What Does the Future Hold for Patients With Nonalcoholic Steatohepatitis: Diagnostic Strategies and Treatment Options in 2021 and Beyond?

Nonalcoholic steatohepatitis (NASH) can progress to cirrhosis and its complications, including hepatocellular carcinoma. Given that the majority of patients with NASH are asymptomatic, developing screening strategies to identify those individuals at risk for progressive NASH remains a highly unmet need. Furthermore, noninvasive tests that accurately predict disease progression as part of the natural history of NASH or regression in response to treatment are urgently needed to decrease the reliance on repeat liver biopsies. To date, there are no US Food and Drug Administration (FDA)-approved medications for NASH that can resolve steatohepatitis and lead to fibrosis regression. The lack of FDA-approved therapy has led to apathy in diagnosis and referral for specialty care. However, several therapeutic agents are rapidly progressing through the different phases of clinical trials with several already in phase 3 programs. In this review, we provide a summary of recent developments in NASH diagnostics and therapeutics that are likely to shape the future management of this underdiagnosed and undertreated disease.

algorithm incorporating Pro‐C3 with age, diabetes, and platelet count

alkaline phosphatase

alanine aminotransferase

aspartate aminotransferase

area under the receiver operating curve

body mass index

controlled attenuated parameter

cytokeratin 18

corrected T1

enhanced liver fibrosis

FibroScan + aspartate aminotransferase

US Food and Drug Administration

fibroblast growth factor

fibroblast growth factor receptor

fibrosis‐4

farnesoid X receptor

glucagon‐like peptide 1

hemoglobin A1c

high‐density lipoprotein

low‐density lipoprotein

metabolic syndrome

resmetirom

magnetic resonance elastography

magnetic resonance imaging

nonalcoholic fatty liver disease

nonalcoholic fatty liver disease activity score

nonalcoholic steatohepatitis

nonalcoholic fatty liver disease fibrosis score

noninvasive test

negative predictive value

obeticholic acid

proton density fat fraction

positive predictive value

randomized control trial

Randomized Global Phase 3 Study to Evaluate the Impact on NASH with Fibrosis of Obeticholic Acid Treatment

sensitivity

specificity

The Liver Meeting Digital Experience

vibration‐controlled transient elastography

Nonalcoholic fatty liver disease (NAFLD) has emerged as the most common chronic liver disease worldwide, with a reported global prevalence as high as 25%.( ) The high prevalence of NAFLD is contemporaneous with epidemics of obesity, type 2 diabetes, unhealthy dietary patterns, and sedentary lifestyle. The spectrum of disease can range from a benign nonprogressive clinical course to a serious state of hepatocellular injury, inflammation, and fibrosis known as nonalcoholic steatohepatitis (NASH), which may then progress to cirrhosis and its complications, including hepatocellular carcinoma (HCC).( , , , )

A recent study prospectively evaluated the prevalence of NASH based on liver biopsy assessment in a large cohort of middle‐aged adults in the United States who were asymptomatic. The cohort consisted of 664 individuals with a mean age of 56 years and mean body mass index (BMI) of 30.48 kg/m2.( ) This study demonstrated that 14% of middle‐aged Americans had evidence of NASH while approximately 6% had evidence of significant fibrosis. NASH has become the leading cause of liver transplantation in women in the United States and the second leading cause in men after alcohol‐associated liver disease.( ) Screening for NAFLD in high‐risk populations and identifying those with NASH and significant liver fibrosis (fibrotic NASH) are the first steps to modify the natural history of the disease, although more data are needed to establish the accuracy and cost effectiveness of different noninvasive tests (NITs) and screening strategies.( , )

Despite its high burden on the health care system, there are no US Food and Drug Administration (FDA)‐approved medications for fibrotic NASH. However, recent data presented in 2020 provide hope for the future. The aim of the current review is to provide an update on recent advances in NASH diagnostics and therapeutics with a focus on data presented at The Liver Meeting Digital Experience (TLMdX) in 2020.

Diagnostic Considerations

Identifying Patients at High Risk in Need for Pharmacologic Treatment

In current clinical practice , a liver biopsy is required to assess the grade of steatosis, lobular inflammation, hepatocyte ballooning, and fibrosis in order to meet diagnostic criteria for NASH.( , ) The initial three components are collectively assessed as the NAFLD activity score (NAS), and a separate stage is assigned for fibrosis.( ) Using NAS and fibrosis staging, which have been applied in the NASH Clinical Research Network, an NAS score of 5‐8 is considered diagnostic for NASH and NAS scores of 3‐4 are considered borderline for NASH, although the gestalt diagnosis of NASH by the pathologist and the presence of ballooning are also required. Among patients with NASH, individuals with NAS ≥ 4 and ≥F2 have been used to distinguish individuals with high‐risk features of NASH.( ) Multiple studies have highlighted that, among the histologic parameters of NASH, fibrosis stage is most closely linked with risk of clinical outcomes.( , , ) Clearly, there are several important limitations of liver biopsy that create barriers in diagnosis and risk stratification of NASH. This includes but is not limited to the invasive nature of the procedure with risk for clinical complications, like bleeding, suboptimal inter‐reader reliability, and concern for sampling error.( , ) Artificial intelligence methods, including machine learning, have been developed to address issues with inter‐reader reliability of NASH biopsies. These methods have shown high concordance with expert pathologist interpretations and may represent a useful mechanism to standardize histologic scoring for NASH in the future.( )

Serologic/Circulating Biomarkers

Circulating biomarkers represent an ideal approach for risk stratification as serologic testing can be done with relative ease, although some testing is proprietary and others are not routinely available in clinical practice. Two of the most commonly used serologic‐based biomarkers for risk stratification in NASH are the fibrosis‐4 (FIB‐4) index and the NAFLD fibrosis score (NFS). Both of these clinical decision aides are offered as mechanisms to help risk stratify patients with NAFLD by American Association for the Study of Liver Diseases guidelines.( ) The NFS is computed based on platelet count, albumin, and aspartate aminotransferase (AST)/alanine aminotransferase (ALT), combined with three clinical parameters (age, BMI, and insulin resistance).( ) The key strength of the NFS is its accurate categorization of likelihood of having advanced fibrosis or cirrhosis (area under the receiver operating curve [AUROC], 0.85; sensitivity [Sn], 90%; specificity [Sp], 60%; negative predictive value [NPV], 88; positive predictive value [PPV], 82%).( ) The NFS has limitations in discriminating between lower stages of fibrosis, and approximately 30% of patients will be categorized as having an “indeterminant” NFS.( , ) FIB‐4 is calculated using platelets, AST, ALT, and age and in a meta‐analysis was shown to identify advanced fibrosis in NAFLD with accuracy similar to NFS.( ) Similar to these two models, the metabolomics advanced steatohepatitis fibrosis (MASEF) score was constructed using lipids, BMI, platelets, AST, and ALT to detect high‐risk NASH. In a cohort of 551 patients with NAFLD with liver biopsies, the MASEF score had an AUROC of 0.91 with Sn 58% and Sp 94%.( )

There are several other circulating biomarkers that have been extensively evaluated for fibrosis risk stratification in NASH. The enhanced liver fibrosis (ELF) panel consists of the following three extracellular matrix turnover proteins: hyaluronic acid, tissue inhibitor of metalloproteinase 1, and N‐terminal procollagen III‐peptide. When used to assess likelihood of advanced fibrosis or cirrhosis, the ELF panel has had excellent performance characteristics, with an AUROC of 0.90, Sn 80%, and Sp 90%.( , ) Pro‐C3 is another marker of collagen synthesis that has been evaluated to predict risk of advanced fibrosis and cirrhosis. When used in isolation, Pro‐C3 had an excellent AUROC of 0.91 with an NPV of 97% and PPV of 56%.( ) Pro‐C3 has been incorporated in combination with other parameters to identify advanced fibrosis in NAFLD and NASH. The FIB‐C3 and ABC3D scores incorporate Pro‐C3 in combination with age, BMI, platelet count, and diabetes to correlate with the severity of steatohepatitis and fibrosis among patients with NAFLD. Both scores yielded high diagnostic accuracy, AUROC of 0.83 and 0.81, Sn 75% and 66%, and Sp 75% and 75% for FIB‐C3 and ABC3D, respectively.( ) A similar algorithm that also incorporates Pro‐C3 with age, diabetes, and platelet count (ADAPT) was shown to accurately identify patients with NAFLD and advanced fibrosis.( ) Cytokeratin 18 (CK‐18) is a major intermediate filament protein in hepatocytes that has been extensively studied as a potential biomarker in NASH, both in isolation and in combination with other serologic markers and clinical variables. A recent study evaluated the utility of CK18 and wisteria floribunda agglutinin‐positive Mac‐2‐binding protein (M2BP) to classify patients with NAFLD according to disease severity. A combination of M2BP and CK18 predicted the presence of fibrotic NASH with an AUROC of 0.88.( )

A blood‐based biomarker panel (NIS4) comprised of microRNA (miR)‐34a‐5p, α2 macroglobulin, YKL‐40, and glycated hemoglobin yielded similar performance characteristics, with an AUROC of 0.80 and an NPV of 77.9% to rule out at‐risk NASH.( ) In evaluating different screening methods to identify patients with at‐risk NASH (NAS ≥ 4 and F ≥ 2), a sequential approach using NIS4 with either FIB‐4 or transient elastography yielded the highest PPV.( ) NIS4 levels have also been shown to help predict risk of fibrosis progression among individuals with NASH.( )

The steatosis‐associated fibrosis estimator (SAFE) score, developed using different machine learning methods, was compared to FIB‐4 and NFS. The SAFE score incorporated age, sex, BMI, diabetes, AST, ALT, alkaline phosphatase (ALP), hematocrit, platelets, gamma‐glutamyl transpeptidase (GGT), albumin, and globulin and outperformed FIB‐4 and NFS to predict >F2 among patients with NAFLD.( ) A second machine learning model constructed using data among adults with diabetes and suspected NAFLD included AST, ALT, platelets, triglycerides, and high‐density lipoprotein (HDL) and yielded an AUROC of 0.77 to distinguish NASH from NAFLD.( ) Machine learning methods have also been used to try and identify individuals with NAFLD at risk for rapid disease progression. A Light Gradient Boosting Model yielded an AUROC of 0.77 to identify fast progressors (6 months to 3 years) from index diagnosis of NAFLD/NASH to cirrhosis or HCC. Fast progressors had higher mean age, ALP, AST, AST/ALT ratio, bilirubin, rate of change of ALP, and anxiety diagnoses. Fast progressors also had lower mean albumin, low‐density lipoprotein (LDL), hematocrit, platelets, and triglycerides.( )

Whole‐transcriptome cell‐free messenger RNA has been used to identify patients with NAFLD with clinically significant fibrosis (F ≥ 2). It was able to identify 50% of patients with at least 90% probability of clinically significant fibrosis.( )

Imaging Biomarkers

Imaging biomarkers have shown great promise to accurately characterize fibrosis in NASH. The primary modalities that have been investigated include vibration‐controlled transient elastography (VCTE), magnetic resonance elastography (MRE) ± proton density fat fraction (PDFF), and multiparametric MR imaging (MRI) (LiverMultiScan). In a prospective head‐to‐head comparison of VCTE, two‐dimension shear wave elastography (SWE), and MRE, MRE had the highest diagnostic accuracy for the detection of stage 4 fibrosis (AUROC, 0.92) and the highest intra/interobserver reproducibility among patients with biopsy‐proven NAFLD.( , , ) For a detailed discussion on imaging tests for NASH and fibrosis, we refer the readers to an excellent recent review on the topic by Ajmera and Loomba.( )

Combining circulating biomarkers with imaging data has been shown to enhance diagnostic accuracy to risk stratify NASH and identify those with NAS ≥ 4 and ≥F2. The FibroScan + AST (FAST) score was developed to predict the presence of NASH with fibrosis by combining the following parameters: liver stiffness measurement by VCTE as a biomarker for fibrosis, controlled attenuated parameter (CAP) as a biomarker for steatosis, and AST as a biomarker of activity.( ) The score was initially developed in a cohort in the United Kingdom and then validated in seven additional international cohorts. Based on the knowledge that MRI‐PDFF is the most accurate method to quantify liver fat and that MRE is the most accurate imaging test to determine baseline fibrosis stage, the MRI and AST (MAST) score was developed to detect patients with NASH with NAS ≥ 4 and F ≥ 2. In the derivation cohort that included 103 patients with biopsy‐proven NAFLD, MAST had an AUROC of 0.93, Sn 85%, and Sp 86%, and in the validation cohort (n = 244), the AUROC was 0.86.( ) A study of 694 patients with biopsy‐proven NASH who underwent multiparametric MRI demonstrated that the combination of corrected T1 (cT1), fat, AST, and glucose yielded excellent diagnostic accuracy to identify patients with high‐risk NASH.( )

Jung and colleagues( ) conducted a prospective assessment in a well‐characterized cohort of patients with biopsy‐proven NAFLD who underwent a liver biopsy as well as a contemporaneous MRE; the aim was to identify patients with stage 2 fibrosis or higher. A combination of MRE ≥ 3.3 kPa plus FIB‐4 ≥ 1.6 (MEFIB) yielded a PPV of 97% in the training cohort. They then validated their findings in a geographically and ethnically distinct cohort residing in Japan with a similarly robust PPV.( ) MEFIB appears to have the highest PPV among all NITs for detection of stage 2 fibrosis or higher in NAFLD. Further head‐to‐head comparative studies are needed to establish hierarchy of these NITs in NAFLD. A summary of NITs that are currently commercially available in the United States, including both serologic and imaging biomarkers, is presented in Table 1.

TABLE 1

Summary of NITs that are currently commercially available in the United States

Biomarker	Variables	Utility	Accuracy	Potential Limitations
Serologic
FIB‐4	Age, AST, ALT, platelets	Predicting advanced fibrosis (F3‐F4)	High NPV	Cutoff should be modified in elderly; less accurate in young adults
NFS	Age, BMI, AST, ALT, platelets, IGT, albumin	Predicting advanced fibrosis (F3‐F4)	High NPV	Less accurate in diabetics and young adults
ELF	HA, TIMP‐1, PIIINP	Predicting advanced fibrosis (F3‐F4)	Higher specificity/PPV than FIB‐4 or NFS	Affected by age and other fibrotic conditions
NIS‐4	miR‐34a‐5p, α2 macroglobulin, YKL‐40, HbA1c	Predicting the presence of fibrotic NASH (NAS ≥ 4 and F ≥ 2)	Low cutoff to maximize NPV and high cutoff to maximize PPV	Needs further external validation
Imaging
VCTE	CAP for steatosis; LSM for fibrosis	Screening for NAFLD; staging fibrosis	High accuracy for predicting advanced fibrosis	Less accurate in severe obesity and those with ALT > 200 U/L
MRI‐PDFF	Liver fat fraction	Quantifying liver fat and assessing response to treatment	High accuracy for quantifying liver fat	Lack of prognostic value in terms of liver‐related outcomes
MRE	Liver fibrosis	Staging fibrosis	High accuracy for predicting baseline fibrosis stage; prognostic value	Less predictive of histologic fibrosis improvement in response to treatment
cT1	Liver fibro‐inflammation	Predicting fibrotic NASH	High accuracy for predicting “at‐risk” NASH; prognostic value	Limited utility for NASH cirrhosis

Abbreviations: HA, hyaluronic acid; IGT, impaired glucose tolerance; LSM, liver stiffness measurement; miR, microRNA; NIS‐4, blood‐based biomarker panel; PIIINP, N‐terminal procollagen III‐peptide; TIMP‐1, tissue inhibitor of metalloproteinase 1.

Monitoring Response to Pharmacologic Agents

Methods to Monitor Response to Therapy

The FDA endpoints for NASH clinical trials have focused on NASH resolution without worsening of fibrosis or fibrosis improvement of at least one fibrosis stage without worsening of steatohepatitis. Both histologic endpoints require a repeat liver biopsy at the end of treatment.( )

Emerging evidence from a series of investigator‐initiated studies done at the University of California at San Diego followed by several large multicenter, randomized, controlled trials have helped establish a well‐validated criteria, defined as ≥30% relative decline in MRI‐PDFF, as recently proposed by Loomba and colleagues.( , , ) MRI‐PDFF response is associated with higher odds of both ≥2‐point improvements in NAS with at least 1‐point improvement in lobular inflammation or ballooning as well as NASH resolution.( ) Further studies are needed to document whether MRI‐PDFF response is associated with improvements in fibrosis.

Given the variability in interpretation of histologic changes in response to treatment by pathologists, machine learning techniques were applied to liver histology assessment using data from the Safety and Efficacy of Selonsertib in Adults with NASH and Bridging (F3) Fibrosis (STELLAR 3) or Cirrhosis (F4) (STELLAR 4) trials of selonsertib and the Study to Evaluate the Safety and Efficacy of Selonsertib, Firsocostat, Cilofexor, and Combinations in Participants With Bridging Fibrosis or Compensated Cirrhosis Due to NASH (ATLAS) trial of selonsertib, firsocostat, and cilofexor. Using these data, researchers developed the Deep Learning Treatment Assessment (DELTA) liver fibrosis score to reflect changes in fibrosis stage from baseline to week 48.( ) DELTA scores correlated with changes in NITs, such as ELF and VCTE, among treatment responders.

Several NITs have been used as surrogate markers to assess response to treatment in NASH clinical trials. Data from the Randomized Global Phase 3 Study to Evaluate the Impact on NASH with Fibrosis of Obeticholic Acid Treatment (REGENERATE; NCT02548351) trial of obeticholic acid (OCA) in NASH was used to evaluate NIT‐based OCA efficacy endpoints among patients treated with OCA 25 mg or placebo. Those in the OCA arm showed statistically significant improvements in AST‐to‐platelet ratio index (APRI), FIB‐4, ALT, FibroSure, and VCTE compared to placebo.( , ) A secondary analysis evaluated changes in FibroMeter, FibroMeter VCTE, and FAST among participants in REGENERATE and demonstrated improvement in these NITs among those in the OCA arm.( ) Treatment with OCA also results in dose‐dependent improvements in cT1 and liver fat content on multiparametric MRI.( )

Using data from 252 patients in the Efficacy and Safety Study of Cenicriviroc for the Treatment of NASH in Adult Participants With Liver Fibrosis (CENTAUR), Pro‐C3 and Pro‐C3 composite score (ADAPT and FIB‐C3) levels significantly decreased among patients with fibrosis improvement. Pro‐C3, ADAPT, FIB‐C3, ELF, APRI, FIB‐4, NFS, and CK‐18 M30 and M65 were all reduced among patients with regression in their NAS.( ) Histologic changes were also significantly correlated with reductions in MRI‐PDFF, ELF, and Pro‐C3 among patients with NASH treated with 36 weeks of resmetirom (MGL‐3196).( )

Data from 339 patients in the Study to Evaluate the Safety, Tolerability, and Efficacy of MSDC‐0602K in Patients With NASH (EMMINENCE) trial of MSDC‐0602K and a meta‐analysis of 17 NASH trials that included 3,717 patients evaluated the correlations between changes in biomarkers and histologic response.( ) This study found that a combination of AST, CK‐18, and hemoglobin A1c (HbA1c) changes best predicted overall liver biopsy changes in response to NASH pharmacotherapy. This composite score could distinguish between patients with and without NASH resolution without worsening of fibrosis with an AUROC of 0.78 and for fibrosis improvement without NASH worsening with an AUROC of 0.75. Patients with NASH treated with NGM282 similarly demonstrated improvements in NITs, including Pro‐C3, ELF and cT1.( )

Therapeutic Agents for NASH

There are no FDA‐approved medications for NASH; however, both vitamin E as an antioxidant and pioglitazone as an insulin sensitizer showed some efficacy against NASH in randomized control trials (RCTs).( , ) The lack of efficacy of vitamin E on liver fibrosis and several adverse events associated with pioglitazone, such as weight gain and edema, have limited the use of these two agents by hepatology providers.

The FDA provided a path forward for conditional approval of NASH drugs if they achieve histologic efficacy endpoints defined by either (a) resolution of NASH without worsening of fibrosis or (b) regression of fibrosis by at least one stage without worsening of NASH.( , , ) Acceptable outcomes for phase 2a trials include improvement in liver steatosis as determined by MRI‐PDFF percentage or fibrosis as determined by imaging or blood biomarkers. However, when assessing a new NASH drug, several aspects need to be taken into consideration in addition to hepatic efficacy endpoints. Given the fact that cardiovascular disease remains the main cause of mortality in patients with noncirrhotic NASH,( ) the effects of any new drug on cardiovascular risk factors, such as the metabolic syndrome (MetS), and its components, such as obesity, diabetes, and dyslipidemia, should be evaluated. Furthermore, adverse events of special interest, such as gastrointestinal side effects or pruritus, may affect how the drug is tolerated and its impact on patients’ quality of life and patient‐reported outcomes. For these reasons, we have created the NASH Drug Score Card to help evaluate the potential impact of new drugs and facilitate comparison between different classes of medications (Fig. 1).

FIG. 1

The NASH Drug Score Card. A useful tool to evaluate the potential impact of new drugs and facilitate comparison between different classes of medications. Abbreviations: AE, adverse event; GI, gastrointestinal; HOMA‐IR, homeostasis model assessment of insulin resistance; TG, triglyceride.

Three drugs are currently in phase 3 RCTs for the treatment of noncirrhotic NASH. OCA is a farnesoid X receptor (FXR), which is a nuclear receptor that regulates bile acid synthesis( ) and lipid/glucose homeostasis and modulates liver fibrosis.( ) OCA was evaluated in the phase 3 REGENERATE trial where patients were randomized to OCA 10 mg or 25 mg daily versus placebo for 18 months. Histologic assessment of patients with NASH and F2‐F3 fibrosis demonstrated significant improvement in fibrosis by one stage in 23% of patients on OCA 25 mg daily compared to 12% of those on placebo (P = 0.0002), although there was no significant effect on NASH resolution. In terms of adverse events, compared to placebo, OCA was associated with higher rates of pruritus, and increases in LDL cholesterol and biliary events, including gallstones and cholecystitis.

Resmetirom is a thyromimetic that targets the thyroid hormone receptor beta, the major receptor expressed in the liver with an established role in regulating hepatic triglyceride and cholesterol metabolism.( , , ) Resmetirom was studied in a phase 2b RCT that included 125 patients treated for 36 weeks. Compared to patients treated with placebo, those treated with resmetirom had significantly higher rates of relative liver fat reduction on MRI‐PDFF at both weeks 12 and 36 and higher rates of NASH resolution at week 36 (6.5% with placebo vs. 27.4% with resmetirom, P = 0.02), although there was no significant effect on fibrosis regression.( ) Importantly, resmetirom was well tolerated and had positive effects on the atherogenic dyslipidemia associated with NAFLD with improvement in triglyceride and LDL cholesterol. This drug is being currently evaluated in two large phase 3 RCTs that will evaluate its efficacy on achieving histologic NASH resolution at 52 weeks of treatment in the Study to Evaluate the Efficacy and Safety of MGL‐3196 (Resmetirom) in Patients With NASH and Fibrosis (MAESTRO‐NASH) (NCT03900429) trial and explore its potential benefits on dyslipidemia and cardiovascular endpoints in the MAESTRO‐NAFLD‐1 (NCT04197479).

Aramchol is a bile acid and a fatty acid (cholic acid–arachidic acid) conjugate that inhibits the stearoyl‐coenzyme A (CoA) desaturase‐1 enzyme leading to down‐regulation of liver steatosis. In the phase 2b Clinical Trial to Evaluate the Efficacy and Safety of Two Aramchol Doses Versus Placebo in Patients With NASH (ARREST RCT) (NCT02279524), 247 patients with NASH were randomized to receive aramchol at 400 mg or 600 mg daily versus placebo for 52 weeks.( ) Aramchol decreased liver fat and improved liver enzymes, and the 600 mg daily dose showed a trend toward higher NASH resolution rates compared to placebo (16.7% and 5%, respectively, P = 0.051). The Clinical Study to Evaluate the Efficacy and Safety of Aramchol in Subjects With NASH (ARMOR) is a phase 3 RCT (NCT04104321) that plans to evaluate the safety and efficacy of aramchol in 2,000 patients with NASH and F2‐F3 fibrosis, with the primary histologic endpoint being NASH resolution/fibrosis improvement at 52 weeks.

Update on NASH Therapeutics From TLMdX

The results of several RCTs that evaluated the safety and efficacy of different NASH drugs were presented at TLMdX. Several therapeutic agents showed promising results in terms of histologic response. Due to space limitation, we will only discuss those agents with histologic data while acknowledging the fact that several other promising agents were effective in improving NITs. We provide an example in Table 2 on how to evaluate these agents using the NASH Drug Score Card. It is important to note that direct comparison cannot be made between these agents because they are in different phases of drug development and lack conclusive phase 3 histologic and long‐term outcomes data. Intriguing proof‐of‐concept data were presented on the potential for combination therapy to increase the efficacy of NASH treatment. On the other hand, some agents failed to show significant histologic improvement in phase 2b and 3 trials.

TABLE 2

Summary of Trial Results of Promising Therapeutic Agents for NASH With Histologic Efficacy Data From TLMdX

Drug (Route of Administration)	Lanifibranor (Oral)	Resmetirom (Oral)	Semaglutide (Injectable)	Efruxifermin (Injectable)	Aldafermin (Injectable)	Pioglitazone (Oral)
Hepatic efficacy endpoints
NASH resolution	Yes	Yes	Yes	Yes	Yes	Yes
Fibrosis improvement	Yes	No	No	Yes	Yes	Yes
MRI‐PDFF	No data		No data			No data
ALT	Yes	Yes	Yes	Yes	Yes	Yes
Effects on MetS
Weight	Weight gain	No	Yes	Yes	Neutral	Weight gain
Dyslipidemia	Yes	Yes	Yes	Yes	Increase in LDL	Yes
Insulin resistance	Yes	No	Yes	Yes	Neutral	Yes
Major AEs	Weight gain; bone loss?	Bone loss?; thyroid effects?	GI AEs; pancreatitis; retinopathy	GI AEs; tremors; bone loss?	GI AEs; malignancies?	Weight gain; bone loss; bladder cancer?

Abbreviations: AE, adverse event; GI, gastrointestinal.

Promising New Therapeutic Agents With Histologic Data

Efruxifermin( )

Efruxifermin is a synthetic fibroblast growth factor 21 (FGF21) analog with a long half‐life and balanced potency on the three FGF receptors (FGFR), FGFR1c, FGFR2c, or FGFR3c. The Phase 2a, Randomized, Double‐Blind, Placebo‐Controlled Study Evaluating the Safety and Efficacy of Efruxifermin in Subjects With NASH (BALANCED; NCT03976401) evaluated three doses of weekly efruxifermin injections (28 mg, 50 mg, or 70 mg) for 16 weeks, with the primary endpoint being liver fat reduction on MRI‐PDFF at week 12 and only patients reducing their liver fat by 30% or more being eligible for repeat liver biopsy at week 16. All efruxifermin dose groups met the primary endpoint, with statistically significant absolute reductions in liver fat of 12%‐14% and relative fat reduction >60%.

In the 16‐week analysis of histologic data in the MRI‐PDFF responders, 48% had fibrosis regression by one stage without worsening of NASH and 28% achieved at least a two‐stage fibrosis improvement. Moreover, 48% of responders achieved NASH resolution with no worsening of fibrosis. In terms of effects on MetS, efruxiferimin was associated with improvements in weight, insulin resistance, and dyslipidemia. Efruxifermin will be evaluated in an innovative adaptive phase 2b/3 pivotal study in patients with biopsy‐confirmed NASH to be initiated in the first half of 2021.

Aldafermin( , )

Aldafermin is a modified FGF19 agonist that regulates bile acid synthesis and lipid homeostasis.( ) Patients with NAFLD exhibit a deficiency in FGF19, making it an attractive therapeutic target. The results of a 24‐week RCT that included 78 patients with paired liver biopsies who were randomized 1:2 to receive daily placebo (n = 25) or aldafermin 1 mg (n = 53) subcutaneously were presented at TLMdX. In terms of efficacy endpoints, NASH resolution with no worsening of fibrosis and fibrosis improvement with no worsening of NASH were achieved in a higher percentage of patients in the aldafermin group compared to placebo (24% vs. 9% and 38% vs. 18%, respectively), although the difference was not statistically significant. Interestingly, significantly higher percentage of patients in the aldafermin arm achieved both NASH resolution and fibrosis improvement (22% vs. 0%, P = 0.015). A rapid and significant decline in ALT, AST, and fibrosis biomarkers was seen with aldafermin treatment.

Lanifibranor( )

Lanifibranor is a pan‐peroxisome proliferator‐activated receptor (PPAR) agonist with well‐balanced efficacy for PPARα, δ, and γ.

In the Phase 2b Study in NASH to Assess IVA337 (NATIVE) (NCT03008070), a double‐blind RCT, 247 patients were randomized to receive once daily lanifibranor at 800 mg or 1,200 mg or placebo for 6 months. The mean age was 54 years, 42% had type 2 diabetes, and 76% had significant fibrosis (F2/F3). Lanifibranor 1,200 mg daily compared to placebo showed impressive efficacy on hepatic outcome, including significant reduction of the steatosis activity fibrosis score (SAF) (49% vs. 27%, P < 0.01), NASH resolution with no worsening of fibrosis (45% vs. 19%, P < 0.001), improvement of fibrosis with no worsening of NASH (42% vs. 24%, P < 0.01), and the combined endpoint of NASH resolution plus fibrosis regression (31% vs. 7%, P < 0.001). In terms of effects on MetS, both doses significantly increased HDL cholesterol and decreased serum triglycerides and lowered HbA1c in diabetics. However, there was a significant weight increase of 2.4 and 2.7 kg in the 800‐mg and 1,200‐mg arms. Lanifibranor was well tolerated with low discontinuation rate due to adverse events (<5%).

Semaglutide( )

Semaglutide is a glucagon‐like peptide 1 receptor agonist (GLP‐1RA) approved for treatment in patients with T2D and has been shown to lead to significant weight reduction in patients with nondiabetic obesity.( , ) At TLMdX, the results of a placebo‐controlled phase 2b RCT (NCT02970942) that included 320 patients with NASH and F1‐F3 fibrosis were presented. Patients were randomized to semaglutide daily injections at 0.1, 0.2, and 0.4 mg or placebo for 72 weeks. In patients with significant fibrosis (F2‐F3, n = 230), the primary endpoint of NASH resolution was achieved by a significantly greater proportion of patients on all doses of semaglutide (58.9% in the 0.4‐mg daily arm compared to 17.2% in the placebo arm, P < 0.0001). Unfortunately, there was no significant fibrosis improvement in the semaglutide arms compared to placebo (P > 0.05 for all). Dose‐dependent improvements in ALT, AST, and biomarkers of fibrosis were seen with semaglutide. As expected, semaglutide use was associated with significant reduction in weight and HbA1C.

Combination Therapy( )

Given the biological heterogeneity of NASH, combining therapies with complementary mechanisms may provide optimal benefit.( ) The ATLAS trial randomized 392 patients with advanced disease (bridging fibrosis in 44% and cirrhosis in 56%) to several combination regimens. This trial demonstrated that the combination of firsocostat (acetyl‐CoA carboxylase [ACC] inhibitor that inhibits de novo lipogenesis) and cilofexor (FXR agonist) was numerically more effective than placebo in improving fibrosis by one stage or more without worsening in NASH (21% vs. 11%, P = 0.17), providing further support to the concept of combination therapy.( )

A phase 2 trial evaluated the safety and efficacy of semaglutide, a GLP‐1RA, alone and in combination with the FXR agonist cilofexor and/or the ACC inhibitor firsocostat in 108 patients with noncirrhotic NASH. There was greater reduction in ALT, liver fat on MRI‐PDFF and CAP, liver stiffness on transient elastography, and the FAST score in the combination arms compared to semaglutide monotherapy, especially with the triple combination regimen (semaglutide + cilofexor + firsocostat). Reductions in body weight, AST, GGT, and ELF were noted in all groups. The most common adverse events were gastrointestinal related to semaglutide, with minimal pruritus/increase in LDL noted in the cilofexor‐containing arms and increase in triglycerides noted in the firsocostat arms. Overall, the results demonstrated that combinations of semaglutide with cilofexor and/or firsocostat were well tolerated and may provide additional benefits versus semaglutide monotherapy.

Failed Therapeutic Agents

Elafibranor( )

Results from an interim analysis of the Phase 3 Study to Evaluate the Efficacy and Safety of Elafibranor Versus Placebo in Patients With Nonalcoholic Steatohepatitis (RESOLVE‐IT; NCT02704403) RCT evaluating once‐daily 120 mg of elafibranor for 72 weeks were presented at TLMdX. The trial did not meet its primary endpoint of NASH resolution without worsening of fibrosis (19.2% with elafibranor compared to 14.7% with placebo) or its secondary endpoint of fibrosis improvement of at least one stage (24.5% with elafibranor compared to 22.4% with placebo). Other key secondary endpoints related to metabolic parameters were not achieved.

Tropifexor( )

Data from the Study of Safety and Efficacy of Tropifexor (LJN452) in Patients With NASH (FLIGHT‐FXR; N CT02855164) phase 2 RCT were presented at the TLMdX. In that trial, 152 patients with NASH and F2‐F3 fibrosis were randomized to receive tropifexor 140 μg, 200 μg, or placebo for 48 weeks. Despite achieving high rates of liver fat reduction by ≥30% on MRI‐PDFF and marked reduction in liver enzymes in the tropifexor arms (55%‐68%), there was no difference in the rates of NASH resolution or fibrosis regression. Pruritus was more common in the tropifexor arms, and there was a modest increase in LDL cholesterol. Combination trials of tropifexor with other agents may provide further clarity on the path for developing tropifexor as a treatment for fibrotic NASH.

Putting This All Together: How Will Patients With NASH Be Managed in the Future?

We foresee a future where patients at high‐risk for NAFLD will be screened and risk stratified based on cost‐effective and accurate NITs. Those with suspected fibrotic NASH will be referred to a subspecialist for consideration of pharmacologic treatment. The choice of the first‐line treatment will depend on disease severity (e.g., patients with F3 will require agents with proven antifibrotic activity), adverse event profile (e.g., patients with extensive coronary artery disease may benefit the most from drugs such as semaglutide while avoiding drugs that may increase cardiovascular risk or worsen dyslipidemia), and patient preference (e.g., some patients may elect not to use drugs that require subcutaneous injection or intravenous infusion if effective oral alternatives are available). Once treatment with the first‐line drugs or regimen starts, assessment for efficacy by NITs should be determined at 12‐18 months with one of the following outcomes:

Adequate response: continue to current drug and continue to monitor for efficacy with NITs on a yearly basis.

Partial response: if the first‐line drug is well tolerated, consider add‐on therapy with another drug that has a complementary mechanism of action.

Futility/lack of response: switch to another drug with a different mechanism of action.

In conclusion, we believe that the management of NAFLD/NASH will have a complete transformation in the next 10 years. More patients will be identified by large‐scale screening strategies in at‐risk populations and triaged noninvasively with accurate tests to the best management strategies that will rely on personalized lifestyle interventions and effective therapeutic agents.