Porous scaffolds of polycaprolactone reinforced with in situ generated hydroxyapatite for bone tissue engineering

## 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 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

## Abstract Model hydroxyapatite (HA) scaffolds with porosities spanning multiple length scales were fabricated by robocasting, a solid freeform fabrication technique based on the robotic deposition of colloidal pastes. Scaffolds of various architectures including periodic, radial, and superlattice

## Abstract As reported previously, a porous composite of uncalcined hydroxyapatite (u‐HA) and poly‐DL‐lactide (PDLLA) showed excellent osteoconductivity and biodegradability as a bone substitute in rabbit model. In this study, to investigate the usefulness of this composite as a scaffold loaded wi

## Abstract In this work, the fabrication and __in vitro__ degradation of porous fumarate‐based/alumoxane nanocomposites were evaluated for their potential as bone tissue engineering scaffolds. The biodegradable polymer poly (propylene fumarate)/propylene fumarate‐diacrylate (PPF/PF‐DA), a macrocom

## 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