Scalable Miniature Human Tissues for Drug Development and Regenerative Medicine

Animal models have been utilized for several decades now for drug development, disease modeling, and to test the efficacy of implantable human tissue constructs. While these models are an important bridge to human clinical trials, it has become clear over many high-profile drug failures that animals do not suffice on their own for preclinical investigations due to significant differences in organ-specific molecular pathways across different species. Therefore, the field of 'tissue engineering' has aimed to create human-relevant tissue culture platforms that can complement and in some cases, replace animal testing altogether. To build such platforms, tissue engineers face common challenges such as sustainable cell sourcing, cell phenotypic stability in vitro, and scaling the constructs for different applications. In this seminar, I will present how we and others have addressed such challenges via state-of-the-art microfabrication tools adapted from the semiconductor industry, novel biomaterials, stem cell differentiation strategies, and multicellular co-cultures. I will present culture platform development within the context of the liver, which is a difficult organ to engineer in vitro due to its many diverse functions, complex architecture, and multiple types of self- and non-self cellular interactions. Since in vitro culture platforms are only as good as the applications which can be effectively targeted with them, I will next present the utility of our engineered human liver platforms for drug toxicity screening, disease modeling (e.g. non-alcoholic fatty liver disease and hepatitis B viral infection), and regenerative medicine; data sets acquired in collaboration with pharmaceutical companies through successful commercial translation will be presented where available. Lastly, I will discuss emerging trends and pending issues that will need to be addressed to fully realize the benefits of the ‘organ-on-a-chip’ revolution, which has garnered substantial attention and funding from the US government. Ultimately, engineered tissues will most likely be one of the most important contributions of bioengineering to 21st-century healthcare.