![]() Zadehnajar P, Akbari B, Karbasi S, Mirmusavi MH (2019) Preparation and characterization of poly e-caprolactonegelatin/multi-walled carbon nanotubes electrospun scaffolds for cartilage tissue engineering applications. Siddiqui HA, Pickering KL, Mucalo MR (2018) A review on the use of hydroxyapatite carbonaceous structure composites in bone replacement materials for strengthening purposes. Yi L, Zuhao L, Guangkai R, Zhonghan W, Chihua G, Chenyu S, Marquis of Haihun, Dankai W (2019) Application and progress of bioactive scaffolds in bone tissue engineering. Mater Sci Eng C Mater Biol Appl 43:182–188. Ĭhen H, Wang C, Zhu X, Zhang K, Fan Y, Zhang X (2014) Fabrication of porous titanium scaffolds by stack sintering of microporous titanium spheres produced with centrifugal granulation technology. Ĭosta MM, Bartolomeu F, Alves N, Silva FS, Miranda G (2019) Tribological behavior of bioactive multi-material structures targeting orthopedic applications. International Journal of Polymeric Materials and Polymeric Biomaterials, 1-7. Zhang J, Feng Y, Zhou X, Shi Y, Wang L (2019) Research status of artificial bone materials. Ann Biomed Eng 44(2):1–11īikas H, Lianos AK, Stavropoulos P (2019) A design framework for additive manufacturing. Shrinking the supply chain for implantable coronary stent devices. Moore S (2015) Kevin O’Sullivan, Verdecchia F. ![]() Mater Sci Eng R 80(1):1–36īose S, Vahabzadeh S, Bandyopadhyay A (2013) Bone tissue engineering using 3D printing. Wu SL, Liu XM, Yeung KWK et al (2014) Biomimetic porous scaffolds for bone tissue engineering. Yong MD (2018) Preparation and properties of 3D porous bone tissue engineering scaffolds. Int J Advan Manuf Technolĭomingos M, Gloria A, Coelho J et al (2017) Three-dimensional printed bone scaffolds: the role of nano/micro-hydroxyapatite particles on the adhesion and differentiation of human mesenchymal stem cells. Oliveira P L S, Vaz F M H F, de Oliveira José Martinho Marques (2018) Biofabrication of glass scaffolds by 3D printing for tissue engineering. Polo-Corrales L, Latorre-Esteves M, Ramirez-Vick JE (2014) Scaffold design for bone regeneration. (2015) 3D printing of personalized artificial bone scaffolds. ![]() Jariwala S H, Lewis G S, Bushman Z J, et al. Bone regenerative medicine: classic options, novel strategies, and future directions. 2019 D-RADA16-RGD-reinforced nano-hydroxyapatite/polyamide 66 ternary biomaterial for bone formation. Current problems and directions for the future development of additive manufacturing technology in the field of bone tissue engineering are also discussed.Ĭampana V, Milano G, Pagano E et al (2014) Bone substitutes in orthopaedic surgery: from basic science to clinical practice. Finally, this paper summarizes the 3D bioprinting technology that has fluid containing nutrients, matrix, and cells as constituent materials. This paper also reviews the modeling processes used in bone tissue engineering, with emphasis on the optimization of the architectural design to achieve gradient structure and improved porosity and mechanical properties. The differences between various additive manufacturing technologies are reviewed, with emphasis on the application of new technologies and materials. This paper reviews the development of additive manufacturing technology for bone tissue engineering. Additive manufacturing technology is widely used in the field of bone tissue engineering because it can directly and accurately construct the pore structure in 3D space, ensure internal connectivity of the scaffolds, and directly use biological materials. Bone tissue engineering scaffolds should establish the internal pore structure of the scaffolds and promote new bone growth. Appropriate scaffolds for tissue-engineered bone not only require mechanical strength, but also conditions that promote new bone growth.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |