morbidity. Transient elastography (FibroScan) has been studied in populations with viral hepatitis, nonalcoholic fatty liver disease (NAFLD), and alcoholic liver disease (ALD). There are varying cutoffs for positivity. Failures of the test are not uncommon, particularly for those with high body mass index, but were frequently not captured in analyses of the validation studies. Given these limitations and the imperfect reference standard, it is difficult to interpret performance characteristics. However, for the purposes of deciding whether a patient has severe fibrosis or cirrhosis, the FibroScan results provide data sufficiently useful to determine therapy. 

Specifically, FibroScan has been used as an alternative to biopsy to establish eligibility regarding presence of fibrosis or cirrhosis in several randomized controlled trials (RCTs) that showed the efficacy of hepatitis C virus (HCV) treatments, which in turn demonstrated that the test can identify patients who would benefit from therapy. The evidence is sufficient to determine that the technology results in a meaningful improvement in the net health outcome.

For individuals who have chronic liver disease who noninvasive radiologic methods other than transient elastography for liver fibrosis measurement, the evidence includes systematic reviews of observational studies. Relevant outcomes are test accuracy and validity, morbid events, and treatment-related morbidity. Other radiologic methods (AFRI, MRE, RTE) may have similar performance for detection of significant fibrosis or cirrhosis. Studies have frequently included varying cutoffs not prespecified or validated. Given these limitations and the imperfect reference standard, it is difficult to interpret performance characteristics. There is no direct evidence that other noninvasive radiologic methods improve health outcomes. The evidence is insufficient to determine the effects of the technology on health outcomes. 

Hepatic fibrosis is associated with a cycle of extracellular matrix deposition and degradation. Biomarkers of extracellular matrix turnover are used to directly assess fibrosis and theoretically to monitor progression or regression (Valva, Rios, De Matteo, & Preciado, 2016). These markers include several glycoproteins, members of the collagen family, collagenases and their inhibitors, and a number of cytokines involved in the fibrogenic process (Valva et al., 2016), individually as well as in panel combinations (Parikh, Ryan, & Tsochatzis, 2017).

Regulatory Status
A search for “fibrosis” on the FDA website on Aug. 7, 2019, did not yield any results relevant to hepatic conditions. Although several of these panels are patented, none are FDA approved. Additionally, many labs have developed specific tests that they must validate and perform in house. These laboratory-developed tests (LDTs) are regulated by the Centers for Medicare & Medicaid Services (CMS) as high-complexity tests under the Clinical Laboratory Improvement Amendments of 1988 (CLIA ’88). As an LDT, the U.S. Food and Drug Administration has not approved or cleared this test; however, FDA clearance or approval is not currently required for clinical use.

Policy
A single FibroScan may be considered MEDICALLY NECESSARY for the initial evaluation of patients with chronic liver disease. 

Subsequent FibroScans are considered investigational and/or unproven and therefore considered NOT MEDICALY NECESSARY FOR monitoring of patients with chronic liver disease.

  1. For individuals with hepatitis C, hepatitis B, nonalcoholic fatty liver disease (NAFLD) (including nonalcoholic steatohepatitis (NASH)), or alcoholic hepatitis, the use of the following multianalyte assays with algorithmic analysis to distinguish hepatic cirrhosis from non-cirrhosis is considered MEDICALLY NECESSARY:
    1. ELF™(ELFTM)
    2. FibroTest®
    3. HBV FibroSURE®
    4. HCV FibroSURE®
  2. For individuals with hepatitis C, hepatitis B, nonalcoholic fatty liver disease (NAFLD), or alcoholic hepatitis, the use of other multianalyte assays with algorithmic analysis (e.g., ASH FibroSURE®, LIVERFAStTM, NASH FibroSURE®, OWLiver®) is considered NOT MEDICALLY NECESSARY.
  3. For individuals with liver disease not meeting the above criteria, the use of multianalyte assays with algorithmic analysis is considered NOT MEDICALLY NECESSARY.

The following does not meet coverage criteria due to a lack of available published scientific literature confirming that the test(s) is/are required and beneficial for the diagnosis and treatment of an individual’s illness:

1. Except as previously described, the use of the following serum biomarkers in immunoassays and/or immunohistochemistry assays is considered NOT MEDICALLY NECESSARY:

  1. Signal-induced proliferation-associated 1 like 1 (SIPA1L1)
  2. microRNA (miRNA or miR) analysis, including but not limited to, the following:
    1. microRNA-21 (miRNA-21 or miR-21)
    2. miRNA-29a (miR-29a)
    3. miRNA-122 (miR-122)
    4. miRNA-221 (miR-221)
    5. miRNA-222 (miR-222)
  3. Chitinase 3-like 1 (CHI3L1)
  4. Hyaluronic acid
  5. Type III procollagen (PCIII)
  6. Type IV collagen
  7. Laminin
  8. Plasma caspase-generated cytokeratin-18
  9. Micro-fibrillar associated glycoprotein 4 (MFAP4)

Table of Terminology

Term

Definition

AAFP American Academy of Family Physicians

AASLD

American Association for the Study of Liver Diseases

AFP

Alpha-fetoprotein

AGA

American Gastroenterological Association

ALT

Alanine aminotransferase

ALT

Alanine transaminase

AST

Aspartate aminotransferase-to-platelet ratio index

AUC

Area under the curve

BMI

Body mass index

CHBV

Chronic hepatitis B virus

CHC

Chronic hepatitis C

CHCV

Chronic hepatitis C virus infection

CK-18

Cytokeratin-18 fragments

CLD

Chronic liver disease

CMS

Centers for Medicare & Medicaid Services

EASD

European Association for the Study of Diabetes

EASL

European Association for the Study of Obesity

GGT

Gamma-glutamyl transferase

HCC

Hepatocellular carcinoma

HCV

Hepatitis C virus

IDSA

Infectious Diseases Society of America

LDTs

Laboratory developed tests

MFAP4

Microfibrillar-associated Protein 4

miRNA

MicroRNA

MTX

Methotrexate

NAFLD

Nonalcoholic fatty liver disease

NASH

Nonalcoholic steatohepatitis

NICE

National Institute for Health and Care Excellence

NILTS

Non-invasive fibrosis tests

NIT

Non-invasive test

SC

Standard care

SIPA1L1

Signal-induced proliferation-associated 1 like 1

SWE

Shear-wave elastography

TACE

Trans-arterial chemoembolization

TE

Transient elastography

US

Ultrasonography

USPSTF

United States Preventive Services Task Force

VCTE

Vibration controlled transient elastography

WHO

World Health Organization

Rationale 
Fibrosis is a wound healing response in which damaged regions are encapsulated by an extracellular matrix. This is common in individuals with chronic liver injury but may be seen in other organs such as

the kidneys or lungs. Chronic liver injury may be caused by numerous conditions, such as hepatitis, and progressive fibrosis may lead to cirrhosis (Friedman, 2022). Liver biopsy remains the gold standard for evaluation of chronic liver disease to monitor treatment and disease progression. However, this invasive procedure has several drawbacks including pain, bleeding, inaccurate staging due to sampling error, and variability of biopsy interpretation (Chin et al., 2016).

