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<font face="trebuchet ms" size=4 style="color:#000">'''Research Overview: </font> <br> </div>
 
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Our research focuses on investigating how the engineered microenvironments direct cell function and tissue regeneration. In particular, we are exploring extracellular matrix (topology, rigidity, dimensionality, etc) regulation of cell fate and function in developmental, physiological and pathological process. Several specific thrusts of the current research program include: microscale cardiovascular tissue engineering, BioMEMS for stem/progenitor cell niche engineering, microengineered platforms for cell-matrix mechanobiology, and mechanical regulation of cancer cell invasion and collective cell migration.  Here is a summary of our current research projects.
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Our research spans the disciplinary boundaries between biomechanics, nanobiotechnology, and cell biology with an emphasis on their applications to tissue engineering and regenerative medicine. We am particularly interested in the development and applications of biomimetic cell culture models and tissue engineering constructs to studying the intricate interactions between mechanical and biochemical signaling in cell/tissue function and fate decisions that are essential for cancer metastasis, tissue repair and regeneration following injury, and various developmental events. The ultimate goal of our research is to better understand complex cellular behavior in response to microenvironmental cues in normal, aging and disease states, to gain new mechanistic insights into the control of cell-tissue structure and function, and to develop multiscale regenerative technologies for improving human health.
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<font face="trebuchet ms" size=4 style="color:#000">'''Technological:</font>  <font face="trebuchet ms" size=4 style="color:#00688B"> Biologically inspired, biomimetic materials, microsystems and cell/tissue microenvironments</font> <br> </div>
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Micro- and nanoengineering for stem cell biology: the promise with a caution (''Trends Biotechnol.'' '''29(8)''', 399-408 [2011])]]Our current research focuses on engineering combinatorial cellular microenvironment through use of variable nano-patterns, and soluble and matrix-bound cell guidance cues in a single experiment, which better mimics the in vivo microenvironment under physiological conditions. For example, we are developing a microfluidics-based on chip assay integrated with complex nanoscale  topographic features to enable the analysis of concerted cell responses to composite gradients of precisely generated and aligned surface-bound ECM molecules and diffusible guidance cues or topographic guidance cues. Using these tools, we strive to systematically characterize live cells to wide spectra of dynamically changing combination of mechanical and chemical stimuli (e.g. ECM proteins, topographic, growth factors and signal transduction pathway inhibitors). The proposed measurements are highly resolved in time and space, using a variety of live cell probes and highly defined extracellular conditions. Using UV-assisted nanomolding and 3D nanofabrication techniques, we are developing nanotopographically-defined cell culture models and biomaterial tissue scaffolds for cell biology and tissue engineering. For high-throughput quantitative analysis, we are also working to combine a large area nanopatterned substrate with a traditional multi-well tissue culture plate. We aim to use these tools to gain new mechanistic insights into cell signaling and function, to design new therapies or diagnostic tests for cancer progression and cardiovascular diseases, and to establish organizing principles for development of precisely defined scaffolds for advanced tissue engineering applications.
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Here is a summary of our research.
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<font face="trebuchet ms" size=4 style="color:#000">'''Fundamental:</font>  <font face="trebuchet ms" size=4 style="color:#00688B"> Cellular mechanobiology and mechanotransduction in engineered tissue models </font> <br> </div>
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1. Micro/Nanoengineered in vitro cell culture models <br>
[[Image:ADDR_Image.jpg|left|thumb|250x250px|Nanotopography-guided tissue engineering and regenerative medicine (''Advanced Drug Delivery Reviews'' '''65''', 536-558 [2013])]]<font size = 3>
