Litcius/Paper detail

Topographically guided hierarchical mineralization

Xuliang Deng, Abshar Hasan, Sherif Elsharkawy, Esther Tejeda‐Montes, Nadezda V. Tarakina, Gabriele Greco, Elizaveta Nikulina, John Stormonth-Darling, Neil Convery, José Carlos Rodríguez‐Cabello, A. Boyde, Nikolaj Gadegaard, Nicola M. Pugno, Maisoon Al‐Jawad, Álvaro Mata

2021Materials Today Bio24 citationsDOIOpen Access PDF

Abstract

Material platforms based on interaction between organic and inorganic phases offer enormous potential to develop materials that can recreate the structural and functional properties of biological systems. However, the capability of organic-mediated mineralizing strategies to guide mineralization with spatial control remains a major limitation. Here, we report on the integration of a protein-based mineralizing matrix with surface topographies to grow spatially guided mineralized structures. We reveal how well-defined geometrical spaces defined within the organic matrix by the surface topographies can trigger subtle changes in single nanocrystal co-alignment, which are then translated to drastic changes in mineralization at the microscale and macroscale. Furthermore, through systematic modifications of the surface topographies, we demonstrate the possibility of selectively guiding the growth of hierarchically mineralized structures. We foresee that the capacity to direct the anisotropic growth of such structures would have important implications in the design of biomineralizing synthetic materials to repair or regenerate hard tissues.

Topics & Concepts

Mineralization (soil science)Microscale chemistryNanotechnologyBiomineralizationMaterials scienceMineralized tissuesOrganic componentNanocrystalAnisotropyComputer scienceBiochemical engineeringGeologyEngineeringSoil scienceOpticsPhysicsComposite materialPaleontologyMathematicsMathematics educationSoil waterDentinCalcium Carbonate Crystallization and InhibitionBone Tissue Engineering MaterialsPickering emulsions and particle stabilization