Conceptual design of three-dimensional scaffolds of powder-based materials for bone tissue engineering applications-Reference-Cited by-同舟云学术

Conceptual design of three-dimensional scaffolds of powder-based materials for bone tissue engineering applications

Published:2015-10-19 Issue:6 Volume:21 Page:716-724
ISSN:1355-2546
Container-title:Rapid Prototyping Journal
language:en
Short-container-title:

Author:

Vasireddi Ramakrishna,Basu Bikramjit

Abstract

Purpose – The purpose of this paper is to investigate the possibility to construct tissue-engineered bone repair scaffolds with pore size distributions using rapid prototyping techniques. Design/methodology/approach – The fabrication of porous scaffolds with complex porous architectures represents a major challenge in tissue engineering and the design aspects to mimic complex pore shape as well as spatial distribution of pore sizes of natural hard tissue remain unexplored. In this context, this work aims to evaluate the three-dimensional printing process to study its potential for scaffold fabrication as well as some innovative design of homogeneously porous or gradient porous scaffolds is described and such design has wider implication in the field of bone tissue engineering. Findings – The present work discusses biomedically relevant various design strategies with spatial/radial gradient in pore sizes as well as with different pore sizes and with different pore geometries. Originality/value – One of the important implications of the proposed novel design scheme would be the development of porous bioactive/biodegradable composites with gradient pore size, porosity, composition and with spatially distributed biochemical stimuli so that stem cells loaded into scaffolds would develop into complex tissues such as those at the bone–cartilage interface.

Publisher

Emerald

Subject

Industrial and Manufacturing Engineering,Mechanical Engineering

Reference66 articles.

1. Abdullah, J. and Hassan, A.Y. (2005), Rapid Prototyping in Orthopaedics: Principles and Applications , Bone Grafts and Bone Substitutes, pp. 547-561.

2. Alaadien, K. , Sebastian, V. , Jur¨gen, W. , Gabriele, G. , Annett, R. , Wolfgang, M. and Matthias, S. (2007), “Development of a new calcium phosphate powder-binder system for the 3D printing of patient specific implants”, Journal of Materials Science: Materials in Medicine , Vol. 18 No. 1, pp. 909-916.

3. Bandyopadhyay, A. , Krishna, B.V. , Xue, W. and Bose, S. (2009), “Application of laser engineered net shaping (LENS) to manufacture porous and functionally graded structures for load bearing implants”, J Mater Sci Mater Med , Vol. 20, pp. 29-34.

4. Basu, B. , Katti, D. and Kumar, A. (2009), Advanced Biomaterials: Fundamentals, Processing and Applications , Wiley-American Ceramic Society, ISBN: 978-0-470-19340-2.

5. Baxter, L.C. , Frauchiger, V. , Textor, M., , Gwynn, I. and Richards, R.G. (2002), “Fibroblast and osteoblast adhesion and morphology on calcium phosphate surfaces”, European Cells & Materials Journal , Vol. 4, pp. 1-17.

Cited by 27 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Nanoparticles in Bone Regeneration: A Narrative Review of Current Advances and Future Directions in Tissue Engineering;Journal of Functional Biomaterials;2024-08-23

2. 3D printed CoCrMo personalised load-bearing meta-scaffold for critical size tibial reconstruction;Annals of 3D Printed Medicine;2024-08

3. Process-structure-biofunctional paradigm in cellular structured implants: an overview and perspective on the synergy between additive manufacturing, bio-mechanical behaviour and biological functions;Artificial Cells, Nanomedicine, and Biotechnology;2023-11-07

4. 3D printing customised stiffness-matched meta-biomaterial with near-zero auxeticity for load-bearing tissue repair;Bioprinting;2023-09

5. 3D printing and enzyme immobilization: An overview of current trends;Bioprinting;2023-09