Current efforts in the area of biomimetic definition of the cell microenvironment have important gaps. First, the state-of-the-art analyses are performed with spatially homogenous patterns of extracellular matrix (ECM) density or nanotopography definition. However, supporting ECM structures in living tissues have generally inhomogeneous, complex structures, variable on the scale of a single cell. Second, cells are exposed to constant pre-defined media, whereas the composition of the soluble cell microenvironment might undergo dynamic alterations. Third, the measurements performed are commonly static, taking snapshots of cells on the nano-defined structures with inferences about the mechanisms of cell structure and function based on the analysis of cells fixed for staining or electron microscopy.
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  As novel strategies to address these issues, our curent research focus on designing combinatorial cellular microenvironment through use of variable nano-patterns, and soluble and matrix-bound cell guidance cues in a single experiment, which better mimics the in vivo microenvironment under physiological conditions. We will explore a microfluidics-based assay integrated with nanopatterned substrates to enable the analysis of concerted cell responses to composite gradients of precisely generated and aligned surface-bound ECM molecules and diffusible guidance cues or topographic guidance cues. Using these tools, we can systematically expose live cells to wide spectra of dynamically changing combination of mechanical and comical stimuli (e.g. ECM proteins, topographic, growth factors and signal transduction pathway inhibitors). The proposed measurements are highly resolved in time and space, using a variety of live cell probes and highly defined extracellular conditions. In collaboration with other complementary groups, we are currently employing UV-assisted capillary force lithography and/or nanoimprinting techniques for fabricating precise nano-topographic features of UV-curable biomaterials on an optically transparent glass coverslip. In a novel fashion, we combine complex nanoscale topographic features with microfluidic chips and multi-well tissue culture plates fabricated in a convenient and scalable manner. Ultimately, we will use these tools to gain new mechanistic insights into cell signaling and function, to design new therapies or diagnostic tests for cancer progression and cardiovascular diseases, and to establish organizing principles for development of precisely defined scaffolds for advanced tissue engineering applications.  
Mechanotransduction - from how cells sense mechanical forces in different tissues to how these mechanical forces are transduced into biochemical signals - is an essential biological process in development, normal physiology and disease. In this exciting area, we are particularly interested in investigating the role of mechano-biological processes associated with cell-cell and cell-matrix  adhesions (e.g. topography and rigidity of the extracellular matrix) in the regulation of collective and directed cell migration and tissue morphogenesis. Using a combination of various techniques, from molecular biology to nanotechnology and live cell imaging, for example, we have been accumulating interesting data suggesting that one of the most important factors distinguishing metastatic from non-metastatic cells could be their ability to collectively invade and migrate towards blood vessels by physically interacting with the surrounding extracellular matrices.  By experimenting with the nanotopographically-defined cell adhesion substratum (i.e. quasi 3D cell culture system) and 3D natural/synthetic extracellular matrices, we are investigating the biophysical and signaling mechanisms of collective cell migration driven by the hypothesis that the physical interaction of migrating cells with the surrounding ECM has a crucial role in the collective guidance of cell migration in the context of cancer invasion and wound healing. To test this hypothesis, we recently developed a micro/nanofabricated collective migration assay as an enabling tool for analysis and control of cancer cell invasion and epithelial/endothelial wound healing in a high-throughput, controlled manner. Using these tools, we also explore the potential role of mechanical guidance in the regulation of collective cell migration and tissue morphogenesis under the presence/absence of growth factor-induced signals, and test their biomedical implication by screening cytoskeletal and signal transduction pathways.