Serum biomarkers, such as the aspartate aminotransferase (AST) to platelet ratio (APRI), have been proposed as measures of hepatic fibrosis assessment, and numerous panels exist (Curry & Afdhal, 2022). These markers (and corresponding panels) may be categorized as “direct” or “indirect.” Direct markers of fibrosis evaluate extracellular matrix turnover, and indirect markers signify changes in hepatic function. Direct biomarkers may be further subdivided by markers associated with matrix deposition, matrix degradation, or cytokines (and chemokines) associated with fibrogenesis. Procollagen I peptide, procollagen III peptide, type I collagen, type IV collagen, YKL-40 (chondrex), laminin, and hyaluronic acid, MMP-2, TIMP-1, -2, TGF-beta, TGF-alpha, and PDGF have all been proposed as direct measures of fibrosis. Indirect markers include serum aminotransferase levels, platelet count, coagulation parameters, gamma-glutamyl transferase (GGT), total bilirubin, alpha-2-macroglobulin, and alpha-2-globulin (haptoglobin) (Curry & Afdhal, 2022). Other markers have been investigated to be used independently or as part of these panels. The human microfibrillar-associated protein 4 (MFAP4) is located in extracellular matrix fibers and plays a role in disease-related tissue remodeling. Bracht et al. (2016) evaluated the “potential” of MFAP4 as a biomarker for hepatic fibrosis. A total of 542 patients were included, and the authors focused on differentiation of no to moderate (F0 – F2) and severe fibrosis stages and cirrhosis (F3 and F4). In the “leave-one-out cross validation,” a sensitivity of 85.8% and specificity of 54.9% was observed and the multivariate model yielded 81.3% sensitivity and 61.5% specificity. The authors suggested that “the combination of MFAP4 with existing tests might lead to a more accurate non-invasive diagnosis of hepatic fibrosis and allow a cost-effective disease management in the era of new direct acting antivirals” (Bracht et al., 2016).

Plasma caspase-generated cytokeratin-18 fragments (CK-18) have been proposed as a biomarker in the diagnosis and staging of nonalcoholic steatohepatitis (NASH). Cusi et al. (2014) studied the clinical value of CK-18. The authors studied the adipose tissue, liver, and muscle insulin resistance of 424 patients as well as liver fat (n = 275) and histology (n = 318). The authors found that median CK-18 levels were elevated in patients with verses without nonalcoholic fatty liver disease (NAFLD) (209 U/L vs. 122 U/L) or with verses without NASH (232 U/L vs. 170 U/L). The CK-18 area under curve to predict NAFLD, NASH, or fibrosis were 0.77, 0.65, and 0.68, respectively. The overall sensitivity/specificity for NAFLD, NASH and fibrosis were 63%/83%, 58%/68% and 54%/85%, respectively. CK-18 correlated most strongly with ALT (r = 0.57) and adipose tissue IR (insulin-suppression of FFA: r = -0.43), but not with ballooning, body mass index, metabolic syndrome, or type 2 diabetes. The authors concluded, “Plasma CK-18 has a high specificity for NAFLD and fibrosis, but its limited sensitivity makes it inadequate as a screening test for staging NASH. Whether combined as a diagnostic panel with other biomarkers or clinical/laboratory tests may prove useful requires further study” (Cusi et al., 2014).

Likewise, Chitinase 3-like 1 (CHI3L1) has been proposed to be a better serum biomarker than hyaluronic acid, type III procollagen, type IV collagen, and laminin. CHI3L1 is preferentially expressed in hepatocytes over any other body tissue. Huang et al. (2015) investigated CHI3L1 in 98 patients with hepatitis B. The authors reported that CHI3L1 can be used to differentiate between early stages of liver fibrosis (S0-S2) from late stages (S3-S4) “with areas under the ROC curves (AUCs) of 0.94 for substantial (S2, S3, S4) fibrosis and 0.96 for advanced (S3, S4) fibrosis” (Huang et al., 2015). Wang et al. (2018) also report that

CHI3L1 is a useful marker for the assessment of liver fibrosis before treatment and can also be used to monitor change during therapy.

MicroRNA (miRNA) sequences have also been proposed as a marker of liver function. MiRNA sequences often have roles in gene regulation and other cellular processes, so changes in these sequences may indicate a liver condition (Tendler, 2022). For example, Abdel-Al et al. (2018) investigated miRNA’s association with Hepatitis C virus (HCV) patients. Forty-two patients with HCV and early-stage fibrosis, 45 patients with HCV and late-stage fibrosis, and 40 healthy controls were examined and the expression patterns of five miRNA sequences (miR-16, miR-146a, miR-214-5p, miR-221, and miR-222) were measured. The authors found miRNA-222 to have the highest sensitivity and specificity for both fibrosis groups, and all mi-RNA sequences except miRNA-214-5p were significantly upregulated in fibrosis. MiRNA-221 was also found to have significant positive correlations with miRNA-16 and miRNA-146a. The authors concluded that “the high sensitivity and specificity of miRNA-222 and miRNA-221 in late-stage fibrosis indicate promising prognostic biomarkers for HCV-induced liver fibrosis (Abdel-Al et al., 2018).

Multiple biomarkers may be combined into a panel. Panels may include a combination of direct markers, indirect markers, or markers from both categories. The most studied panels are the aspartate aminotransferase (AST) to platelet ratio (APRI), FibroTest/FibroSure, and Hepascore, although many more exist. FibroTest/FibroSure incorporates alpha-2-macroglobulin, alpha-2-globulin (haptoglobin), gamma globulin, apolipoprotein A1, GGT, and total bilirubin, age, and sex. HepaScore measures bilirubin, GGT, hyaluronic acid, alpha-2-macroglobulin, age, and sex. These panels have demonstrated some promising results, but Curry and Afdhal (2022) note that indeterminate outcomes are common. Furthermore, they state that no singular panel has emerged as the standard of care (Curry & Afdhal, 2022). Another test, known as the LIVERFAStTM by Fibronostics, utilizes a blood sample to measure 10 biomarkers; algorithm technology is used “to determine the fibrosis, activity and steatosis stages of the liver” (Fibronsotics, 2020). OWLiver® by CIMA Sciences, LLC, evaluates 28 metabolites from a blood sample. Relative concentrations of those biomarkers are analyzed together with two algorithms to generate a final OWLiver® score, which “indicates the probability of approximation of the patient’s liver status to a healthy liver / steatosis stage, a non-alcoholic steatohepatitis (NASH *) stage, or NASH and significant-advanced fibrosis (≥ F2) stage” (CIMA Sciences, 2023).

Many combinations of biomarkers, and even combinations of panels, exist. For example, FibroMax combines FibroTest, SteatoTest, NashTest, ActiTest, and AshTest on the same result sheet and provides a more comprehensive estimation of the liver injury. This test measures 10 biomarkers which are as follows: GGT, total bilirubin, alpha-2-macroglobulin, apolipoprotein A1, haptoglobin, alanine aminotransferase (ALT), AST Transaminase, triglycerides, cholesterol, and fasting glucose (BioPredictive, 2019). Fouad et al. (2013) analyzed samples from 44 patients and found that FibroMax results were positively correlated with viral load by quantitative polymerase chain reaction and histopathological findings. Further, body mass index was significantly higher in steatotic patients and was significantly associated with the results on FibroMax (Fouad et al., 2013).

Clinical Utility and Validity
Berends et al. (2007) performed a study assessing FibroTest’s (known as FibroSure in the United States) ability to detect methotrexate (MTX)-induced hepatic fibrosis. Twenty-four psoriasis patients that underwent a liver biopsy were included, and FibroTest identified 83 percent of the patients who had significant fibrosis. The authors suggested FibroTest may be used as part of monitoring MTX-induced fibrosis (Berends et al., 2007).

