Abstract
There is an increasing need for novel biomaterials compatible with advanced biofabrication technologies, which also permit cells to remodel their microenvironment. This remodelling is crucial for maturing tissue constructs into fully functional tissue replacements. Recent progress in supramolecular chemistries has allowed for the production of dynamic biomaterials. Their properties enable bonds to be reversibly broken by cells, facilitating processes requiring morphological changes or migration, crucial for tissue development and homeostasis. Here, we present a one-of-its-kind gelatin-based hybrid covalent/supramolecular biomaterial. We demonstrate the advantage of adding supramolecular-reactive moieties on covalent materials, over covalent bonds alone, in facilitating processes such as cell growth, migration, spreading and organoid proliferation. This is exemplified by enhanced MSC and T cell migration and improved vascular network formation in hybrid hydrogels over covalent-only materials. The combination of supramolecular and covalent bonds further enabled control over photocrosslinking, allowing the use of the material in volumetric bioprinting of complex structures with high shape fidelity. As a proof-of-concept we bioprinted complex breast-like structures from encapsulated normal breast cell lines with a tumor organoid core. We demonstrated that engineered T cells can migrate large distances into the breast tissue, specifically targeting tumor cells. Graphical abstract
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Abstract
There is an increasing need for novel biomaterials compatible with advanced biofabrication technologies, which also permit cells to remodel their microenvironment. This remodelling is crucial for maturing tissue constructs into fully functional tissue replacements. Recent progress in supramolecular chemistries has allowed for the production of dynamic biomaterials. Their properties enable bonds to be reversibly broken by cells, facilitating processes requiring morphological changes or migration, crucial for tissue development and homeostasis. Here, we present a one-of-its-kind gelatin-based hybrid covalent/supramolecular biomaterial. We demonstrate the advantage of adding supramolecular-reactive moieties on covalent materials, over covalent bonds alone, in facilitating processes such as cell growth, migration, spreading and organoid proliferation. This is exemplified by enhanced MSC and T cell migration and improved vascular network formation in hybrid hydrogels over covalent-only materials. The combination of supramolecular and covalent bonds further enabled control over photocrosslinking, allowing the use of the material in volumetric bioprinting of complex structures with high shape fidelity. As a proof-of-concept we bioprinted complex breast-like structures from encapsulated normal breast cell lines with a tumor organoid core. We demonstrated that engineered T cells can migrate large distances into the breast tissue, specifically targeting tumor cells.
Competing Interest Statement
M.F, P.N.B, M.B, A.R., and R.L. are inventors on a provisional patent application that covers the hydrogel reported in this manuscript and its application for bioprinting, and cell and organoid culture. R.L. is scientific advisor for Readily3D SA. The other authors declare no competing interests.
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