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Photo‐crosslinkable hydrogel incorporated with bone matrix particles for advancements in dentin tissue engineering

Isabela Sanches Pompeo da Silva, Ester Alves Ferreira Bordini, Érika Soares Bronze‐Uhle, Vitor de Toledo Stuani, Matheus de Castro Costa, Letícia Alves Martins de Carvalho, Fernanda Balestrero Cassiano, Lucas José de Azevedo‐Silva, Ana Flávia Sanches Borges, Diana Gabriela Soares

2024Journal of Biomedical Materials Research Part A12 citationsDOI

Abstract

The objective of this study was to create injectable photo-crosslinkable biomaterials, using gelatin methacryloyl (GelMA) hydrogel, combined with a decellularized bone matrix (BMdc) and a deproteinized (BMdp) bovine bone matrix. These were intended to serve as bioactive scaffolds for dentin regeneration. The parameters for GelMA hydrogel fabrication were initially selected, followed by the incorporation of BMdc and BMdp at a 1% (w/v) ratio. Nano-hydroxyapatite (nHA) was also included as a control. A physicochemical characterization was conducted, with FTIR analysis indicating that the mineral phase was complexed with GelMA, and BMdc was chemically bonded to the amide groups of gelatin. The porous structure was preserved post-BMdc incorporation, with bone particles incorporated alongside the pores. Conversely, the mineral phase was situated inside the pore opening, affecting the degree of porosity. The mineral phase did not modify the degradability of GelMA, even under conditions of type I collagenase-mediated enzymatic challenge, allowing hydrogel injection and increased mechanical strength. Subsequently, human dental pulp cells (HDPCs) were seeded onto the hydrogels. The cells remained viable and proliferative, irrespective of the GelMA composition. All mineral phases resulted in a significant increase in alkaline phosphatase activity and mineralized matrix deposition. However, GelMA-BMdc exhibited higher cell expression values, significantly surpassing those of all other formulations. In conclusion, our results showed that GelMA-BMdc produced a porous and stable hydrogel, capable of enhancing odontoblastic differentiation and mineral deposition when in contact with HDPCs, thereby showing potential for dentin regeneration.

Topics & Concepts

DentinTissue engineeringMaterials scienceMatrix (chemical analysis)Biomedical engineeringBone matrixComposite materialEngineeringAnatomyMedicineCartilage3D Printing in Biomedical ResearchBone Tissue Engineering MaterialsAnatomy and Medical Technology