Engineering Multicellular Tissue Structure, Function and Vascularization
University Of Pennsylvania, Philadelphia PA
Investigators
Linked publications & trials
Abstract
Title: Engineering Multicellular Tissue Structure, Function, and Vascularization Abstract This project focuses on how the spatial organization of cells and resultant cell-cell interactions regulate the development and maintenance of stable tissue function within a tissue engineered construct. In vivo, cell-to- cell communication and cooperation mediated through juxtacrine and paracrine signals is a hallmark of multicellular life, and is thought to play a critical role in the establishment of native tissue functions. Because the spatial organization of cells within tissues defines which juxtapositions exist between which cell types, this architecture ultimately can determine whether a tissue engineered construct ultimate will fail or succeed. Unfortunately, few tools currently exist to manipulate multicellular spatial organization; thus little is known about the true impact of tissue architecture to tissue function. The long-term goal of this project is to develop such cellular patterning tools, to use them to investigate the role of multicellular organization in regulating tissue function, and to explore how such organization can be used to enhance the function of engineered tissues. While the tools to be developed can be considered generic, the investigators will focus as a case study on the development of a vascularized engineered liver. The investigators have recently developed several multicellular patterning tools, and used them to demonstrate the importance of both hepatocyte-stromal cell- cell interactions in supporting hepatocyte function, and interactions between parenchymal and vascular compartments in driving angiogenesis. Interestingly, there appear to be relevant pairwise interactions that occur between several cell types in this setting, and involve a combination of soluble paracrine signals and direct effects through cadherin engagement. It is apparent from these early studies that careful mechanistic studies are necessary to deconvolute and understand how these multiple interactions will contribute to the vascularization and differentiated function of the liver construct, so that a rational strategy can be developed to ultimately construct a functional tissue. It is proposed that a multifaceted in vitro and in vivo effort will be required to develop the necessary tools and studies to meet these goals. Specific Aim 1 will be to investigate the role of cell-cell interactions between hepatocytes, fibroblasts, and endothelial cells in regulating liver and angiogenic functions using several novel two-dimensional patterning tools. Specific Aim 2 will be to investigate how the organization of cells in three-dimensional constructs affects tissue function. Specific Aim 3 will be to explore the involvement of multicellular organization in regulating tissue integration and vascularization in an in vivo setting. In addition to novel approaches to generate patterned multi-cell type constructs, the investigators will also develop nanoparticles for non-invasive monitoring of tissue vascularization. This project will lead to an integrated understanding of the role of multicellular organization and cell-cell communication in stabilizing tissue function, and provide new tools and strategies to engineer complex multicellular tissues.
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