This protocol describes a simple but robust microfluidic assay combining three-dimensional (3D) and two-dimensional (2D) cell culture. The microfluidic platform comprises hydrogel incorporating chambers between surface-accessible microchannels. Using this platform, well-defined biochemical and biophysical stimuli can be applied to multiple cell types interacting over distances of <1mm, thereby replicating many aspects of the in vivo microenvironment. Capabilities exist for time-dependent manipulation of flows and concentration gradients as well as high-resolution real-time imaging for observing spatial-temporal single cell behavior, cell-cell communication, cell-matrix interactions and cell population dynamics. These heterotypic cell type assays can be used to study cell survival, proliferation, migration, morphogenesis and differentiation under controlled conditions. Applications include the study of previously unexplored cellular interactions, and have already provided new insights into how biochemical and biophysical factors regulate interactions between populations of different cell types. It takes 3 days to fabricate the system and experiments can run for up to several weeks.
Capillary morphogenesis is a complex cellular process that occurs in response to external stimuli. A number of assays have been used to study critical regulators of the process, but those assays are typically limited by the inability to control biochemical gradients and to obtain images on the single cell level. We have recently developed a new microfluidic platform that has the capability to control the biochemical and biomechanical forces within a three dimensional scaffold coupled with accessible image acquisition. Here, the developed platform is used to evaluate and quantify capillary growth and endothelial cell migration from an intact cell monolayer. We also evaluate the endothelial cell response when placed in co-culture with physiologically relevant cell types, including cancer cells and smooth muscle cells. This resulted in the following observations: cancer cells can either attract (MTLn3 cancer cell line) endothelial cells and induce capillary formation or have minimal effect (U87MG cancer cell line) while smooth muscle cells (10T 1/2) suppress endothelial activity. Results presented demonstrate the capabilities of this platform to study cellular morphogenesis both qualitatively and quantitatively while having the advantage of enhanced imaging and internal biological controls. Finally, the platform has numerous applications in the study of angiogenesis, or migration of other cell types including tumor cells, into a three-dimensional scaffold or across an endothelial layer under precisely controlled conditions of mechanical, biochemical and co-culture environments.
Increasing interest has focused on capturing the complexity of tissues and organs in vitro as models of human pathophysiological processes. In particular, a need exists for a model that can investigate the interactions in three dimensions (3D) between epithelial tissues and a microvascular network since vascularization is vital for reconstructing functional tissues in vitro. Here, we implement a microfluidic platform to analyze angiogenesis in 3D cultures of rat primary hepatocytes and rat/human microvascular endothelial cells (rMVECs/hMVECs). Liver and vascular cells were cultured on each sidewall of a collagen gel scaffold between two microfluidic channels under static or flow conditions. Morphogenesis of 3D hepatocyte cultures was found to depend on diffusion and convection across the nascent tissue. Furthermore, rMVECs formed 3D capillary-like structures that extended across an intervening gel to the hepatocyte tissues in hepatocyte-rMVEC coculture while they formed 2D sheet-like structures in rMVEC monoculture. In addition, diffusion of fluorescent dextran across the gel scaffold was analyzed, demonstrating that secreted proteins from the hepatocytes and MVECs can be exchanged across the gel scaffold by diffusional transport. The experimental approach described here is useful more generally for investigating microvascular networks within 3D engineered tissues with multiple cell types in vitro.
Vascularization by endothelial cells (ECs) is an essential element in tissue-engineering of organoids. Morphogenesis of these cells is regulated not only by the biochemical properties of the extracellular matrix (ECM) but also by its mechanical properties. Here, we investigated the effect of substrate mechanical properties on the formation of capillary-like networks by ECs; in particular, we examined the three-dimensional (3D) configurations of the resulting networks. Bovine pulmonary microvascular ECs (BPMECs) were cultured on a series of collagen gels of different stiffness but the same collagen concentration. Imaging techniques revealed that cells cultured in rigid and flexible gels formed 3D networks via different processes; cells formed dense, thin networks in the flexible gel, whereas thicker and deeper networks were formed in the rigid gel. Cross-sections of the networks revealed that those formed within the rigid gel had large lumens composed of multiple cells, whereas those formed within the flexible gel had small, intracellular vacuoles. The expression of vinculin, a focal adhesion protein, appeared to change with the mechanical properties of collagen gel. Our results indicate that the mechanical properties of adhesion substrates play an important role in regulating 3D network formation.
Sprouting angiogenesis requires a coordinated guidance from a variety of angiogenic factors. Here, we have developed a unique hydrogel incorporating microfluidic platform which mimics the physiological microenvironment in 3D under a precisely orchestrated gradient of soluble angiogenic factors, VEGF and ANG-1. The system enables the quantified investigation in chemotactic response of endothelial cells during the collective angiogenic sprouting process. While the presence of a VEGF gradient alone was sufficient in inducing a greater number of tip cells, addition of ANG-1 to the VEGF gradient enhanced the number of tip cells that are attached to collectively migrated stalk cells. The chemotactic response of tip cells attracted by the VEGF gradient and the stabilizing role of ANG-1 were morphologically investigated, elucidating the 3D co-operative migration of tip and stalk cells as well as their structures. We found that ANG-1 enhanced the connection of the stalk cells with the tip cells, and then the direct connection regulated the morphogenesis and/or life cycle of stalk cells.
Recent advances in microfluidic technologies have opened the door for creating more realistic in vitro cell culture methods that replicate many aspects of the true in vivo microenvironment. These new designs (i) provide enormous flexibility in controlling the critical biochemical and biomechanical factors that influence cell behavior, (ii) allow for the introduction of multiple cell types in a single system, (iii) provide for the establishment of biochemical gradients in two- or three-dimensional geometries, and (iv) allow for high quality, time-lapse imaging. Here, some of the recent developments are reviewed, with a focus on studies from our own laboratory in three separate areas: angiogenesis, cell migration in the context of tumor cell-endothelial interactions, and liver tissue engineering.
Robust induction of realistic angiogenesis into a 3D matrix material under simultaneous imaging and a stably controlled concentration gradient of chemoattractants is presented. The formation of a 3D vascular network is demonstrated to be a direct consequence of surface treatment of the region of the device‐containing matrix material.
Microfluidic devices allow for precise control of the cellular and noncellular microenvironment at physiologically relevant length- and time-scales. These devices have been shown to mimic the complex in vivo microenvironment better than conventional in vitro assays, and allow real-time monitoring of homotypic or heterotypic cellular interactions. Microfluidic culture platforms enable new assay designs for culturing multiple different cell populations and∕or tissue specimens under controlled user-defined conditions. Applications include fundamental studies of cell population behaviors, high-throughput drug screening, and tissue engineering. In this review, we summarize recent developments in this field along with studies of heterotypic cell-cell interactions and tissue specimen culture in microfluidic devices from our own laboratory.
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