2. Mechanotransduction in cancer cell invasion and metastasis <br>
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Mechanotransduction - from how cells sense mechanical forces in different tissues to how these mechanical forces are transduced into biochemical signals - is an essential biological process in development, normal physiology and disease. The long-term goal of our research in this exciting area is to gain new insights into pathways of mechanotransduction using bioengineering and nanotechnology-based innovative tools; to elucidate the relationship of mechanotransduction, cell mechanical property changes, and human disease states; and to design new modes of therapeutic intervention. We will combine in-chip live cell culture platforms with time-lapse imaging with fluorescently-labeled mechanotransductive signaling proteins or advanced microscopy such as FRET (‘fluorescence’ or ‘Förster’ resonance emission transfer) imaging (so called “in-chip molecular live cell imaging”). Using these novel tools, our research involves quantitative characterization of the individual and collective behaviors of live cells in normal and disease states (i.e. cancer and wound healing) in controlled microenvironments. Our research particularly focuses on the analysis of signaling, migration and mechanical properties of metastatic (vs. belign) cancer cells and epithelial cells.
  Using a combination of various techniques, from molecular biology to nanotechnology with microrheological measurements, we have been accumulating interesting data suggesting that one of the most important factors distinguishing metastatic from non-metastatic cells could be their ability to physically interact with the surrounding ECM and re-organize it. We also found that inhibition of the PI3K interferes polarization and movement of metastatic melanoma (the most dangerous type of skin cancer) cells cultured on nanostructured substrata that mimic oriented matrix fibers in vivo. These results have important implications for our understanding of metastasis processes in melanoma and their control by ECM signals and topography. For additional evidence of cancer cell-matrix interactions, we also perform cancer cell migration experiments within 3D collagen gel culture construct, which would be more flexible and controllable than the in vivo experiments. In these experiments, we trace the movement of metastatic and/or non-metastatic cells integrated with collagen gel as well as the local re-organization of surrounding gel structure.


