Liver Disease

Using ultrasound (US) to evaluate sarcopenic obesity in patients with cirrhosis may offer accuracy on par with computed tomography (CT), according to investigators.

US-based assessment presents a more affordable point-of-care strategy that limits radiation exposure, which enables sequential monitoring, reported lead author Sukhpal Dhariwal, MBBS, MD, of the Postgraduate Institute of Medical Education and Research, Chandigarh, India.

“Preliminary data in patients with liver disease ... suggest that US muscle assessment–derived indices, especially thigh muscle thickness, identify sarcopenia CT-skeletal muscle index (SMI) and also predict hospitalization and mortality,” the investigators wrote in Journal of Clinical Gastroenterology. “However, the applicability of US-based techniques to measure muscle mass in the high-risk group of patients with cirrhosis and sarcopenic obesity has not been evaluated.”

To address this knowledge gap, the investigators performed both US- and CT-based muscle assessments in 52 patients with obesity and evidence of cirrhosis; 40 patients were male and the mean age was 50.9 years. In all, 20 (38.5%) were diagnosed with sarcopenia based on CT-determined SMI scores of less than 39 cm²/m² for women and 50 cm²/m² for men.

US showed that it was similarly capable of categorizing patients. The modality significantly differentiated individuals with or without sarcopenia based on high area under the curve values in four muscle indices: quadriceps muscle thickness (0.98), quadriceps muscle feather index (0.95), forearm muscle thickness (0.85), and forearm feather index (0.80).

Direct comparison of US-based assessment against CT-based SMI revealed positive correlations, with significant r values ranging from 0.40 to 0.58. These correlations were stronger in a male-only subgroup analysis, in which r values ranged from 0.52 to 0.70. R values were not calculated in the female subgroup because of the small sample size (n = 12).

The investigators adjusted indices for height, which may pose bias for overestimating muscle mass. Another limitation is the small sample size.

“US-based assessment of sarcopenia has excellent diagnostic accuracy and correlates highly with cross-sectional imaging-based SMI in cirrhosis patients with sarcopenic obesity,” the investigators concluded. “US may serve as an easy-to-use, point-of-care tool for assessing sarcopenia in sarcopenic obesity with the advantage of repeated sequential assessment.”

According to Jamile Wakim-Fleming, MD, of the Cleveland Clinic, “US-based muscle mass assessment seems to be reliable, reproducible, and simple to perform and should be encouraged along with nutrition assessments in all patients with cirrhosis and obesity.”

In a written comment, Dr. Wakim-Fleming noted the importance of timely monitoring and intervention in this patient population.

“Considering the morbidity and the poor outcomes associated with sarcopenic obesity and its frequency in cirrhosis, it is important to make early diagnosis and institute a management plan to improve muscle mass and function,” she said.

The study was supported the Patient-Centered Outcomes Research Institute, the American Medical Association, and the American Heart Association. The investigators disclosed additional relationships with Pfizer, Bristol Myers Squibb, and Novartis. Dr. Wakim-Fleming reported no relevant conflicts of interest.

Using ultrasound (US) to evaluate sarcopenic obesity in patients with cirrhosis may offer accuracy on par with computed tomography (CT), according to investigators.

US-based assessment presents a more affordable point-of-care strategy that limits radiation exposure, which enables sequential monitoring, reported lead author Sukhpal Dhariwal, MBBS, MD, of the Postgraduate Institute of Medical Education and Research, Chandigarh, India.

“Preliminary data in patients with liver disease ... suggest that US muscle assessment–derived indices, especially thigh muscle thickness, identify sarcopenia CT-skeletal muscle index (SMI) and also predict hospitalization and mortality,” the investigators wrote in Journal of Clinical Gastroenterology. “However, the applicability of US-based techniques to measure muscle mass in the high-risk group of patients with cirrhosis and sarcopenic obesity has not been evaluated.”

To address this knowledge gap, the investigators performed both US- and CT-based muscle assessments in 52 patients with obesity and evidence of cirrhosis; 40 patients were male and the mean age was 50.9 years. In all, 20 (38.5%) were diagnosed with sarcopenia based on CT-determined SMI scores of less than 39 cm²/m² for women and 50 cm²/m² for men.

US showed that it was similarly capable of categorizing patients. The modality significantly differentiated individuals with or without sarcopenia based on high area under the curve values in four muscle indices: quadriceps muscle thickness (0.98), quadriceps muscle feather index (0.95), forearm muscle thickness (0.85), and forearm feather index (0.80).

Direct comparison of US-based assessment against CT-based SMI revealed positive correlations, with significant r values ranging from 0.40 to 0.58. These correlations were stronger in a male-only subgroup analysis, in which r values ranged from 0.52 to 0.70. R values were not calculated in the female subgroup because of the small sample size (n = 12).

The investigators adjusted indices for height, which may pose bias for overestimating muscle mass. Another limitation is the small sample size.

“US-based assessment of sarcopenia has excellent diagnostic accuracy and correlates highly with cross-sectional imaging-based SMI in cirrhosis patients with sarcopenic obesity,” the investigators concluded. “US may serve as an easy-to-use, point-of-care tool for assessing sarcopenia in sarcopenic obesity with the advantage of repeated sequential assessment.”

According to Jamile Wakim-Fleming, MD, of the Cleveland Clinic, “US-based muscle mass assessment seems to be reliable, reproducible, and simple to perform and should be encouraged along with nutrition assessments in all patients with cirrhosis and obesity.”

In a written comment, Dr. Wakim-Fleming noted the importance of timely monitoring and intervention in this patient population.

“Considering the morbidity and the poor outcomes associated with sarcopenic obesity and its frequency in cirrhosis, it is important to make early diagnosis and institute a management plan to improve muscle mass and function,” she said.

The study was supported the Patient-Centered Outcomes Research Institute, the American Medical Association, and the American Heart Association. The investigators disclosed additional relationships with Pfizer, Bristol Myers Squibb, and Novartis. Dr. Wakim-Fleming reported no relevant conflicts of interest.

Using ultrasound (US) to evaluate sarcopenic obesity in patients with cirrhosis may offer accuracy on par with computed tomography (CT), according to investigators.

US-based assessment presents a more affordable point-of-care strategy that limits radiation exposure, which enables sequential monitoring, reported lead author Sukhpal Dhariwal, MBBS, MD, of the Postgraduate Institute of Medical Education and Research, Chandigarh, India.

“Preliminary data in patients with liver disease ... suggest that US muscle assessment–derived indices, especially thigh muscle thickness, identify sarcopenia CT-skeletal muscle index (SMI) and also predict hospitalization and mortality,” the investigators wrote in Journal of Clinical Gastroenterology. “However, the applicability of US-based techniques to measure muscle mass in the high-risk group of patients with cirrhosis and sarcopenic obesity has not been evaluated.”

To address this knowledge gap, the investigators performed both US- and CT-based muscle assessments in 52 patients with obesity and evidence of cirrhosis; 40 patients were male and the mean age was 50.9 years. In all, 20 (38.5%) were diagnosed with sarcopenia based on CT-determined SMI scores of less than 39 cm²/m² for women and 50 cm²/m² for men.

US showed that it was similarly capable of categorizing patients. The modality significantly differentiated individuals with or without sarcopenia based on high area under the curve values in four muscle indices: quadriceps muscle thickness (0.98), quadriceps muscle feather index (0.95), forearm muscle thickness (0.85), and forearm feather index (0.80).

Direct comparison of US-based assessment against CT-based SMI revealed positive correlations, with significant r values ranging from 0.40 to 0.58. These correlations were stronger in a male-only subgroup analysis, in which r values ranged from 0.52 to 0.70. R values were not calculated in the female subgroup because of the small sample size (n = 12).

The investigators adjusted indices for height, which may pose bias for overestimating muscle mass. Another limitation is the small sample size.

“US-based assessment of sarcopenia has excellent diagnostic accuracy and correlates highly with cross-sectional imaging-based SMI in cirrhosis patients with sarcopenic obesity,” the investigators concluded. “US may serve as an easy-to-use, point-of-care tool for assessing sarcopenia in sarcopenic obesity with the advantage of repeated sequential assessment.”

According to Jamile Wakim-Fleming, MD, of the Cleveland Clinic, “US-based muscle mass assessment seems to be reliable, reproducible, and simple to perform and should be encouraged along with nutrition assessments in all patients with cirrhosis and obesity.”

In a written comment, Dr. Wakim-Fleming noted the importance of timely monitoring and intervention in this patient population.

“Considering the morbidity and the poor outcomes associated with sarcopenic obesity and its frequency in cirrhosis, it is important to make early diagnosis and institute a management plan to improve muscle mass and function,” she said.

The study was supported the Patient-Centered Outcomes Research Institute, the American Medical Association, and the American Heart Association. The investigators disclosed additional relationships with Pfizer, Bristol Myers Squibb, and Novartis. Dr. Wakim-Fleming reported no relevant conflicts of interest.

Hepatic protein PP2A-C-alpha may serve as a protective factor against parenteral nutrition–associated hepatic steatosis by improving liver function, according to a recent study published in Cellular and Molecular Gastroenterology and Hepatology.

Parenteral nutrition–associated hepatic steatosis likely involves the down-regulation of hepatic PP2A-C-alpha and consequent increased phosphorylation of Akt2; this in turn alters hepatic lipid metabolism, promotes triglyceride accumulation, and leads to liver injury, wrote the researchers, led by Gulisudumu Maitiabula and Feng Tian of the Research Institute of General Surgery at Jinling Hospital, Nanjing, China, and the Medical School of Nanjing University.

“Our study provides a strong rationale that PP2A-C-alpha may be involved in the pathogenesis of [parenteral nutrition–associated hepatic steatosis],” they wrote. “Further research is merited to establish whether interventions to enhance PP2A function might suppress the development of hepatic steatosis in patients receiving long-term [parenteral nutrition].”

Parenteral nutrition can be a lifesaving therapy for patients with intestinal failure caused by insufficient bowel length or function, the authors noted However, long-term use can lead to potentially fatal complications such as liver disease, but an understanding of the pathological mechanisms behind parenteral nutrition–associated hepatic steatosis limited.

The research team performed comparative proteomic/phosphoproteomic analyses of liver samples from 10 patients with parenteral nutrition–associated hepatic steatosis, as well as 8 cholelithiasis patients as controls, who were admitted to Jinling Hospital between June 2018 and June 2019. The researchers also assessed the effect of PP2A-C-alpha on liver injury from total parenteral nutrition in mice.

The research team found that PP2A-C-alpha was down-regulated in patients and mice with parenteral nutrition–associated hepatic steatosis. In addition, in patients with parenteral nutrition–associated hepatic steatosis, they found enhanced activation of serine/threonine kinase Akt2 and decreased activation of AMPK.

Mice that were given total parenteral nutrition infusion for 14 days developed hepatic steatosis, down-regulation of PP2A-C-alpha, activation of Akt2, and inhibition of AMPK. Hepatocyte-specific deletion of PP2A-C-alpha in mice given parenteral nutrition exacerbated the Akt2 activation, AMPK inhibition, and hepatic steatosis through an effect on fatty acid degradation.

On the other hand, forced expression of PP2A-C-alpha led to reductions in hepatocyte fat deposition and the pathological score for liver steatosis. Overexpression also significantly improved hepatic steatosis, suppressed Akt2, and activated AMPK. In addition, pharmacological activation of Akt2 in mice overexpressing PP2A-C-alpha led to the aggravation of hepatic steatosis.

“Collectively, these observations suggest that [parenteral nutrition] for [more than] 14 days leads to a down-regulation in PP2A-C-alpha expression that activates Akt2-dependent signaling, which would likely lead to hepatic steatosis,” the study authors wrote.

Intervention trials of PP2A-C-alpha in humans have not been performed because PP2A-C-alpha activators or effector analogs were unavailable for clinical use, they wrote. Additional clinical studies are needed to investigate the effects of PP2A-C-alpha intervention on the development of hepatic steatosis in patients receiving long-term parenteral nutrition.

The study was supported by the National Natural Science Foundation of China, the Science Foundation of Outstanding Youth in Jiangsu Province, the National Science and Technology Research Funding for Public Welfare Medical Projects, “The 13th Five-Year Plan” Foundation of Jiangsu Province for Medical Key Talents, and the Natural Science Foundation of Jiangsu Province. The study authors disclosed no conflicts of interest.

Hepatic protein PP2A-C-alpha may serve as a protective factor against parenteral nutrition–associated hepatic steatosis by improving liver function, according to a recent study published in Cellular and Molecular Gastroenterology and Hepatology.

Parenteral nutrition–associated hepatic steatosis likely involves the down-regulation of hepatic PP2A-C-alpha and consequent increased phosphorylation of Akt2; this in turn alters hepatic lipid metabolism, promotes triglyceride accumulation, and leads to liver injury, wrote the researchers, led by Gulisudumu Maitiabula and Feng Tian of the Research Institute of General Surgery at Jinling Hospital, Nanjing, China, and the Medical School of Nanjing University.

“Our study provides a strong rationale that PP2A-C-alpha may be involved in the pathogenesis of [parenteral nutrition–associated hepatic steatosis],” they wrote. “Further research is merited to establish whether interventions to enhance PP2A function might suppress the development of hepatic steatosis in patients receiving long-term [parenteral nutrition].”

Parenteral nutrition can be a lifesaving therapy for patients with intestinal failure caused by insufficient bowel length or function, the authors noted However, long-term use can lead to potentially fatal complications such as liver disease, but an understanding of the pathological mechanisms behind parenteral nutrition–associated hepatic steatosis limited.

The research team performed comparative proteomic/phosphoproteomic analyses of liver samples from 10 patients with parenteral nutrition–associated hepatic steatosis, as well as 8 cholelithiasis patients as controls, who were admitted to Jinling Hospital between June 2018 and June 2019. The researchers also assessed the effect of PP2A-C-alpha on liver injury from total parenteral nutrition in mice.

The research team found that PP2A-C-alpha was down-regulated in patients and mice with parenteral nutrition–associated hepatic steatosis. In addition, in patients with parenteral nutrition–associated hepatic steatosis, they found enhanced activation of serine/threonine kinase Akt2 and decreased activation of AMPK.

Mice that were given total parenteral nutrition infusion for 14 days developed hepatic steatosis, down-regulation of PP2A-C-alpha, activation of Akt2, and inhibition of AMPK. Hepatocyte-specific deletion of PP2A-C-alpha in mice given parenteral nutrition exacerbated the Akt2 activation, AMPK inhibition, and hepatic steatosis through an effect on fatty acid degradation.

On the other hand, forced expression of PP2A-C-alpha led to reductions in hepatocyte fat deposition and the pathological score for liver steatosis. Overexpression also significantly improved hepatic steatosis, suppressed Akt2, and activated AMPK. In addition, pharmacological activation of Akt2 in mice overexpressing PP2A-C-alpha led to the aggravation of hepatic steatosis.

“Collectively, these observations suggest that [parenteral nutrition] for [more than] 14 days leads to a down-regulation in PP2A-C-alpha expression that activates Akt2-dependent signaling, which would likely lead to hepatic steatosis,” the study authors wrote.

Intervention trials of PP2A-C-alpha in humans have not been performed because PP2A-C-alpha activators or effector analogs were unavailable for clinical use, they wrote. Additional clinical studies are needed to investigate the effects of PP2A-C-alpha intervention on the development of hepatic steatosis in patients receiving long-term parenteral nutrition.

The study was supported by the National Natural Science Foundation of China, the Science Foundation of Outstanding Youth in Jiangsu Province, the National Science and Technology Research Funding for Public Welfare Medical Projects, “The 13th Five-Year Plan” Foundation of Jiangsu Province for Medical Key Talents, and the Natural Science Foundation of Jiangsu Province. The study authors disclosed no conflicts of interest.

Hepatic protein PP2A-C-alpha may serve as a protective factor against parenteral nutrition–associated hepatic steatosis by improving liver function, according to a recent study published in Cellular and Molecular Gastroenterology and Hepatology.

Parenteral nutrition–associated hepatic steatosis likely involves the down-regulation of hepatic PP2A-C-alpha and consequent increased phosphorylation of Akt2; this in turn alters hepatic lipid metabolism, promotes triglyceride accumulation, and leads to liver injury, wrote the researchers, led by Gulisudumu Maitiabula and Feng Tian of the Research Institute of General Surgery at Jinling Hospital, Nanjing, China, and the Medical School of Nanjing University.

“Our study provides a strong rationale that PP2A-C-alpha may be involved in the pathogenesis of [parenteral nutrition–associated hepatic steatosis],” they wrote. “Further research is merited to establish whether interventions to enhance PP2A function might suppress the development of hepatic steatosis in patients receiving long-term [parenteral nutrition].”

Parenteral nutrition can be a lifesaving therapy for patients with intestinal failure caused by insufficient bowel length or function, the authors noted However, long-term use can lead to potentially fatal complications such as liver disease, but an understanding of the pathological mechanisms behind parenteral nutrition–associated hepatic steatosis limited.

The research team performed comparative proteomic/phosphoproteomic analyses of liver samples from 10 patients with parenteral nutrition–associated hepatic steatosis, as well as 8 cholelithiasis patients as controls, who were admitted to Jinling Hospital between June 2018 and June 2019. The researchers also assessed the effect of PP2A-C-alpha on liver injury from total parenteral nutrition in mice.

The research team found that PP2A-C-alpha was down-regulated in patients and mice with parenteral nutrition–associated hepatic steatosis. In addition, in patients with parenteral nutrition–associated hepatic steatosis, they found enhanced activation of serine/threonine kinase Akt2 and decreased activation of AMPK.

Mice that were given total parenteral nutrition infusion for 14 days developed hepatic steatosis, down-regulation of PP2A-C-alpha, activation of Akt2, and inhibition of AMPK. Hepatocyte-specific deletion of PP2A-C-alpha in mice given parenteral nutrition exacerbated the Akt2 activation, AMPK inhibition, and hepatic steatosis through an effect on fatty acid degradation.

On the other hand, forced expression of PP2A-C-alpha led to reductions in hepatocyte fat deposition and the pathological score for liver steatosis. Overexpression also significantly improved hepatic steatosis, suppressed Akt2, and activated AMPK. In addition, pharmacological activation of Akt2 in mice overexpressing PP2A-C-alpha led to the aggravation of hepatic steatosis.

“Collectively, these observations suggest that [parenteral nutrition] for [more than] 14 days leads to a down-regulation in PP2A-C-alpha expression that activates Akt2-dependent signaling, which would likely lead to hepatic steatosis,” the study authors wrote.

Intervention trials of PP2A-C-alpha in humans have not been performed because PP2A-C-alpha activators or effector analogs were unavailable for clinical use, they wrote. Additional clinical studies are needed to investigate the effects of PP2A-C-alpha intervention on the development of hepatic steatosis in patients receiving long-term parenteral nutrition.

The study was supported by the National Natural Science Foundation of China, the Science Foundation of Outstanding Youth in Jiangsu Province, the National Science and Technology Research Funding for Public Welfare Medical Projects, “The 13th Five-Year Plan” Foundation of Jiangsu Province for Medical Key Talents, and the Natural Science Foundation of Jiangsu Province. The study authors disclosed no conflicts of interest.

Mortality after implantation of a transjugular intrahepatic portosystemic shunt (TIPS) is increased for patients aged 70 and older with cirrhosis, but creatinine and sodium levels can help with decision-making, according to a study published in Hepatology.

TIPS can improve survival in cirrhotic patients with refractory ascites or portal hypertensive bleeding, and age alone shouldn’t preclude older patients from receiving TIPS, wrote the researchers led by Francesco Vizzutti, MD, of the department of experimental and clinical medicine at the University of Florence in Italy.

“However, the indication for TIPS in older adult patients (70 years and over) is debated, and a specific prediction model developed in this particular setting is lacking,” they wrote.

JFalcetti / iStock / Getty Images

Dr. Vizzutti and colleagues aimed to develop and validate a multivariable model to accurately predict mortality in older adults. They prospectively enrolled 411 patients at four Italian referral centers with de novo TIPS implantation for refractory ascites or secondary prophylaxis of variceal bleeding between October 2020 and March 2021.

All patients underwent TIPS placement using Viatorr-covered stent grafts. All patients had follow-up outpatient appointments every 6 months until the end of the study or when clinically indicated, such as recurrence of portal hypertension complications or TIPS dysfunction.

The research team created a competing risks model to predict liver-related mortality attributable to liver failure, portal hypertensive bleeding, hepatorenal syndrome, or hepatocellular carcinoma, with orthotopic liver transplant and death from extrahepatic causes considered as competing events. In older adults, the only competing event was death from extrahepatic causes because this age group could not receive orthotopic liver transplant.

Alcohol use disorder was the most common etiology at 37%, followed by viral infection at 30%. At the time of TIPS placement, alcohol use disorder was present as a main or concomitant etiology of liver disease in 181 patients, including 36 with active alcohol consumption.

Compared with younger patients, older adults had significantly higher prevalence of viral etiology (at 41%) and lower prevalence of alcohol use disorder (at 18%). In terms of liver function, older adults had significantly less advanced liver disease based on international normalized ratio levels, likely “reflecting a more careful selection by physicians when managing older adults,” the study authors wrote. However, older adults had significantly higher creatinine levels than younger patients, “underlining the importance of the assessment of kidney function when selecting patients for TIPS placement,” the authors wrote.

During a median follow-up time of about 20 months after TIPS placement, 99 of 411 (or 24%) of patients died of liver-related causes, 49 underwent a transplant, and 17 died of extrahepatic causes. Among the 99 older adults, 44 (or 44%) died of liver-related causes, and 7 patients died of extrahepatic causes.

In the overall cohort, the probabilities of liver-related death were 13% after 1 year, 17% after 2 years, and 24% after 3 years. The probabilities were higher in older adults, at 19% after 1 year, 30% after 2 years, and 41% after 3 years.

According to the model, age, alcoholic etiology, creatinine levels, and international normalized ratio levels were independently associated with a higher risk of liver-related death. In older adults, creatinine and sodium levels were the only independent risk factors for death.

Notably, older adult patients with favorable creatinine and sodium levels (1.2 mg/dL and 140 mEq/L, respectively) had survival probabilities of liver-related death at 1, 2, and 3 years from TIPS placement of 14%, 26%, and 34%, respectively, the authors wrote. In contrast, older adults with creatinine levels of 2.5 mg/dL and sodium levels of 130 mEq/L had worse outcomes, with risks of liver-related death of 71%, 92%, and 96%, respectively.

“These results suggest that older adult patients with preserved renal function and normal sodium levels could obtain a survival outcome after TIPS placement similar to younger patients,” they wrote. “Moreover, the occurrence of [hepatic encephalopathy] and/or recurrence of ascites or bleeding was not significantly different comparing the two groups of patients according to age.”

Future research should update the prediction model with larger sample sizes, the study authors wrote.

“The decision for or against TIPS should be made only after carefully weighing the risks and benefits, taking into consideration the available literature,” said Bubu Banini, MD, PhD, an assistant professor of digestive diseases and translational research director of the Metabolic Health and Weight Loss Program at Yale University, New Haven, Conn.

Dr. Banini, who wasn’t involved with the study, said the prediction model could be a useful tool to guide the decision-making process.

“As is usually the case with management of portal hypertension–related complications, a multidisciplinary discussion with evaluation of a multitude of factors, including quality of life, comorbidities, risks, and benefits, should guide decision-making,” she said.

Dr. Banini highlighted the finding that alcohol etiology for cirrhosis was associated with higher mortality compared with viral etiology.

“This is important in the context of unfortunately increasing trends in alcohol consumption in the pre- and peri-COVID era and the increased prevalence of alcohol-associated liver disease, especially in women,” she said.

The study was supported by grants from the University of Florence and the University of Modena and Reggio Emilia. The study authors have received lecture fees from Gore Medical, which creates stent grafts. Dr. Banini reported no relevant disclosures.

Mortality after implantation of a transjugular intrahepatic portosystemic shunt (TIPS) is increased for patients aged 70 and older with cirrhosis, but creatinine and sodium levels can help with decision-making, according to a study published in Hepatology.

TIPS can improve survival in cirrhotic patients with refractory ascites or portal hypertensive bleeding, and age alone shouldn’t preclude older patients from receiving TIPS, wrote the researchers led by Francesco Vizzutti, MD, of the department of experimental and clinical medicine at the University of Florence in Italy.

“However, the indication for TIPS in older adult patients (70 years and over) is debated, and a specific prediction model developed in this particular setting is lacking,” they wrote.

JFalcetti / iStock / Getty Images

Dr. Vizzutti and colleagues aimed to develop and validate a multivariable model to accurately predict mortality in older adults. They prospectively enrolled 411 patients at four Italian referral centers with de novo TIPS implantation for refractory ascites or secondary prophylaxis of variceal bleeding between October 2020 and March 2021.

All patients underwent TIPS placement using Viatorr-covered stent grafts. All patients had follow-up outpatient appointments every 6 months until the end of the study or when clinically indicated, such as recurrence of portal hypertension complications or TIPS dysfunction.

The research team created a competing risks model to predict liver-related mortality attributable to liver failure, portal hypertensive bleeding, hepatorenal syndrome, or hepatocellular carcinoma, with orthotopic liver transplant and death from extrahepatic causes considered as competing events. In older adults, the only competing event was death from extrahepatic causes because this age group could not receive orthotopic liver transplant.

Alcohol use disorder was the most common etiology at 37%, followed by viral infection at 30%. At the time of TIPS placement, alcohol use disorder was present as a main or concomitant etiology of liver disease in 181 patients, including 36 with active alcohol consumption.

Compared with younger patients, older adults had significantly higher prevalence of viral etiology (at 41%) and lower prevalence of alcohol use disorder (at 18%). In terms of liver function, older adults had significantly less advanced liver disease based on international normalized ratio levels, likely “reflecting a more careful selection by physicians when managing older adults,” the study authors wrote. However, older adults had significantly higher creatinine levels than younger patients, “underlining the importance of the assessment of kidney function when selecting patients for TIPS placement,” the authors wrote.

During a median follow-up time of about 20 months after TIPS placement, 99 of 411 (or 24%) of patients died of liver-related causes, 49 underwent a transplant, and 17 died of extrahepatic causes. Among the 99 older adults, 44 (or 44%) died of liver-related causes, and 7 patients died of extrahepatic causes.

In the overall cohort, the probabilities of liver-related death were 13% after 1 year, 17% after 2 years, and 24% after 3 years. The probabilities were higher in older adults, at 19% after 1 year, 30% after 2 years, and 41% after 3 years.

According to the model, age, alcoholic etiology, creatinine levels, and international normalized ratio levels were independently associated with a higher risk of liver-related death. In older adults, creatinine and sodium levels were the only independent risk factors for death.

Notably, older adult patients with favorable creatinine and sodium levels (1.2 mg/dL and 140 mEq/L, respectively) had survival probabilities of liver-related death at 1, 2, and 3 years from TIPS placement of 14%, 26%, and 34%, respectively, the authors wrote. In contrast, older adults with creatinine levels of 2.5 mg/dL and sodium levels of 130 mEq/L had worse outcomes, with risks of liver-related death of 71%, 92%, and 96%, respectively.

“These results suggest that older adult patients with preserved renal function and normal sodium levels could obtain a survival outcome after TIPS placement similar to younger patients,” they wrote. “Moreover, the occurrence of [hepatic encephalopathy] and/or recurrence of ascites or bleeding was not significantly different comparing the two groups of patients according to age.”

Future research should update the prediction model with larger sample sizes, the study authors wrote.

“The decision for or against TIPS should be made only after carefully weighing the risks and benefits, taking into consideration the available literature,” said Bubu Banini, MD, PhD, an assistant professor of digestive diseases and translational research director of the Metabolic Health and Weight Loss Program at Yale University, New Haven, Conn.

Dr. Banini, who wasn’t involved with the study, said the prediction model could be a useful tool to guide the decision-making process.

“As is usually the case with management of portal hypertension–related complications, a multidisciplinary discussion with evaluation of a multitude of factors, including quality of life, comorbidities, risks, and benefits, should guide decision-making,” she said.

Dr. Banini highlighted the finding that alcohol etiology for cirrhosis was associated with higher mortality compared with viral etiology.

“This is important in the context of unfortunately increasing trends in alcohol consumption in the pre- and peri-COVID era and the increased prevalence of alcohol-associated liver disease, especially in women,” she said.

The study was supported by grants from the University of Florence and the University of Modena and Reggio Emilia. The study authors have received lecture fees from Gore Medical, which creates stent grafts. Dr. Banini reported no relevant disclosures.

Mortality after implantation of a transjugular intrahepatic portosystemic shunt (TIPS) is increased for patients aged 70 and older with cirrhosis, but creatinine and sodium levels can help with decision-making, according to a study published in Hepatology.

TIPS can improve survival in cirrhotic patients with refractory ascites or portal hypertensive bleeding, and age alone shouldn’t preclude older patients from receiving TIPS, wrote the researchers led by Francesco Vizzutti, MD, of the department of experimental and clinical medicine at the University of Florence in Italy.

“However, the indication for TIPS in older adult patients (70 years and over) is debated, and a specific prediction model developed in this particular setting is lacking,” they wrote.

JFalcetti / iStock / Getty Images

Dr. Vizzutti and colleagues aimed to develop and validate a multivariable model to accurately predict mortality in older adults. They prospectively enrolled 411 patients at four Italian referral centers with de novo TIPS implantation for refractory ascites or secondary prophylaxis of variceal bleeding between October 2020 and March 2021.

All patients underwent TIPS placement using Viatorr-covered stent grafts. All patients had follow-up outpatient appointments every 6 months until the end of the study or when clinically indicated, such as recurrence of portal hypertension complications or TIPS dysfunction.

The research team created a competing risks model to predict liver-related mortality attributable to liver failure, portal hypertensive bleeding, hepatorenal syndrome, or hepatocellular carcinoma, with orthotopic liver transplant and death from extrahepatic causes considered as competing events. In older adults, the only competing event was death from extrahepatic causes because this age group could not receive orthotopic liver transplant.

Alcohol use disorder was the most common etiology at 37%, followed by viral infection at 30%. At the time of TIPS placement, alcohol use disorder was present as a main or concomitant etiology of liver disease in 181 patients, including 36 with active alcohol consumption.

Compared with younger patients, older adults had significantly higher prevalence of viral etiology (at 41%) and lower prevalence of alcohol use disorder (at 18%). In terms of liver function, older adults had significantly less advanced liver disease based on international normalized ratio levels, likely “reflecting a more careful selection by physicians when managing older adults,” the study authors wrote. However, older adults had significantly higher creatinine levels than younger patients, “underlining the importance of the assessment of kidney function when selecting patients for TIPS placement,” the authors wrote.

During a median follow-up time of about 20 months after TIPS placement, 99 of 411 (or 24%) of patients died of liver-related causes, 49 underwent a transplant, and 17 died of extrahepatic causes. Among the 99 older adults, 44 (or 44%) died of liver-related causes, and 7 patients died of extrahepatic causes.

In the overall cohort, the probabilities of liver-related death were 13% after 1 year, 17% after 2 years, and 24% after 3 years. The probabilities were higher in older adults, at 19% after 1 year, 30% after 2 years, and 41% after 3 years.

According to the model, age, alcoholic etiology, creatinine levels, and international normalized ratio levels were independently associated with a higher risk of liver-related death. In older adults, creatinine and sodium levels were the only independent risk factors for death.

Notably, older adult patients with favorable creatinine and sodium levels (1.2 mg/dL and 140 mEq/L, respectively) had survival probabilities of liver-related death at 1, 2, and 3 years from TIPS placement of 14%, 26%, and 34%, respectively, the authors wrote. In contrast, older adults with creatinine levels of 2.5 mg/dL and sodium levels of 130 mEq/L had worse outcomes, with risks of liver-related death of 71%, 92%, and 96%, respectively.

“These results suggest that older adult patients with preserved renal function and normal sodium levels could obtain a survival outcome after TIPS placement similar to younger patients,” they wrote. “Moreover, the occurrence of [hepatic encephalopathy] and/or recurrence of ascites or bleeding was not significantly different comparing the two groups of patients according to age.”

Future research should update the prediction model with larger sample sizes, the study authors wrote.

“The decision for or against TIPS should be made only after carefully weighing the risks and benefits, taking into consideration the available literature,” said Bubu Banini, MD, PhD, an assistant professor of digestive diseases and translational research director of the Metabolic Health and Weight Loss Program at Yale University, New Haven, Conn.

Dr. Banini, who wasn’t involved with the study, said the prediction model could be a useful tool to guide the decision-making process.

“As is usually the case with management of portal hypertension–related complications, a multidisciplinary discussion with evaluation of a multitude of factors, including quality of life, comorbidities, risks, and benefits, should guide decision-making,” she said.

Dr. Banini highlighted the finding that alcohol etiology for cirrhosis was associated with higher mortality compared with viral etiology.

“This is important in the context of unfortunately increasing trends in alcohol consumption in the pre- and peri-COVID era and the increased prevalence of alcohol-associated liver disease, especially in women,” she said.

The study was supported by grants from the University of Florence and the University of Modena and Reggio Emilia. The study authors have received lecture fees from Gore Medical, which creates stent grafts. Dr. Banini reported no relevant disclosures.

The risk of developing incident heart failure is 1.5-times higher in people with nonalcoholic fatty liver disease (NAFLD) during a median follow-up of 10 years, according to a new meta-analysis.

The risk appears to increase with greater liver disease severity and was independent of age, sex, ethnicity, obesity, and the presence of diabetes, hypertension, and other common cardiovascular risk factors.

“Health care professionals should be aware that the risk of new-onset heart failure is moderately higher in patients with NAFLD,” senior author Giovanni Targher, MD, said in an interview.

“Because of the link between the two conditions, more careful surveillance of these patients will be needed,” said Dr. Targher, who is an associate professor of diabetes and endocrinology at the University of Verona (Italy). “In particular, the results of this meta-analysis highlight the need for a patient-centered, multidisciplinary, and holistic approach to manage both liver disease and cardiovascular risk in patients with NAFLD.”

The study was published online in Gut.
 

Risk calculations

NAFLD has become one of the most common causes of chronic liver disease worldwide (affecting up to about 30% of the world’s adults), and is expected to rise sharply in the next decade, the study authors write. The disease is linked with liver-related conditions, such as nonalcoholic steatohepatitis, cirrhosis, and hepatocellular carcinoma, as well as complications in other organs.

Previous meta-analyses have found an association between NAFLD and a higher risk of heart failure, though the analyses included a relatively small number of studies and a relatively modest sample size, Dr. Targher and colleagues write.

Since then, several new cohort studies have examined the association, which inspired a new meta-analysis.

The research team analyzed 11 observational cohort studies with aggregate data on more than 11 million middle-aged people from different countries, including nearly 3 million with NAFLD and nearly 98,000 cases of incident heart failure over a median follow-up of 10 years.

In the studies, NAFLD was diagnosed by serum liver enzyme levels, serum biomarkers or scores, diagnostic codes, imaging techniques, or liver histology. Four studies were conducted in the United States, three were conducted in South Korea, and four were carried out in Europe, including Finland, Sweden, and the United Kingdom.

Dr. Targher and colleagues found that the presence of NAFLD was associated with a moderately higher risk of new-onset heart failure, with a pooled random-effects hazard ratio of 1.5. The risk was independent of age, sex, ethnicity, adiposity measures, diabetes, hypertension, and other typical cardiovascular risk factors.

The association between NAFLD and heart failure risk was consistent even when the comparison was stratified by study country, follow-up length, modality of heart failure diagnosis, and modality of NAFLD diagnosis.

In addition, sensitivity analyses didn’t change the results, and a funnel plot suggested that publication bias was unlikely.

“Accumulating evidence supports that NAFLD is part of a multisystem disease that adversely affects several extrahepatic organs, including the heart,” Dr. Targher said.

“NAFLD not only promotes accelerated coronary atherosclerosis but also confers a higher risk of myocardial abnormalities (cardiac remodeling and hypertrophy) and certain arrhythmias (mostly atrial fibrillation), which may precede and promote the development of new-onset heart failure over time,” he said.
 

Future research

Dr. Targher and colleagues also found that the risk of incident heart failure appeared to further increase with more advanced liver disease, particularly with higher levels of liver fibrosis, as assessed by noninvasive fibrosis biomarkers or histology. With only two cohort studies that examined the association, the authors judged there was insufficient data available to combine the studies into a meta-analysis.

But the observations are consistent with other recent meta-analyses that reported a significant association between the presence and severity of NAFLD and the risk of developing adverse cardiovascular outcomes, atrial fibrillation, chronic kidney disease, or other non-liver complications.

“It’s reassuring that the observations that have come from single studies hold true when you look at the totality of evidence,” Ambarish Pandey, MD, a cardiologist and assistant professor of internal medicine at the University of Texas Southwestern Medical Center, Dallas, told this news organization.

Dr. Pandey, who wasn’t involved with this study, conducted one of the recent meta-analyses that found a 1.6-times increased risk of heart failure associated with NAFLD, as well as a further increased risk with more advanced liver disease.

Now Dr. Pandey and colleagues are studying the underlying mechanisms for the link between NAFLD and heart failure risk, including cardiac structure and function, biomarkers of injury and stress, and how proportions of liver fat influence risk. Additional studies should investigate whether resolving NAFLD could reduce the risk of heart failure, he said.

“It’s really important to look for patients with NAFLD in primary care and think about cardiovascular disease in our liver patients,” he said. “Early strategies to implement the prevention of heart failure would go a long way in reducing long-term risks for these patients.”

The study authors did not declare a specific grant for this research from any funding agency in the public, commercial, or nonprofit sectors. Dr. Targher and Dr. Pandey report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

The risk of developing incident heart failure is 1.5-times higher in people with nonalcoholic fatty liver disease (NAFLD) during a median follow-up of 10 years, according to a new meta-analysis.

The risk appears to increase with greater liver disease severity and was independent of age, sex, ethnicity, obesity, and the presence of diabetes, hypertension, and other common cardiovascular risk factors.

“Health care professionals should be aware that the risk of new-onset heart failure is moderately higher in patients with NAFLD,” senior author Giovanni Targher, MD, said in an interview.

“Because of the link between the two conditions, more careful surveillance of these patients will be needed,” said Dr. Targher, who is an associate professor of diabetes and endocrinology at the University of Verona (Italy). “In particular, the results of this meta-analysis highlight the need for a patient-centered, multidisciplinary, and holistic approach to manage both liver disease and cardiovascular risk in patients with NAFLD.”

The study was published online in Gut.
 

Risk calculations

NAFLD has become one of the most common causes of chronic liver disease worldwide (affecting up to about 30% of the world’s adults), and is expected to rise sharply in the next decade, the study authors write. The disease is linked with liver-related conditions, such as nonalcoholic steatohepatitis, cirrhosis, and hepatocellular carcinoma, as well as complications in other organs.

Previous meta-analyses have found an association between NAFLD and a higher risk of heart failure, though the analyses included a relatively small number of studies and a relatively modest sample size, Dr. Targher and colleagues write.

Since then, several new cohort studies have examined the association, which inspired a new meta-analysis.

The research team analyzed 11 observational cohort studies with aggregate data on more than 11 million middle-aged people from different countries, including nearly 3 million with NAFLD and nearly 98,000 cases of incident heart failure over a median follow-up of 10 years.

In the studies, NAFLD was diagnosed by serum liver enzyme levels, serum biomarkers or scores, diagnostic codes, imaging techniques, or liver histology. Four studies were conducted in the United States, three were conducted in South Korea, and four were carried out in Europe, including Finland, Sweden, and the United Kingdom.

Dr. Targher and colleagues found that the presence of NAFLD was associated with a moderately higher risk of new-onset heart failure, with a pooled random-effects hazard ratio of 1.5. The risk was independent of age, sex, ethnicity, adiposity measures, diabetes, hypertension, and other typical cardiovascular risk factors.

The association between NAFLD and heart failure risk was consistent even when the comparison was stratified by study country, follow-up length, modality of heart failure diagnosis, and modality of NAFLD diagnosis.

In addition, sensitivity analyses didn’t change the results, and a funnel plot suggested that publication bias was unlikely.

“Accumulating evidence supports that NAFLD is part of a multisystem disease that adversely affects several extrahepatic organs, including the heart,” Dr. Targher said.

“NAFLD not only promotes accelerated coronary atherosclerosis but also confers a higher risk of myocardial abnormalities (cardiac remodeling and hypertrophy) and certain arrhythmias (mostly atrial fibrillation), which may precede and promote the development of new-onset heart failure over time,” he said.
 

Future research

Dr. Targher and colleagues also found that the risk of incident heart failure appeared to further increase with more advanced liver disease, particularly with higher levels of liver fibrosis, as assessed by noninvasive fibrosis biomarkers or histology. With only two cohort studies that examined the association, the authors judged there was insufficient data available to combine the studies into a meta-analysis.

But the observations are consistent with other recent meta-analyses that reported a significant association between the presence and severity of NAFLD and the risk of developing adverse cardiovascular outcomes, atrial fibrillation, chronic kidney disease, or other non-liver complications.

“It’s reassuring that the observations that have come from single studies hold true when you look at the totality of evidence,” Ambarish Pandey, MD, a cardiologist and assistant professor of internal medicine at the University of Texas Southwestern Medical Center, Dallas, told this news organization.

Dr. Pandey, who wasn’t involved with this study, conducted one of the recent meta-analyses that found a 1.6-times increased risk of heart failure associated with NAFLD, as well as a further increased risk with more advanced liver disease.

Now Dr. Pandey and colleagues are studying the underlying mechanisms for the link between NAFLD and heart failure risk, including cardiac structure and function, biomarkers of injury and stress, and how proportions of liver fat influence risk. Additional studies should investigate whether resolving NAFLD could reduce the risk of heart failure, he said.

“It’s really important to look for patients with NAFLD in primary care and think about cardiovascular disease in our liver patients,” he said. “Early strategies to implement the prevention of heart failure would go a long way in reducing long-term risks for these patients.”

The study authors did not declare a specific grant for this research from any funding agency in the public, commercial, or nonprofit sectors. Dr. Targher and Dr. Pandey report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

The risk of developing incident heart failure is 1.5-times higher in people with nonalcoholic fatty liver disease (NAFLD) during a median follow-up of 10 years, according to a new meta-analysis.

The risk appears to increase with greater liver disease severity and was independent of age, sex, ethnicity, obesity, and the presence of diabetes, hypertension, and other common cardiovascular risk factors.

“Health care professionals should be aware that the risk of new-onset heart failure is moderately higher in patients with NAFLD,” senior author Giovanni Targher, MD, said in an interview.

“Because of the link between the two conditions, more careful surveillance of these patients will be needed,” said Dr. Targher, who is an associate professor of diabetes and endocrinology at the University of Verona (Italy). “In particular, the results of this meta-analysis highlight the need for a patient-centered, multidisciplinary, and holistic approach to manage both liver disease and cardiovascular risk in patients with NAFLD.”

The study was published online in Gut.
 

Risk calculations

NAFLD has become one of the most common causes of chronic liver disease worldwide (affecting up to about 30% of the world’s adults), and is expected to rise sharply in the next decade, the study authors write. The disease is linked with liver-related conditions, such as nonalcoholic steatohepatitis, cirrhosis, and hepatocellular carcinoma, as well as complications in other organs.

Previous meta-analyses have found an association between NAFLD and a higher risk of heart failure, though the analyses included a relatively small number of studies and a relatively modest sample size, Dr. Targher and colleagues write.

Since then, several new cohort studies have examined the association, which inspired a new meta-analysis.

The research team analyzed 11 observational cohort studies with aggregate data on more than 11 million middle-aged people from different countries, including nearly 3 million with NAFLD and nearly 98,000 cases of incident heart failure over a median follow-up of 10 years.

In the studies, NAFLD was diagnosed by serum liver enzyme levels, serum biomarkers or scores, diagnostic codes, imaging techniques, or liver histology. Four studies were conducted in the United States, three were conducted in South Korea, and four were carried out in Europe, including Finland, Sweden, and the United Kingdom.

Dr. Targher and colleagues found that the presence of NAFLD was associated with a moderately higher risk of new-onset heart failure, with a pooled random-effects hazard ratio of 1.5. The risk was independent of age, sex, ethnicity, adiposity measures, diabetes, hypertension, and other typical cardiovascular risk factors.

The association between NAFLD and heart failure risk was consistent even when the comparison was stratified by study country, follow-up length, modality of heart failure diagnosis, and modality of NAFLD diagnosis.

In addition, sensitivity analyses didn’t change the results, and a funnel plot suggested that publication bias was unlikely.

“Accumulating evidence supports that NAFLD is part of a multisystem disease that adversely affects several extrahepatic organs, including the heart,” Dr. Targher said.

“NAFLD not only promotes accelerated coronary atherosclerosis but also confers a higher risk of myocardial abnormalities (cardiac remodeling and hypertrophy) and certain arrhythmias (mostly atrial fibrillation), which may precede and promote the development of new-onset heart failure over time,” he said.
 

Future research

Dr. Targher and colleagues also found that the risk of incident heart failure appeared to further increase with more advanced liver disease, particularly with higher levels of liver fibrosis, as assessed by noninvasive fibrosis biomarkers or histology. With only two cohort studies that examined the association, the authors judged there was insufficient data available to combine the studies into a meta-analysis.

But the observations are consistent with other recent meta-analyses that reported a significant association between the presence and severity of NAFLD and the risk of developing adverse cardiovascular outcomes, atrial fibrillation, chronic kidney disease, or other non-liver complications.

“It’s reassuring that the observations that have come from single studies hold true when you look at the totality of evidence,” Ambarish Pandey, MD, a cardiologist and assistant professor of internal medicine at the University of Texas Southwestern Medical Center, Dallas, told this news organization.

Dr. Pandey, who wasn’t involved with this study, conducted one of the recent meta-analyses that found a 1.6-times increased risk of heart failure associated with NAFLD, as well as a further increased risk with more advanced liver disease.

Now Dr. Pandey and colleagues are studying the underlying mechanisms for the link between NAFLD and heart failure risk, including cardiac structure and function, biomarkers of injury and stress, and how proportions of liver fat influence risk. Additional studies should investigate whether resolving NAFLD could reduce the risk of heart failure, he said.

“It’s really important to look for patients with NAFLD in primary care and think about cardiovascular disease in our liver patients,” he said. “Early strategies to implement the prevention of heart failure would go a long way in reducing long-term risks for these patients.”

The study authors did not declare a specific grant for this research from any funding agency in the public, commercial, or nonprofit sectors. Dr. Targher and Dr. Pandey report no relevant financial relationships.

A version of this article first appeared on Medscape.com.

Nonalcoholic fatty liver disease (NAFLD) is defined by the presence of hepatic steatosis detected on either imaging or histology in the absence of secondary causes of fatty liver (e.g., excessive alcohol consumption) or other chronic liver diseases.¹ For practical NAFLD diagnosis purposes, excessive alcohol intake can be defined as an active or recent history of more than 21 standard drinks per week in men and more than¹⁴ standard drinks per week in women. For the sake of terminology, NAFLD is characterized by fatty liver infiltration, affecting at least 5% of hepatocytes, with no evidence of hepatocyte injury, whereas nonalcoholic steatohepatitis (NASH) is defined as the presence of necroinflammation with or without fibrosis in a background of fatty liver.¹

Natural history

NASH and the degree of fibrosis are the two most important determinants of the natural history of NAFLD. NASH can evolve into fibrosis and cirrhosis, whereas advanced fibrosis and cirrhosis (stages 3 or 4 of fibrosis) significantly increase the risk of liver-related decompensation and mortality. NAFLD, per se, has been associated with an increased risk of overall mortality, compared with that of the general population.² The three most common causes of mortality for patients with NAFLD are cardiovascular diseases (CVD), extrahepatic malignancies, and liver-related deaths. Mortality and liver-related events, including hepatic decompensation and hepatocellular carcinoma (HCC), may significantly increase in a dose-dependent manner with increasing fibrosis stages, and stages 3 or 4 of fibrosis may display the highest rates of all-cause mortality and liver-related events.^3,4 It is important to note, however, that almost 15% of HCCs occur in patients with NAFLD who do not have cirrhosis.⁵ The presence of commonly associated comorbidities such as obesity, insulin resistance or diabetes, dyslipidemia, hypothyroidism, polycystic ovary syndrome, and sleep apnea may contribute to an increased risk of NASH and advanced fibrosis and, therefore, an accelerated clinical course of NAFLD.

Nonpharmacological interventions

Lifestyle modification

Lifestyle modification to achieve weight loss remains a first-line intervention in patients with NAFLD. Weight loss achieved either by hypocaloric diet alone or in conjunction with increased physical activity can be beneficial for all patients with NAFLD. The benefits extend not only to those who are overweight and obese but also to those within normal body weight (lean NAFLD).^1,6,7 Weight loss of approximately 3%-5% is necessary to improve hepatic steatosis, but a greater weight loss (7%-10%) is required to improve other histopathological features like necroinflammatory lesions and fibrosis.^8-10 Individuals with higher BMI and/or type 2 diabetes (T2D) will require a larger weight reduction to achieve a similar benefit on NAFLD-related features.^7,8 Weight loss via lifestyle changes can also decrease hepatic venous pressure gradient (HVPG), with greater declines reported among those with more than 10% weight loss.¹¹

Weight loss can be achieved through a variety of modalities, but long-term maintenance of lost weight is much more challenging. A combination of a hypocaloric diet with a caloric deficit of 500-1,000 kcal/d, alongside moderate-intensity exercise and intensive on-site behavioral treatment, will likely increase the possibility of a sustained weight loss over time.^1,12 A growing body of scientific evidence indicates that a healthy diet that includes a reduction of high-glycemic-index foods and refined carbohydrates; increased consumption of monounsaturated fatty acids, omega-3 fatty acids, and fibers; and high intakes of olive oil, nuts, vegetables, fruits, legumes, whole grains, and fish can have beneficial effects on NAFLD and its severity.^13-16 Adherence to these healthy dietary patterns has been associated with a marked reduction in CVD morbidity and mortality and is, thus, a strategic lifestyle recommendation for patients with NAFLD in whom the leading cause of morbidity and death is CVD.^1,3

Exercise alone in adults with NAFLD may reduce hepatic steatosis, but its ability to improve inflammation and fibrosis has not been proven in well-designed RCTs.^17,18 Physical activity and exercise have been shown to curb both the development and the progression of NAFLD, and beneficial effects could be achieved independent of weight loss.^17,19,20 Most importantly, moderate-to-vigorous physical activity is likely associated with lower all-cause and cardiovascular mortality in patients with NAFLD.²¹

Heavy alcohol intake should be avoided by patients with NAFLD or NASH, and those with cirrhotic NASH should avoid any alcohol consumption given the risk of HCC and hepatic decompensation.^1,4,22 Limiting light-to-moderate alcohol intake among patients without cirrhosis is still under debate.¹ People with NAFLD may be advised to drink an equivalent of two to three 8-oz cups of regular brewed coffee daily as it has shown certain antifibrotic effects in NAFLD patients.²³
 

Bariatric surgery

Bariatric surgery is an attractive therapeutic option for eligible obese patients with NAFLD. Bariatric surgery has the potential for inducing great weight loss and, therefore, reverses not only the steatosis, inflammation, and fibrosis among NAFLD individuals but also important comorbid conditions like T2D. A recent systematic review and meta-analysis examining data on the effects of bariatric surgery on histologic features of NAFLD from 32 cohort studies (no RCTs included) showed that bariatric surgery was associated with significant improvements in steatosis (66%), lobular inflammation (50%), ballooning degeneration (76%), and fibrosis (40%), and the benefits were significantly higher in those who underwent Roux-en-Y gastric bypass (RYGB). Of note, worsening of liver histology, including fibrosis, could be seen in up to 12% of patients who underwent bariatric surgery.²⁴ The postsurgical weight regained after RYGB could explain partly the lack of fibrosis improvement or even worsening of fibrosis, although further research is needed to clarify these controversial findings.

RYGB and sleeve gastrectomy (SG) are the most commonly performed bariatric surgeries worldwide. Patients who undergo RYGB achieve higher weight loss when compared with those treated with SG.²⁵ Among all bariatric procedures, RYGB could result in a higher proportion of complete resolution of NAFLD than SG, although evidence is inconclusive on fibrosis improvement rates.^24,26 Most recently, a single-center RCT has compared the effects of RYGB vs. SG on liver fat content and fibrosis in patients with severe obesity and T2D.²⁷ Data showed that both surgical procedures were highly and equally effective in reducing fatty liver content (quantified by magnetic resonance imaging), with an almost complete resolution of the fatty liver at 1 year of both surgical interventions. The beneficial effects of both GB and SG on fibrosis (assessed by enhanced liver test [ELF]) were less evident with no substantial difference between the two groups. Importantly, 69% of participants had an increase in their ELF scores during the study, despite the majority of participants achieving significant reductions in their body weights and better glycemic control at the end of the study. These findings might be considered with caution as several factors, such as the duration of the study (only 1 year) and lack of a liver biopsy to confirm fibrosis changes over time, could be influencing the study results.

Among all NAFLD phenotypes, those with cirrhosis and, most importantly, hepatic decompensation appear to be at increased risk of perioperative mortality and inpatient hospital stays than those without cirrhosis.^28-29 Bariatric surgery is an absolute contraindication in patients with decompensated cirrhosis (Child B and Child C). Among compensated -Child A- cirrhotics, those with portal hypertension are at increased risk of morbidity and perioperative mortality.³⁰ A recent analysis of National Inpatient Sample data suggested that the rates of complications in those with cirrhosis have decreased with time, which could be due to a better selection process and the use of more restrictive bariatric surgery in those with cirrhosis. Low volume centers (defined as less than 50 procedures per year) and nonrestrictive bariatric surgery were associated with a higher mortality rate. These data may suggest that patients with cirrhosis should undergo bariatric surgery only in high-volume centers after a multidisciplinary evaluation.³¹ Bariatric endoscopy is emerging as a new treatment for obesity, but the long-term durability of its effects remains to be determined.

A recent retrospective cohort study, including 1,158 adult patients with biopsy-proven NASH, has investigated the benefits of bariatric surgery on the occurrence of major adverse liver and cardiovascular outcomes in 650 patients who underwent bariatric surgery, compared with 508 patients who received nonsurgical usual care. This study showed that bariatric surgery was associated with 88% lower risk of progression of fatty liver to cirrhosis, liver cancer, or liver-related death, and 70% lower risk of serious CVD events during a follow-up period of 10 years.³² Within 1 year after surgery, 0.6% of patients died from surgical complications. The potential benefits of bariatric surgery in patients with NAFLD must be balanced against surgical risk, especially in eligible obese individuals with established cirrhosis. Data from a retrospective cohort study have shown that bariatric surgery in obese cirrhotic patients does not seem to associate with excessive mortality, compared with noncirrhotic obese patients.³³ More data on immediate complication rates and long-term outcomes in patients with NAFLD by type of bariatric surgery is also required.

NAFLD as a standalone is not an indication for bariatric surgery. However, it could be considered in NAFLD patients who have a BMI of 40 kg/m² or more without coexisting comorbidities or with a BMI of 35 kg/m² or more and one or more severe obesity-related comorbidities, including T2D, hypertension, hyperlipidemia, or obstructive sleep apnea. Bariatric surgery must always be offered in centers with an experienced bariatric surgery program.¹
 

Management of comorbidities

Given the multiple comorbidities associated with NAFLD and the potential to influence its severity, a comprehensive and multidisciplinary approach is needed to ameliorate not only the progression of liver disease but also those complications related to metabolic syndrome, hyperlipidemia, hypertension, diabetes, and other related conditions. Of note, all patients with NAFLD should receive aggressive management of comorbidities regardless of the severity of NAFLD. Ideally, a multidisciplinary team – including a primary care provider, an endocrinologist for patients with T2D, and a gastroenterologist/hepatologist – is needed to successfully manage patients with NAFLD.

It is well recognized that individuals with biopsy-proven NAFLD are at a higher risk of coronary heart disease, stroke, congestive heart failure, and death resulting from CVD when compared with the non-NAFLD population, and excess in CVD morbidity and mortality is evident across all stages of NAFLD and increases with worsening disease severity.³⁴ The strong association between CVD and NAFLD has important clinical implications that may influence the decision to initiate treatment for primary prevention, including lipid-lowering, antihypertensive, or antiplatelet therapies.³⁵ Statins are widely used to reduce LDL cholesterol and have been proven to be safe in NAFLD, including for those with elevated liver enzymes and even in compensated cirrhosis, in several studies conducted during the last 15 years.³⁶ Statins are characterized by anti-inflammatory, anti-oxidative, antifibrotic, and plaque-stabilizing effects, whereby they may improve vascular and hepatic function among patients with NAFLD and reduce cardiovascular risk.³⁷ Statin use for the treatment of NAFLD is still controversial and off-label and is not specifically recommended to treat NASH, but positive results have been shown for reductions in liver enzymes.¹ A recent meta-analysis of 13 studies showed that continued use of statin in cirrhosis was associated with a 46% and 44% risk reduction in hepatic decompensation and mortality, respectively.³⁸

The Food and Drug Administration has approved omega-3 (n-3) fatty acid agents and fibrates for the treatment of very high triglycerides (500 mg/dL or higher); however, no specific indications exist to treat NAFLD.¹ Fenofibrate is related to mild aminotransferase elevations and, in some cases, severe liver injury, so caution must be paid, especially within 2 days of taking the drug.^39-40

NAFLD phenotypes that need liver pharmacotherapy

There are still no FDA-approved drugs or biological treatments for NASH. Pharmacological interventions aiming primarily at improving liver disease should generally be limited to those with biopsy-proven NASH and clinically significant fibrosis (fibrosis stages of 2 or greater).^1,4 For FDA approval, medications used for treating NAFLD with fibrosis need to meet one of the following endpoint criteria: resolution of NASH without worsening of fibrosis, improvement in fibrosis without worsening of NASH, or both. In addition to those criteria, a new medication might improve the metabolic profile and have a tolerable safety profile. Table 1 displays those NAFLD phenotypes that will likely benefit from liver-directed therapy.

Obeticholic acid as an experimental therapy for NASH

A planned month-18 interim analysis of a multicentre, phase III RCT examined the efficacy and safety of obeticholic acid (OCA), a farnesoid X receptor agonist, in patients with NASH and stages 1-3 of fibrosis. The primary endpoint (fibrosis reduction 1 stage or more with no worsening of NASH) was met by 12% of patients in the placebo group, 18% of patients receiving OCA 10 mg (P = .045), and 23% of those receiving OCA 25 mg (P = .0002). An alternative primary endpoint of NASH resolution with no worsening of fibrosis was not met. OCA 25 mg led to the highest rates of pruritus and hyperlipidemia, compared with OCA 10 mg.⁴² These side effects seem to be related to the activation of the farnesoid X receptor.⁴³
 

Currently available but off label medications

Vitamin E, an antioxidant, administered at a daily dose of 800 IU/day improves steatosis, inflammation, and ballooning, but not fibrosis in nondiabetic adults with biopsy-proven NASH.⁴⁴ Vitamin E for 96 weeks was associated with a significantly higher rate of improvement in NASH (43% vs. 19%, P less than .01), compared with placebo.⁴⁴ In the Treatment of Nonalcoholic Fatty Liver Disease in Children trial (TONIC), which examined vitamin E (800 IU/day) or metformin (500 mg twice daily) against placebo in children with biopsy-proven NAFLD, resolution of NASH was significantly greater in children treated with vitamin E than in children treated with placebo (58% vs. 28%, P less than .01). Metformin did not significantly improve the NASH resolution rates, compared with placebo (41% vs. 28%, P = .23). Vitamin E could be recommended for nondiabetic adults or children if lifestyle modifications do not produce the expected results as a result of noncompliance or ineffectiveness. Since continued use of vitamin E has been suggested to be associated with a very small increase in the risk for prostate cancer (an absolute increase of 1.6 per 1,000 person-years of vitamin E use) in men, risks and benefits should be discussed with each patient before starting therapy. A meta-analysis of nine placebo-controlled trials including roughly 119,000 patients reported that vitamin E supplementation increases the risk of hemorrhagic stroke by 20% while reducing ischemic stroke by 10%. It was estimated that vitamin E supplementation would prevent one ischemic stroke per 476 treated patients while inducing one hemorrhagic stroke for every 1,250 patients. It is noteworthy that the combination of vitamin E with anticoagulant and/or antiplatelet therapy was not examined in this trial, so we could not determine how combination therapy might affect the risk of ischemic or hemorrhagic stroke.⁴⁵

Thiazolidinediones drugs have been reported to be effective in improving NAFLD in many human studies. Evidence from RCTs suggests that pioglitazone could significantly improve glucose metabolism, alanine aminotransferase, and liver histology – such as hepatic steatosis, lobular inflammation, and ballooning degeneration – among patients with or without T2D. However, the beneficial effects on improving fibrosis remain to be verified.^1,46 Because of safety concerns, the risk/benefit balance of using pioglitazone to treat NASH should be discussed with each patient.^47-48 Pioglitazone has been associated with long-term risk of bladder cancer,⁴⁹ congestive heart failure,⁵⁰ and bone fractures.⁵¹ Data from the Pioglitazone, Vitamin E, or Placebo for Nonalcoholic Steatohepatitis (PIVENS) trial showed that pioglitazone was significantly associated with weight gain but with no other serious adverse events. However, this study was not powered to test any safety-related hypotheses.⁴⁴

Glucagon-like peptide 1 analogs have been reported to induce weight loss and reduce insulin resistance, which may lead to improvements in NAFLD. Phase II RCTs of glucagon-like peptide 1 receptor agonists (liraglutide and semaglutide) for the treatment of biopsy-proven NASH showed significant improvements in serum liver enzymes, steatosis, and inflammation, as well as NASH resolution without worsening liver fibrosis, although no direct benefit was observed in reversing fibrosis.^52-53 One of these studies explores the efficacy and safety of different doses of daily subcutaneous semaglutide vs. placebo on the rates of resolution of NASH with no worsening of fibrosis. The highest dose (0.4 mg) showed the greatest difference (59% vs. 17%, P less than .01), compared with the placebo arm. However, there was no difference in improvement in fibrosis stage between the two groups (43% in the 0.4-mg group vs. 33% in the placebo group, ^P = .48).⁵³ Gastrointestinal adverse events were common in the semaglutide arm.

“Spontaneous” NASH resolution and fibrosis improvement are commonly seen in participants assigned to placebo arms in clinical trials. A recent meta-analysis of 43 RCTs including 2649 placebo-treated patients showed a pooled estimate of NASH resolution without worsening of fibrosis and 1 stage reduction or more in fibrosis of 12% and 19%, respectively. Relevant factors involved in “spontaneous” NASH improvement are unknown but could be related to changes in BMI resulting from lifestyle changes, race and ethnicity, age, and, likely, NAFLD-related genetic variations, although more data is needed to better understand the histologic response in placebo-treated patients.⁵⁴

Semaglutide injections (2.4 mg once weekly) or (2.0 mg once weekly) have been recently approved by the FDA for chronic weight management in adults with obesity or overweight with at least one weight-related condition or glucose control of T2D, respectively. Of note, the semaglutide dose used in the NASH trial is not currently available for the treatment of patients who are overweight/obese or have T2D, but the beneficial effects on body weight reductions and glucose control are similar overall to the effects seen with currently available doses for management of obesity or diabetes. One may consider using semaglutide in patients who are overweight/obese or have T2D with NASH, but in the senior author’s experience, it has been quite challenging to receive the payer’s approval, as its use is not specifically approved to treat liver disease.¹
 

How to follow patients with NAFLD in the clinic

Once a diagnosis of NAFLD is made, the use of noninvasive testing may aid to identify which patients are at high risk of fibrosis. Easy to use clinical tools, such as the NAFLD Fibrosis Score and the Fib-4 index, and liver stiffness measurements using vibration-controlled transient elastography (FibroScan) or magnetic resonance elastography (MRE) are clinically useful noninvasive tools for identifying patients with NAFLD who have a higher likelihood of progressing to advanced fibrosis.^1,55 The use of either NAFLD Fibrosis Score (less than -1.455) or Fib-4 index (less than 1.30) low cutoffs may be particularly useful to rule out advanced fibrosis. People with a NAFLD Fibrosis Score (greater than –1.455) or Fib-4 index (greater than 1.30) should undergo liver stiffness measurement (LSM) via FibroScan. Those with an LSM of 8 kPa or higher should be referred to specialized care, where a decision to perform a liver biopsy and initiate monitoring and therapy will be taken. MRE is the most accurate noninvasive method for the estimation of liver fibrosis. When MRE is available, it can be a diagnostic alternative to accurately rule in and rule out patients with advanced fibrosis. This technique can be preferred in clinical trials, but it is rarely used in clinical practice because it is expensive and not easily available. Reassessment by noninvasive scores at 1-3 years’ follow-up will be considered for those with an LSM less than 8 kPa. Patients with NASH cirrhosis should be screened for both gastroesophageal varix and HCC according to the American Association for the Study of Liver Diseases guidelines.^56-57

Dr. Vilar-Gomez is assistant professor in the division of gastroenterology and hepatology at Indiana University, Indianapolis. Dr. Chalasani is vice president for academic affairs at Indiana University Health, Indianapolis, and the David W. Crabb Professor of Gastroenterology and Hepatology and an adjunct professor of anatomy, cell biology, and physiology in the division of gastroenterology and hepatology at Indiana University. Dr. Vilar-Gomez reports no financial conflicts of interest. Dr. Chalasani serves as a paid consultant to AbbVie, Boehringer-Ingelheim, Altimmune, Madrigal, Lilly, Zydus, and Galectin. He receives research support from Galectin and DSM.

References

1. Chalasani N et al. Hepatology 2018;67:328-57.

2. Söderberg C et al. Hepatology 2010;51:595-602.

3. Sanyal AJ et al. N Engl J Med 2021;385:1559-69.

4. Vilar-Gomez E et al. Gastroenterology 2018;155:443-57.e17.

5. Younossi ZM et al. Hepatology 2016;64:73-84.

6. EASL-EASD-EASO. J Hepatol 2016;64:1388-402.

7. Wong VW et al. J Hepatol 2018; 69:1349-56.

8. Vilar-Gomez E et al. Gastroenterology 2015;149:367-78.e5; quiz e14-5.

9. Promrat K et al. Hepatology 2010;51:121-9.

10. Wong VW et al. J Hepatol 2013;59:536-42.

11. Berzigotti A et al. Hepatology 2017;65:1293-1305.

12. Sacks FM et al. N Engl J Med 2009;360:859-73.

13. Vilar-Gomez E et al. Hepatology 2022 Jun;75(6):1491-1506.

14. Zelber-Sagi S et al. Liver Int 2017;37:936-49.

15. Hassani Zadeh S et al. J Gastroenterol Hepatol 2021;36:1470-8.

16. Yaskolka Meir A et al. Gut 2021;70:2085-95.

17. Sung KC et al. J Hepatol 2016;65:791-7.

18. Orci LA et al. Clin Gastroenterol Hepatol 2016;14:1398-411.

19. Ryu S et al. J Hepatol 2015;63:1229-37.

20. Kim D et al. Hepatology 2020;72:1556-68.

21. Kim D et al. Clin Gastroenterol Hepatol 2021;19:1240-7.e5.

22. Ascha MS et al. Hepatology 2010;51:1972-8.

23. Bambha K et al. Liver Int 2014;34:1250-8.

24. Lee Y et al. Clin Gastroenterol Hepatol 2019;17:1040-60.e11.

25. Grönroos S et al. JAMA Surg 2021;156:137-46.

26. Fakhry TK et al. Surg Obes Relat Dis 2019;15:502-11.

27. Seeberg KA et al. Ann Intern Med 2022;175:74-83.

28. Bower G et al. Obes Surg 2015;25:2280-9.

29. Jan A et al. Obes Surg 2015;25:1518-26.

30. Hanipah ZN et al. Obes Surg 2018;28:3431-8.

31. Are VS et al. Am J Gastroenterol 2020;115:1849-56.

32. Aminian A et al. JAMA 2021;326:2031-42.

33. Vuppalanchi R et al. Ann Surg 2022;275:e174-80.

34. Simon TG et al. Gut 2021. doi: 10.1136/gutjnl-2021-325724.

35. Lonardo A et al. J Hepatol 2018;68:335-52.

36. Chalasani N et al. Gastroenterology 2004;126:1287-92.

37. Pastori D et al. Dig Liver Dis 2015;47:4-11.

38. Kim RG et al. Clin Gastroenterol Hepatol 2017;15:1521-30.e8.

39. Ahmad J et al. Dig Dis Sci 2017;62:3596-604.

40. Chalasani NP et al. Am J Gastroenterol 2021;116(5):878-98.

41. Rinella ME et al. Hepatology 2019;70:1424-36.

42. Younossi ZM et al. Lancet 2019;394:2184-96.

43. Ratziu V. Clin Liver Dis (Hoboken) 2021;17:398-400.

44. Sanyal AJ et al. N Engl J Med 2010;341:1675-85.

45. Schürks M et al. BMJ 2010;341:c5702.

46. Cusi K et al. Ann Intern Med 2016;165:305-15.

47. Lewis JD et al. JAMA 2015;314:265-77.

48. Billington EO et al. Diabetologia 2015;58:2238-46.

49. Lewis JD et al. Diabetes Care 2011;34:916-22.

50. Erdmann E et al. Diabetes Care 2007;30:2773-8.

51. Viscoli CM et al. J Clin Endocrinol Metab 2017;102:914-22.

52. Armstong MJ et al. Lancet 2016;387:679-90.

53. Newsome PN et al. N Engl J Med 2021;384:1113-24.

54. Ng CH et al. Hepatology 2022;75:1647-61.

55. Kanwal F et al. Gastroenterology 2021;161:1030-1042.e8.

56. Garcia-Tsao G et al. Hepatology 2017;65:310-35.

57. Heimbach JK et al. Hepatology 2018;67:358-80.

Nonalcoholic fatty liver disease (NAFLD) is defined by the presence of hepatic steatosis detected on either imaging or histology in the absence of secondary causes of fatty liver (e.g., excessive alcohol consumption) or other chronic liver diseases.¹ For practical NAFLD diagnosis purposes, excessive alcohol intake can be defined as an active or recent history of more than 21 standard drinks per week in men and more than¹⁴ standard drinks per week in women. For the sake of terminology, NAFLD is characterized by fatty liver infiltration, affecting at least 5% of hepatocytes, with no evidence of hepatocyte injury, whereas nonalcoholic steatohepatitis (NASH) is defined as the presence of necroinflammation with or without fibrosis in a background of fatty liver.¹

Natural history

NASH and the degree of fibrosis are the two most important determinants of the natural history of NAFLD. NASH can evolve into fibrosis and cirrhosis, whereas advanced fibrosis and cirrhosis (stages 3 or 4 of fibrosis) significantly increase the risk of liver-related decompensation and mortality. NAFLD, per se, has been associated with an increased risk of overall mortality, compared with that of the general population.² The three most common causes of mortality for patients with NAFLD are cardiovascular diseases (CVD), extrahepatic malignancies, and liver-related deaths. Mortality and liver-related events, including hepatic decompensation and hepatocellular carcinoma (HCC), may significantly increase in a dose-dependent manner with increasing fibrosis stages, and stages 3 or 4 of fibrosis may display the highest rates of all-cause mortality and liver-related events.^3,4 It is important to note, however, that almost 15% of HCCs occur in patients with NAFLD who do not have cirrhosis.⁵ The presence of commonly associated comorbidities such as obesity, insulin resistance or diabetes, dyslipidemia, hypothyroidism, polycystic ovary syndrome, and sleep apnea may contribute to an increased risk of NASH and advanced fibrosis and, therefore, an accelerated clinical course of NAFLD.

Nonpharmacological interventions

Lifestyle modification

Lifestyle modification to achieve weight loss remains a first-line intervention in patients with NAFLD. Weight loss achieved either by hypocaloric diet alone or in conjunction with increased physical activity can be beneficial for all patients with NAFLD. The benefits extend not only to those who are overweight and obese but also to those within normal body weight (lean NAFLD).^1,6,7 Weight loss of approximately 3%-5% is necessary to improve hepatic steatosis, but a greater weight loss (7%-10%) is required to improve other histopathological features like necroinflammatory lesions and fibrosis.^8-10 Individuals with higher BMI and/or type 2 diabetes (T2D) will require a larger weight reduction to achieve a similar benefit on NAFLD-related features.^7,8 Weight loss via lifestyle changes can also decrease hepatic venous pressure gradient (HVPG), with greater declines reported among those with more than 10% weight loss.¹¹

Weight loss can be achieved through a variety of modalities, but long-term maintenance of lost weight is much more challenging. A combination of a hypocaloric diet with a caloric deficit of 500-1,000 kcal/d, alongside moderate-intensity exercise and intensive on-site behavioral treatment, will likely increase the possibility of a sustained weight loss over time.^1,12 A growing body of scientific evidence indicates that a healthy diet that includes a reduction of high-glycemic-index foods and refined carbohydrates; increased consumption of monounsaturated fatty acids, omega-3 fatty acids, and fibers; and high intakes of olive oil, nuts, vegetables, fruits, legumes, whole grains, and fish can have beneficial effects on NAFLD and its severity.^13-16 Adherence to these healthy dietary patterns has been associated with a marked reduction in CVD morbidity and mortality and is, thus, a strategic lifestyle recommendation for patients with NAFLD in whom the leading cause of morbidity and death is CVD.^1,3

Exercise alone in adults with NAFLD may reduce hepatic steatosis, but its ability to improve inflammation and fibrosis has not been proven in well-designed RCTs.^17,18 Physical activity and exercise have been shown to curb both the development and the progression of NAFLD, and beneficial effects could be achieved independent of weight loss.^17,19,20 Most importantly, moderate-to-vigorous physical activity is likely associated with lower all-cause and cardiovascular mortality in patients with NAFLD.²¹

Heavy alcohol intake should be avoided by patients with NAFLD or NASH, and those with cirrhotic NASH should avoid any alcohol consumption given the risk of HCC and hepatic decompensation.^1,4,22 Limiting light-to-moderate alcohol intake among patients without cirrhosis is still under debate.¹ People with NAFLD may be advised to drink an equivalent of two to three 8-oz cups of regular brewed coffee daily as it has shown certain antifibrotic effects in NAFLD patients.²³
 

Bariatric surgery

Bariatric surgery is an attractive therapeutic option for eligible obese patients with NAFLD. Bariatric surgery has the potential for inducing great weight loss and, therefore, reverses not only the steatosis, inflammation, and fibrosis among NAFLD individuals but also important comorbid conditions like T2D. A recent systematic review and meta-analysis examining data on the effects of bariatric surgery on histologic features of NAFLD from 32 cohort studies (no RCTs included) showed that bariatric surgery was associated with significant improvements in steatosis (66%), lobular inflammation (50%), ballooning degeneration (76%), and fibrosis (40%), and the benefits were significantly higher in those who underwent Roux-en-Y gastric bypass (RYGB). Of note, worsening of liver histology, including fibrosis, could be seen in up to 12% of patients who underwent bariatric surgery.²⁴ The postsurgical weight regained after RYGB could explain partly the lack of fibrosis improvement or even worsening of fibrosis, although further research is needed to clarify these controversial findings.

RYGB and sleeve gastrectomy (SG) are the most commonly performed bariatric surgeries worldwide. Patients who undergo RYGB achieve higher weight loss when compared with those treated with SG.²⁵ Among all bariatric procedures, RYGB could result in a higher proportion of complete resolution of NAFLD than SG, although evidence is inconclusive on fibrosis improvement rates.^24,26 Most recently, a single-center RCT has compared the effects of RYGB vs. SG on liver fat content and fibrosis in patients with severe obesity and T2D.²⁷ Data showed that both surgical procedures were highly and equally effective in reducing fatty liver content (quantified by magnetic resonance imaging), with an almost complete resolution of the fatty liver at 1 year of both surgical interventions. The beneficial effects of both GB and SG on fibrosis (assessed by enhanced liver test [ELF]) were less evident with no substantial difference between the two groups. Importantly, 69% of participants had an increase in their ELF scores during the study, despite the majority of participants achieving significant reductions in their body weights and better glycemic control at the end of the study. These findings might be considered with caution as several factors, such as the duration of the study (only 1 year) and lack of a liver biopsy to confirm fibrosis changes over time, could be influencing the study results.

Among all NAFLD phenotypes, those with cirrhosis and, most importantly, hepatic decompensation appear to be at increased risk of perioperative mortality and inpatient hospital stays than those without cirrhosis.^28-29 Bariatric surgery is an absolute contraindication in patients with decompensated cirrhosis (Child B and Child C). Among compensated -Child A- cirrhotics, those with portal hypertension are at increased risk of morbidity and perioperative mortality.³⁰ A recent analysis of National Inpatient Sample data suggested that the rates of complications in those with cirrhosis have decreased with time, which could be due to a better selection process and the use of more restrictive bariatric surgery in those with cirrhosis. Low volume centers (defined as less than 50 procedures per year) and nonrestrictive bariatric surgery were associated with a higher mortality rate. These data may suggest that patients with cirrhosis should undergo bariatric surgery only in high-volume centers after a multidisciplinary evaluation.³¹ Bariatric endoscopy is emerging as a new treatment for obesity, but the long-term durability of its effects remains to be determined.

A recent retrospective cohort study, including 1,158 adult patients with biopsy-proven NASH, has investigated the benefits of bariatric surgery on the occurrence of major adverse liver and cardiovascular outcomes in 650 patients who underwent bariatric surgery, compared with 508 patients who received nonsurgical usual care. This study showed that bariatric surgery was associated with 88% lower risk of progression of fatty liver to cirrhosis, liver cancer, or liver-related death, and 70% lower risk of serious CVD events during a follow-up period of 10 years.³² Within 1 year after surgery, 0.6% of patients died from surgical complications. The potential benefits of bariatric surgery in patients with NAFLD must be balanced against surgical risk, especially in eligible obese individuals with established cirrhosis. Data from a retrospective cohort study have shown that bariatric surgery in obese cirrhotic patients does not seem to associate with excessive mortality, compared with noncirrhotic obese patients.³³ More data on immediate complication rates and long-term outcomes in patients with NAFLD by type of bariatric surgery is also required.

NAFLD as a standalone is not an indication for bariatric surgery. However, it could be considered in NAFLD patients who have a BMI of 40 kg/m² or more without coexisting comorbidities or with a BMI of 35 kg/m² or more and one or more severe obesity-related comorbidities, including T2D, hypertension, hyperlipidemia, or obstructive sleep apnea. Bariatric surgery must always be offered in centers with an experienced bariatric surgery program.¹
 

Management of comorbidities

Given the multiple comorbidities associated with NAFLD and the potential to influence its severity, a comprehensive and multidisciplinary approach is needed to ameliorate not only the progression of liver disease but also those complications related to metabolic syndrome, hyperlipidemia, hypertension, diabetes, and other related conditions. Of note, all patients with NAFLD should receive aggressive management of comorbidities regardless of the severity of NAFLD. Ideally, a multidisciplinary team – including a primary care provider, an endocrinologist for patients with T2D, and a gastroenterologist/hepatologist – is needed to successfully manage patients with NAFLD.

It is well recognized that individuals with biopsy-proven NAFLD are at a higher risk of coronary heart disease, stroke, congestive heart failure, and death resulting from CVD when compared with the non-NAFLD population, and excess in CVD morbidity and mortality is evident across all stages of NAFLD and increases with worsening disease severity.³⁴ The strong association between CVD and NAFLD has important clinical implications that may influence the decision to initiate treatment for primary prevention, including lipid-lowering, antihypertensive, or antiplatelet therapies.³⁵ Statins are widely used to reduce LDL cholesterol and have been proven to be safe in NAFLD, including for those with elevated liver enzymes and even in compensated cirrhosis, in several studies conducted during the last 15 years.³⁶ Statins are characterized by anti-inflammatory, anti-oxidative, antifibrotic, and plaque-stabilizing effects, whereby they may improve vascular and hepatic function among patients with NAFLD and reduce cardiovascular risk.³⁷ Statin use for the treatment of NAFLD is still controversial and off-label and is not specifically recommended to treat NASH, but positive results have been shown for reductions in liver enzymes.¹ A recent meta-analysis of 13 studies showed that continued use of statin in cirrhosis was associated with a 46% and 44% risk reduction in hepatic decompensation and mortality, respectively.³⁸

The Food and Drug Administration has approved omega-3 (n-3) fatty acid agents and fibrates for the treatment of very high triglycerides (500 mg/dL or higher); however, no specific indications exist to treat NAFLD.¹ Fenofibrate is related to mild aminotransferase elevations and, in some cases, severe liver injury, so caution must be paid, especially within 2 days of taking the drug.^39-40

NAFLD phenotypes that need liver pharmacotherapy

There are still no FDA-approved drugs or biological treatments for NASH. Pharmacological interventions aiming primarily at improving liver disease should generally be limited to those with biopsy-proven NASH and clinically significant fibrosis (fibrosis stages of 2 or greater).^1,4 For FDA approval, medications used for treating NAFLD with fibrosis need to meet one of the following endpoint criteria: resolution of NASH without worsening of fibrosis, improvement in fibrosis without worsening of NASH, or both. In addition to those criteria, a new medication might improve the metabolic profile and have a tolerable safety profile. Table 1 displays those NAFLD phenotypes that will likely benefit from liver-directed therapy.

Obeticholic acid as an experimental therapy for NASH

A planned month-18 interim analysis of a multicentre, phase III RCT examined the efficacy and safety of obeticholic acid (OCA), a farnesoid X receptor agonist, in patients with NASH and stages 1-3 of fibrosis. The primary endpoint (fibrosis reduction 1 stage or more with no worsening of NASH) was met by 12% of patients in the placebo group, 18% of patients receiving OCA 10 mg (P = .045), and 23% of those receiving OCA 25 mg (P = .0002). An alternative primary endpoint of NASH resolution with no worsening of fibrosis was not met. OCA 25 mg led to the highest rates of pruritus and hyperlipidemia, compared with OCA 10 mg.⁴² These side effects seem to be related to the activation of the farnesoid X receptor.⁴³
 

Currently available but off label medications

Vitamin E, an antioxidant, administered at a daily dose of 800 IU/day improves steatosis, inflammation, and ballooning, but not fibrosis in nondiabetic adults with biopsy-proven NASH.⁴⁴ Vitamin E for 96 weeks was associated with a significantly higher rate of improvement in NASH (43% vs. 19%, P less than .01), compared with placebo.⁴⁴ In the Treatment of Nonalcoholic Fatty Liver Disease in Children trial (TONIC), which examined vitamin E (800 IU/day) or metformin (500 mg twice daily) against placebo in children with biopsy-proven NAFLD, resolution of NASH was significantly greater in children treated with vitamin E than in children treated with placebo (58% vs. 28%, P less than .01). Metformin did not significantly improve the NASH resolution rates, compared with placebo (41% vs. 28%, P = .23). Vitamin E could be recommended for nondiabetic adults or children if lifestyle modifications do not produce the expected results as a result of noncompliance or ineffectiveness. Since continued use of vitamin E has been suggested to be associated with a very small increase in the risk for prostate cancer (an absolute increase of 1.6 per 1,000 person-years of vitamin E use) in men, risks and benefits should be discussed with each patient before starting therapy. A meta-analysis of nine placebo-controlled trials including roughly 119,000 patients reported that vitamin E supplementation increases the risk of hemorrhagic stroke by 20% while reducing ischemic stroke by 10%. It was estimated that vitamin E supplementation would prevent one ischemic stroke per 476 treated patients while inducing one hemorrhagic stroke for every 1,250 patients. It is noteworthy that the combination of vitamin E with anticoagulant and/or antiplatelet therapy was not examined in this trial, so we could not determine how combination therapy might affect the risk of ischemic or hemorrhagic stroke.⁴⁵

Thiazolidinediones drugs have been reported to be effective in improving NAFLD in many human studies. Evidence from RCTs suggests that pioglitazone could significantly improve glucose metabolism, alanine aminotransferase, and liver histology – such as hepatic steatosis, lobular inflammation, and ballooning degeneration – among patients with or without T2D. However, the beneficial effects on improving fibrosis remain to be verified.^1,46 Because of safety concerns, the risk/benefit balance of using pioglitazone to treat NASH should be discussed with each patient.^47-48 Pioglitazone has been associated with long-term risk of bladder cancer,⁴⁹ congestive heart failure,⁵⁰ and bone fractures.⁵¹ Data from the Pioglitazone, Vitamin E, or Placebo for Nonalcoholic Steatohepatitis (PIVENS) trial showed that pioglitazone was significantly associated with weight gain but with no other serious adverse events. However, this study was not powered to test any safety-related hypotheses.⁴⁴

Glucagon-like peptide 1 analogs have been reported to induce weight loss and reduce insulin resistance, which may lead to improvements in NAFLD. Phase II RCTs of glucagon-like peptide 1 receptor agonists (liraglutide and semaglutide) for the treatment of biopsy-proven NASH showed significant improvements in serum liver enzymes, steatosis, and inflammation, as well as NASH resolution without worsening liver fibrosis, although no direct benefit was observed in reversing fibrosis.^52-53 One of these studies explores the efficacy and safety of different doses of daily subcutaneous semaglutide vs. placebo on the rates of resolution of NASH with no worsening of fibrosis. The highest dose (0.4 mg) showed the greatest difference (59% vs. 17%, P less than .01), compared with the placebo arm. However, there was no difference in improvement in fibrosis stage between the two groups (43% in the 0.4-mg group vs. 33% in the placebo group, ^P = .48).⁵³ Gastrointestinal adverse events were common in the semaglutide arm.

“Spontaneous” NASH resolution and fibrosis improvement are commonly seen in participants assigned to placebo arms in clinical trials. A recent meta-analysis of 43 RCTs including 2649 placebo-treated patients showed a pooled estimate of NASH resolution without worsening of fibrosis and 1 stage reduction or more in fibrosis of 12% and 19%, respectively. Relevant factors involved in “spontaneous” NASH improvement are unknown but could be related to changes in BMI resulting from lifestyle changes, race and ethnicity, age, and, likely, NAFLD-related genetic variations, although more data is needed to better understand the histologic response in placebo-treated patients.⁵⁴

Semaglutide injections (2.4 mg once weekly) or (2.0 mg once weekly) have been recently approved by the FDA for chronic weight management in adults with obesity or overweight with at least one weight-related condition or glucose control of T2D, respectively. Of note, the semaglutide dose used in the NASH trial is not currently available for the treatment of patients who are overweight/obese or have T2D, but the beneficial effects on body weight reductions and glucose control are similar overall to the effects seen with currently available doses for management of obesity or diabetes. One may consider using semaglutide in patients who are overweight/obese or have T2D with NASH, but in the senior author’s experience, it has been quite challenging to receive the payer’s approval, as its use is not specifically approved to treat liver disease.¹
 

How to follow patients with NAFLD in the clinic

Once a diagnosis of NAFLD is made, the use of noninvasive testing may aid to identify which patients are at high risk of fibrosis. Easy to use clinical tools, such as the NAFLD Fibrosis Score and the Fib-4 index, and liver stiffness measurements using vibration-controlled transient elastography (FibroScan) or magnetic resonance elastography (MRE) are clinically useful noninvasive tools for identifying patients with NAFLD who have a higher likelihood of progressing to advanced fibrosis.^1,55 The use of either NAFLD Fibrosis Score (less than -1.455) or Fib-4 index (less than 1.30) low cutoffs may be particularly useful to rule out advanced fibrosis. People with a NAFLD Fibrosis Score (greater than –1.455) or Fib-4 index (greater than 1.30) should undergo liver stiffness measurement (LSM) via FibroScan. Those with an LSM of 8 kPa or higher should be referred to specialized care, where a decision to perform a liver biopsy and initiate monitoring and therapy will be taken. MRE is the most accurate noninvasive method for the estimation of liver fibrosis. When MRE is available, it can be a diagnostic alternative to accurately rule in and rule out patients with advanced fibrosis. This technique can be preferred in clinical trials, but it is rarely used in clinical practice because it is expensive and not easily available. Reassessment by noninvasive scores at 1-3 years’ follow-up will be considered for those with an LSM less than 8 kPa. Patients with NASH cirrhosis should be screened for both gastroesophageal varix and HCC according to the American Association for the Study of Liver Diseases guidelines.^56-57

Dr. Vilar-Gomez is assistant professor in the division of gastroenterology and hepatology at Indiana University, Indianapolis. Dr. Chalasani is vice president for academic affairs at Indiana University Health, Indianapolis, and the David W. Crabb Professor of Gastroenterology and Hepatology and an adjunct professor of anatomy, cell biology, and physiology in the division of gastroenterology and hepatology at Indiana University. Dr. Vilar-Gomez reports no financial conflicts of interest. Dr. Chalasani serves as a paid consultant to AbbVie, Boehringer-Ingelheim, Altimmune, Madrigal, Lilly, Zydus, and Galectin. He receives research support from Galectin and DSM.

References

1. Chalasani N et al. Hepatology 2018;67:328-57.

2. Söderberg C et al. Hepatology 2010;51:595-602.

3. Sanyal AJ et al. N Engl J Med 2021;385:1559-69.

4. Vilar-Gomez E et al. Gastroenterology 2018;155:443-57.e17.

5. Younossi ZM et al. Hepatology 2016;64:73-84.

6. EASL-EASD-EASO. J Hepatol 2016;64:1388-402.

7. Wong VW et al. J Hepatol 2018; 69:1349-56.

8. Vilar-Gomez E et al. Gastroenterology 2015;149:367-78.e5; quiz e14-5.

9. Promrat K et al. Hepatology 2010;51:121-9.

10. Wong VW et al. J Hepatol 2013;59:536-42.

11. Berzigotti A et al. Hepatology 2017;65:1293-1305.

12. Sacks FM et al. N Engl J Med 2009;360:859-73.

13. Vilar-Gomez E et al. Hepatology 2022 Jun;75(6):1491-1506.

14. Zelber-Sagi S et al. Liver Int 2017;37:936-49.

15. Hassani Zadeh S et al. J Gastroenterol Hepatol 2021;36:1470-8.

16. Yaskolka Meir A et al. Gut 2021;70:2085-95.

17. Sung KC et al. J Hepatol 2016;65:791-7.

18. Orci LA et al. Clin Gastroenterol Hepatol 2016;14:1398-411.

19. Ryu S et al. J Hepatol 2015;63:1229-37.

20. Kim D et al. Hepatology 2020;72:1556-68.

21. Kim D et al. Clin Gastroenterol Hepatol 2021;19:1240-7.e5.

22. Ascha MS et al. Hepatology 2010;51:1972-8.

23. Bambha K et al. Liver Int 2014;34:1250-8.

24. Lee Y et al. Clin Gastroenterol Hepatol 2019;17:1040-60.e11.

25. Grönroos S et al. JAMA Surg 2021;156:137-46.

26. Fakhry TK et al. Surg Obes Relat Dis 2019;15:502-11.

27. Seeberg KA et al. Ann Intern Med 2022;175:74-83.

28. Bower G et al. Obes Surg 2015;25:2280-9.

29. Jan A et al. Obes Surg 2015;25:1518-26.

30. Hanipah ZN et al. Obes Surg 2018;28:3431-8.

31. Are VS et al. Am J Gastroenterol 2020;115:1849-56.

32. Aminian A et al. JAMA 2021;326:2031-42.

33. Vuppalanchi R et al. Ann Surg 2022;275:e174-80.

34. Simon TG et al. Gut 2021. doi: 10.1136/gutjnl-2021-325724.

35. Lonardo A et al. J Hepatol 2018;68:335-52.

36. Chalasani N et al. Gastroenterology 2004;126:1287-92.

37. Pastori D et al. Dig Liver Dis 2015;47:4-11.

38. Kim RG et al. Clin Gastroenterol Hepatol 2017;15:1521-30.e8.

39. Ahmad J et al. Dig Dis Sci 2017;62:3596-604.

40. Chalasani NP et al. Am J Gastroenterol 2021;116(5):878-98.

41. Rinella ME et al. Hepatology 2019;70:1424-36.

42. Younossi ZM et al. Lancet 2019;394:2184-96.

43. Ratziu V. Clin Liver Dis (Hoboken) 2021;17:398-400.

44. Sanyal AJ et al. N Engl J Med 2010;341:1675-85.

45. Schürks M et al. BMJ 2010;341:c5702.

46. Cusi K et al. Ann Intern Med 2016;165:305-15.

47. Lewis JD et al. JAMA 2015;314:265-77.

48. Billington EO et al. Diabetologia 2015;58:2238-46.

49. Lewis JD et al. Diabetes Care 2011;34:916-22.

50. Erdmann E et al. Diabetes Care 2007;30:2773-8.

51. Viscoli CM et al. J Clin Endocrinol Metab 2017;102:914-22.

52. Armstong MJ et al. Lancet 2016;387:679-90.

53. Newsome PN et al. N Engl J Med 2021;384:1113-24.

54. Ng CH et al. Hepatology 2022;75:1647-61.

55. Kanwal F et al. Gastroenterology 2021;161:1030-1042.e8.

56. Garcia-Tsao G et al. Hepatology 2017;65:310-35.

57. Heimbach JK et al. Hepatology 2018;67:358-80.

Nonalcoholic fatty liver disease (NAFLD) is defined by the presence of hepatic steatosis detected on either imaging or histology in the absence of secondary causes of fatty liver (e.g., excessive alcohol consumption) or other chronic liver diseases.¹ For practical NAFLD diagnosis purposes, excessive alcohol intake can be defined as an active or recent history of more than 21 standard drinks per week in men and more than¹⁴ standard drinks per week in women. For the sake of terminology, NAFLD is characterized by fatty liver infiltration, affecting at least 5% of hepatocytes, with no evidence of hepatocyte injury, whereas nonalcoholic steatohepatitis (NASH) is defined as the presence of necroinflammation with or without fibrosis in a background of fatty liver.¹

Natural history

NASH and the degree of fibrosis are the two most important determinants of the natural history of NAFLD. NASH can evolve into fibrosis and cirrhosis, whereas advanced fibrosis and cirrhosis (stages 3 or 4 of fibrosis) significantly increase the risk of liver-related decompensation and mortality. NAFLD, per se, has been associated with an increased risk of overall mortality, compared with that of the general population.² The three most common causes of mortality for patients with NAFLD are cardiovascular diseases (CVD), extrahepatic malignancies, and liver-related deaths. Mortality and liver-related events, including hepatic decompensation and hepatocellular carcinoma (HCC), may significantly increase in a dose-dependent manner with increasing fibrosis stages, and stages 3 or 4 of fibrosis may display the highest rates of all-cause mortality and liver-related events.^3,4 It is important to note, however, that almost 15% of HCCs occur in patients with NAFLD who do not have cirrhosis.⁵ The presence of commonly associated comorbidities such as obesity, insulin resistance or diabetes, dyslipidemia, hypothyroidism, polycystic ovary syndrome, and sleep apnea may contribute to an increased risk of NASH and advanced fibrosis and, therefore, an accelerated clinical course of NAFLD.

Nonpharmacological interventions

Lifestyle modification

Lifestyle modification to achieve weight loss remains a first-line intervention in patients with NAFLD. Weight loss achieved either by hypocaloric diet alone or in conjunction with increased physical activity can be beneficial for all patients with NAFLD. The benefits extend not only to those who are overweight and obese but also to those within normal body weight (lean NAFLD).^1,6,7 Weight loss of approximately 3%-5% is necessary to improve hepatic steatosis, but a greater weight loss (7%-10%) is required to improve other histopathological features like necroinflammatory lesions and fibrosis.^8-10 Individuals with higher BMI and/or type 2 diabetes (T2D) will require a larger weight reduction to achieve a similar benefit on NAFLD-related features.^7,8 Weight loss via lifestyle changes can also decrease hepatic venous pressure gradient (HVPG), with greater declines reported among those with more than 10% weight loss.¹¹

Weight loss can be achieved through a variety of modalities, but long-term maintenance of lost weight is much more challenging. A combination of a hypocaloric diet with a caloric deficit of 500-1,000 kcal/d, alongside moderate-intensity exercise and intensive on-site behavioral treatment, will likely increase the possibility of a sustained weight loss over time.^1,12 A growing body of scientific evidence indicates that a healthy diet that includes a reduction of high-glycemic-index foods and refined carbohydrates; increased consumption of monounsaturated fatty acids, omega-3 fatty acids, and fibers; and high intakes of olive oil, nuts, vegetables, fruits, legumes, whole grains, and fish can have beneficial effects on NAFLD and its severity.^13-16 Adherence to these healthy dietary patterns has been associated with a marked reduction in CVD morbidity and mortality and is, thus, a strategic lifestyle recommendation for patients with NAFLD in whom the leading cause of morbidity and death is CVD.^1,3

Exercise alone in adults with NAFLD may reduce hepatic steatosis, but its ability to improve inflammation and fibrosis has not been proven in well-designed RCTs.^17,18 Physical activity and exercise have been shown to curb both the development and the progression of NAFLD, and beneficial effects could be achieved independent of weight loss.^17,19,20 Most importantly, moderate-to-vigorous physical activity is likely associated with lower all-cause and cardiovascular mortality in patients with NAFLD.²¹

Heavy alcohol intake should be avoided by patients with NAFLD or NASH, and those with cirrhotic NASH should avoid any alcohol consumption given the risk of HCC and hepatic decompensation.^1,4,22 Limiting light-to-moderate alcohol intake among patients without cirrhosis is still under debate.¹ People with NAFLD may be advised to drink an equivalent of two to three 8-oz cups of regular brewed coffee daily as it has shown certain antifibrotic effects in NAFLD patients.²³
 

Bariatric surgery

Bariatric surgery is an attractive therapeutic option for eligible obese patients with NAFLD. Bariatric surgery has the potential for inducing great weight loss and, therefore, reverses not only the steatosis, inflammation, and fibrosis among NAFLD individuals but also important comorbid conditions like T2D. A recent systematic review and meta-analysis examining data on the effects of bariatric surgery on histologic features of NAFLD from 32 cohort studies (no RCTs included) showed that bariatric surgery was associated with significant improvements in steatosis (66%), lobular inflammation (50%), ballooning degeneration (76%), and fibrosis (40%), and the benefits were significantly higher in those who underwent Roux-en-Y gastric bypass (RYGB). Of note, worsening of liver histology, including fibrosis, could be seen in up to 12% of patients who underwent bariatric surgery.²⁴ The postsurgical weight regained after RYGB could explain partly the lack of fibrosis improvement or even worsening of fibrosis, although further research is needed to clarify these controversial findings.

RYGB and sleeve gastrectomy (SG) are the most commonly performed bariatric surgeries worldwide. Patients who undergo RYGB achieve higher weight loss when compared with those treated with SG.²⁵ Among all bariatric procedures, RYGB could result in a higher proportion of complete resolution of NAFLD than SG, although evidence is inconclusive on fibrosis improvement rates.^24,26 Most recently, a single-center RCT has compared the effects of RYGB vs. SG on liver fat content and fibrosis in patients with severe obesity and T2D.²⁷ Data showed that both surgical procedures were highly and equally effective in reducing fatty liver content (quantified by magnetic resonance imaging), with an almost complete resolution of the fatty liver at 1 year of both surgical interventions. The beneficial effects of both GB and SG on fibrosis (assessed by enhanced liver test [ELF]) were less evident with no substantial difference between the two groups. Importantly, 69% of participants had an increase in their ELF scores during the study, despite the majority of participants achieving significant reductions in their body weights and better glycemic control at the end of the study. These findings might be considered with caution as several factors, such as the duration of the study (only 1 year) and lack of a liver biopsy to confirm fibrosis changes over time, could be influencing the study results.

Among all NAFLD phenotypes, those with cirrhosis and, most importantly, hepatic decompensation appear to be at increased risk of perioperative mortality and inpatient hospital stays than those without cirrhosis.^28-29 Bariatric surgery is an absolute contraindication in patients with decompensated cirrhosis (Child B and Child C). Among compensated -Child A- cirrhotics, those with portal hypertension are at increased risk of morbidity and perioperative mortality.³⁰ A recent analysis of National Inpatient Sample data suggested that the rates of complications in those with cirrhosis have decreased with time, which could be due to a better selection process and the use of more restrictive bariatric surgery in those with cirrhosis. Low volume centers (defined as less than 50 procedures per year) and nonrestrictive bariatric surgery were associated with a higher mortality rate. These data may suggest that patients with cirrhosis should undergo bariatric surgery only in high-volume centers after a multidisciplinary evaluation.³¹ Bariatric endoscopy is emerging as a new treatment for obesity, but the long-term durability of its effects remains to be determined.

A recent retrospective cohort study, including 1,158 adult patients with biopsy-proven NASH, has investigated the benefits of bariatric surgery on the occurrence of major adverse liver and cardiovascular outcomes in 650 patients who underwent bariatric surgery, compared with 508 patients who received nonsurgical usual care. This study showed that bariatric surgery was associated with 88% lower risk of progression of fatty liver to cirrhosis, liver cancer, or liver-related death, and 70% lower risk of serious CVD events during a follow-up period of 10 years.³² Within 1 year after surgery, 0.6% of patients died from surgical complications. The potential benefits of bariatric surgery in patients with NAFLD must be balanced against surgical risk, especially in eligible obese individuals with established cirrhosis. Data from a retrospective cohort study have shown that bariatric surgery in obese cirrhotic patients does not seem to associate with excessive mortality, compared with noncirrhotic obese patients.³³ More data on immediate complication rates and long-term outcomes in patients with NAFLD by type of bariatric surgery is also required.

NAFLD as a standalone is not an indication for bariatric surgery. However, it could be considered in NAFLD patients who have a BMI of 40 kg/m² or more without coexisting comorbidities or with a BMI of 35 kg/m² or more and one or more severe obesity-related comorbidities, including T2D, hypertension, hyperlipidemia, or obstructive sleep apnea. Bariatric surgery must always be offered in centers with an experienced bariatric surgery program.¹
 

Management of comorbidities

Given the multiple comorbidities associated with NAFLD and the potential to influence its severity, a comprehensive and multidisciplinary approach is needed to ameliorate not only the progression of liver disease but also those complications related to metabolic syndrome, hyperlipidemia, hypertension, diabetes, and other related conditions. Of note, all patients with NAFLD should receive aggressive management of comorbidities regardless of the severity of NAFLD. Ideally, a multidisciplinary team – including a primary care provider, an endocrinologist for patients with T2D, and a gastroenterologist/hepatologist – is needed to successfully manage patients with NAFLD.

It is well recognized that individuals with biopsy-proven NAFLD are at a higher risk of coronary heart disease, stroke, congestive heart failure, and death resulting from CVD when compared with the non-NAFLD population, and excess in CVD morbidity and mortality is evident across all stages of NAFLD and increases with worsening disease severity.³⁴ The strong association between CVD and NAFLD has important clinical implications that may influence the decision to initiate treatment for primary prevention, including lipid-lowering, antihypertensive, or antiplatelet therapies.³⁵ Statins are widely used to reduce LDL cholesterol and have been proven to be safe in NAFLD, including for those with elevated liver enzymes and even in compensated cirrhosis, in several studies conducted during the last 15 years.³⁶ Statins are characterized by anti-inflammatory, anti-oxidative, antifibrotic, and plaque-stabilizing effects, whereby they may improve vascular and hepatic function among patients with NAFLD and reduce cardiovascular risk.³⁷ Statin use for the treatment of NAFLD is still controversial and off-label and is not specifically recommended to treat NASH, but positive results have been shown for reductions in liver enzymes.¹ A recent meta-analysis of 13 studies showed that continued use of statin in cirrhosis was associated with a 46% and 44% risk reduction in hepatic decompensation and mortality, respectively.³⁸

The Food and Drug Administration has approved omega-3 (n-3) fatty acid agents and fibrates for the treatment of very high triglycerides (500 mg/dL or higher); however, no specific indications exist to treat NAFLD.¹ Fenofibrate is related to mild aminotransferase elevations and, in some cases, severe liver injury, so caution must be paid, especially within 2 days of taking the drug.^39-40

NAFLD phenotypes that need liver pharmacotherapy

There are still no FDA-approved drugs or biological treatments for NASH. Pharmacological interventions aiming primarily at improving liver disease should generally be limited to those with biopsy-proven NASH and clinically significant fibrosis (fibrosis stages of 2 or greater).^1,4 For FDA approval, medications used for treating NAFLD with fibrosis need to meet one of the following endpoint criteria: resolution of NASH without worsening of fibrosis, improvement in fibrosis without worsening of NASH, or both. In addition to those criteria, a new medication might improve the metabolic profile and have a tolerable safety profile. Table 1 displays those NAFLD phenotypes that will likely benefit from liver-directed therapy.

Obeticholic acid as an experimental therapy for NASH

A planned month-18 interim analysis of a multicentre, phase III RCT examined the efficacy and safety of obeticholic acid (OCA), a farnesoid X receptor agonist, in patients with NASH and stages 1-3 of fibrosis. The primary endpoint (fibrosis reduction 1 stage or more with no worsening of NASH) was met by 12% of patients in the placebo group, 18% of patients receiving OCA 10 mg (P = .045), and 23% of those receiving OCA 25 mg (P = .0002). An alternative primary endpoint of NASH resolution with no worsening of fibrosis was not met. OCA 25 mg led to the highest rates of pruritus and hyperlipidemia, compared with OCA 10 mg.⁴² These side effects seem to be related to the activation of the farnesoid X receptor.⁴³
 

Currently available but off label medications

Vitamin E, an antioxidant, administered at a daily dose of 800 IU/day improves steatosis, inflammation, and ballooning, but not fibrosis in nondiabetic adults with biopsy-proven NASH.⁴⁴ Vitamin E for 96 weeks was associated with a significantly higher rate of improvement in NASH (43% vs. 19%, P less than .01), compared with placebo.⁴⁴ In the Treatment of Nonalcoholic Fatty Liver Disease in Children trial (TONIC), which examined vitamin E (800 IU/day) or metformin (500 mg twice daily) against placebo in children with biopsy-proven NAFLD, resolution of NASH was significantly greater in children treated with vitamin E than in children treated with placebo (58% vs. 28%, P less than .01). Metformin did not significantly improve the NASH resolution rates, compared with placebo (41% vs. 28%, P = .23). Vitamin E could be recommended for nondiabetic adults or children if lifestyle modifications do not produce the expected results as a result of noncompliance or ineffectiveness. Since continued use of vitamin E has been suggested to be associated with a very small increase in the risk for prostate cancer (an absolute increase of 1.6 per 1,000 person-years of vitamin E use) in men, risks and benefits should be discussed with each patient before starting therapy. A meta-analysis of nine placebo-controlled trials including roughly 119,000 patients reported that vitamin E supplementation increases the risk of hemorrhagic stroke by 20% while reducing ischemic stroke by 10%. It was estimated that vitamin E supplementation would prevent one ischemic stroke per 476 treated patients while inducing one hemorrhagic stroke for every 1,250 patients. It is noteworthy that the combination of vitamin E with anticoagulant and/or antiplatelet therapy was not examined in this trial, so we could not determine how combination therapy might affect the risk of ischemic or hemorrhagic stroke.⁴⁵

Thiazolidinediones drugs have been reported to be effective in improving NAFLD in many human studies. Evidence from RCTs suggests that pioglitazone could significantly improve glucose metabolism, alanine aminotransferase, and liver histology – such as hepatic steatosis, lobular inflammation, and ballooning degeneration – among patients with or without T2D. However, the beneficial effects on improving fibrosis remain to be verified.^1,46 Because of safety concerns, the risk/benefit balance of using pioglitazone to treat NASH should be discussed with each patient.^47-48 Pioglitazone has been associated with long-term risk of bladder cancer,⁴⁹ congestive heart failure,⁵⁰ and bone fractures.⁵¹ Data from the Pioglitazone, Vitamin E, or Placebo for Nonalcoholic Steatohepatitis (PIVENS) trial showed that pioglitazone was significantly associated with weight gain but with no other serious adverse events. However, this study was not powered to test any safety-related hypotheses.⁴⁴

Glucagon-like peptide 1 analogs have been reported to induce weight loss and reduce insulin resistance, which may lead to improvements in NAFLD. Phase II RCTs of glucagon-like peptide 1 receptor agonists (liraglutide and semaglutide) for the treatment of biopsy-proven NASH showed significant improvements in serum liver enzymes, steatosis, and inflammation, as well as NASH resolution without worsening liver fibrosis, although no direct benefit was observed in reversing fibrosis.^52-53 One of these studies explores the efficacy and safety of different doses of daily subcutaneous semaglutide vs. placebo on the rates of resolution of NASH with no worsening of fibrosis. The highest dose (0.4 mg) showed the greatest difference (59% vs. 17%, P less than .01), compared with the placebo arm. However, there was no difference in improvement in fibrosis stage between the two groups (43% in the 0.4-mg group vs. 33% in the placebo group, ^P = .48).⁵³ Gastrointestinal adverse events were common in the semaglutide arm.

“Spontaneous” NASH resolution and fibrosis improvement are commonly seen in participants assigned to placebo arms in clinical trials. A recent meta-analysis of 43 RCTs including 2649 placebo-treated patients showed a pooled estimate of NASH resolution without worsening of fibrosis and 1 stage reduction or more in fibrosis of 12% and 19%, respectively. Relevant factors involved in “spontaneous” NASH improvement are unknown but could be related to changes in BMI resulting from lifestyle changes, race and ethnicity, age, and, likely, NAFLD-related genetic variations, although more data is needed to better understand the histologic response in placebo-treated patients.⁵⁴

Semaglutide injections (2.4 mg once weekly) or (2.0 mg once weekly) have been recently approved by the FDA for chronic weight management in adults with obesity or overweight with at least one weight-related condition or glucose control of T2D, respectively. Of note, the semaglutide dose used in the NASH trial is not currently available for the treatment of patients who are overweight/obese or have T2D, but the beneficial effects on body weight reductions and glucose control are similar overall to the effects seen with currently available doses for management of obesity or diabetes. One may consider using semaglutide in patients who are overweight/obese or have T2D with NASH, but in the senior author’s experience, it has been quite challenging to receive the payer’s approval, as its use is not specifically approved to treat liver disease.¹
 

How to follow patients with NAFLD in the clinic

Once a diagnosis of NAFLD is made, the use of noninvasive testing may aid to identify which patients are at high risk of fibrosis. Easy to use clinical tools, such as the NAFLD Fibrosis Score and the Fib-4 index, and liver stiffness measurements using vibration-controlled transient elastography (FibroScan) or magnetic resonance elastography (MRE) are clinically useful noninvasive tools for identifying patients with NAFLD who have a higher likelihood of progressing to advanced fibrosis.^1,55 The use of either NAFLD Fibrosis Score (less than -1.455) or Fib-4 index (less than 1.30) low cutoffs may be particularly useful to rule out advanced fibrosis. People with a NAFLD Fibrosis Score (greater than –1.455) or Fib-4 index (greater than 1.30) should undergo liver stiffness measurement (LSM) via FibroScan. Those with an LSM of 8 kPa or higher should be referred to specialized care, where a decision to perform a liver biopsy and initiate monitoring and therapy will be taken. MRE is the most accurate noninvasive method for the estimation of liver fibrosis. When MRE is available, it can be a diagnostic alternative to accurately rule in and rule out patients with advanced fibrosis. This technique can be preferred in clinical trials, but it is rarely used in clinical practice because it is expensive and not easily available. Reassessment by noninvasive scores at 1-3 years’ follow-up will be considered for those with an LSM less than 8 kPa. Patients with NASH cirrhosis should be screened for both gastroesophageal varix and HCC according to the American Association for the Study of Liver Diseases guidelines.^56-57

Dr. Vilar-Gomez is assistant professor in the division of gastroenterology and hepatology at Indiana University, Indianapolis. Dr. Chalasani is vice president for academic affairs at Indiana University Health, Indianapolis, and the David W. Crabb Professor of Gastroenterology and Hepatology and an adjunct professor of anatomy, cell biology, and physiology in the division of gastroenterology and hepatology at Indiana University. Dr. Vilar-Gomez reports no financial conflicts of interest. Dr. Chalasani serves as a paid consultant to AbbVie, Boehringer-Ingelheim, Altimmune, Madrigal, Lilly, Zydus, and Galectin. He receives research support from Galectin and DSM.

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13. Vilar-Gomez E et al. Hepatology 2022 Jun;75(6):1491-1506.

14. Zelber-Sagi S et al. Liver Int 2017;37:936-49.

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A novel liquid biopsy test, which uses two circulating proteins, appears to be effective for diagnosing two major liver conditions, according to a new study published in Gut.

The test could allow clinicians to determine the staging of both liver fibrosis and nonalcoholic steatohepatitis, wrote the researchers led by Giulia Angelini, PhD, a postdoctoral fellow focused on nonalcoholic fatty liver disease pathophysiology at the Catholic University of the Sacred Heart in Rome.

ftwitty/E+/Getty Images

“The diagnosis of nonalcoholic steatohepatitis (NASH) currently relies on invasive liver biopsy,” they wrote. “There is, therefore, an urgent need to find noninvasive biomarkers for NASH diagnosis, disease progression, and intervention response monitoring.”

The research team sought to identify a biomarker and algorithm able to predict the presence and severity of nonalcoholic steatohepatitis (NASH) or liver fibrosis. The study evaluated two proteins found in circulating monocytes, which are a type of white blood cell: PLIN2 as a predictor of histological NASH and RAB14 levels as a predictor of liver fibrosis.

The multicenter study included 250 patients, with 100 subjects in the discovery cohort from the Bariatric Surgery Versus Nonalcoholic Steatohepatitis trial, or BRAVES, and 150 subjects in the validation cohort from the Liquid Biopsy for NASH and Liver Fibrosis trial, or LIBRA. The patients had histologically proven nonalcoholic fatty liver disease or NASH with or without fibrosis.

After careful molecular analysis, the research team used neural network classifiers to predict the presence of NASH and NASH stages. The analysis for the prediction of the presence of NASH produced an accuracy of 93% in the discovery cohort and 92% in the validation cohort. Sensitivity and specificity were 95% and 90% in the discovery group and 88% and 100% in the validation group, respectively. The research team also used a neural network analysis to predict the stages of NASH, which showed an accuracy of 85% in the discovery group and 85.2% in the validation cohort.

RAB14 was used to predict liver fibrosis with a logistic model that included waist circumference, age, plasma glucose, high-density lipoprotein, and alanine aminotransferase. In the discovery group, accuracy was 99.2%, sensitivity was 100%, and specificity was 95.8%. In the validation group, accuracy was 97.6%, sensitivity was 99%, and specificity was 89.6%.

When RAB14 was used as the only variable in the model, the accuracy, sensitivity, and specificity in the discovery cohort were 86.4%, 96%, and 45.8%, respectively. In the validation cohort, they were 92.4%, 96.9%, and 34.5%, respectively. In both cohorts, half of the subjects without fibrosis were erroneously predicted as having fibrosis, but the diagnosis of fibrosis was correctly predicted in nearly all subjects.

A limitation of the study is that only White subjects were enrolled, which limits the generalizability to other racial/ethnic groups, the investigators wrote, although they don’t expect differences would be seen in other groups.

“PLIN2 and RAB14 may permit diagnosis of NASH and/or liver fibrosis with a simple blood test,” they wrote. “Our biomarkers can be used in community and population studies permitting to investigate the real prevalence of NASH and liver fibrosis. Moreover, since it requires only blood sampling, they are potentially valuable tools for population-based and prevention studies in children.”
 

A step forward

“Obesity is a silent pandemic with an expected prevalence rate that will exceed 50% globally by 2030, of which 25% of the adults have fatty liver and approximately 6.5% with NASH, a progressive form of fatty liver,” said Kalyan Ram Bhamidimarri, MD, chief of hepatology and associate professor of clinical medicine at the University of Miami, who was not involved in the research. “Liver biopsy is the current clinical standard to diagnose NASH, but relying on an invasive procedure like liver biopsy that is fraught with several risks in a consistently growing volume of individuals with obesity is unsustainable.

Courtesy University of Miami

“So, there is an unmet need to diagnose NASH without invasive procedures such as liver biopsy,” he said. He pointed out that many of the alternatives to liver biopsy, such as liver stiffness measurements and scoring systems, pose their own difficulties.

On the other hand, he noted that “blood-based tests that correlate well with liver biopsy, the so-called wet biomarkers or liquid liver biopsy, are easier to perform, accessed widely, and could be tested frequently to assess efficacy of therapies.”

The study was funded by Elucidating Pathways of Steatohepatitis (EPOS Horizon 2020), Stratification of Obese Phenotypes to Optimize Future Obesity Therapy (SOPHIA IMI), Metadeq Inc., and support from the Transcampus Initiative. The study authors declared various competing interests, including some who serve as an advisor or stock option holder for Metadeq Limited. Dr. Bhamidimarri reported no relevant conflicts of interest.

Help your patients understand their risks for NASH by sharing AGA patient education at www.gastro.org/NASH.

A novel liquid biopsy test, which uses two circulating proteins, appears to be effective for diagnosing two major liver conditions, according to a new study published in Gut.

The test could allow clinicians to determine the staging of both liver fibrosis and nonalcoholic steatohepatitis, wrote the researchers led by Giulia Angelini, PhD, a postdoctoral fellow focused on nonalcoholic fatty liver disease pathophysiology at the Catholic University of the Sacred Heart in Rome.

ftwitty/E+/Getty Images

“The diagnosis of nonalcoholic steatohepatitis (NASH) currently relies on invasive liver biopsy,” they wrote. “There is, therefore, an urgent need to find noninvasive biomarkers for NASH diagnosis, disease progression, and intervention response monitoring.”

The research team sought to identify a biomarker and algorithm able to predict the presence and severity of nonalcoholic steatohepatitis (NASH) or liver fibrosis. The study evaluated two proteins found in circulating monocytes, which are a type of white blood cell: PLIN2 as a predictor of histological NASH and RAB14 levels as a predictor of liver fibrosis.

The multicenter study included 250 patients, with 100 subjects in the discovery cohort from the Bariatric Surgery Versus Nonalcoholic Steatohepatitis trial, or BRAVES, and 150 subjects in the validation cohort from the Liquid Biopsy for NASH and Liver Fibrosis trial, or LIBRA. The patients had histologically proven nonalcoholic fatty liver disease or NASH with or without fibrosis.

After careful molecular analysis, the research team used neural network classifiers to predict the presence of NASH and NASH stages. The analysis for the prediction of the presence of NASH produced an accuracy of 93% in the discovery cohort and 92% in the validation cohort. Sensitivity and specificity were 95% and 90% in the discovery group and 88% and 100% in the validation group, respectively. The research team also used a neural network analysis to predict the stages of NASH, which showed an accuracy of 85% in the discovery group and 85.2% in the validation cohort.

RAB14 was used to predict liver fibrosis with a logistic model that included waist circumference, age, plasma glucose, high-density lipoprotein, and alanine aminotransferase. In the discovery group, accuracy was 99.2%, sensitivity was 100%, and specificity was 95.8%. In the validation group, accuracy was 97.6%, sensitivity was 99%, and specificity was 89.6%.

When RAB14 was used as the only variable in the model, the accuracy, sensitivity, and specificity in the discovery cohort were 86.4%, 96%, and 45.8%, respectively. In the validation cohort, they were 92.4%, 96.9%, and 34.5%, respectively. In both cohorts, half of the subjects without fibrosis were erroneously predicted as having fibrosis, but the diagnosis of fibrosis was correctly predicted in nearly all subjects.

A limitation of the study is that only White subjects were enrolled, which limits the generalizability to other racial/ethnic groups, the investigators wrote, although they don’t expect differences would be seen in other groups.

“PLIN2 and RAB14 may permit diagnosis of NASH and/or liver fibrosis with a simple blood test,” they wrote. “Our biomarkers can be used in community and population studies permitting to investigate the real prevalence of NASH and liver fibrosis. Moreover, since it requires only blood sampling, they are potentially valuable tools for population-based and prevention studies in children.”
 

A step forward

“Obesity is a silent pandemic with an expected prevalence rate that will exceed 50% globally by 2030, of which 25% of the adults have fatty liver and approximately 6.5% with NASH, a progressive form of fatty liver,” said Kalyan Ram Bhamidimarri, MD, chief of hepatology and associate professor of clinical medicine at the University of Miami, who was not involved in the research. “Liver biopsy is the current clinical standard to diagnose NASH, but relying on an invasive procedure like liver biopsy that is fraught with several risks in a consistently growing volume of individuals with obesity is unsustainable.

Courtesy University of Miami

“So, there is an unmet need to diagnose NASH without invasive procedures such as liver biopsy,” he said. He pointed out that many of the alternatives to liver biopsy, such as liver stiffness measurements and scoring systems, pose their own difficulties.

On the other hand, he noted that “blood-based tests that correlate well with liver biopsy, the so-called wet biomarkers or liquid liver biopsy, are easier to perform, accessed widely, and could be tested frequently to assess efficacy of therapies.”

The study was funded by Elucidating Pathways of Steatohepatitis (EPOS Horizon 2020), Stratification of Obese Phenotypes to Optimize Future Obesity Therapy (SOPHIA IMI), Metadeq Inc., and support from the Transcampus Initiative. The study authors declared various competing interests, including some who serve as an advisor or stock option holder for Metadeq Limited. Dr. Bhamidimarri reported no relevant conflicts of interest.

Help your patients understand their risks for NASH by sharing AGA patient education at www.gastro.org/NASH.

A novel liquid biopsy test, which uses two circulating proteins, appears to be effective for diagnosing two major liver conditions, according to a new study published in Gut.

The test could allow clinicians to determine the staging of both liver fibrosis and nonalcoholic steatohepatitis, wrote the researchers led by Giulia Angelini, PhD, a postdoctoral fellow focused on nonalcoholic fatty liver disease pathophysiology at the Catholic University of the Sacred Heart in Rome.

ftwitty/E+/Getty Images

“The diagnosis of nonalcoholic steatohepatitis (NASH) currently relies on invasive liver biopsy,” they wrote. “There is, therefore, an urgent need to find noninvasive biomarkers for NASH diagnosis, disease progression, and intervention response monitoring.”

The research team sought to identify a biomarker and algorithm able to predict the presence and severity of nonalcoholic steatohepatitis (NASH) or liver fibrosis. The study evaluated two proteins found in circulating monocytes, which are a type of white blood cell: PLIN2 as a predictor of histological NASH and RAB14 levels as a predictor of liver fibrosis.

The multicenter study included 250 patients, with 100 subjects in the discovery cohort from the Bariatric Surgery Versus Nonalcoholic Steatohepatitis trial, or BRAVES, and 150 subjects in the validation cohort from the Liquid Biopsy for NASH and Liver Fibrosis trial, or LIBRA. The patients had histologically proven nonalcoholic fatty liver disease or NASH with or without fibrosis.

After careful molecular analysis, the research team used neural network classifiers to predict the presence of NASH and NASH stages. The analysis for the prediction of the presence of NASH produced an accuracy of 93% in the discovery cohort and 92% in the validation cohort. Sensitivity and specificity were 95% and 90% in the discovery group and 88% and 100% in the validation group, respectively. The research team also used a neural network analysis to predict the stages of NASH, which showed an accuracy of 85% in the discovery group and 85.2% in the validation cohort.

RAB14 was used to predict liver fibrosis with a logistic model that included waist circumference, age, plasma glucose, high-density lipoprotein, and alanine aminotransferase. In the discovery group, accuracy was 99.2%, sensitivity was 100%, and specificity was 95.8%. In the validation group, accuracy was 97.6%, sensitivity was 99%, and specificity was 89.6%.

When RAB14 was used as the only variable in the model, the accuracy, sensitivity, and specificity in the discovery cohort were 86.4%, 96%, and 45.8%, respectively. In the validation cohort, they were 92.4%, 96.9%, and 34.5%, respectively. In both cohorts, half of the subjects without fibrosis were erroneously predicted as having fibrosis, but the diagnosis of fibrosis was correctly predicted in nearly all subjects.

A limitation of the study is that only White subjects were enrolled, which limits the generalizability to other racial/ethnic groups, the investigators wrote, although they don’t expect differences would be seen in other groups.

“PLIN2 and RAB14 may permit diagnosis of NASH and/or liver fibrosis with a simple blood test,” they wrote. “Our biomarkers can be used in community and population studies permitting to investigate the real prevalence of NASH and liver fibrosis. Moreover, since it requires only blood sampling, they are potentially valuable tools for population-based and prevention studies in children.”
 

A step forward

“Obesity is a silent pandemic with an expected prevalence rate that will exceed 50% globally by 2030, of which 25% of the adults have fatty liver and approximately 6.5% with NASH, a progressive form of fatty liver,” said Kalyan Ram Bhamidimarri, MD, chief of hepatology and associate professor of clinical medicine at the University of Miami, who was not involved in the research. “Liver biopsy is the current clinical standard to diagnose NASH, but relying on an invasive procedure like liver biopsy that is fraught with several risks in a consistently growing volume of individuals with obesity is unsustainable.

Courtesy University of Miami

“So, there is an unmet need to diagnose NASH without invasive procedures such as liver biopsy,” he said. He pointed out that many of the alternatives to liver biopsy, such as liver stiffness measurements and scoring systems, pose their own difficulties.

On the other hand, he noted that “blood-based tests that correlate well with liver biopsy, the so-called wet biomarkers or liquid liver biopsy, are easier to perform, accessed widely, and could be tested frequently to assess efficacy of therapies.”

The study was funded by Elucidating Pathways of Steatohepatitis (EPOS Horizon 2020), Stratification of Obese Phenotypes to Optimize Future Obesity Therapy (SOPHIA IMI), Metadeq Inc., and support from the Transcampus Initiative. The study authors declared various competing interests, including some who serve as an advisor or stock option holder for Metadeq Limited. Dr. Bhamidimarri reported no relevant conflicts of interest.

Help your patients understand their risks for NASH by sharing AGA patient education at www.gastro.org/NASH.

Patients with alcohol-related cirrhosis have a higher fracture rate and a higher post-fracture mortality rate, compared with the general population, according to a large new study from Sweden.

Alcohol-related cirrhosis was associated with an almost fourfold increased fracture rate, and the post-fracture mortality rates were higher at both 30 days and 1 year later.

“Half of all fractures were presumably associated with osteoporosis,” write the study authors, who are gastroenterologists and epidemiologists at the Karolinska Institute, Stockholm. “This suggests that existing pharmacotherapy for osteoporosis may reduce the fracture risk in patients with alcohol-related cirrhosis and possibly also reduce mortality rates.”

But, the authors continue, “our data indicate that osteoporosis may not be the only explanatory factor for this increased fracture risk. Removing modifiable risk factors such as smoking, heavy alcohol use, or malnutrition may further reduce the risk of fractures.”

The study was published online in Clinical Gastroenterology and Hepatology.
 

Analyzing risks

The association between liver cirrhosis and fractures appears strongest in patients with alcohol-related cirrhosis, the most common cause of cirrhosis in many countries, including Sweden, the authors write.

Previous studies have examined mostly relative risk or hip fractures. The authors aimed to determine not only the relative risk but also the absolute risk, which “can better inform clinicians and policymakers of the actual size of the problem,” they write.

In a nationwide population-based cohort study, they analyzed data from the Swedish National Patient Registry between 1969 and 2016, which included 25,090 patients with alcohol-related cirrhosis. Patients were matched for sex, age, and municipality with 239,458 controls from the Swedish Total Population Registry. They calculated the cumulative incidence of fractures and accounted for competing risks, such as death or liver transportation.

Overall, 48,635 fractures occurred during 3.4 million person-years of follow-up, including 3,659 (14.6%) among patients and 44,976 (18.8%) among controls.

Patients with alcohol-related cirrhosis had a 3.8-times higher fracture rate, with 38.7 fractures per 1,000 person-years, compared with 13.3 in controls. Alcohol-related cirrhosis was also associated with a 1.9-times higher fracture rate than nonalcoholic cirrhosis and a 1.3-times higher fracture rate than noncirrhotic alcohol-related liver disease.

The cumulative incidence of fractures was elevated for patients with alcohol-related cirrhosis in the first 19 years of follow-up, with a 5-year risk at nearly 10%, compared with 4.5% for controls, and a 10-year risk of 13.5%, compared with 8.7% for controls.

Among those with a fracture, the median time to death was 2.8 years in patients with alcohol-related cirrhosis and 3.5 years in controls.

Patients with alcohol-related cirrhosis had a 1.6-times higher post-fracture mortality rate at 30 days, as well as a 1.8-times higher post-fracture mortality rate after one year.

“Falls and fractures kill patients with cirrhosis. Data like these are crucial to spread awareness and represent a call to arms,” Elliot Tapper, MD, an assistant professor of gastroenterology at the University of Michigan, Ann Arbor, told this news organization.

Dr. Tapper, who wasn’t involved with this study, researches the health outcomes of patients with cirrhosis. His previous studies have found that falls, injuries, and death are common in patients with cirrhosis, which could be predicted with an algorithm based on a prior history of falls, blood sodium level, mobility, and quality of life.

“The data emphasize that a fall and fracture herald a time of increased risk,” he said. “Research is needed to develop interventions that prevent falls and help patients remain more resilient when they happen.”
 

Promoting bone health

Osteoporosis was the most common presumed mechanism in both patients with alcohol-related cirrhosis (49.4%) and controls (52.2%), while high-energy trauma from motor vehicle crashes or heights preceded 10.9% of fractures in patients and 13.5% in controls.

The Karolinska Institute study found that patients with alcohol-related cirrhosis had a 4.4-times higher rate of osteoporotic fracture than controls, which remained 3.6-times higher when using a stricter definition of osteoporotic fracture (a diagnosis of osteoporosis before, at, or within 3 months from the date of a fracture of the vertebrae, pelvis, proximal humerus, distal forearm, or hip).

Patients with osteoporosis at baseline had a 2.5-times higher incidence of fractures than controls with baseline osteoporosis. The absolute risk of fractures in patients with alcohol-related cirrhosis and osteoporosis was higher than for controls with osteoporosis during the first 3 years after a cirrhosis diagnosis.

In addition, the post-fracture mortality rate in those with osteoporosis was more than double in patients with cirrhosis in the first 30 days after a fracture and more than tripled after one year.

“Bone health isn’t necessarily prioritized for our patients, even though it is linked to higher mortality and disability,” Arpan Patel, MD, PhD, a hepatologist at the West Los Angeles VA Medical Center and assistant professor at the David Geffen School of Medicine at the University of California, Los Angeles, told this news organization.

Dr. Patel, who wasn’t involved with this study, has researched the associations between osteoporotic fracture risk, hospitalization, and death in patients with cirrhosis.

“Current guidelines support assessing post-liver transplant patients for bone density but do not currently advocate for doing so in patients with cirrhosis or alcohol-associated liver disease, who are a much larger at-risk population,” Dr. Patel said.

“The current paper supports the idea that we should consider the broad ramifications of alcohol use on bone health for our patients and suggests that there should be greater efforts to screen for and manage osteoporosis and osteopenia in our patients earlier,” he added.

The researchers were supported by grants from Region Stockholm and the Syskonen Svensson Foundation, though the funders had no role in the conduct of the study. The study authors reported no other disclosures or conflicts of interest. Dr. Tapper and Dr. Patel report no relevant financial relationships. 

A version of this article first appeared on Medscape.com.

Patients with alcohol-related cirrhosis have a higher fracture rate and a higher post-fracture mortality rate, compared with the general population, according to a large new study from Sweden.

Alcohol-related cirrhosis was associated with an almost fourfold increased fracture rate, and the post-fracture mortality rates were higher at both 30 days and 1 year later.

“Half of all fractures were presumably associated with osteoporosis,” write the study authors, who are gastroenterologists and epidemiologists at the Karolinska Institute, Stockholm. “This suggests that existing pharmacotherapy for osteoporosis may reduce the fracture risk in patients with alcohol-related cirrhosis and possibly also reduce mortality rates.”

But, the authors continue, “our data indicate that osteoporosis may not be the only explanatory factor for this increased fracture risk. Removing modifiable risk factors such as smoking, heavy alcohol use, or malnutrition may further reduce the risk of fractures.”

The study was published online in Clinical Gastroenterology and Hepatology.
 

Analyzing risks

The association between liver cirrhosis and fractures appears strongest in patients with alcohol-related cirrhosis, the most common cause of cirrhosis in many countries, including Sweden, the authors write.

Previous studies have examined mostly relative risk or hip fractures. The authors aimed to determine not only the relative risk but also the absolute risk, which “can better inform clinicians and policymakers of the actual size of the problem,” they write.

In a nationwide population-based cohort study, they analyzed data from the Swedish National Patient Registry between 1969 and 2016, which included 25,090 patients with alcohol-related cirrhosis. Patients were matched for sex, age, and municipality with 239,458 controls from the Swedish Total Population Registry. They calculated the cumulative incidence of fractures and accounted for competing risks, such as death or liver transportation.

Overall, 48,635 fractures occurred during 3.4 million person-years of follow-up, including 3,659 (14.6%) among patients and 44,976 (18.8%) among controls.

Patients with alcohol-related cirrhosis had a 3.8-times higher fracture rate, with 38.7 fractures per 1,000 person-years, compared with 13.3 in controls. Alcohol-related cirrhosis was also associated with a 1.9-times higher fracture rate than nonalcoholic cirrhosis and a 1.3-times higher fracture rate than noncirrhotic alcohol-related liver disease.

The cumulative incidence of fractures was elevated for patients with alcohol-related cirrhosis in the first 19 years of follow-up, with a 5-year risk at nearly 10%, compared with 4.5% for controls, and a 10-year risk of 13.5%, compared with 8.7% for controls.

Among those with a fracture, the median time to death was 2.8 years in patients with alcohol-related cirrhosis and 3.5 years in controls.

Patients with alcohol-related cirrhosis had a 1.6-times higher post-fracture mortality rate at 30 days, as well as a 1.8-times higher post-fracture mortality rate after one year.

“Falls and fractures kill patients with cirrhosis. Data like these are crucial to spread awareness and represent a call to arms,” Elliot Tapper, MD, an assistant professor of gastroenterology at the University of Michigan, Ann Arbor, told this news organization.

Dr. Tapper, who wasn’t involved with this study, researches the health outcomes of patients with cirrhosis. His previous studies have found that falls, injuries, and death are common in patients with cirrhosis, which could be predicted with an algorithm based on a prior history of falls, blood sodium level, mobility, and quality of life.

“The data emphasize that a fall and fracture herald a time of increased risk,” he said. “Research is needed to develop interventions that prevent falls and help patients remain more resilient when they happen.”
 

Promoting bone health

Osteoporosis was the most common presumed mechanism in both patients with alcohol-related cirrhosis (49.4%) and controls (52.2%), while high-energy trauma from motor vehicle crashes or heights preceded 10.9% of fractures in patients and 13.5% in controls.

The Karolinska Institute study found that patients with alcohol-related cirrhosis had a 4.4-times higher rate of osteoporotic fracture than controls, which remained 3.6-times higher when using a stricter definition of osteoporotic fracture (a diagnosis of osteoporosis before, at, or within 3 months from the date of a fracture of the vertebrae, pelvis, proximal humerus, distal forearm, or hip).

Patients with osteoporosis at baseline had a 2.5-times higher incidence of fractures than controls with baseline osteoporosis. The absolute risk of fractures in patients with alcohol-related cirrhosis and osteoporosis was higher than for controls with osteoporosis during the first 3 years after a cirrhosis diagnosis.

In addition, the post-fracture mortality rate in those with osteoporosis was more than double in patients with cirrhosis in the first 30 days after a fracture and more than tripled after one year.

“Bone health isn’t necessarily prioritized for our patients, even though it is linked to higher mortality and disability,” Arpan Patel, MD, PhD, a hepatologist at the West Los Angeles VA Medical Center and assistant professor at the David Geffen School of Medicine at the University of California, Los Angeles, told this news organization.

Dr. Patel, who wasn’t involved with this study, has researched the associations between osteoporotic fracture risk, hospitalization, and death in patients with cirrhosis.

“Current guidelines support assessing post-liver transplant patients for bone density but do not currently advocate for doing so in patients with cirrhosis or alcohol-associated liver disease, who are a much larger at-risk population,” Dr. Patel said.

“The current paper supports the idea that we should consider the broad ramifications of alcohol use on bone health for our patients and suggests that there should be greater efforts to screen for and manage osteoporosis and osteopenia in our patients earlier,” he added.

The researchers were supported by grants from Region Stockholm and the Syskonen Svensson Foundation, though the funders had no role in the conduct of the study. The study authors reported no other disclosures or conflicts of interest. Dr. Tapper and Dr. Patel report no relevant financial relationships. 

A version of this article first appeared on Medscape.com.

Patients with alcohol-related cirrhosis have a higher fracture rate and a higher post-fracture mortality rate, compared with the general population, according to a large new study from Sweden.

Alcohol-related cirrhosis was associated with an almost fourfold increased fracture rate, and the post-fracture mortality rates were higher at both 30 days and 1 year later.

“Half of all fractures were presumably associated with osteoporosis,” write the study authors, who are gastroenterologists and epidemiologists at the Karolinska Institute, Stockholm. “This suggests that existing pharmacotherapy for osteoporosis may reduce the fracture risk in patients with alcohol-related cirrhosis and possibly also reduce mortality rates.”

But, the authors continue, “our data indicate that osteoporosis may not be the only explanatory factor for this increased fracture risk. Removing modifiable risk factors such as smoking, heavy alcohol use, or malnutrition may further reduce the risk of fractures.”

The study was published online in Clinical Gastroenterology and Hepatology.
 

Analyzing risks

The association between liver cirrhosis and fractures appears strongest in patients with alcohol-related cirrhosis, the most common cause of cirrhosis in many countries, including Sweden, the authors write.

Previous studies have examined mostly relative risk or hip fractures. The authors aimed to determine not only the relative risk but also the absolute risk, which “can better inform clinicians and policymakers of the actual size of the problem,” they write.

In a nationwide population-based cohort study, they analyzed data from the Swedish National Patient Registry between 1969 and 2016, which included 25,090 patients with alcohol-related cirrhosis. Patients were matched for sex, age, and municipality with 239,458 controls from the Swedish Total Population Registry. They calculated the cumulative incidence of fractures and accounted for competing risks, such as death or liver transportation.

Overall, 48,635 fractures occurred during 3.4 million person-years of follow-up, including 3,659 (14.6%) among patients and 44,976 (18.8%) among controls.

Patients with alcohol-related cirrhosis had a 3.8-times higher fracture rate, with 38.7 fractures per 1,000 person-years, compared with 13.3 in controls. Alcohol-related cirrhosis was also associated with a 1.9-times higher fracture rate than nonalcoholic cirrhosis and a 1.3-times higher fracture rate than noncirrhotic alcohol-related liver disease.

The cumulative incidence of fractures was elevated for patients with alcohol-related cirrhosis in the first 19 years of follow-up, with a 5-year risk at nearly 10%, compared with 4.5% for controls, and a 10-year risk of 13.5%, compared with 8.7% for controls.

Among those with a fracture, the median time to death was 2.8 years in patients with alcohol-related cirrhosis and 3.5 years in controls.

Patients with alcohol-related cirrhosis had a 1.6-times higher post-fracture mortality rate at 30 days, as well as a 1.8-times higher post-fracture mortality rate after one year.

“Falls and fractures kill patients with cirrhosis. Data like these are crucial to spread awareness and represent a call to arms,” Elliot Tapper, MD, an assistant professor of gastroenterology at the University of Michigan, Ann Arbor, told this news organization.

Dr. Tapper, who wasn’t involved with this study, researches the health outcomes of patients with cirrhosis. His previous studies have found that falls, injuries, and death are common in patients with cirrhosis, which could be predicted with an algorithm based on a prior history of falls, blood sodium level, mobility, and quality of life.

“The data emphasize that a fall and fracture herald a time of increased risk,” he said. “Research is needed to develop interventions that prevent falls and help patients remain more resilient when they happen.”
 

Promoting bone health

Osteoporosis was the most common presumed mechanism in both patients with alcohol-related cirrhosis (49.4%) and controls (52.2%), while high-energy trauma from motor vehicle crashes or heights preceded 10.9% of fractures in patients and 13.5% in controls.

The Karolinska Institute study found that patients with alcohol-related cirrhosis had a 4.4-times higher rate of osteoporotic fracture than controls, which remained 3.6-times higher when using a stricter definition of osteoporotic fracture (a diagnosis of osteoporosis before, at, or within 3 months from the date of a fracture of the vertebrae, pelvis, proximal humerus, distal forearm, or hip).

Patients with osteoporosis at baseline had a 2.5-times higher incidence of fractures than controls with baseline osteoporosis. The absolute risk of fractures in patients with alcohol-related cirrhosis and osteoporosis was higher than for controls with osteoporosis during the first 3 years after a cirrhosis diagnosis.

In addition, the post-fracture mortality rate in those with osteoporosis was more than double in patients with cirrhosis in the first 30 days after a fracture and more than tripled after one year.

“Bone health isn’t necessarily prioritized for our patients, even though it is linked to higher mortality and disability,” Arpan Patel, MD, PhD, a hepatologist at the West Los Angeles VA Medical Center and assistant professor at the David Geffen School of Medicine at the University of California, Los Angeles, told this news organization.

Dr. Patel, who wasn’t involved with this study, has researched the associations between osteoporotic fracture risk, hospitalization, and death in patients with cirrhosis.

“Current guidelines support assessing post-liver transplant patients for bone density but do not currently advocate for doing so in patients with cirrhosis or alcohol-associated liver disease, who are a much larger at-risk population,” Dr. Patel said.

“The current paper supports the idea that we should consider the broad ramifications of alcohol use on bone health for our patients and suggests that there should be greater efforts to screen for and manage osteoporosis and osteopenia in our patients earlier,” he added.

The researchers were supported by grants from Region Stockholm and the Syskonen Svensson Foundation, though the funders had no role in the conduct of the study. The study authors reported no other disclosures or conflicts of interest. Dr. Tapper and Dr. Patel report no relevant financial relationships. 

A version of this article first appeared on Medscape.com.

Ongoing follow-up and lifestyle interventions are needed in lean patients with nonalcoholic fatty liver disease (NAFLD), suggests a panel of experts in a recent review.

They also urge screening for NAFLD in individuals who are older than 40 years with type 2 diabetes, even if they are not overweight.

NAFLD is a leading cause of chronic liver disease that affects more than 25% of the United States and worldwide populations, note lead author Michelle T. Long, MD, Boston Medical Center, Boston University, and colleagues.

Evidence-based approaches

The 15 best practice advice statements covered a wide range of clinical areas, first defining lean as a body mass index (BMI) less than 25 in non-Asian persons and less than 23 in Asian persons.

The authors go on to stipulate, for example, that lean individuals in the general population should not be screened for NAFLD but that screening should be considered for individuals older than 40 years with type 2 diabetes.

More broadly, they write that the condition should be considered in lean individuals with metabolic diseases, such as type 2 diabetes, dyslipidemia, and hypertension, as well as elevated values on liver biochemical tests or incidentally noted hepatic steatosis.

After other causes of liver diseases are ruled out, the authors note that clinicians should consider liver biopsy as the reference test if uncertainties remain about liver injury causes and/or liver fibrosis staging.

They also write that the NAFLD fibrosis score and Fibrosis-4 score, along with imaging techniques, may be used as alternatives to biopsy for staging and during follow-up.

The authors, who provide a diagnosis and management algorithm to aid clinicians, suggest that lean patients with NAFLD follow lifestyle interventions, such as exercise, diet modification, and avoidance of fructose- and sugar-sweetened drinks, to achieve weight loss of 3%-5%.

Vitamin E may be considered, they continue, in patients with biopsy-confirmed nonalcoholic steatohepatitis but without type 2 diabetes or cirrhosis. Additionally, oral pioglitazone may be considered in lean persons with biopsy-confirmed nonalcoholic steatohepatitis without cirrhosis.

In contrast, they write that the role of glucagonlike peptide 1 agonists and sodium-glucose cotransporter 2 inhibitors requires further investigation.

The advice also says that lean patients with NAFLD should be routinely evaluated for comorbid conditions, such as type 2 diabetes, dyslipidemia, and hypertension, and risk-stratified for hepatic fibrosis to identify those with advanced fibrosis or cirrhosis.

For lean patients with NAFLD and clinical markers compatible with liver cirrhosis, twice-yearly surveillance for hepatocellular carcinoma is also advised.

Fatty liver disease in lean people with metabolic conditions

Approached for comment, Liyun Yuan, MD, PhD, assistant professor of clinical medicine, University of Southern California, Los Angeles, said it is very important to have uniform guidelines for general practitioners and other specialties on NAFLD in lean individuals.

Dr. Yuan, who was not involved in the review, told this news organization that it is crucial to raise awareness of NAFLD, just like awareness of breast cancer screening among women of a certain age was increased, so that individuals are screened for metabolic conditions regardless of whether they have obesity or overweight.

Zobair Younossi, MD, MPH, professor of medicine, Virginia Commonwealth University, Inova Campus, Falls Church, Va., added that there is a lack of awareness that NAFLD occurs in lean individuals, especially in those who have diabetes.

He said in an interview that although it is accurate to define individuals as being lean in terms of their BMI, the best way is to look not only at BMI but also at waist circumference.

Dr. Younossi said that he and his colleagues have shown that when BMI is combined with waist circumference, the prediction of mortality risk in NAFLD is affected, such that lean individuals with an obese waist circumference have a higher risk for all-cause mortality.

Dr. Long is supported in part by the National Institute of Diabetes and Digestive and Kidney Diseases, Doris Duke Charitable Foundation, Gilead Sciences Research Scholars Award, Boston University School of Medicine Department of Medicine Career Investment Award, and Boston University Clinical Translational Science Institute. Dr. Long declares relationships with Novo Nordisk, Echosens Corporation, and Gilead Sciences. Dr. Yuan declares relationships with Genfit, Intercept, and Gilead Sciences. Dr. Younossi declares no relevant relationships.

A version of this article first appeared on Medscape.com.

*This article was updated on July 27, 2022.

Ongoing follow-up and lifestyle interventions are needed in lean patients with nonalcoholic fatty liver disease (NAFLD), suggests a panel of experts in a recent review.

They also urge screening for NAFLD in individuals who are older than 40 years with type 2 diabetes, even if they are not overweight.

NAFLD is a leading cause of chronic liver disease that affects more than 25% of the United States and worldwide populations, note lead author Michelle T. Long, MD, Boston Medical Center, Boston University, and colleagues.

Evidence-based approaches

The 15 best practice advice statements covered a wide range of clinical areas, first defining lean as a body mass index (BMI) less than 25 in non-Asian persons and less than 23 in Asian persons.

The authors go on to stipulate, for example, that lean individuals in the general population should not be screened for NAFLD but that screening should be considered for individuals older than 40 years with type 2 diabetes.

More broadly, they write that the condition should be considered in lean individuals with metabolic diseases, such as type 2 diabetes, dyslipidemia, and hypertension, as well as elevated values on liver biochemical tests or incidentally noted hepatic steatosis.

After other causes of liver diseases are ruled out, the authors note that clinicians should consider liver biopsy as the reference test if uncertainties remain about liver injury causes and/or liver fibrosis staging.

They also write that the NAFLD fibrosis score and Fibrosis-4 score, along with imaging techniques, may be used as alternatives to biopsy for staging and during follow-up.

The authors, who provide a diagnosis and management algorithm to aid clinicians, suggest that lean patients with NAFLD follow lifestyle interventions, such as exercise, diet modification, and avoidance of fructose- and sugar-sweetened drinks, to achieve weight loss of 3%-5%.

Vitamin E may be considered, they continue, in patients with biopsy-confirmed nonalcoholic steatohepatitis but without type 2 diabetes or cirrhosis. Additionally, oral pioglitazone may be considered in lean persons with biopsy-confirmed nonalcoholic steatohepatitis without cirrhosis.

In contrast, they write that the role of glucagonlike peptide 1 agonists and sodium-glucose cotransporter 2 inhibitors requires further investigation.

The advice also says that lean patients with NAFLD should be routinely evaluated for comorbid conditions, such as type 2 diabetes, dyslipidemia, and hypertension, and risk-stratified for hepatic fibrosis to identify those with advanced fibrosis or cirrhosis.

For lean patients with NAFLD and clinical markers compatible with liver cirrhosis, twice-yearly surveillance for hepatocellular carcinoma is also advised.

Fatty liver disease in lean people with metabolic conditions

Approached for comment, Liyun Yuan, MD, PhD, assistant professor of clinical medicine, University of Southern California, Los Angeles, said it is very important to have uniform guidelines for general practitioners and other specialties on NAFLD in lean individuals.

Dr. Yuan, who was not involved in the review, told this news organization that it is crucial to raise awareness of NAFLD, just like awareness of breast cancer screening among women of a certain age was increased, so that individuals are screened for metabolic conditions regardless of whether they have obesity or overweight.

Zobair Younossi, MD, MPH, professor of medicine, Virginia Commonwealth University, Inova Campus, Falls Church, Va., added that there is a lack of awareness that NAFLD occurs in lean individuals, especially in those who have diabetes.

He said in an interview that although it is accurate to define individuals as being lean in terms of their BMI, the best way is to look not only at BMI but also at waist circumference.

Dr. Younossi said that he and his colleagues have shown that when BMI is combined with waist circumference, the prediction of mortality risk in NAFLD is affected, such that lean individuals with an obese waist circumference have a higher risk for all-cause mortality.

Dr. Long is supported in part by the National Institute of Diabetes and Digestive and Kidney Diseases, Doris Duke Charitable Foundation, Gilead Sciences Research Scholars Award, Boston University School of Medicine Department of Medicine Career Investment Award, and Boston University Clinical Translational Science Institute. Dr. Long declares relationships with Novo Nordisk, Echosens Corporation, and Gilead Sciences. Dr. Yuan declares relationships with Genfit, Intercept, and Gilead Sciences. Dr. Younossi declares no relevant relationships.

A version of this article first appeared on Medscape.com.

*This article was updated on July 27, 2022.

Ongoing follow-up and lifestyle interventions are needed in lean patients with nonalcoholic fatty liver disease (NAFLD), suggests a panel of experts in a recent review.

They also urge screening for NAFLD in individuals who are older than 40 years with type 2 diabetes, even if they are not overweight.

NAFLD is a leading cause of chronic liver disease that affects more than 25% of the United States and worldwide populations, note lead author Michelle T. Long, MD, Boston Medical Center, Boston University, and colleagues.

Evidence-based approaches

The 15 best practice advice statements covered a wide range of clinical areas, first defining lean as a body mass index (BMI) less than 25 in non-Asian persons and less than 23 in Asian persons.

The authors go on to stipulate, for example, that lean individuals in the general population should not be screened for NAFLD but that screening should be considered for individuals older than 40 years with type 2 diabetes.

More broadly, they write that the condition should be considered in lean individuals with metabolic diseases, such as type 2 diabetes, dyslipidemia, and hypertension, as well as elevated values on liver biochemical tests or incidentally noted hepatic steatosis.

After other causes of liver diseases are ruled out, the authors note that clinicians should consider liver biopsy as the reference test if uncertainties remain about liver injury causes and/or liver fibrosis staging.

They also write that the NAFLD fibrosis score and Fibrosis-4 score, along with imaging techniques, may be used as alternatives to biopsy for staging and during follow-up.

The authors, who provide a diagnosis and management algorithm to aid clinicians, suggest that lean patients with NAFLD follow lifestyle interventions, such as exercise, diet modification, and avoidance of fructose- and sugar-sweetened drinks, to achieve weight loss of 3%-5%.

Vitamin E may be considered, they continue, in patients with biopsy-confirmed nonalcoholic steatohepatitis but without type 2 diabetes or cirrhosis. Additionally, oral pioglitazone may be considered in lean persons with biopsy-confirmed nonalcoholic steatohepatitis without cirrhosis.

In contrast, they write that the role of glucagonlike peptide 1 agonists and sodium-glucose cotransporter 2 inhibitors requires further investigation.

The advice also says that lean patients with NAFLD should be routinely evaluated for comorbid conditions, such as type 2 diabetes, dyslipidemia, and hypertension, and risk-stratified for hepatic fibrosis to identify those with advanced fibrosis or cirrhosis.

For lean patients with NAFLD and clinical markers compatible with liver cirrhosis, twice-yearly surveillance for hepatocellular carcinoma is also advised.

Fatty liver disease in lean people with metabolic conditions

Approached for comment, Liyun Yuan, MD, PhD, assistant professor of clinical medicine, University of Southern California, Los Angeles, said it is very important to have uniform guidelines for general practitioners and other specialties on NAFLD in lean individuals.

Dr. Yuan, who was not involved in the review, told this news organization that it is crucial to raise awareness of NAFLD, just like awareness of breast cancer screening among women of a certain age was increased, so that individuals are screened for metabolic conditions regardless of whether they have obesity or overweight.

Zobair Younossi, MD, MPH, professor of medicine, Virginia Commonwealth University, Inova Campus, Falls Church, Va., added that there is a lack of awareness that NAFLD occurs in lean individuals, especially in those who have diabetes.

He said in an interview that although it is accurate to define individuals as being lean in terms of their BMI, the best way is to look not only at BMI but also at waist circumference.

Dr. Younossi said that he and his colleagues have shown that when BMI is combined with waist circumference, the prediction of mortality risk in NAFLD is affected, such that lean individuals with an obese waist circumference have a higher risk for all-cause mortality.

Dr. Long is supported in part by the National Institute of Diabetes and Digestive and Kidney Diseases, Doris Duke Charitable Foundation, Gilead Sciences Research Scholars Award, Boston University School of Medicine Department of Medicine Career Investment Award, and Boston University Clinical Translational Science Institute. Dr. Long declares relationships with Novo Nordisk, Echosens Corporation, and Gilead Sciences. Dr. Yuan declares relationships with Genfit, Intercept, and Gilead Sciences. Dr. Younossi declares no relevant relationships.

A version of this article first appeared on Medscape.com.

*This article was updated on July 27, 2022.

The global prevalence of fatty liver disease not caused by alcohol is considerably higher than previously estimated and is continuing to increase at an alarming rate, report researchers from Canada.

Their analysis suggests nearly one-third of the global general adult population has nonalcoholic fatty liver disease (NAFLD), with men much more likely to have the disease than women.

“Greater awareness of NAFLD and the development of cost-effective risk stratification strategies are needed to address the growing burden NAFLD,” wrote Abdel-Aziz Shaheen, MBBCh, MSc, and colleagues with the University of Calgary (Alta.).

The study was published online in Lancet Gastroenterology and Hepatology.

NAFLD is the most common liver disease worldwide and a leading cause of liver-related illness and death. Yet, high-quality reports on the epidemiology of NAFLD at a global level are scarce and temporal trends of the NAFLD burden, including by gender, have not been described, until now.

Using MEDLINE, EMBASE, Scopus, and Web of Science, the Calgary team identified reports on NAFLD incidence and prevalence in study populations representative of the general adult population published between the date of database inception to May 25, 2021.

In total, 72 publications, with a sample population of more than 1 million adults from 17 countries, were included in the prevalence analysis, and 16 publications, with a sample population of nearly 382,000 individuals from five countries, were included in the incidence analysis.

By their estimates, the overall global prevalence of NAFLD is 32.4%, with prevalence increasing steadily and significantly over time, from 25.5% in or before 2005 to 37.8% in 2016 or later. The overall prevalence is significantly higher in men than in women (39.7% vs. 25.6%).

These figures contrast with recent meta-analyses and systematic reviews that put the global prevalence of NAFLD at between 25.2% and 29.8%. However, these studies had “considerable” limitations with “potentially biased inferences,” Dr. Shaheen and colleagues noted.

By region, their data put the prevalence of NAFLD at 31.6% in Asia, 32.6% in Europe, 47.8% in North America, and 56.8% in Africa.

Dr. Shaheen and colleagues estimate the overall incidence of NAFLD to be 46.9 cases per 1,000 person-years, with a higher incidence in men than women (70.8 vs. 29.6 cases per 1000 person-years), in line with the gender differences in prevalence.

They caution that there was “considerable” heterogeneity between studies in both NAFLD prevalence and incidence (I₂ = 99.9%) and few “high-quality” studies.

Despite these limitations, Dr. Shaheen and colleagues said the rise in NAFLD prevalence “should drive enhanced awareness of NAFLD at the level of primary care physicians, public health specialists, and health policy makers to encourage the development of more effective preventive policies.”

Funding for the study was provided by the Canadian Institutes of Health. Dr. Shaheen has received research grants from Gilead and Intercept, and honoraria from SCOPE Canada.

A version of this article first appeared on Medscape.com.

The global prevalence of fatty liver disease not caused by alcohol is considerably higher than previously estimated and is continuing to increase at an alarming rate, report researchers from Canada.

Their analysis suggests nearly one-third of the global general adult population has nonalcoholic fatty liver disease (NAFLD), with men much more likely to have the disease than women.

“Greater awareness of NAFLD and the development of cost-effective risk stratification strategies are needed to address the growing burden NAFLD,” wrote Abdel-Aziz Shaheen, MBBCh, MSc, and colleagues with the University of Calgary (Alta.).

The study was published online in Lancet Gastroenterology and Hepatology.

NAFLD is the most common liver disease worldwide and a leading cause of liver-related illness and death. Yet, high-quality reports on the epidemiology of NAFLD at a global level are scarce and temporal trends of the NAFLD burden, including by gender, have not been described, until now.

Using MEDLINE, EMBASE, Scopus, and Web of Science, the Calgary team identified reports on NAFLD incidence and prevalence in study populations representative of the general adult population published between the date of database inception to May 25, 2021.

In total, 72 publications, with a sample population of more than 1 million adults from 17 countries, were included in the prevalence analysis, and 16 publications, with a sample population of nearly 382,000 individuals from five countries, were included in the incidence analysis.

By their estimates, the overall global prevalence of NAFLD is 32.4%, with prevalence increasing steadily and significantly over time, from 25.5% in or before 2005 to 37.8% in 2016 or later. The overall prevalence is significantly higher in men than in women (39.7% vs. 25.6%).

These figures contrast with recent meta-analyses and systematic reviews that put the global prevalence of NAFLD at between 25.2% and 29.8%. However, these studies had “considerable” limitations with “potentially biased inferences,” Dr. Shaheen and colleagues noted.

By region, their data put the prevalence of NAFLD at 31.6% in Asia, 32.6% in Europe, 47.8% in North America, and 56.8% in Africa.

Dr. Shaheen and colleagues estimate the overall incidence of NAFLD to be 46.9 cases per 1,000 person-years, with a higher incidence in men than women (70.8 vs. 29.6 cases per 1000 person-years), in line with the gender differences in prevalence.

They caution that there was “considerable” heterogeneity between studies in both NAFLD prevalence and incidence (I₂ = 99.9%) and few “high-quality” studies.

Despite these limitations, Dr. Shaheen and colleagues said the rise in NAFLD prevalence “should drive enhanced awareness of NAFLD at the level of primary care physicians, public health specialists, and health policy makers to encourage the development of more effective preventive policies.”

Funding for the study was provided by the Canadian Institutes of Health. Dr. Shaheen has received research grants from Gilead and Intercept, and honoraria from SCOPE Canada.

A version of this article first appeared on Medscape.com.

The global prevalence of fatty liver disease not caused by alcohol is considerably higher than previously estimated and is continuing to increase at an alarming rate, report researchers from Canada.

Their analysis suggests nearly one-third of the global general adult population has nonalcoholic fatty liver disease (NAFLD), with men much more likely to have the disease than women.

“Greater awareness of NAFLD and the development of cost-effective risk stratification strategies are needed to address the growing burden NAFLD,” wrote Abdel-Aziz Shaheen, MBBCh, MSc, and colleagues with the University of Calgary (Alta.).

The study was published online in Lancet Gastroenterology and Hepatology.

NAFLD is the most common liver disease worldwide and a leading cause of liver-related illness and death. Yet, high-quality reports on the epidemiology of NAFLD at a global level are scarce and temporal trends of the NAFLD burden, including by gender, have not been described, until now.

Using MEDLINE, EMBASE, Scopus, and Web of Science, the Calgary team identified reports on NAFLD incidence and prevalence in study populations representative of the general adult population published between the date of database inception to May 25, 2021.

In total, 72 publications, with a sample population of more than 1 million adults from 17 countries, were included in the prevalence analysis, and 16 publications, with a sample population of nearly 382,000 individuals from five countries, were included in the incidence analysis.

By their estimates, the overall global prevalence of NAFLD is 32.4%, with prevalence increasing steadily and significantly over time, from 25.5% in or before 2005 to 37.8% in 2016 or later. The overall prevalence is significantly higher in men than in women (39.7% vs. 25.6%).

These figures contrast with recent meta-analyses and systematic reviews that put the global prevalence of NAFLD at between 25.2% and 29.8%. However, these studies had “considerable” limitations with “potentially biased inferences,” Dr. Shaheen and colleagues noted.

By region, their data put the prevalence of NAFLD at 31.6% in Asia, 32.6% in Europe, 47.8% in North America, and 56.8% in Africa.

Dr. Shaheen and colleagues estimate the overall incidence of NAFLD to be 46.9 cases per 1,000 person-years, with a higher incidence in men than women (70.8 vs. 29.6 cases per 1000 person-years), in line with the gender differences in prevalence.

They caution that there was “considerable” heterogeneity between studies in both NAFLD prevalence and incidence (I₂ = 99.9%) and few “high-quality” studies.

Despite these limitations, Dr. Shaheen and colleagues said the rise in NAFLD prevalence “should drive enhanced awareness of NAFLD at the level of primary care physicians, public health specialists, and health policy makers to encourage the development of more effective preventive policies.”

Funding for the study was provided by the Canadian Institutes of Health. Dr. Shaheen has received research grants from Gilead and Intercept, and honoraria from SCOPE Canada.

A version of this article first appeared on Medscape.com.

Past decompensation in alcohol-associated hepatitis may be linked with worse survival following liver transplantation, but it’s not all bad news, according to a retrospective study.

Traditionally, patients with alcoholic liver disease were asked to be alcohol free for 6 months before consideration for a liver transplantation. In recent years, there’s been a loosening of that policy, with physicians considering “early” liver transplantation (early LT) instead of waiting 6 months. “It became obvious that a lot of patients do resume alcohol use after transplant, and most of them don’t appear to suffer too much in the way of adverse consequences,” said Paul Martin, MD, chief of hepatology at the University of Miami, who was not involved in the current research.

In 2011, a study confirmed that suspicion, finding that 6-month survival was 77% among carefully selected patients with alcohol-associated hepatitis for whom the 6-month sobriety requirement was waived; 6-month survival in those who did not receive a transplant was 22%. The selection criteria included the presence of supportive family members, the absence of severe coexisting conditions, and a commitment to abstaining from alcohol.

Sebastian Kaulitzki/Science Photo Library

However, authors of the current study, published in the American Journal of Gastroenterology sought nuance: The appropriateness of prior decompensation as exclusion criteria in published studies is unknown, so the researchers compared outcomes of patients with prior versus first-time liver decompensation in alcohol-associated hepatitis.
 

Not all bad news

The study included 241 patients from six sites who consecutively received early LT between 2007 and 2020. Among these, 210 were identified as having a first-time liver decompensation event and 31 as having had a prior history of liver decompensation, defined as being diagnosed with ascites, hepatic encephalopathy, variceal bleeding, or jaundice.

There was no significant difference in median age, Model for End-Stage Liver Disease (MELD) scores, or post–liver transplant follow-up time between those with first-time liver decompensation or a prior history. The unadjusted 1-year survival rate was 93% in the first decompensation group (95% confidence interval, 89%-96%) and 86% in the prior decompensation group (95% CI, 66%-94%). The unadjusted 3-year survival rates were 85% (95% CI, 79%-90%) and 78% (95% CI, 57%-89%), respectively.

Importantly, the researchers found an association between prior decompensation and higher adjusted post–liver transplantation mortality (adjusted hazard ratio, 2.72; 95% CI, 1.61-4.59) and harmful alcohol use (aHR, 1.77; 95% CI, 1.07-2.92).

However, the researchers noted that these patients, who had MELD scores of 39 and previous decompensation, were at exceptionally high risk of short-term mortality, but still had 1- and 3-year survival rates above 85% and 75%, respectively, with early LT. “While longer follow-up is desirable as graft failure related to alcohol is most apparent after 5-years post LT, these results suggest that prior decompensation alone should not be considered an absolute contraindication to early LT.”

Limitations of the study included its retrospective data and small sample size for patients with prior decompensation.

“These findings validate the value of the ‘first decompensation’ criteria in published experiences regarding early LT for [alcoholic hepatitis],” the investigators concluded. “Further larger and prospective studies with longer-term follow-up will be needed to assess ways to optimally select patients in this cohort who may benefit most from early LT, and ways to manage patients at highest risk for worse outcomes post LT.”
 

A note of caution for early LT

About half of all liver mortality is attributable to alcoholic-associated liver disease. Corticosteroids can improve short-term survival, but there are no medications proven to increase long-term survival. That leaves liver transplant as the sole alternative for patients who don’t respond to corticosteroids.

“Programs in North America have liberalized their acceptance criteria for patients with alcoholic liver disease, and that’s resulted in large numbers of patients being transplanted who have less than 6 months abstinence. And overall, the results seem good, but I think this paper strikes an appropriate note of caution. In essence, if a patient had at least one prior episode of liver failure related to alcoholic excess and had recovered from that, and continued to drink and got into trouble again, [and then] presented for consideration for liver transplantation, the fact that they resumed alcohol use after prior episodes of decompensation suggests that they may be less-than-ideal candidates [for liver transplantation],” said Dr. Martin.

He pointed out important caveats to the study, including its retrospective nature and its inclusion of a relatively small number of patients with a history of liver decompensation. But it reinforces what physicians generally know, which is that some patients with severe alcohol use disorder also have liver failure, and they tend to fare worse than others after a liver transplant.

Still, physicians also face a conundrum because there are increasing numbers of younger patients who won’t survive if they don’t get a liver transplant. “The challenge is picking out patients who are going to be good candidates from a purely medical point of view, but have a low likelihood of resuming alcohol use after transplantation [which could injure] the new liver,” said Dr. Martin. The new study has the potential to provide some additional guidance in patient selection.

The study authors disclosed no relevant conflicts of interest. Dr. Martin has no relevant financial disclosures.

Past decompensation in alcohol-associated hepatitis may be linked with worse survival following liver transplantation, but it’s not all bad news, according to a retrospective study.

Traditionally, patients with alcoholic liver disease were asked to be alcohol free for 6 months before consideration for a liver transplantation. In recent years, there’s been a loosening of that policy, with physicians considering “early” liver transplantation (early LT) instead of waiting 6 months. “It became obvious that a lot of patients do resume alcohol use after transplant, and most of them don’t appear to suffer too much in the way of adverse consequences,” said Paul Martin, MD, chief of hepatology at the University of Miami, who was not involved in the current research.

In 2011, a study confirmed that suspicion, finding that 6-month survival was 77% among carefully selected patients with alcohol-associated hepatitis for whom the 6-month sobriety requirement was waived; 6-month survival in those who did not receive a transplant was 22%. The selection criteria included the presence of supportive family members, the absence of severe coexisting conditions, and a commitment to abstaining from alcohol.

Sebastian Kaulitzki/Science Photo Library

However, authors of the current study, published in the American Journal of Gastroenterology sought nuance: The appropriateness of prior decompensation as exclusion criteria in published studies is unknown, so the researchers compared outcomes of patients with prior versus first-time liver decompensation in alcohol-associated hepatitis.
 

Not all bad news

The study included 241 patients from six sites who consecutively received early LT between 2007 and 2020. Among these, 210 were identified as having a first-time liver decompensation event and 31 as having had a prior history of liver decompensation, defined as being diagnosed with ascites, hepatic encephalopathy, variceal bleeding, or jaundice.

There was no significant difference in median age, Model for End-Stage Liver Disease (MELD) scores, or post–liver transplant follow-up time between those with first-time liver decompensation or a prior history. The unadjusted 1-year survival rate was 93% in the first decompensation group (95% confidence interval, 89%-96%) and 86% in the prior decompensation group (95% CI, 66%-94%). The unadjusted 3-year survival rates were 85% (95% CI, 79%-90%) and 78% (95% CI, 57%-89%), respectively.

Importantly, the researchers found an association between prior decompensation and higher adjusted post–liver transplantation mortality (adjusted hazard ratio, 2.72; 95% CI, 1.61-4.59) and harmful alcohol use (aHR, 1.77; 95% CI, 1.07-2.92).

However, the researchers noted that these patients, who had MELD scores of 39 and previous decompensation, were at exceptionally high risk of short-term mortality, but still had 1- and 3-year survival rates above 85% and 75%, respectively, with early LT. “While longer follow-up is desirable as graft failure related to alcohol is most apparent after 5-years post LT, these results suggest that prior decompensation alone should not be considered an absolute contraindication to early LT.”

Limitations of the study included its retrospective data and small sample size for patients with prior decompensation.

“These findings validate the value of the ‘first decompensation’ criteria in published experiences regarding early LT for [alcoholic hepatitis],” the investigators concluded. “Further larger and prospective studies with longer-term follow-up will be needed to assess ways to optimally select patients in this cohort who may benefit most from early LT, and ways to manage patients at highest risk for worse outcomes post LT.”
 

A note of caution for early LT

About half of all liver mortality is attributable to alcoholic-associated liver disease. Corticosteroids can improve short-term survival, but there are no medications proven to increase long-term survival. That leaves liver transplant as the sole alternative for patients who don’t respond to corticosteroids.

“Programs in North America have liberalized their acceptance criteria for patients with alcoholic liver disease, and that’s resulted in large numbers of patients being transplanted who have less than 6 months abstinence. And overall, the results seem good, but I think this paper strikes an appropriate note of caution. In essence, if a patient had at least one prior episode of liver failure related to alcoholic excess and had recovered from that, and continued to drink and got into trouble again, [and then] presented for consideration for liver transplantation, the fact that they resumed alcohol use after prior episodes of decompensation suggests that they may be less-than-ideal candidates [for liver transplantation],” said Dr. Martin.

He pointed out important caveats to the study, including its retrospective nature and its inclusion of a relatively small number of patients with a history of liver decompensation. But it reinforces what physicians generally know, which is that some patients with severe alcohol use disorder also have liver failure, and they tend to fare worse than others after a liver transplant.

Still, physicians also face a conundrum because there are increasing numbers of younger patients who won’t survive if they don’t get a liver transplant. “The challenge is picking out patients who are going to be good candidates from a purely medical point of view, but have a low likelihood of resuming alcohol use after transplantation [which could injure] the new liver,” said Dr. Martin. The new study has the potential to provide some additional guidance in patient selection.

The study authors disclosed no relevant conflicts of interest. Dr. Martin has no relevant financial disclosures.

Past decompensation in alcohol-associated hepatitis may be linked with worse survival following liver transplantation, but it’s not all bad news, according to a retrospective study.

Traditionally, patients with alcoholic liver disease were asked to be alcohol free for 6 months before consideration for a liver transplantation. In recent years, there’s been a loosening of that policy, with physicians considering “early” liver transplantation (early LT) instead of waiting 6 months. “It became obvious that a lot of patients do resume alcohol use after transplant, and most of them don’t appear to suffer too much in the way of adverse consequences,” said Paul Martin, MD, chief of hepatology at the University of Miami, who was not involved in the current research.

In 2011, a study confirmed that suspicion, finding that 6-month survival was 77% among carefully selected patients with alcohol-associated hepatitis for whom the 6-month sobriety requirement was waived; 6-month survival in those who did not receive a transplant was 22%. The selection criteria included the presence of supportive family members, the absence of severe coexisting conditions, and a commitment to abstaining from alcohol.

Sebastian Kaulitzki/Science Photo Library

However, authors of the current study, published in the American Journal of Gastroenterology sought nuance: The appropriateness of prior decompensation as exclusion criteria in published studies is unknown, so the researchers compared outcomes of patients with prior versus first-time liver decompensation in alcohol-associated hepatitis.
 

Not all bad news

The study included 241 patients from six sites who consecutively received early LT between 2007 and 2020. Among these, 210 were identified as having a first-time liver decompensation event and 31 as having had a prior history of liver decompensation, defined as being diagnosed with ascites, hepatic encephalopathy, variceal bleeding, or jaundice.

There was no significant difference in median age, Model for End-Stage Liver Disease (MELD) scores, or post–liver transplant follow-up time between those with first-time liver decompensation or a prior history. The unadjusted 1-year survival rate was 93% in the first decompensation group (95% confidence interval, 89%-96%) and 86% in the prior decompensation group (95% CI, 66%-94%). The unadjusted 3-year survival rates were 85% (95% CI, 79%-90%) and 78% (95% CI, 57%-89%), respectively.

Importantly, the researchers found an association between prior decompensation and higher adjusted post–liver transplantation mortality (adjusted hazard ratio, 2.72; 95% CI, 1.61-4.59) and harmful alcohol use (aHR, 1.77; 95% CI, 1.07-2.92).

However, the researchers noted that these patients, who had MELD scores of 39 and previous decompensation, were at exceptionally high risk of short-term mortality, but still had 1- and 3-year survival rates above 85% and 75%, respectively, with early LT. “While longer follow-up is desirable as graft failure related to alcohol is most apparent after 5-years post LT, these results suggest that prior decompensation alone should not be considered an absolute contraindication to early LT.”

Limitations of the study included its retrospective data and small sample size for patients with prior decompensation.

“These findings validate the value of the ‘first decompensation’ criteria in published experiences regarding early LT for [alcoholic hepatitis],” the investigators concluded. “Further larger and prospective studies with longer-term follow-up will be needed to assess ways to optimally select patients in this cohort who may benefit most from early LT, and ways to manage patients at highest risk for worse outcomes post LT.”
 

A note of caution for early LT

About half of all liver mortality is attributable to alcoholic-associated liver disease. Corticosteroids can improve short-term survival, but there are no medications proven to increase long-term survival. That leaves liver transplant as the sole alternative for patients who don’t respond to corticosteroids.

“Programs in North America have liberalized their acceptance criteria for patients with alcoholic liver disease, and that’s resulted in large numbers of patients being transplanted who have less than 6 months abstinence. And overall, the results seem good, but I think this paper strikes an appropriate note of caution. In essence, if a patient had at least one prior episode of liver failure related to alcoholic excess and had recovered from that, and continued to drink and got into trouble again, [and then] presented for consideration for liver transplantation, the fact that they resumed alcohol use after prior episodes of decompensation suggests that they may be less-than-ideal candidates [for liver transplantation],” said Dr. Martin.

He pointed out important caveats to the study, including its retrospective nature and its inclusion of a relatively small number of patients with a history of liver decompensation. But it reinforces what physicians generally know, which is that some patients with severe alcohol use disorder also have liver failure, and they tend to fare worse than others after a liver transplant.

Still, physicians also face a conundrum because there are increasing numbers of younger patients who won’t survive if they don’t get a liver transplant. “The challenge is picking out patients who are going to be good candidates from a purely medical point of view, but have a low likelihood of resuming alcohol use after transplantation [which could injure] the new liver,” said Dr. Martin. The new study has the potential to provide some additional guidance in patient selection.

The study authors disclosed no relevant conflicts of interest. Dr. Martin has no relevant financial disclosures.