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Continuous Formation of Ultrathin, Strong Collagen Sheets with Tunable Anisotropy and Compaction

Shashi Malladi, David Miranda-Nieves, Lian Leng, Stephanie Grainger, Constantine Tarabanis, Alexander P. Nesmith, Revanth Kosaraju, Carolyn A. Haller, Kevin Kit Parker, Elliot L. Chaikof, Axel Günther

2020ACS Biomaterials Science & Engineering33 citationsDOIOpen Access PDF

Abstract

The multiscale organization of protein-based fibrillar materials is a hallmark of many organs, but the recapitulation of hierarchal structures down to fibrillar scales, which is a requirement for withstanding physiological loading forces, has been challenging. We present a microfluidic strategy for the continuous, large-scale formation of strong, handleable, free-standing, multicentimeter-wide collagen sheets of unprecedented thinness through the application of hydrodynamic focusing with the simultaneous imposition of strain. Sheets as thin as 1.9 μm displayed tensile strengths of 0.5-2.7 MPa, Young's moduli of 3-36 MPa, and modulated the diffusion of molecules as a function of collagen nanoscale structure. Smooth muscle cells cultured on engineered sheets oriented in the direction of aligned collagen fibrils and generated coordinated vasomotor responses. The described biofabrication approach enables rapid formation of ultrathin collagen sheets that withstand physiologically relevant loads for applications in tissue engineering and regenerative medicine, as well as in organ-on-chip and biohybrid devices.

Topics & Concepts

BiofabricationMaterials scienceNanoscopic scaleNanotechnologyMechanobiologyCollagen fibrilNanomechanicsUltimate tensile strengthTissue engineeringAnisotropyBiomedical engineeringComposite materialBiophysicsAtomic force microscopyAnatomyBiologyQuantum mechanicsMedicinePhysics3D Printing in Biomedical ResearchCollagen: Extraction and CharacterizationCellular Mechanics and Interactions
Continuous Formation of Ultrathin, Strong Collagen Sheets with Tunable Anisotropy and Compaction | Litcius