Kwok et al. (2014) performed a meta-analysis of non-invasive assessments of NASH. The authors identified nine studies for transient elastography (TE) and 11 for cytokeratin‐18 (CK-18). The pooled sensitivities and specificities for TE to diagnose F ≥ 2, F ≥ 3, and F4 disease were 79% and 75%, 85% and 85%, and 92% and 92%, respectively. CK-18 was found to have a pooled sensitivity of 66% and specificity of 82% in diagnosing NASH. The authors concluded that “At present, serum tests and physical measurements such as TE come close as highly accurate non‐invasive tests to exclude advanced fibrosis and cirrhosis in NAFLD patients. CK18 has moderate accuracy in diagnosing NASH, while other biomarkers have not been extensively studied” (Kwok et al., 2014).

Gao et al. (2018) compared aspartate amino transferase–to-platelet ratio index (APRI), the Fibrosis-4 index (FIB-4), transient elastography (TE), and two-dimensional (2D) shear-wave elastography (SWE). A total of 402 patients with chronic hepatitis B were included. 2D-SWE was found to have the highest area under the curve (AUC), with 0.87 compared to APRI’s 0.70, TE’s 0.80, and FIB-4’s 0.73 (Gao et al., 2018).

Dong et al. (2018) compared the performance of several biomarkers (serum hyaluronan (HA), procollagen type III N-terminal peptide (PIIINP), type IV collagen (IVC), laminin (LN), ALT, AST) to transient elastography (FibroScan). Seventy patients with hepatitis B underwent a liver biopsy. Fibrosis was found in 24 patients. The correlation of serum levels with fibrosis stage are as follows: 0.468 (HA), 0.392 (PIIINP), 0.538 (IVC), 0.213 (LN), 0.350 (ALT), 0.375 (AST). The authors found that the combination of all five biomarkers yielded a superior diagnostic performance (area under curve: 0.861) compared to all five alone (Dong et al., 2018).

A pilot study of the FM-fibro index was performed with 400 patients enrolled, and the FM-fibro index, CA‐fibro index, and European Liver Fibrosis panel (ELF) were compared with respect to estimating prognosis of patients with NAFLD. Three separate biomarkers comprise the FM-fibro index: type IV collagen 7S, hyaluronic acid, and vascular cell adhesion molecule‐1. The area under the curve was 0.7093 for the CA-fibro index, 0.7245 for ELF, and 0.7178 (type IV collagen 7S)/0.7095 (hyaluronic acid)/0.7065 (vascular cell adhesion molecule‐1) (Itoh et al., 2018). The sensitivity and specificity of the FM-fibro index for predicting NASH-related fibrosis was 0.5359/0.5210/0.4641 and 0.8333/0.8182/0.8788, respectively (Itoh et al., 2018). The accuracy of the FM-fibro index was not significantly different from that of the CA-fibro index and the ELF panel.

Patel et al. (2018) performed a retrospective study focusing on fibrosis scoring systems to identify NAFLD. A total of 329 patients (296 NAFLD, 33 controls) were included. The following indices were studied: “NAFLD fibrosis score (NFS), fibrosis-4 calculator (FIB-4), aspartate aminotransferase-to-alanine aminotransferase ratio (AST/ALT ratio), AST-to-platelet ratio index (APRI), and body mass index, AST/ALT ratio, and diabetes (BARD) score by age groups” (Patel et al., 2018). NFS and FIB-4 were found to best predict advanced fibrosis with areas under curve of 0.71 – 0.76 and 0.62 – 0.80 respectively. However, the authors concluded that “While NFS and FIB-4 scores exhibit good diagnostic accuracy, FIB-4 is optimal in identifying NAFLD advanced fibrosis in the VHA. Easily implemented as a point-of-care clinical test, FIB-4 can be useful in directing patients that are most likely to have advanced fibrosis to GI/hepatology consultation and follow-up” (Patel et al., 2018).

Kim et al. (2017) evaluated the “association between plasma miR-122 [microRNA-122] and treatment outcomes following transarterial chemoembolization (TACE) in hepatocellular carcinoma patients.” A total of 177 patients were included, and miR-122 levels were measured; the researchers found that 112 patients exhibited TACE refractoriness. Multivariate analyses showed that tumor number (hazard ratio [HR], 2.51) and tumor size (HR, 2.65) can independently predict overall TACE refractoriness. High miR-122 expression (> 100) was associated with early TACE refractoriness (within 1 year; HR, 2.77; 95% CI,) together with tumor number (HR, 22.73) and tumor size (HR, 4.90). Univariate analyses showed that high miR-122 expression tends to be associated with poor liver transplantation-free survival (HR, 1.42). However, this was statistically insignificant in multivariate analysis. The authors concluded that “High expression levels of plasma miR‐122 are associated with early TACE refractoriness in HCC patients treated with TACE” (Kim et al., 2017).

Suehiro et al. (2018) performed a study analyzing “the importance of serum exosomal miRNA expression levels in hepatocellular carcinoma (HCC) patients that underwent transarterial chemoembolization (TACE).” Seventy-five patients underwent TACE. Exosomal miR-122 expression levels significantly decreased after TACE. The expression levels of exosomal miR-122 before TACE were shown to correlate significantly with AST (r = 0.31) and ALT (r = 0.33) levels. According to the median relative expression of miR-122 after TACE/before TACE (miR-122 ratio) in liver cirrhosis patients (n = 57), the patients with a higher miR-122 ratio had significantly longer disease-specific survival compared with that of the patients with the lower miR-122 ratio. A lower exosomal miR-122 ratio (HR 2.720) was associated with the disease-specific survival. The authors concluded that “the exosomal miR‑122 level alterations may represent a predictive biomarker in HCC patients with liver cirrhosis treated with TACE” (Suehiro et al., 2018).

Kar et al. (2019) analyzed the performance of biomarkers implicated in hepatic inflammation. The authors enrolled 52 patients with NAFLD/NASH and evaluated the following biomarkers: IL-6, CRP, TNFα, MCP-1, MIP-1β, eotaxin, and VCAM-1. Serum IL-6 was found to be increased in patients with advanced fibrosis (2.71 pg/mL in fibrosis stages 3 and 4 compared to 1.26 pg/mL in stages 1 – 2 and 1.39 pg/mL in stage 0), but there were no other significant differences in CRP, TNFα, MCP-1, MIP-1β. VCAM-1 was noted to have increased by 55% over the mild fibrosis group and 40% over the no fibrosis group. VCAM-1 was also observed to have an area under curve of 0.87. The authors suggested that the “addition of biomarkers such as IL-6 and VCAM-1 to panels may yield increased sensitivity and specificity for staging of NASH” (Kar et al., 2019).

Srivastava et al. (2019) performed a cost-benefit analysis of non-invasive fibrosis tests (NILTS) for nonalcoholic fatty liver disease (NAFLD). The authors compared the current standard of care, FIB-4, and the Enhanced Liver Fibrosis (ELF) panel. The simulations consisted of 10000 NAFLD patients. Standard care (SC) was compared to the following four scenarios: “FIB-4 for all patients followed by ELF test for patients with indeterminate FIB-4 results; FIB-4 followed by fibroscan for indeterminate FIB-4; ELF alone; and fibroscan alone.” The authors identified the following observations: “Introduction of NILT increased detection of advanced fibrosis over one year by 114, 118, 129 and 137% compared to SC in scenarios 2, 3, 4 and 5 respectively with reduction in unnecessary referrals by 85, 78, 71 and 42% respectively. Total budget spend [sic] was reduced by 25.2, 22.7, 15.1 and 4.0% in Scenarios 2, 3, 4 and 5 compared to £670 K at baseline.” The authors suggested that the “use of NILT in primary care can increase early detection of advanced liver fibrosis and reduce unnecessary referral of patients with mild disease and is cost efficient” (Srivastava et al., 2019).

