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Engineering Biomimetic Microvascular Capillary Networks in Hydrogel Fibrous Scaffolds via Microfluidics-Assisted Co-Axial Wet-Spinning

Alessia Paradiso, Marina Volpi, Diana C. Martinez, Jakub Jaroszewicz, Marco Costantini, Wojciech Święszkowski

2024ACS Applied Materials & Interfaces12 citationsDOIOpen Access PDF

Abstract

High Resolution Image Download MS PowerPoint Slide The microvascular bed plays a crucial role in establishing nutrient exchange and waste removal, as well as maintaining tissue metabolic activity in the human body. However, achieving microvascularization of engineered 3D tissue constructs is still an unsolved challenge. In this work, we developed biomimetic cell-laden hydrogel microfibers recapitulating oriented microvascular capillary-like networks by using a 3D bioprinting technique combined with microfluidics-assisted coaxial wet-spinning. Highly packed and aligned bundles embedding a coculture of human bone marrow-derived mesenchymal stem cells (MSCs) and human umbilical vein endothelial cells (HUVECs) were produced by simultaneously extruding two different bioinks. To this aim, core–shell fibers were wet-spun in a coagulation bath to collect the scaffolds later on a rotary drum. Initially, the versatility of the proposed system was assessed for the extrusion of multimaterial core–shell hydrogel fibers. Subsequently, the platform was validated for the in vitro biofabrication of samples promoting optimal cell alignment along the fiber axis. After 3 weeks of culture, such fiber configuration resulted in the development of an oriented capillary-like network within the fibrin-based core and in the endothelial-specific CD31 marker expression upon MSC/HUVEC maturation. Synergistically, the vertical arrangement of the coaxial nozzle coupled with the rotation of the fiber collector facilitated the rapid creation of tightly packed bundles characterized by a dense, oriented, and extensively branched capillary network. Notably, such findings suggest that the proposed biofabrication strategy can be used for the microvascularization of tissue-specific 3D constructs.

Topics & Concepts

BiofabricationMaterials scienceBiomedical engineeringMicrofluidicsMicrofiberTissue engineeringCapillary actionSelf-healing hydrogelsUmbilical veinFiberMesenchymal stem cellNanotechnologyComposite materialChemistryIn vitroCell biologyBiochemistryBiologyMedicinePolymer chemistry3D Printing in Biomedical ResearchAdditive Manufacturing and 3D Printing TechnologiesElectrospun Nanofibers in Biomedical Applications
Engineering Biomimetic Microvascular Capillary Networks in Hydrogel Fibrous Scaffolds via Microfluidics-Assisted Co-Axial Wet-Spinning | Litcius