(LOS ANGELES) – Non-alcoholic fatty liver disease (NAFLD) is the most prevalent chronic liver disease worldwide. It is found in 30% of people in developed countries and occurs in approximately 25% of people in the United States. Risk factors for the disease include obesity, diabetes, high cholesterol and poor eating habits, although this does not exclude individuals without these risk factors.
There is normally a small amount of fat found in the liver; however, if the amount of fat makes up 5% or more of the liver, this is considered to be NAFLD and it must be managed to avoid serious disease progression. In its worst-case scenario, NAFLD can result in swelling and inflammation of the liver, fibrosis, or scarring, of the liver, liver failure or liver cancer.
The liver is a complex organ, and the physiological events involved in NAFLD progression involve multiple steps and different kinds of cells found in the liver. Abnormal accumulation of fatty acids in the liver triggers immune cells called Kupffer cells, as well as endothelial cells lining the liver’s blood vessels, to release both signaling and chemically reactive molecules. These molecules stimulate cells called stellate cells to synthesize and deposit fibrosis proteins, which lead to scar formation in the liver.
NAFLD can be managed by a healthy diet and exercise and by losing and/or controlling weight, but there is currently no definitive treatment or cure. One of the main difficulties in developing treatments is that there are no accurate NAFLD models with which to test treatment efficacy. Animal models do not truly represent the steps involved in human NAFLD and human models developed in the past have also shown limitations. A relatively advanced “artificial fibrosis model” to stimulate the final, fibrosis-development part of the disease sequence has been created, but it did not fully correlate with observations of the full disease progression.
A collaborative team from the Terasaki Institute for Biomedical Innovation (TIBI) has developed an advanced, multicellular, structurally representative liver-on-a-chip model which mimics the full progression sequence of NAFLD. The model contains all four types of human primary cells which are involved in the sequence: Kupffer cells, endothelial cells, stellate cells and hepatocytes.
The cells were mixed together and grown as multicellular microtissues in an array of pyramid-shaped microwells; the cell numbers and proportions were adjusted to yield microtissues of optimum shape to maintain nutrient and oxygen concentrations similar to naturally-occurring liver tissues. The microtissues were then enclosed within a gelatinous substance to enable the tissues to more fully match the structure and cell-to-cell interactions of native liver tissues.
The team used their multicellular liver-on-a-chip model in tests designed to validate the role of stellate cells in NAFLD. They concluded that stellate cells appear to be involved with blood vessel formation, production of chemically reactive compounds and to some degree in fatty acid accumulation. They also concluded that stellate cells may interact with Kupffer and other liver cells to produce certain signaling molecules. All these events are crucial components in full NAFLD progression.
The team also tested the effects of fatty acid addition to their model. The results indicated that the presence of fatty acids and active stellate cells accelerated inflammatory responses and increased the production of fibrotic proteins, further validating the model’s mimicry of the natural progression of NAFLD.
Subsequent tests compared TIBI’s NAFLD model to the previously mentioned artificial fibrosis model driven by transforming growth factor (TGF)-β. When comparing both models, TIBI’s fibrosis model mimicked the natural progression of NAFLD by exhibiting higher levels of fat accumulation and fibrosis molecules than in the artificial fibrosis model.
In addition, the team tested the response to anti-fibrotic drugs in both models. The tests demonstrated that TIBI’s NAFLD model demonstrated a more robust drug transport and metabolic response upon delivery of the drugs. This finding is significant if the model is to be used for screening of potential drugs for the treatment of NAFLD.
“Our multicellular liver-on-a-chip system is a laboratory model that is more advanced and more fully represents the natural progression of NAFLD than in previous models,” said Junmin Lee, Ph.D., a member of the TIBI team. “This is supported by the experimental results from our comparison studies.”
It is the hope that TIBI’s NAFLD model can be used for elucidating the mechanisms behind this disease and for testing possible drug treatments for efficacy. It also has the potential to personalize treatments by obtaining the full array of cells needed from individual patients and using them to create custom disease models.
“The multicellular model described here is an exemplary demonstration of the level of work that we do in developing personalized physiological models,” said Ali Khademhosseini, Ph.D., director and CEO of the Terasaki Institute. “It has the potential for helping to discover treatments for a prevalent and potentially fatal disease.”
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Additional authors are Hyun-Jong Cho, Han-Jun Kim, KangJu Lee, Soufian Lasli, Aly Ung, Tyler Hoffman, Rohollah Nasiri, Praveen Bandaru, Samad Ahadian, Mehmet R Dokmeci and Ali Khademhosseini.
This work was supported by the National Institutes of Health (1UG3TR003148-01 and 1R01GM126571-01) and by the Office of the Secretary of Defense under Agreement Number W911NF-17-3-003. It was also funded in part by the Advanced Regenerative Manufacturing Institute, Inc. (“ARMI”)
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Terasaki Institute for Biomedical Innovation
The Terasaki Institute for Biomedical Innovation (terasaki.org) is a non-profit research organization that invents and fosters practical solutions that restore or enhance the health of individuals. Research at the Terasaki Institute leverages scientific advancements that enable an understanding of what makes each person unique, from the macroscale of human tissues down to the microscale of genes, to create technological solutions for some of the most pressing medical problems of our time. We use innovative technology platforms to study human disease on the level of individual patients by incorporating advanced computational and tissue-engineering methods. Findings yielded by these studies are translated by our research teams into tailored diagnostic and therapeutic approaches encompassing personalized materials, cells and implants with unique potential and broad applicability to a variety of diseases, disorders and injuries.
The Institute is made possible through an endowment from the late Dr. Paul I Terasaki, a pioneer in the field of organ transplant technology.
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