Weis et al. (2019) evaluated miRNA expression’s ability to distinguish between HCC and cirrhosis. Sixty patients with chronic hepatitis C (CHC) were divided into three groups; 20 with fibrosis stages 0 – 2, 20 with cirrhosis, and 20 with cirrhosis and HCC. A total of 372 miRNA sequences were measured. The authors found that a theoretical panel consisting of miRNA-122-5p, miRNA-486-5p, and miRNA-142-3p distinguished HCC from cirrhosis (area under the curve [AUC] = 0.94; sensitivity = 80%, specificity = 95%) outperforming alpha-fetoprotein (AFP) (AUC = 0.64). Another theoretical panel of miRNA-122-5p and miRNA-409-3p distinguished cirrhosis from mild disease (AUC = 0.80; sensitivity = 85%, specificity = 70%).

The authors concluded that “MicroRNAs have great potential as diagnostic biomarkers in CHC, particularly in HCC where they outperform the only currently-used biomarker, AFP” (Weis et al., 2019).

Both Parikh et al. (2017) and Kaswala et al. (2016) performed studies evaluating the diagnostic accuracy of non-invasive markers for liver conditions. Parikh et al. (2017) focused on chronic hepatitis B virus (HBV) infections while Kaswala et al. (2016) studied nonalcoholic fatty liver. Tables detailing their summarized findings are listed below:

 

 

Diagnostic accuracy of most commonly used non-invasive fibrosis (≥ F2) tests in chronic HBV infection from (Parikh et al., 2017)

 

Test

Cut-off

AUROC

Sensitivity (%)

Specificity (%)

 

Indirect markers

 

   FIB-4 index (high cutoff)

3.25

N/A

16.2

73.6

 

   FIB-4 index (low cutoff)

1.45 – 1.62

0.78

65

77

 

   APRI (low cutoff)

0.5

0.79

84

41

 

   APRI (high cutoff)

1.5

 

49

84

 

   Forns index (low cutoff)

3.11

0.68

91.4

31.5

 

   Forns index (high cutoff)

5.11

N/A

42.5

75

 

 

 

 

 

 

 

Direct markers

       

 

   Hyaluronic acid

113 – 203

0.73

63 – 80

78 – 94

 

   Hepascore

0.32

0.75

74

69

 

   Fibrotest

0.38

0.77

65

78

 

   Fibrometer

0.47

0.84

73

80

 

   ELF

8.75

0.8

NA

NA

 

Diagnostic accuracy of most commonly used noninvasive fibrosis tests in nonalcoholic fatty liver (NAFL) from (Kaswala et al., 2016)

Test

Cut-off

AUROC

Sensitivity (%)

Specificity (%)

AST/ALT ratio

1

0.83

21

90

AST to platelet ratio index (low cutoff)

0.45

0.67 – 0.94

30

93

AST to platelet ratio index (high cutoff)

1.5

     

BAAT score

2

0.84

71

80

BARD

2

0.8

86.8

32.5

ELF test

8.5 – 11.35

0.82 – 0.90

80

90

FibroMeter (low cutoff)

F3: 0.61

0.90 – 0.94

81

84

FibroMeter (high cutoff)

0.71

     

FibroTest (low cutoff)

0.3

0.81 – 0.92

15 – 77

77 – 90

FibroTest (high cutoff)

0.7

     

FIB-4 (low cutoff)

1.3 – 1.92

0.88

26 – 74

71 – 98

FIB-4 (high cutoff)

3.25

     

Hepascore

0.37

0.81

75.5

84.1

 

0.7

0.9

87

89

NAFLD (low cutoff)

−1.45

0.81

51

96

NAFLD (high cutoff)

0.67

     

AST- aspartate aminotransferase; APRI- AST to platelet ratio; BAAT- body mass index (BMI), age, alanine aminotransferase (ALT), triglycerides; BARD- BMI, AST/ALT ratio, diabetes; ELF- Enhanced Liver Fibrosis panel; FIB-4- Fibrosis-4 index; NAFLD — Nonalcoholic fatty liver disease

Bril et al. (2019) assessed the performance of the FibroTest, along with other tests which measure steatosis, necrosis, and inflammation (the SteatoTest, ActiTest, NashTest), in a cohort of patients with type 2 diabetes. A total of 220 diabetic patients participated in this study. Plasma samples from each participant were used for the FibroTest. The researchers note that “Regarding the FibroTest score, its performance to identify patients with moderate or advanced fibrosis was 0.67” (Bril et al., 2019). The authors concluded that “Non-invasive panels for the diagnosis of steatosis, NASH and/or fibrosis, which were developed and validated in non-diabetic cohorts, underperformed when applied to a large cohort of patients with T2DM [type 2 diabetes mellitus]” (Bril et al., 2019)

In a metanalysis, seven studies reported the accuracy of FibroTest™ in nonalcoholic fatty liver disease (NAFLD) patients. The mean AUC was 0.77, mean sensitivity was 0.72, and mean specificity was 0.69. Due to poor AUC, sensitivity, and specificity values, FibroTest™ did not meet the minimally acceptable performance level in detecting significant, advanced, or any fibrosis. However, diagnostic accuracy of FibroTest™ was more promising in detecting cirrhosis, with an AUC of 0.92. The author states that in primary care settings which have a low disease prevalence, FibroTest™ can have a high negative predictive value, based on sensitivities between 0.90 and 0.98, demonstrating its ability to rule out advanced fibrosis in NAFLD patients. However, the test does have low specificity, leading to a considerable number of false positive results, which can lead to invasive and expensive follow-up tests. Overall, "this analysis showed that by optimizing sensitivity to values above 0.90, the test could result in high NPVs (> 90%) in settings with low prevalence of disease, such as primary and secondary care settings, but with relatively low PPVs (11% – 61%)" (Vali et al., 2021).

American Academy of Family Physicians (AAFP)
The 2019 AAFP guideline lists viral hepatitis, alcoholic liver disease, and nonalcoholic steatohepatitis as the most common causes of cirrhosis. They state that “common serum and ultrasound-based screening tests to assess fibrosis include the aspartate transaminase to platelet ratio index score, Fibrosis 4 score, FibroTest/FibroSure, nonalcoholic fatty liver fibrosis score, standard ultrasonography, and transient elastography. Generally noninvasive tests are most useful in identifying patients with no to minimal fibrosis or advanced fibrosis. Chronic liver disease management includes directed counseling, laboratory testing, and ultrasound monitoring” (AAFP, 2019).

In regards to the monitoring of patients post-diagnosis and staging, “For patients with cirrhosis, a basic metabolic panel, liver function tests, complete blood count, and PT/INR should be completed every six months to recalculate Child-Pugh and Model for End-Stage Liver Disease scores” (AAFP, 2019).