3. Mechanics and signaling in collective cell migration <br>
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We pursue to examine the biological mechanics and signaling in collective epithelial (and endothelial) cell migration in the context of wound healing driven by the hypothesis that the physical interaction of migrating cells with the surrounding ECM has a crucial role in the guidance of wound repair. To test this hypothesis, we recently developed a microfabricated epithelial wound model integrated with nanotopographic substrata as an experimental platform, allowing time-lapse high-resolution microscopy of fluorescently tagged cytoskeletal and signaling proteins. Using these tools, we explore the potential role of mechanical guidance in the regulation of collective cell migration under the presence/absence of growth factor-induced signals, and test their biomedical implication by screening cytoskeletal and signal transduction inhibitors, including Rho-associated kinase (ROCK) inhibitor (i.e. Y27632) and PI3K inhibitor (i.e. LY294002).
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<font face="trebuchet ms" size=4 style="color:#000">'''Translational:</font>  <font face="trebuchet ms" size=4 style="color:#00688B"> Microenvironmental stem cell niche engineering and functional tissue engineering </font> <br> </div>
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4. Nanostructure-cell interactions for stem cell and cardiovascular tissue engineering <br>
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With advances in nanofabrication and biomaterials, scaffolding materials can be designed to integrate biomimetic structural and mechanical cues present in the in vivo ECM environment. Based on ultrastructural analyses of the native heart tissue, we recently employed a bio-inspired design of a model cardiac tissue, to demonstrate that it is through the cardiac tissue engineering on the nano- rather than micro-scale that we can control the engineered cardiac tissue function most effectively and bio-mimetically (Kim et al., PNAS, 2010). We are further extending this work toward better understanding of cardiac tissue structure-function relationships, and seek applications in stem cell-based therapies for tissue repair and regeneration.
<font size = 3>
The ultimate goal of this project is to develop nanopatterned functional cardiac patches for heart tissue repair. The working hypothesis is that cultivation of cardiac cells and/or stem cells on novel biomaterials scaffolds integrated with nanotopographic cues promotes biomimetic anisotropic assembly of uniformly contractile engineered muscle, while simultaneously enabling control over local cell alignment. We further hypothesize that integrating the transplantable stem cells with the proposed nano-grafting techniques have therapeutic potential in repairing cardiac tissue damage and may prevent the onset of heart failure. In order to test these hypotheses, our research focuses on elucidating the relationships between scaffold-mediated nanostructural cues and tissue engineered cardiac graft contractility and function. In addition, the therapeutic potential of a nanopatterned cardiac stem cell graft will be studied in vitro and in vivo (implantation onto the left ventricle in an adult rat model of myocardial infarction). Tissue structure and function will be characterized at various hierarchical scales (molecular, structural, functional) and the obtained experimental data will be used to tailor the conditions and duration of cultivation, leading to engineering implantable grafts.  
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Finally, we will demonstrate in vivo that the tissue repair following such nano-patch transplantation is significantly enhanced, with cells on the patch integrating into the surrounding heart tissue and facilitating its repair. This research has great significance due to its potential to yield novel insights into in vivo cardiovascular regeneration and tissue remodeling, and establish therapeutic and biocompatible tissue-engineered cardiac grafts that mimic the cardiophysiological architecture and function. The specific objectives are: (1) to develop a method to engineer structurally organized cardiac tissue with controllable architecture; (2) to characterize the mechanical and electrophysiological functions of nano-engineered cardiac tissue; and (3) to investigate the therapeutic potential of nano-patterned cardiac stem cell patches in a myocardial infarction model.
[[Image:Translational.tif|thumb|200x200px|Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs (''PNAS'' '''107''', 565-570 [2010])]]With advances in nanofabrication and biomaterials, scaffolding materials can be designed to integrate biomimetic structural and mechanical cues present in the in vivo ECM environment. Based on ultrastructural analyses of the native heart tissue, we are developing a bio-inspired model cardiac tissue to better understand cardiac tissue structure-function relationships, and to seek applications in stem cell-based therapies for cardiac tissue repair and regeneration. The ultimate goal of this project is to develop nanopatterned functional cardiac patches for treating the damaged heart tissue (e.g. myocardial infarction). The working hypothesis is that cultivation of cardiac cells and/or stem cells on novel biomaterials scaffolds integrated with nanotopographic cues promotes biomimetic anisotropic assembly of uniformly contractile engineered muscle, while simultaneously enabling control over local cell alignment. We further envision that integrating the transplantable stem cells with the proposed nano-grafting techniques have therapeutic potential in repairing cardiac tissue damage and may prevent the onset of heart failure. In order to test these hypotheses, our research focuses on elucidating the relationships between scaffold-mediated nanostructural cues and tissue engineered cardiac graft contractility and function. In addition, the therapeutic potential of a nanopatterned cardiac stem cell graft will be studied in vitro and in vivo (implantation onto the left ventricle in an adult rat model of myocardial infarction). Tissue structure and function will be characterized at various hierarchical scales (molecular, structural, functional) and the obtained experimental data will be used to tailor the conditions and duration of cultivation, leading to engineering implantable grafts.  
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<br>
<font size = 3> '''Funding Sources''':
<br>
<font size = 3>Our research would not be possible without the the generous support of the following public and private organizations. <br>


