Your search keyword '"Xu, Xiaodong"' showing total 2 results

1. 3D printing algorithm of anisotropic biological scaffold with oxidized nanocellulose and gelatin.

Author

Xu, Xiaodong, Zhou, Jiping, Feng, Chen, Jiang, Yani, Zhang, Qi, and Shi, Hongcan

Subjects

*GELATIN, *THREE-dimensional printing, *TISSUE scaffolds, *3-D printers, *ALGORITHMS

Abstract

Tissue scaffolds need to have anisotropic mechanical properties and a porous structure to meet the needs of different tissues and organs. This report presents results of a study on an especially-designed 3D printing method with oxidized nanocellulose and gelatin, analyzes the servo principle of pneumatic condensing extrusion 3D printer, and proposes a hexagonal algorithm. For the purpose of this study, a printing process file was written by G code, physical and mechanical performance of the 3D scaffolds was evaluated with Solidworks simulation, the porous structure and pressure-pull performance of the printed 3D scaffolds was observed by SEM, and experiments were conducted to measure their bio-compatibility. The study draws the conclusion that scaffolds thus printed have a highly porous structure and anisotropic mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2019

2. 3D printing process of oxidized nanocellulose and gelatin scaffold.

Author

Xu, Xiaodong, Zhou, Jiping, Jiang, Yani, Zhang, Qi, Shi, Hongcan, and Liu, Dongfang

Subjects

*THREE-dimensional printing, *TISSUE engineering, *TISSUE scaffolds, *CELLULOSE, *GELATIN, *CELL proliferation

Abstract

For tissue engineering applications tissue scaffolds need to have a porous structure to meet the needs of cell proliferation/differentiation, vascularisation and sufficient mechanical strength for the specific tissue. Here we report the results of a study of the 3D printing process for composite materials based on oxidized nanocellulose and gelatin, that was optimised through measuring rheological properties of different batches of materials after different crosslinking times, simulation of the pneumatic extrusion process and 3D scaffolds fabrication with Solidworks Flow Simulation, observation of its porous structure by SEM, measurement of pressure-pull performance, and experiments aimed at finding out the vitro cytotoxicity and cell morphology. The materials printed are highly porous scaffolds with good mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2018