American Association for the Study of Liver Diseases (AASLD)
The 2015 AASLD and Infectious Diseases Society of America (IDSA) recommendations for testing, managing, and treating adults infected with hepatitis C virus stated that “Recently, noninvasive tests to stage the degree of fibrosis in patients with chronic HCV infection include models incorporating indirect serum biomarkers (routine tests such as aspartate transaminase, alanine transaminase [ALT], and platelet count), direct serum biomarkers (components of the extracellular matrix produced by activated hepatic stellate cells), and vibration‐controlled transient liver elastography. No single method is recognized to have high accuracy alone, and the results of each test must be interpreted carefully.” The guidelines further stated that “although liver biopsy is the diagnostic standard, sampling error and observer variability limit test performance, particularly when inadequate sampling occurs. In addition, the test is invasive and minor complications are common, limiting patient and practitioner acceptance. Serious complications such as bleeding, although rare, are well recognized” (AASLD-IDSA, 2015).

The 2018 AASLD and Infectious Diseases Society of America (IDSA) recommendations for HCV testing stated that “evaluation for advanced fibrosis using liver biopsy, imaging, and/or noninvasive markers is recommended for all persons with HCV infection, to facilitate an appropriate decision regarding HCV treatment strategy and to determine the need for initiating additional measures for the management of cirrhosis (e.g., hepatocellular carcinoma screening). Rating: Class I, Level A” (AASLD-IDSA, 2019).

The 2018 AASLD update (Terrault et al., 2018) on prevention, diagnosis, and treatment of chronic hepatitis B states that:

For monitoring patients with a chronic HBV infection, who are not currently on treatment, “Alternative methods to assess fibrosis are elastography (preferred) and liver fibrosis biomarkers (e.g., FIB‐4 or FibroTest). If these noninvasive tests indicate significant fibrosis (≥ F2), treatment is recommended.”

The 2018 AASLD practice guidelines (Chalasani et al., 2017) on the diagnosis and management of nonalcoholic fatty liver disease recommend:

  • “In patients with NAFLD, metabolic syndrome predicts the presence of steatohepatitis, and its presence can be used to target patients for a liver biopsy.”
  • “NFS or FIB-4 index are clinically useful tools for identifying NAFLD patients with higher likelihood of having bridging fibrosis (stage 3) or cirrhosis (stage 4).”
  • “Vibration controlled transient elastography or magnetic resonance elastography are clinically useful tools for identifying advanced fibrosis in patients with NAFLD.“

The AASLD does not mention miRNA for assessment in liver disease.

A 2019 update from the AASLD and IDSA states that “Noninvasive tests using serum biomarkers or imaging allow for accurate diagnosis of cirrhosis in most individuals” and frequently used noninvasive methods to estimate liver disease severity include “serum fibrosis marker panels” (AASLD-IDSA, 2019). Further, regarding recommendations for counseling persons with an active HCV infection, the guideline recommend that “Evaluation for advanced fibrosis using noninvasive markers or liver biopsy, if required, is recommended for all persons with HCV infection to facilitate an appropriate decision regarding HCV treatment strategy, and to determine the need for initiating additional measures for cirrhosis management (e.g., hepatocellular carcinoma screening)” (AASLD-IDSA, 2019).

In a 2021 update, AASLD discussed changes in liver biochemistry during normal pregnancy. AASLD states that an “elevation in aminotransferases, bilirubin, or bile acids in pregnancy is abnormal and requires investigation. Evaluation in pregnant patients must include a thorough history (including travel, environmental, and drug exposures), physical examination, and focused serologic testing. Hepatic ultrasonography (US) is the favored initial imaging modality. Diagnosis can usually be determined without liver biopsy” (Sarkar et al., 2021).

American Gastroenterological Association (AGA)
The 2017 guidelines (Lim et al., 2017) on the Role of Elastography in the Evaluation of Liver Fibrosis state that:

  • “In patients with chronic hepatitis C, the AGA recommends vibration controlled transient elastography, if available, rather than other nonproprietary, noninvasive serum tests (APRI, FIB-4) to detect cirrhosis.”
  • “In patients with chronic hepatitis B, the AGA suggests vibration controlled transient elastography (VCTE) rather than other nonproprietary noninvasive serum tests (ie, APRI and FIB-4) to detect cirrhosis.”
  • “The AGA makes no recommendation regarding the role of VCTE in the diagnosis of cirrhosis in adults with NAFLD.”

World Health Organization (WHO)
In March 2015, the WHO released Guidelines for the Prevention, Care and Treatment of Persons with Chronic Hepatitis B Infection. In the section titled “Non-invasive Assessment of Liver Disease Stage at Baseline and during Follow up,” the following is noted: aspartate aminotransferase (AST)-to-platelet ratio index (APRI) is recommended as the preferred non-invasive test (NIT) to assess for the presence of cirrhosis (APRI score > 2 in adults) in resource-limited settings. Transient elastography (e.g., FibroScan) or FibroTest may be the preferred NITs in settings where they are available and cost is not a major constraint (WHO, 2015).

In 2018, the WHO also published guidelines for management of patients with Hepatitis C. In it, they suggest “that aminotransferase/platelet ratio index (APRI) or FIB-4 be used for the assessment of hepatic fibrosis rather than other noninvasive tests that require more resources such as elastography or FibroTest.” However, they do note that “FibroScan, which is more accurate than APRI and FIB-4, may be preferable in settings where the equipment is available and the cost of the test is not a barrier to testing.”

The WHO does not mention miRNA as a tool for assessment of hepatitis (WHO, 2018).

United States Preventive Services Task Force (USPSTF)
The USPSTF published their final recommendation statement on Hepatitis C screening in adolescents and adults in 2020. THE USPSTF recommends “screening for hepatitis C virus (HCV) in adults aged 18 to 79” (grade B recommendation) (USPSTF, 2020).

National Institute for Health and Care Excellence (NICE)
NICE has released guidelines regarding chronic liver conditions. They note that the enhanced liver fibrosis test (ELF) may be considered in patients with NAFLD to test for advanced liver fibrosis. The ELF test should be offered to adults every three years and to children and young people every two years. (NICE, 2016).

European Association for the Study of the Liver (EASL), European Association for the Study of Diabetes (EASD) and European Association for the Study of Obesity
These joint guidelines include recommendations for fibrosis, mentioning ELF, FibroTest, NFS, and FIB-4. Their recommendations include the following:

  • “Biomarkers and scores of fibrosis, as well as transient elastography, are acceptable non-invasive procedures for the identification of cases at low risk of advanced fibrosis/cirrhosis (A21,5). The combination of biomarkers/ scores and transient elastography might confer additional diagnostic accuracy and might save a number of diagnostic liver biopsies (B22,5).”
  • “Monitoring of fibrosis progression in clinical practice may rely on a combination of biomarkers/scores and transient elastography, although this strategy requires validation (C23,5).”
  • “The identification of advanced fibrosis or cirrhosis by serum biomarkers/scores and/or elastography is less accurate and needs to be confirmed by liver biopsy, according to the clinical context (B22,5).”
  • The guidelines observe that due to noninvasive tests’ high negative predictive values, they “may be confidently used for first-line risk stratification to exclude severe disease.” Still, they state that “There is no consensus on thresholds or strategies for use in clinical practice when trying to avoid liver biopsy. Some data suggest that the combination of elastography and serum markers performs better than either method alone. Importantly, longitudinal data correlating changes in histological severity and in non-invasive measurements are urgently needed.”
  • For nonalcoholic steatohepatitis (NASH), the guidelines state that “to date, non-invasive tests are not validated for the diagnosis of NASH” and addresses CK-18 as a proposed biomarker.
  • For monitoring of NAFLD, the guidelines state that “Monitoring should include routine biochemistry, assessment of comorbidities and non-invasive monitoring of fibrosis” (EASL et al., 2016).

