Fabrication of a hydroxyapatite scaffold for bone tissue regeneration using microstereolithography and molding technology

## Abstract Tissue‐engineering scaffold‐based strategies have suffered from limited cell depth viability when cultured __in vitro__, with viable cells existing within the outer periphery of the fluid–scaffold interface. This is primarily believed to be due to the lack of nutrient delivery into and

## Abstract Conventional methods in fabrication of scaffolds based on polymer/bioceramic composites frequently make use of solution casting then particle leaching. The residues of common organic solvents can get trapped in this technique hence provide safety concerns on final scaffold. In this stud

## Abstract The objective of this study was to develop a biomimetic, highly porous collagen‐hydroxyapatite (HA) composite scaffold for bone tissue engineering (TE), combining the biological performance and the high porosity of a collagen scaffold with the high mechanical stiffness of a HA scaffold.

## Abstract This investigation describes the production and characterization of calcium phosphate scaffolds with defined and reproducible porous macro‐architectures and their preliminary __in vitro__ and __in vivo__ bone‐tissue‐engineered response. Fugitive wax molds were designed and produced usin

## Abstract Over the last decade, bone engineered tissues have been developed as alternatives to autografts and allografts to repair and reconstruct bone defects. This article provides a review of the current technologies in bone tissue engineering. Factors used for fabrication of three‐dimensional

## Abstract A novel scaffold with large dimension of 3–4 cm in length and 1–1.5 cm in diameter was designed and fabricated for engineering large bone tissue __in vivo__. The scaffold was constructed by filling hydroxyapatite (HA) spherules into a porous HA tube. The HA spherules were prepared by ch