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Revision as of 09:10, 9 April 2014

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Research Overview:

Our research focuses on investigating how the engineered microenvironments direct cell function and tissue regeneration. In particular, we are exploring extracellular matrix (topology, rigidity, dimensionality, etc) regulation of cell fate and function in developmental, physiological and pathological process. Several specific thrusts of the current research program include: microscale cardiovascular tissue engineering, BioMEMS for stem/progenitor cell niche engineering, microengineered platforms for cell-matrix mechanobiology, and mechanical regulation of cancer cell invasion and collective cell migration. Here is a summary of our current research projects.

Technological: Biologically inspired, biomimetic materials, microsystems and cell/tissue microenvironments
Micro- and nanoengineering for stem cell biology: the promise with a caution (Trends Biotechnol. 29(8), 399-408 [2011])
Our current research focuses on engineering combinatorial cellular microenvironment through use of variable nano-patterns, and soluble and matrix-bound cell guidance cues in a single experiment, which better mimics the in vivo microenvironment under physiological conditions. For example, we are developing a microfluidics-based on chip assay integrated with complex nanoscale topographic features to enable the analysis of concerted cell responses to composite gradients of precisely generated and aligned surface-bound ECM molecules and diffusible guidance cues or topographic guidance cues. Using these tools, we strive to systematically characterize live cells to wide spectra of dynamically changing combination of mechanical and chemical stimuli (e.g. ECM proteins, topographic, growth factors and signal transduction pathway inhibitors). The proposed measurements are highly resolved in time and space, using a variety of live cell probes and highly defined extracellular conditions. Using UV-assisted nanomolding and 3D nanofabrication techniques, we are developing nanotopographically-defined cell culture models and biomaterial tissue scaffolds for cell biology and tissue engineering. For high-throughput quantitative analysis, we are also working to combine a large area nanopatterned substrate with a traditional multi-well tissue culture plate. We aim to use these tools to gain new mechanistic insights into cell signaling and function, to design new therapies or diagnostic tests for cancer progression and cardiovascular diseases, and to establish organizing principles for development of precisely defined scaffolds for advanced tissue engineering applications.
Fundamental: Cellular mechanobiology and mechanotransduction in engineered tissue models
Nanotopography-guided tissue engineering and regenerative medicine (Advanced Drug Delivery Reviews 65, 536-558 [2013])
Mechanotransduction - from how cells sense mechanical forces in different tissues to how these mechanical forces are transduced into biochemical signals - is an essential biological process in development, normal physiology and disease. In this exciting area, we are particularly interested in investigating the role of mechano-biological processes associated with cell-cell and cell-matrix adhesions (e.g. topography and rigidity of the extracellular matrix) in the regulation of collective and directed cell migration and tissue morphogenesis. Using a combination of various techniques, from molecular biology to nanotechnology and live cell imaging, for example, we have been accumulating interesting data suggesting that one of the most important factors distinguishing metastatic from non-metastatic cells could be their ability to collectively invade and migrate towards blood vessels by physically interacting with the surrounding extracellular matrices. By experimenting with the nanotopographically-defined cell adhesion substratum (i.e. quasi 3D cell culture system) and 3D natural/synthetic extracellular matrices, we are investigating the biophysical and signaling mechanisms of collective cell migration driven by the hypothesis that the physical interaction of migrating cells with the surrounding ECM has a crucial role in the collective guidance of cell migration in the context of cancer invasion and wound healing. To test this hypothesis, we recently developed a micro/nanofabricated collective migration assay as an enabling tool for analysis and control of cancer cell invasion and epithelial/endothelial wound healing in a high-throughput, controlled manner. Using these tools, we also explore the potential role of mechanical guidance in the regulation of collective cell migration and tissue morphogenesis under the presence/absence of growth factor-induced signals, and test their biomedical implication by screening cytoskeletal and signal transduction pathways.
Translational: Microenvironmental stem cell niche engineering and functional tissue engineering

Nanoscale cues regulate the structure and function of macroscopic cardiac tissue constructs (PNAS 107, 565-570 [2010])
With advances in nanofabrication and biomaterials, scaffolding materials can be designed to integrate biomimetic structural and mechanical cues present in the in vivo ECM environment. Based on ultrastructural analyses of the native heart tissue, we are developing a bio-inspired model cardiac tissue to better understand cardiac tissue structure-function relationships, and to seek applications in stem cell-based therapies for cardiac tissue repair and regeneration. The ultimate goal of this project is to develop nanopatterned functional cardiac patches for treating the damaged heart tissue (e.g. myocardial infarction). The working hypothesis is that cultivation of cardiac cells and/or stem cells on novel biomaterials scaffolds integrated with nanotopographic cues promotes biomimetic anisotropic assembly of uniformly contractile engineered muscle, while simultaneously enabling control over local cell alignment. We further envision that integrating the transplantable stem cells with the proposed nano-grafting techniques have therapeutic potential in repairing cardiac tissue damage and may prevent the onset of heart failure. In order to test these hypotheses, our research focuses on elucidating the relationships between scaffold-mediated nanostructural cues and tissue engineered cardiac graft contractility and function. In addition, the therapeutic potential of a nanopatterned cardiac stem cell graft will be studied in vitro and in vivo (implantation onto the left ventricle in an adult rat model of myocardial infarction). Tissue structure and function will be characterized at various hierarchical scales (molecular, structural, functional) and the obtained experimental data will be used to tailor the conditions and duration of cultivation, leading to engineering implantable grafts.


Funding Sources:
Our research would not be possible without the the generous support of the following public and private organizations.

   link = http://www.nih.gov/    link = http://www.heart.org/HEARTORG/         
link =http://www.whcf.org/    link = http://depts.washington.edu/uwc4c/      link = http://www.lsdfa.org/    link = http://www.washington.edu/    link = http://www.ksea.org/2013/   
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