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Flow in fetoplacental-like microvessels in vitro enhances perfusion, barrier function, and matrix stability

Marta Cherubini, Scott Erickson, Prasanna Padmanaban, Per Haberkant, Frank Stein, Violeta Beltrán-Sastre, Kristina Haase

2023Science Advances30 citationsDOIOpen Access PDF

Abstract

Proper placental vascularization is vital for pregnancy outcomes, but assessing it with animal models and human explants has limitations. We introduce a 3D in vitro model of human placenta terminal villi including fetal mesenchyme and vascular endothelium. By coculturing HUVEC, placental fibroblasts, and pericytes in a macrofluidic chip with a flow reservoir, we generate fully perfusable fetal microvessels. Pressure-driven flow facilitates microvessel growth and remodeling, resulting in early formation of interconnected and lasting placental-like vascular networks. Computational fluid dynamics simulations predict shear forces, which increase microtissue stiffness, decrease diffusivity, and enhance barrier function as shear stress rises. Mass spectrometry analysis reveals enhanced protein expression with flow, including matrix stability regulators, proteins associated with actin dynamics, and cytoskeleton organization. Our model provides a powerful tool for deducing complex in vivo parameters, such as shear stress on developing vascularized placental tissue, and holds promise for unraveling gestational disorders related to the vasculature.

Topics & Concepts

Cell biologyMicrovesselCytoskeletonMesenchymePlacentaShear stressIn vitroArteriogenesisChemistryIn vivoEndotheliumBiologyFetusMesenchymal stem cellAngiogenesisMaterials scienceCellEndocrinologyPregnancyBiochemistryCancer researchGeneticsComposite materialBiotechnologyPregnancy and preeclampsia studiesAngiogenesis and VEGF in CancerRenal and related cancers
Flow in fetoplacental-like microvessels in vitro enhances perfusion, barrier function, and matrix stability | Litcius