New fatty liver disease treatment could save millions of people worldwide

Scientists at Michigan Medicine have made a significant breakthrough in treating nonalcoholic fatty liver disease (NAFLD), a condition that affects billions worldwide. Their research has led to the development of a promising new drug that could change the treatment landscape for this prevalent disease.

NAFLD is characterized by the accumulation of fat in the liver, which can lead to inflammation and scarring. It is estimated to affect up to 32% of the global population.

When the condition progresses to nonalcoholic steatohepatitis (NASH), it can cause irreversible liver damage. NASH, the more severe form of NAFLD, is estimated to impact around 6.5% of people worldwide, increasing the risk of cirrhosis and liver failure.

Despite the widespread prevalence of NASH, there has been no effective treatment available until now. Many previous drug candidates have failed to demonstrate significant improvements or have raised safety concerns during clinical trials. However, Michigan Medicine researchers have developed a compound that shows strong potential in reversing liver damage caused by NASH.

The breakthrough treatment, known as DT-109, is a glycine-based tripeptide designed to reduce fat accumulation and prevent liver scarring. Researchers tested the compound in both mice and non-human primates, finding that it effectively reversed fat buildup in the liver and prevented further damage.

Dr. Eugene Chen, senior author of the study and Frederick G. L. Huetwell Professor of Cardiovascular Medicine at the University of Michigan Medical School, emphasized the importance of this discovery. He noted that efforts to develop a treatment for NASH have faced numerous setbacks, with many drug candidates failing to meet safety and efficacy standards in clinical trials.

“NASH is rising at a staggering rate, and successful treatment of non-human primates with our drug candidate, DT-109, brings us closer than ever to treating the millions of people suffering from this condition,” said Dr. Chen. His statement highlights the urgency of finding an effective treatment for this growing public health concern.

The development of DT-109 was based on the researchers’ discovery that impaired glycine metabolism is a cause of NAFLD and NASH. While hundreds of compounds have successfully treated NASH in mice, Chen says mouse NASH models are limited because not all aspects of the human disease are accurately mimicked and, therefore, are not easily translatable to the clinic.

The research team’s non-human primate model for NASH, confirmed using multiomics profiling studies, is among the first to accomplish the feat.

In both non-human primates and mice, investigators found that treatment with DT-109 reverses fat buildup and prevents fibrosis progression by stimulating fatty acid degradation and antioxidant formation. The drug also inhibited the production of lithocholic acid, a toxic secondary bile acid closely linked to NAFLD.

“With this significant breakthrough in preclinical models, we can now consider evaluating DT-109 as a potential drug candidate for the treatment of NASH in future clinical trials,” said Jifeng Zhang, Ph.D., co-corresponding author and research associate professor of cardiovascular medicine at Michigan Medicine. “With millions of people suffering from NASH, the need for an effective treatment is more pressing than ever.”

NAFLD is a growing problem around the world, with rates increasing in parallel with the obesity epidemic. The condition is closely linked to metabolic syndrome, which includes obesity, high blood pressure, and insulin resistance. NAFLD can progress to NASH, which is a more severe form of the disease that is associated with inflammation and scarring of the liver.

NASH-related cirrhosis is now one of the most common reasons for liver transplantation, and there are currently no approved treatments for the condition. Lifestyle changes, such as diet and exercise, are recommended for people with NAFLD and NASH, but these changes are often difficult to sustain, and they do not always reverse the damage that has already been done to the liver.

NAFLD and NASH are also closely linked to other health problems, including type 2 diabetes, obesity, and metabolic syndrome. As the prevalence of these conditions increases worldwide, so does the incidence of NAFLD and NASH.

Currently, there are no approved medications for the treatment of NASH. This is partly due to the complex nature of the disease and the fact that it often occurs in people who already have multiple health conditions. In addition, the lack of suitable animal models for NASH has made it difficult to develop and test potential treatments.

The success of DT-109 in non-human primate models is therefore a significant breakthrough for researchers and clinicians working to develop effective treatments for NASH. The compound has shown promising results in reversing fat buildup and preventing scarring in the liver, which are two key features of NASH.

The research team conducted a series of experiments to test the efficacy of DT-109 in non-human primate models of NASH. The animals were treated with the compound for several weeks, and their livers were analyzed for signs of fat buildup, inflammation, and scarring.

The results of the study showed that DT-109 was effective in reversing the damage caused by NASH in both mice and non-human primates. The compound reduced the buildup of fat in the liver and prevented the formation of scar tissue, which can lead to permanent liver damage.

The researchers also found that DT-109 works by stimulating fatty acid degradation and antioxidant formation in the liver. These processes help to break down the excess fat that accumulates in the liver and prevent the development of scar tissue.

In addition, DT-109 was found to inhibit the production of lithocholic acid, a toxic secondary bile acid that is closely linked to the development of NASH. By blocking the production of this compound, DT-109 may help to prevent the progression of the disease and reduce the risk of complications.

The success of DT-109 in non-human primate models of NASH is an important step towards developing an effective treatment for this condition. However, further research is needed to determine the safety and efficacy of the compound in humans.

The researchers plan to conduct clinical trials of DT-109 in the near future to test its effectiveness in humans with NASH. If the trials are successful, DT-109 could become the first approved medication for the treatment of this condition.

The development of DT-109 is an example of the growing importance of precision medicine in healthcare. Precision medicine involves tailoring treatments to the specific needs of individual patients based on their genetic makeup, lifestyle, and other factors.

By developing a compound that targets the specific metabolic pathways involved in the development of NASH, the researchers have taken a step towards precision medicine for this condition. This approach could lead to more effective treatments that are tailored to the individual needs of patients with NASH.

The successful development of DT-109 for the treatment of NASH is a significant breakthrough for researchers and clinicians working to address this growing health problem. NASH is a complex disease that has proven difficult to treat, but the promising results of this study offer hope for millions of people around the world who suffer from this condition.

As further research is conducted, it is possible that DT-109 could become the first approved medication for the treatment of NASH, providing a much-needed option for patients who currently have few treatment options available to them.