A Synthetic Dynamic Polyvinyl Alcohol Photoresin for Fast Volumetric Bioprinting of Functional Ultrasoft Hydrogel Constructs
Abstract
Tomographic volumetric bioprinting (VBP) enables fast photofabrication of cell-laden hydrogel constructs in one step, addressing the limitations of conventional layer-by-layer additive manufacturing. However, existing biomaterials that fulfill the physicochemical requirements of VBP are limited to gelatin-based photoresins of high polymer concentrations. The printed microenvironments are predominantly static and stiff, lacking sufficient capacity to support 3D cell growth. Here a dynamic resin based on thiol-ene photo-clickable polyvinyl alcohol (PVA) and thermo-sensitive sacrificial gelatin for fast VBP of functional ultrasoft cell-laden hydrogel constructs within 7-15 s is reported. Using gelatin allows VBP of permissive hydrogels with low PVA contents of 1.5%, providing a stress-relaxing environment for fast cell spreading, 3D osteogenic differentiation of embedded human mesenchymal stem cells and matrix mineralization. Additionally, site-specific immobilization of molecules-of-interest inside a PVA hydrogel is achieved by 3D tomographic thiol-ene photopatterning. This technique may enable spatiotemporal control of cell-material interactions and guides in vitro tissue formation using programmed cell-friendly light. Altogether, this study introduces a synthetic dynamic photoresin enabling fast VBP of functional ultrasoft hydrogel constructs with well-defined physicochemical properties and high efficiency. Show more
Permanent link
https://doi.org/10.3929/ethz-b-000600747Publication status
publishedExternal links
Journal / series
Advanced Functional MaterialsVolume
Pages / Article No.
Publisher
Wiley-VCHSubject
bioresins; hydrogels; polyvinyl alcohol; thiol-ene reactions; volumetric bioprintingOrganisational unit
03565 - Müller, Ralph / Müller, Ralph
Funding
188522 - Subtractive 3D Micro-Printing of Functional Osteocyte Networks as An In Vitro Model for Bone Organoids (SNF)
190345 - Mini-Bone-on-a-Chip: Microfluidic Engineering of 3D Osteocyte Networks in Void-forming Hydrogels (SNF)
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