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Functional Human Tissue-Engineered Liver Generated from Stem and Progenitor Cells

Liver disease affects pediatric and adult patients, impacting one in ten people in the United States

by Children’s Hospital Los Angeles
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A research team led by investigators at The Saban Research Institute of Children’s Hospital Los Angeles has generated functional human and mouse tissue-engineered liver from adult stem and progenitor cells. Tissue-engineered Liver (TELi) was found to contain normal structural components such as hepatocytes, bile ducts, and blood vessels. The study has been published online in the journal Stem Cells Translational Medicine.

liver organoid units The research team generated liver organoid units (LOU) from human and mouse liver and implanted both varieties of LOU into murine models.Photo courtesy of the Children’s Hospital Los AngelesLiver disease affects pediatric and adult patients, impacting one in ten people in the United States. Liver transplantation is the only effective treatment for end-stage liver disease, but scarcity of available organs and the need for lifelong immunosuppressive medication make this treatment challenging.

Alternate approaches that have been investigated include significant limitations. For example, conventional liver cell transplantation requires scarce donor liver and a perfusion protocol that wastes many cells. This type of cell transplant typically lasts less than one year, with most patients ultimately requiring a liver transplant. Human-induced pluripotent stem (iPS) cells are another possibility but, so far, iPS cells have remained immature rather than developing into functional and proliferative liver cells, called hepatocytes. There continues to be a need for a durable treatment, particularly one that could eliminate the need for immunosuppression.

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“Based on the success in my lab generating tissue-engineered intestine and other cell types, we hypothesized that by modifying the protocol used to generate intestine, we would be able to develop liver organoid units that could generate functional tissue-engineered liver when transplanted,” said Tracy C. Grikscheit, MD, a pediatric surgeon and researcher at The Saban Research Institute of CHLA and co-principal investigator on the study. Grikscheit is also a tenured associate professor of surgery at the Keck School of Medicine of USC.

The research team generated liver organoid units (LOU) from human and mouse liver and implanted both varieties of LOU into murine models. Tissue-engineered liver developed from the human and mouse LOU, with key cell types required for hepatic function including patent bile ducts and blood vessels, hepatocytes, stellate cells, and endothelial cells. However, the cellular organization differed from native liver tissue.

Human albumin, the main type of protein in the blood, was detected in the host mouse serum, indicating in vivo secretory function from the human-derived tissue-engineered liver. In a mouse model of liver failure, tissue-engineered liver was able to provide some hepatic function. In addition, the hepatocytes proliferated in the tissue-engineered liver.

“A cellular therapy for liver disease would be a game-changer for many patients, particularly children with metabolic disorders,” said Kasper S. Wang, MD, a pediatric surgeon and researcher at The Saban Research Institute of CHLA and co-principal investigator on the study. “By demonstrating the ability to generate hepatocytes comparable to those in native liver, and to show that these cells are functional and proliferative, we’ve moved one step closer to that goal.”  Wang is also associate professor of surgery at the Keck School of Medicine of USC and a principal investigator for the national consortium, the Childhood Liver Disease Research and Educational Network.

Additional contributors to the study include Nirmala Mavila, Andrew Trecartin, Ryan Spurrier, Yi Xiao, Xiaogang Hou, David James, Xiaowei Fu, and Clara Wang of Children’s Hospital Los Angeles and Brian Truong and Gerald S. Lipshutz of the David Geffen School of Medicine at UCLA. Funding was provided in part by the National Institutes of Health (1R01NS071076-05A1), California Institute of Regenerative Medicine (TR4-06831), and the European Union (668294).