Position statement on the diagnosis and management of non-alcoholic fatty liver disease

Liver biopsy

Liver biopsy (LB), with its limitations and potential complications, is still the gold standard for NASH diagnosis and for assessing fibrosis progression; however, it is not recommended in all patients with NAFLD. Most international guidelines recommend LB for patients with risk factors for advanced fibrosis with NASH, when there is diagnostic uncertainty, or to rule out other causes of liver disorders. Some guidelines suggest LB for patients with NAFLD who are undergoing other unrelated surgical procedures.3,4

The presence of >5% steatosis in hepatocytes is now the accepted minimum criterion for the histological diagnosis of NAFLD, while the minimum histologic criteria for NASH are the presence of steatosis, hepatocellular ballooning, and necroinflammation, typically in zone 3. The presence of fibrosis is not required for a diagnosis of NASH, although it is an indicator of disease progression and is the strongest histologic predictor of prognosis.

Noninvasive methods

Several noninvasive diagnostic tools have been proposed and assessed in NAFLD. These tools generally fall into 2 categories: imaging-based or blood tests. The targets of their use and capabilities are to define one or more of the following: the a) identification and quantification of hepatic steatosis, b) prediction of NASH, and/or c) prediction of advanced fibrosis or cirrhosis. These methods, although in use, have inherent limitations in the diagnosis and assessment of NAFLD. The most important methods are summarized in Table 1.

Serum biomarkers

Several clinical and biochemical markers have been investigated to predict the presence of NASH and differentiate it from simple steatosis (NAFL). These include clinical (age, gender, DM, BMI), biochemical (aminotransferases, bilirubin and ferritin), and metabolic (glycated hemoglobin, insulin and HOMA-IR and lipid) markers. Some of these biomarkers have been independently validated.

The NAFLD fibrosis score (NFS) is one of the most thoroughly validated scores for the diagnosis of fibrosis in NAFLD patients. It is a simple predictive model (which includes age, impaired fasting glucose/DM, BMI, platelets, albumin and AST/ALT ratio). This score has been validated in multiple studies with an estimated area under the receiver operating curve (AUROC) of 0.85 (95% CI 0.81-0.90).21 The NFS has the advantage of simplicity and the ability to provide prognostic information about liver complications and mortality.21 In addition, the NFS has been endorsed by several guidelines and can be calculated online (http://nafldscore.com/). Its application for use is limited by the finding that a significant percentage (20-58%) of patients fall between the 2 proposed cutoff values and will have an indeterminate score. Therefore, the NFS serves best for excluding advanced fibrosis/cirrhosis and could be used as a first line test to identify individuals at low risk for advanced disease.

The FIB-4 score has been validated for the evaluation of fibrosis in patients with NAFLD. In one of the studies using LB as the control comparative arm; the FIB-4 score had the best diagnostic accuracy for advanced fibrosis (AUROC 0.86), and it was better than the aspartate aminotransferase (AST)/alanine aminotransferase (ALT), ratio (AUROC 0.83), NFS score (AUROC 0.81), BARD (AUROC 0.77) and AST to platelet ratio index (AUROC 0.67).22 In a recent systemic review and meta-analysis that assessed several of these noninvasive tests, the NFS and FIB-4 seemed to offer the best diagnostic performance for detecting advanced fibrosis in patient with NAFLD.23

Radiology-based tools

One of the most popular imaging-based tools for estimating fibrosis is transient elastography (TE). Most of its validation studies are on viral hepatitis; however, recently, several studies have assessed the use of TE for fibrosis in NAFLD patients, alone or in combination with other tests. The combination of noninvasive tests and TE improves diagnostic accuracy in NAFLD; pooled sensitivities and specificities of TE to diagnose F ≥2, F ≥3 and F4 disease in NAFLD patients were 79% and 75%, 85% and 85%, and 92% and 92%, respectively,24 Liver stiffness measurements (LSMs) often fail in obese patients, but the success rate might be improved with the use of the XL probe. In a recent USA cohort with NAFLD compared with LB, the median LSMs for patients with and without F3-F4 (advanced) fibrosis were 14.4 kPA (12.1-24.3) and 6.6 kPA (5.3-8.9), respectively. The optimal LSM cutoff for advanced fibrosis was 9.9 kPA (sensitivity 95% and specificity 77%). In addition, 100% of patients with LSM <7.9 kPA did not have advanced fibrosis. The AUROC was 0.93 (95% CI: 0.86-0.96) for the detection of F3-F4 fibrosis. This was superior to the AUROC for NFS 0.77, p=0.0125. A comparison of supersonic shear imaging (SSI), fibroscan, and acoustic radiation force impulse (ARFI) with LB for the diagnosis of different stages of liver fibrosis in NAFLD showed better performance of SSI and fibroscan over ARFI, with even slightly better but similar performance of SSI over fibroscan.26

The controlled attenuation parameter (CAP) provides an assessment of steatosis simultaneously with LSMs. The CAP has been assessed in several studies for the diagnosis and grading of steatosis, with overall good performance. In a recent meta-analysis of 11 studies, the AUROC for the diagnosis of steatosis grades were 0.86, 0.88 and 0.94 for the diagnosis of steatosis stage ≥S1, ≥S2, ≥S3, respectively.27 Several cutoff values for each grade of steatosis have been proposed in different studies.

