Generating perfusable 3D microvessels in vitro is an important goal for tissue engineering, as well as for reliable modelling of blood vessel function. To date, in vitro blood vessel models have not been able to accurately reproduce the dynamics and responses of endothelial cells to grow perfusable and functional 3D vascular networks. Here we describe a microfluidic-based platform whereby we model natural cellular programs found during normal development and angiogenesis to form perfusable networks of intact 3D microvessels as well as tumor vasculatures based on the spatially controlled co-culture of endothelial cells with stromal fibroblasts, pericytes or cancer cells. The microvessels possess the characteristic morphological and biochemical markers of in vivo blood vessels, and exhibit strong barrier function and long-term stability. An open, unobstructed microvasculature allows the delivery of nutrients, chemical compounds, biomolecules and cell suspensions, as well as flow-induced mechanical stimuli into the luminal space of the endothelium, and exhibits faithful responses to physiological shear stress as demonstrated by cytoskeleton rearrangement and increased nitric oxide synthesis. This simple and versatile platform provides a wide range of applications in vascular physiology studies as well as in developing vascularized organ-on-a-chip and human disease models for pharmaceutical screening.
Molecular gradients play an important role in diverse physiological and pathological phenomena such as immune response, wound healing, development and cancer metastasis. In the past 10 years, engineering tools have been increasingly used to develop experimental platforms that capture important aspects of cellular microenvironments to allow quantitative and reproducible characterization of cellular response to gradients. This review discusses the emergence of microfluidics-based gradient generators and their applications in enhancing our understanding of fundamental biological processes such as chemotaxis and morphogenesis. The principles and applications of microfluidic gradient generation in both 2D and 3D cellular microenvironments are discussed with emphasis on approaches to manipulate spatial and temporal distribution of signaling molecules.
A crucial yet ill-defined phenomenon involved in the remodeling of vascular networks, including angiogenic sprouting, is flow-mediated endothelial dynamics and phenotype changes. Despite interstitial flow (IF) being ubiquitously present in living tissues surrounding blood capillaries, it is rarely investigated and poorly understood how endothelial cells respond to this flow during morphogenesis. Here we develop a microfluidic 3D in vitro model to investigate the role of IF during vasculogenic formation and angiogenic remodeling of microvascular networks. In the presented model, human blood endothelial cells co-cultured with stromal fibroblasts spontaneously organize into an interconnected microvascular network and then further expand to adjacent avascular regions in a manner of neovessel sprouting. We found that in the presence of IF, vasculogenic organization of the microvascular network was significantly facilitated regardless of the flow direction, whereas angiogenic sprouting was promoted only when the directions of flow and sprouting were opposite while angiogenic activity was suppressed into the direction of flow. We also observed that the vasculatures switch between active angiogenic remodeling and quiescent/non-sprouting state in the contexts provided by IF. This regulatory effect can be utilized to examine the role of anti-angiogenic compounds, clearly distinguishing the differential influences of the compounds depending on their mechanisms of action. Collectively, these results suggest that IF may serve as a critical regulator in tissue vascularization and pathological angiogenesis.
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