Published: 19th July 2021
Researchers find new metabolism process that recycles drug in the gut and liver
The discovery has important implications for scientists trying to understand how both phytochemicals and medicines are metabolised in the body
A team of University of Houston pharmaceutical researchers has reported a newly recognised process of drug metabolism in the intestines, followed by recycling through the liver that could have important implications for developing treatments for intestinal diseases and for taking multiple medications at the same time.
The study was published in the journal eLife. "The intestines play a crucial role in metabolising and recycling certain plant compounds and drugs," said Ming Hu, Diana S L Chow Endowed Professor of Drug Discovery and Development and the senior author of the paper in eLife. "The discovery has important implications for scientists trying to understand how both phytochemicals (a type of plant compound, such as flavonoids) and medicines are metabolized in the body."
The new information could help chemists develop better drugs and clinicians to fine-tune medication dosing, especially when dealing with polypharmacy, where a patient takes multiple drugs at the same time. Scientists have long recognised that bile acid is produced in the liver and released into the intestines and is then recycled back through the liver for reuse as bile. Some medications that are metabolised in the liver also go through this process, known as enterohepatic recycling (EHR). This can extend the life of drugs in the body, which may affect how well they work and whether they cause side effects. "The liver has long been considered the most important organ for drug metabolism," said lead author Yifan Tu, who conducted the study while he was doing his doctoral work at the UH College of Pharmacy. "But we have shown that the intestines also play a major role in drug metabolism."
In their experiments, the team administered 16 different types of flavonoids or drugs directly to the liver or intestines and then tracked what happened to the treatments. They found that some drugs and compounds were metabolized in the intestines and the metabolites were then transported to the liver before being cycled back into the intestines. "In this process, the liver acts only as a recycling organ, which is rare, since the liver is known to be the metabolic 'superstar' organ in humans," said Tu, who is now a postdoctoral fellow at the pharmaceutical company Boehringer Ingelheim in Connecticut.
The team has called this new mechanism 'hepatic enteric recycling' (HER). They found that, in this process, the roles of the liver and intestines are reversed. "This may explain why some drugs or plant compounds have larger effects on the intestine than anticipated and could help scientists understand how intestinal diseases may alter drug metabolism in the body," said Tu. "We hope our findings will be useful for medicinal chemists to design new drugs tailored to treat intestinal, especially colonic diseases," Hu added.