Magnetic resonance elastography is an excellent tool for the assessment of liver steatosis, and it may perform better than TE. However, TE has the advantage over MRI in terms of easy availability, cost and time taken for the tests. Therefore, TE is an economically attractive alternative to LB and other noninvasive tests, especially for patients with advanced liver fibrosis.28

Initial assessment of suspected NAFLD case

The most common presentation scenario of NAFLD is incidentally discovered high liver enzymes (typically ALT, AST and sometimes ALP) in asymptomatic patients or the detection of steatosis on imaging done for other purposes, typically in patients with risk factors such as MetS. Occasionally, the initial presentation shows features of advanced liver disease or HCC. The most important steps in evaluating patients with suspected NAFLD are confirming the diagnosis, staging liver fibrosis, assessing liver-related risk, and formulating a management plan.

After the initial clinical assessment, blood tests and imaging are usually needed to confirm diagnosis and rule out other competing liver disorders. Table 2 summarizes a proposed approach for the initial assessment and monitoring of NAFLD patients.

Lifestyle interventions

A large body of evidence suggests a strong relationship between an unhealthy lifestyle and risk factors for NAFLD. Lifestyle modifications including weight loss, exercise and dietary changes should be recommended as the primary interventions for all NAFLD patients. Weight loss is the only intervention with established evidence suggesting benefits and safety, with a clear dose-response association regardless of the type of exercise. Furthermore, this intervention helps in managing and minimizing the risk of associated comorbidities, such as MetS and CVD.

Weight loss and increased physical activity are associated with sustained improvement in liver enzymes, histology, serum insulin levels, and quality of life in patients with NAFLD.31 The highest rates of NASH reduction, NASH resolution, and fibrosis regression occurred in patients with weight loss ≥10%.32 The benefit of exercise on liver fat occurred even with minimal or no weight loss.31,33

Dietary recommendations for NAFLD patients should include the restriction of daily caloric intake, (approximately 500-1000 kcal/day less than the daily requirement), avoidance of high-glycemic index foods (such as processed foods and beverages high in added fructose), and adoption of a low-fat diet (especially reducing the consumption of saturated fatty acids).4,34

Pharmacologic therapy

To date, there are no approved medications for NASH. Several targets have been studied for the pharmacologic therapy of NASH, which include anti-inflammatory, anti-apoptotic, and anti-fibrotic factors as well as metabolic regulators and anti-oxidant pathways.

Insulin sensitizers

Thiazolidinediones (TZD) such as pioglitazone may improve biochemical and histological parameters in NASH patients. The PIVENS trial compared pioglitazone, vitamin E and placebo for 2 years in patients without DM. Pioglitazone in this study improved all histological features (except fibrosis) and achieved resolution of NASH more often than placebo.35 Subsequent studies and meta-analyses showed histological benefits in diabetic and nondiabetic NASH patients; however, the data on fibrosis improvement are not consistent.36 Weight gain, bone fractures in women and, rarely, congestive heart failure are concerning potential long-term side effects. Therefore, TZD can be used in DM and non-DM patients with biopsy-proven NASH.

Vitamin E

Vitamin E has been investigated in the treatment of NASH because of its anti-oxidant effect. In the PIVENS study, vitamin E at a dose of 800 IU/D was superior to placebo for the NASH treatment of nondiabetic adult patients; it led to an improvement in liver enzymes in addition to an improvement in steatosis and lobular inflammation but showed no improvement in fibrosis.35 Similar results have been confirmed in several studies. Concerns exist over the long-term use of vitamin E, especially at doses >400 IU/d, regarding increases in all-cause mortality, prostate cancer, and hemorrhagic stroke. Based on current evidence and potential long-term risks, vitamin E can be used in nondiabetic patients with biopsy-proven NASH.

New emerging therapies for NAFLD

Over the last few years, many new drugs targeting different pathways have been investigated for NASH treatment, although few have gone beyond phase 2. We will discuss briefly some results of phase 2 studies for some medications that have shown potential in phase 3 and for which studies are ongoing.

Obeticholic acid (OCA) is a synthetic Farnesoid-X receptor agonist. In a phase 2 FLINT study, noncirrhotic NASH patients who received OCA had improvements in all components of the NAFLD activity score (steatosis, hepatocellular ballooning, and lobular inflammation) and small improvements in fibrosis compared to those who received placebo. However, pruritus occurred in 23% of patients.37

Elafibranor is a dual peroxisome proliferator-activated receptor (PPAR)-a/d agonist. It improves insulin sensitivity, glucose homeostasis, and lipid metabolism and reduces inflammation. A phase 2 trial in NASH patients without cirrhosis showed the resolution of NASH without a worsening of fibrosis and good tolerance.38

Cenicriviroc (CVC) is a dual antagonist of CCR2/CCR5 receptors, which have been shown to play key roles in hepatic inflammation and fibrosis. A phase 2 study showed that 1-year treatment with CVC resulted in a significantly higher improvement in fibrosis without worsening of NASH compared with placebo treatment.39

Selonsertib is a selective inhibitor of ASK1, and it leads to an improvement in inflammation and fibrosis. In a multicenter phase 2 trial, selonsertib-treated patients had higher rates of fibrosis improvement and lower rates of fibrosis progression than patients treated with simtuzumab alone over a 24-week treatment period.40

Liraglutide is a glucagon-like peptide-1 analogue that can reduce weight, hepatic steatosis, liver enzymes, and IR in NAFLD. In a phase 2 LEAN trial, liraglutide led to significantly more histological resolution of NASH compared to placebo.41 However, larger studies with long-term follow up are needed.

Drugs commonly used to treat NASH with no proven efficacy

In clinical practice, some drugs are commonly prescribed in patients with NAFLD or NASH, such as metformin, ursodeoxycholic acid, omega-3 fatty acids and probiotics. These drugs may have evidence for biochemical improvement; however, strong consistent evidence for histological improvement is lacking. Thus, these drugs cannot be recommended, although they may be used to treat NAFLD-associated conditions.3,4

Bariatric surgery

Obese patients with NASH or MetS may benefit from bariatric surgery; however, NAFLD per se is not an indication for bariatric surgery. Bariatric surgery is associated with a significant improvement in histological and biochemical markers of NAFLD and components of MetS. However, the data are inconsistent and possibly biased, including high heterogeneity of results in reported systematic reviews. Several long-term follow up studies and registration databases have shown a significant reduction in mortality including the risk of CVD, DM and cancer for patients who underwent bariatric surgery.42,43 In addition, bariatric surgery has been shown to be cost effective for obese-NASH patients, regardless of fibrosis stage.44

It is worth mentioning that fibrosis may progress in some NASH patients after bariatric surgery. Therefore, comprehensive liver assessment and postoperative follow-up are mandatory, as ALT is not a reliable marker for liver disease or cirrhosis in bariatric surgery patients with or without NAFLD.45 Therefore, to avoid deterioration of liver function and to improve outcomes after surgery, proper preoperative assessment of patients including noninvasive tests and possible biopsy during surgery with close medical follow-up post-surgery should be implemented.

Liver transplantation

Non-alcoholic steatohepatitis may go unrecognized until patients present with decompensated liver disease. Non-alcoholic steatohepatitis is currently the second most common indication for liver transplantation in the USA and SA.1,14 Globally, NASH patients on the waiting list for LT are old and have a high body mass index (BMI), prevalence of type 2 DM, metabolic comorbidities and low glomerular filtration rates. Despite high rates of operative difficulties and postoperative complications, the overall long-term patient and graft survival at 1, 3, and 5 years seems to be similar to those of other indications in most studies, with the main causes of death in patients with NAFLD following LT being sepsis and CV disease.46

Statins and NAFLD

Serious liver injury with statins is rare and unpredictable in individual patients, and routine periodic monitoring of liver enzymes does not appear to be effective in detecting or preventing serious liver injury. Hence, the FDA modified labels for statin use, recommending that liver enzyme tests be performed before starting statin therapy and thereafter, as clinically indicated (not routinely).47

In statin-treated patients, an increase in liver enzymes may be due to different etiologies. A mild to modest increase in liver enzymes (without evidence of significant liver injury, such as a rise in bilirubin or other clinical evidence) is not necessarily a contraindication to either the initiation or continuation of statins, especially if the clinical presentation and subsequent assessment suggests NASH as the reason for the liver enzyme elevation.48

Statins are generally safe to use when indicated in all chronic liver disease, including compensated cirrhosis, autoimmune hepatitis and liver transplant recipients48. A significant body of evidence supports that statins are safe in NAFLD patients, with the main benefit of reducing CVD events, which represent the leading cause of death in this population. Several systematic reviews have shown that statins may improve aminotransferase levels, impede the progression of hepatic fibrosis, reduce portal hypertension, prevent hepatic decompensation in cirrhosis, and reduce all-cause mortality in patients with chronic liver disease.49 International guidelines support the use of statins when clinically indicated (such as for lowering lipids or for the prevention of CVD) in NAFLD patients, including those with mild elevation of transaminases or compensated cirrhosis, but they are not recommended as a therapeutic option for liver disease, as strong evidence is still lacking.3,4,50