1 Grade A Evidence Quality — High: Further research is very unlikely to change our confidence in the estimate of effect
2 Grade B Evidence Quality — Moderate: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
3 Grade C Evidence Quality — Low or very low quality: Further research is very likely to have an important impact on our confidence in the estimate of effect and may change the estimate effect. Any estimate of effect is uncertain.
4 Grade 1 Recommendation — Strong: Factors influencing the strength of the recommendation included the quality of the evidence, presumed patient-important outcomes, and cost.
5 Grade 2 Recommendation — Weak: Variability in preferences and values, or more uncertainty. Recommendation is made with less certainty, higher cost or resource consumption.

The EASL also released guidelines on management of Hepatitis C. In it, they recommend that “Fibrosis stage must be assessed by non-invasive methods initially, with liver biopsy reserved for cases where there is uncertainty or potential additional aetiologies (A11,4)” (grading scale same as the 2016 guideline

above). Non-invasive methods include FibroScan, ARFI, Aixplorer, FibroTest, APRI, and FIB-4 (EASL, 2018).

Guidelines for Hepatitis B were also published. In it, EASL remarks that “the diagnostic accuracy of all non-invasive methods is better at excluding than confirming advanced fibrosis or cirrhosis.” Non-invasive methods include assessment of serum biomarkers of liver fibrosis (EASL, 2017).

The EASL also published guidelines titled “Non-invasive tests for evaluation of liver disease severity and prognosis.” In it, they state the following (grading scale same as the 2016 guideline above):

  • “Serum biomarkers can be used in clinical practice due to their high applicability (> 95%) and good interlaboratory reproducibility. However, they should be preferably obtained in fasting patients (particularly those including hyaluronic acid) and following the manufacturer’s recommendations for the patented tests (A11,4).”
  • “Serum biomarkers of fibrosis are well validated in patients with chronic viral hepatitis (with more evidence for HCV than for HBV and HIV/HCV coinfection). They are less well validated in NAFLD and not validated in other chronic liver diseases (A11,4).”
  • “Their performances are better for detecting cirrhosis than significant fibrosis (A11,4).”
  • “FibroTest®, APRI and NAFLD fibrosis score are the most widely used and validated patented and nonpatented tests (A11,4).”
  • “Among the different available strategies, algorithms combining TE and serum biomarkers appear to be the most attractive and validated one (A21,5).”
  • “HCV patients who were diagnosed with cirrhosis based on non-invasive diagnosis should undergo screening for HCC and PH and do not need confirmatory liver biopsy (A11,4).”
  • “Non-invasive assessment including serum biomarkers or TE can be used as first line procedure for the identification of patients at low risk of severe fibrosis/cirrhosis (A11,4).”
  • “The identification of significant fibrosis is less accurate with non-invasive tests as compared to liver biopsy and may necessitate, according to the clinical context, histological confirmation (A11,4).”
  • “Follow-up assessment by either serum biomarkers or TE for progression of liver fibrosis should be performed among NAFLD patients at a 3 year interval (B12,4)” (EASL & ALEH, 2015).

1 Grade A Evidence Quality — High: Further research is very unlikely to change our confidence in the estimate of effect
2 Grade B Evidence Quality — Moderate: Further research is likely to have an important impact on our confidence in the estimate of effect and may change the estimate.
3 Grade 1 Recommendation — Strong: Factors influencing the strength of the recommendation included the quality of the evidence, presumed patient-important outcomes, and cost.
Grade 2 Recommendation — Weak: Variability in preferences and values, or more uncertainty. Recommendation is made with less certainty, higher cost or resource consumption.

EASL released guidelines on noninvasive tests for evaluation of liver disease severity and prognosis (EASL, 2020). The following recommendations were made (grading scale same as the 2016 guideline above):

  • “Serum biomarkers can be used in clinical practice due to their high applicability (> 95%) and good interlaboratory reproducibility. However, they should be preferably obtained in fasting patients (particularly those including hyaluronic acid) and following the manufacturer’s recommendations for the patented tests (A11,4).”
  • “TE and serum biomarkers have equivalent performance for detecting significant fibrosis in patients with untreated viral hepatitis (A11,4).”
  • “In patients with viral hepatitis C, when TE and serum biomarkers results are in accordance, the diagnostic accuracy is increased for detecting significant fibrosis but not for cirrhosis. In cases of unexplained discordance, a liver biopsy should be performed if the results would change the patient management (A11,4).”

“All HCV patients should be screened to exclude cirrhosis by TE if available. Serum biomarkers can be used in the absence of TE (A11,4)”(EASL, 2020).

References:

  1. AAFP. (2019). Cirrhosis: Diagnosis and Management. American Family Physician. https://www.aafp.org/pubs/afp/issues/2019/1215/p759.html#staging-fibrosis-and-diagnosing-cirrhosis
  2. AASLD-IDSA. (2015). Hepatitis C guidance: AASLD-IDSA recommendations for testing, managing, and treating adults infected with hepatitis C virus. Hepatology, 62(3), 932-954. https://doi.org/10.1002/hep.27950 AASLD-IDSA. (2019). HCV Testing and Linkage to Care. https://www.hcvguidelines.org/evaluate/testing-and-linkage
  3. Abdel-Al, A., El-Ahwany, E., Zoheiry, M., Hassan, M., Ouf, A., Abu-Taleb, H., Abdel Rahim, A., El-Talkawy, M. D., & Zada, S. (2018). miRNA-221 and miRNA-222 are promising biomarkers for progression of liver fibrosis in HCV Egyptian patients. Virus Res, 253, 135-139. https://doi.org/10.1016/j.virusres.2018.06.007
  4. Berends, M. A., Snoek, J., de Jong, E. M., Van Krieken, J. H., de Knegt, R. J., van Oijen, M. G., van de Kerkhof, P. C., & Drenth, J. P. (2007). Biochemical and biophysical assessment of MTX-induced liver
  5. fibrosis in psoriasis patients: Fibrotest predicts the presence and Fibroscan predicts the absence of significant liver fibrosis. Liver Int, 27(5), 639-645. https://doi.org/10.1111/j.1478-3231.2007.01489.x BioPredictive. (2019). FibroMax. https://www.biopredictive.com/products/fibromax/
  6. Bracht, T., Molleken, C., Ahrens, M., Poschmann, G., Schlosser, A., Eisenacher, M., Stuhler, K., Meyer, H. E., Schmiegel, W. H., Holmskov, U., Sorensen, G. L., & Sitek, B. (2016). Evaluation of the biomarker candidate MFAP4 for non-invasive assessment of hepatic fibrosis in hepatitis C patients. J Transl Med, 14(1), 201. https://doi.org/10.1186/s12967-016-0952-3
  7. Bril, F., McPhaul, M. J., Caulfield, M. P., Castille, J. M., Poynard, T., Soldevila-Pico, C., Clark, V. C., Firpi-Morell, R. J., Lai, J., & Cusi, K. (2019). Performance of the SteatoTest, ActiTest, NashTest and FibroTest in a multiethnic cohort of patients with type 2 diabetes mellitus. J Investig Med, 67(2), 303-311. https://doi.org/10.1136/jim- 2018-000864
  8. Chalasani, N., Younossi, Z., Lavine, J. E., Charlton, M., Cusi, K., Rinella, M., Harrison, S. A., Brunt, E. M., & Sanyal, A. J. (2017). The diagnosis and management of nonalcoholic fatty liver disease: Practice guidance from the American Association for the Study of Liver Diseases. Hepatology, 67(1), 328-357. https://doi.org/10.1002/hep.29367
  9. Chin, J. L., Pavlides, M., Moolla, A., & Ryan, J. D. (2016). Non-invasive Markers of Liver Fibrosis: Adjuncts or Alternatives to Liver Biopsy? Front Pharmacol, 7, 159. https://doi.org/10.3389/fphar.2016.00159 CIMA Sciences. (2023). OWLiver: Test for Fatty Liver Disease. https://cimasciences.com/owliver/
  10. Curry, M., & Afdhal, N. (2022). Noninvasive assessment of hepatic fibrosis: Overview of serologic and radiographic tests - UpToDate. In K. Robson (Ed.), UptoDate. https://www.uptodate.com/contents/noninvasive-assessment-of-hepatic-fibrosis-overview-of-serologic-tests-and-imaging-examinations
  11. Cusi, K., Chang, Z., Harrison, S., Lomonaco, R., Bril, F., Orsak, B., Ortiz-Lopez, C., Hecht, J., Feldstein, A. E., Webb, A., Louden, C., Goros, M., & Tio, F. (2014). Limited value of plasma cytokeratin-18 as a biomarker for NASH and fibrosis in patients with non-alcoholic fatty liver disease. J Hepatol, 60(1), 167-174. https://doi.org/10.1016/j.jhep.2013.07.042
  12. Dong, H., Xu, C., Zhou, W., Liao, Y., Cao, J., Li, Z., & Hu, B. (2018). The combination of 5 serum markers compared to FibroScan to predict significant liver fibrosis in patients with chronic hepatitis B virus. Clin Chim Acta, 483, 145-150. https://doi.org/10.1016/j.cca.2018.04.036
  13. EASL. (2017). EASL 2017 Clinical Practice Guidelines on the management of hepatitis B virus infection. https://easl.eu/wp-content/uploads/2018/10/HepB-English-report.pdf EASL. (2018). Treatment of Hepatitis C https://easl.eu/wp-content/uploads/2018/10/HepC-English-report.pdf
  14. EASL. (2020). EASL Clinical Practice Guidelines on non-invasive tests for evaluation of liver disease severity and prognosis – 2020 update. https://www.echosens.com/wp-content/uploads/2021/07/EASL-CPG-NITs-2021_Supplementary-1.pdf
  15. EASL, & ALEH. (2015). EASL-ALEH Clinical Practice Guidelines: Non-invasive tests for evaluation of liver disease severity and prognosis. J Hepatol, 63(1), 237-264. https://doi.org/10.1016/j.jhep.2015.04.006
  16. EASL, EASD, & EASO. (2016). EASL-EASD-EASO Clinical Practice Guidelines for the management of non-alcoholic fatty liver disease. J Hepatol, 64(6), 1388-1402. https://doi.org/10.1016/j.jhep.2015.11.004 Fibronsotics. (2020). LIVERFAst. https://www.fibronostics.com/liverfast/
  17. Fouad, A., Sabry, D., Ahmed, R., Kamal, M., Allah, S. A., Marzouk, S., Amin, M., Abd El Aziz, R., El Badri, A., Khattab, H., & Helmy, D. (2013). Comparative diagnostic study of biomarkers using FibroMax™ and pathology for prediction of liver steatosis in patients with chronic hepatitis C virus infection: an Egyptian study. In Int J Gen Med (Vol. 6, pp. 127-134). https://doi.org/10.2147/ijgm.s36433
  18. Friedman, S. L. (2022). Pathogenesis of hepatic fibrosis. https://www.uptodate.com/contents/pathogenesis-of-hepatic-fibrosis
  19. Gao, Y., Zheng, J., Liang, P., Tong, M., Wang, J., Wu, C., He, X., Liu, C., Zhang, S., Huang, L., Jiang, T., Cheng, C., Meng, F., Mu, X., Lu, Y., Li, Y., Ai, H., Qiao, X., Xie, X. Y., . . . Zheng, R. (2018). Liver Fibrosis with Two-dimensional US Shear-Wave Elastography in Participants with Chronic Hepatitis B: A Prospective Multicenter Study. Radiology, 172479. https://doi.org/10.1148/radiol.2018172479
  20. Huang, H., Wu, T., Mao, J., Fang, Y., Zhang, J., Wu, L., Zheng, S., Lin, B., & Pan, H. (2015). CHI3L1 Is a Liver-Enriched, Noninvasive Biomarker That Can Be Used to Stage and Diagnose Substantial Hepatic Fibrosis. Omics, 19(6), 339-345. https://doi.org/10.1089/omi.2015.0037
  21. Itoh, Y., Seko, Y., Shima, T., Nakajima, T., Mizuno, K., Kawamura, Y., Akuta, N., Ito, K., Kawanaka, M., Hiramatsu, A., Sakamoto, M., Harada, K., Goto, Y., Nakayama, T., Kumada, H., & Okanoue, T. (2018). The accuracy of noninvasive scoring systems for diagnosing nonalcoholic steatohepatitis-related fibrosis: multi-center validation study. Hepatol Res. https://doi.org/10.1111/hepr.13226
  22. Kar, S., Paglialunga, S., Jaycox, S. H., Islam, R., & Paredes, A. H. (2019). Assay validation and clinical performance of chronic inflammatory and chemokine biomarkers of NASH fibrosis. PLoS One, 14(7), e0217263. https://doi.org/10.1371/journal.pone.0217263
  23. Kaswala, D. H., Lai, M., & Afdhal, N. H. (2016). Fibrosis Assessment in Nonalcoholic Fatty Liver Disease (NAFLD) in 2016. Dig Dis Sci, 61(5), 1356-1364. https://doi.org/10.1007/s10620-016-4079-4
  24. Kim, S. S., Nam, J. S., Cho, H. J., Won, J. H., Kim, J. W., Ji, J. H., Yang, M. J., Park, J. H., Noh, C. K., Shin, S. J., Lee, K. M., Cho, S. W., & Cheong, J. Y. (2017). Plasma micoRNA-122 as a predictive marker for treatment response following transarterial chemoembolization in patients with hepatocellular carcinoma. J Gastroenterol Hepatol, 32(1), 199-207. https://doi.org/10.1111/jgh.13448
  25. Kwok, R., Tse, Y. K., Wong, G. L., Ha, Y., Lee, A. U., Ngu, M. C., Chan, H. L., & Wong, V. W. (2014). Systematic review with meta-analysis: non-invasive assessment of non-alcoholic fatty liver disease--the role of transient elastography and plasma cytokeratin-18 fragments. Aliment Pharmacol Ther, 39(3), 254-269. https://doi.org/10.1111/apt.12569
  26. Lim, J. K., Flamm, S. L., Singh, S., & Falck-Ytter, Y. T. (2017). American Gastroenterological Association Institute Guideline on the Role of Elastography in the Evaluation of Liver Fibrosis. Gastroenterology, 152(6), 1536-1543. https://doi.org/10.1053/j.gastro.2017.03.017
  27. NICE. (2016). Non-alcoholic fatty liver disease (NAFLD): assessment and management. https://www.nice.org.uk/guidance/NG49/chapter/Recommendations#assessment-for-advanced-liver-fibrosis
  28. Parikh, P., Ryan, J. D., & Tsochatzis, E. A. (2017). Fibrosis assessment in patients with chronic hepatitis B virus (HBV) infection. Ann Transl Med, 5(3), 40. https://doi.org/10.21037/atm.2017.01.28
  29. Patel, Y. A., Gifford, E. J., Glass, L. M., Turner, M. J., Han, B., Moylan, C. A., Choi, S., Suzuki, A., Provenzale, D., & Hunt, C. M. (2018). Identifying Nonalcoholic Fatty Liver Disease Advanced Fibrosis in the Veterans Health Administration. Dig Dis Sci. https://doi.org/10.1007/s10620-018-5123-3
  30. Sarkar, M., Brady, C. W., Fleckenstein, J., Forde, K. A., Khungar, V., Molleston, J. P., Afshar, Y., & Terrault, N. A. (2021). Reproductive Health and Liver Disease: Practice Guidance by the American Association for the Study of Liver Diseases. Hepatology, 73(1), 318-365. https://doi.org/10.1002/hep.31559
  31. Srivastava, A., Jong, S., Gola, A., Gailer, R., Morgan, S., Sennett, K., Tanwar, S., Pizzo, E., O'Beirne, J., Tsochatzis, E., Parkes, J., & Rosenberg, W. (2019). Cost-comparison analysis of FIB-4, ELF and fibroscan in community pathways for non-alcoholic fatty liver disease. BMC Gastroenterol, 19(1), 122. https://doi.org/10.1186/s12876-019-1039-4
  32. Suehiro, T., Miyaaki, H., Kanda, Y., Shibata, H., Honda, T., Ozawa, E., Miuma, S., Taura, N., & Nakao, K. (2018). Serum exosomal microRNA-122 and microRNA-21 as predictive biomarkers in transarterial chemoembolization-treated hepatocellular carcinoma patients. Oncol Lett, 16(3), 3267-3273. https://doi.org/10.3892/ol.2018.8991
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Coding Section

Code 

Number

Description

CPT 76981 Other Diagnostic Ultrasound Procedures such as Ultrasound, elastography; parenchyma (er, organ)
  81517 Liver disease, analysis of 3 biomarkers (hyaluronic acid [HA], procollagen III amino terminal peptide [PIIINP], tissue inhibitor of metalloproteinase 1 [TIMP-1]), using immunoassays, utilizing serum, prognostic algorithm reported as a risk score and risk of liver fibrosis and liver-related clinical events within 5 years

 

81596

Infectious disease, chronic hepatitis c virus (HCV) infection, six biochemical assays (ALT, A2-macroglobulin, apolipoprotein A-1, total bilirubin, GGT, and haptoglobin) utilizing serum, prognostic algorithm reported as scores for fibrosis and necroinflammatory activity in liver
Proprietary test: HCV FibroSURE™, FibroTest™
Laboratory/Manufacturer: BioPredictive S.A.S

 

81599

Unlisted multianalyte assay with algorithmic analysis

 

84999

Unlisted chemistry procedure

 

88341

Immunohistochemistry or immunocytochemistry, per specimen; each additional single antibody stain procedure (List separately in addition to code for primary procedure)

 

88342

Immunohistochemistry or immunocytochemistry, per specimen; initial single antibody stain procedure 

 

0002M

Liver disease, ten biochemical assays (ALT, A2-macroglobulin, apolipoprotein A-1, total bilirubin, GGT, haptoglobin, AST, glucose, total cholesterol and triglycerides) utilizing serum, prognostic algorithm reported as quantitative scores for fibrosis, steatosis and alcoholic steatohepatitis (ASH)
Proprietary test: ASH FibroSURE™
Laboratory/Manufacturer: BioPredictive S.A.S

 

0003M

Liver disease, ten biochemical assays (ALT, A2-macroglobulin, apolipoprotein A-1, total bilirubin, GGT, haptoglobin, AST, glucose, total cholesterol and triglycerides) utilizing serum, prognostic algorithm reported as quantitative scores for fibrosis, steatosis and nonalcoholic steatohepatitis (NASH)
Proprietary test: NASH FibroSURE™
Laboratory/Manufacturer: BioPredictive S.A.S

 

0014M (deleted on 01/01/2024)

Liver disease, analysis of 3 biomarkers (hyaluronic acid [HA], procollagen III amino terminal peptide [PIIINP], tissue inhibitor of metalloproteinase 1 [TIMP-1]), using immunoassays, utilizing serum,
prognostic algorithm reported as a risk score and risk of liver fibrosis and liver-related clinical events within 5 years
Proprietary test: Enhanced Liver Fibrosis™ (ELFTM) Test
Lab/Manufacturer: Siemens Healthcare
Diagnostics Inc/Siemens Healthcare Laboratory LLC

 

 0166U

Liver disease, 10 biochemical assays (α2-macroglobulin, haptoglobin, apolipoprotein A1, bilirubin, GGT, ALT, AST, triglycerides, cholesterol, fasting glucose) and biometric and demographic data, utilizing serum, algorithm reported as scores for fibrosis, necroinflammatory activity, and steatosis with a summary interpretation
Proprietary test: LiverFASt™
Lab/Manufacturer: Fibronostics

  0344U Hepatology (nonalcoholic fatty liver disease [NAFLD]), semiquantitative evaluation of 28 lipid markers by liquid chromatography with tandem mass spectrometry (LC-MS/MS), serum, reported as at-risk for nonalcoholic steatohepatitis (NASH) or not NASH
Protietary test: OWLiver®
Lab/Manufacturer: CIMA Sciences, LLC
  0468U (effective 07/01/2024) Hepatology (nonalcoholic steatohepatitis [NASH]), miR-34a 5p, alpha 2-macroglobulin, YKL40, HbA1c, serum and whole blood, algorithm reported as a single score for NASH activity and fibrosis
Protietary test: NASHnextTM (NIS4TM)
Lab/Manufacturer: Labcorp, Labcorp

ICD-10  

B18.1 

Chronic viral hepatitis B without delta-agent 

 

O98.411 

Viral hepatitis complicating pregnancy, first trimester 

 

O98.412 Viral hepatitis complicating pregnancy, second trimester

 

O98.413 

Viral hepatitis complicating pregnancy, third trimester 

 

O98.419 Viral hepatitis complicating pregnancy, unspecified trimester

 

O98.42 

Viral hepatitis complicating childbirth 

 

O98.43 Viral hepatitis complicating the puerperium

Procedure and diagnosis codes on Medical Policy documents are included only as a general reference tool for each policy. They may not be all-inclusive. 

This medical policy was developed through consideration of peer-reviewed medical literature generally recognized by the relevant medical community, U.S. FDA approval status, nationally accepted standards of medical practice and accepted standards of medical practice in this community, Blue Cross Blue Shield Association technology assessment program (TEC) and other nonaffiliated technology evaluation centers, reference to federal regulations, other plan medical policies, and accredited national guidelines.

"Current Procedural Terminology © American Medical Association. All Rights Reserved" 

History from 2024 forward:

06/26/2024 Interim review to add PLA code 0468U to coding section.

01012024  NEW POLICY

Complementary Content
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