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Computer Methods in Biomechanics and Biomedical Engineering Volume 22, 2019 - Issue 13
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Articles

Structure and properties of a personalized bio-fixed implant prepared with selective laser melting

Guoqing ZhangSchool of mechanical and electrical engineering, Zhoukou Normal University, Zhoukou, PR China; Correspondence[email protected]
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,
Junxin LiSchool of mechanical and electrical engineering, Zhoukou Normal University, Zhoukou, PR China; View further author information
,
Jin LiSchool of mechanical and electrical engineering, Zhoukou Normal University, Zhoukou, PR China; View further author information
,
Xiaoyu ZhouSchool of mechanical and electrical engineering, Zhoukou Normal University, Zhoukou, PR China; View further author information
&
Anmin WangSchool of Mechanical and Automotive Engineering, South China University of Technology, Guangzhou, PR ChinaView further author information
Pages 1034-1042 | Received 17 Jan 2019, Accepted 03 May 2019, Published online: 14 Jul 2019

References

  • Biermann JS, Holt GE, Lewis VO, Schwartz HS, Yaszemski MJ. 2009. Metastatic bone disease: diagnosis, evaluation, and treatment. J Bone Joint Surg Am. 91(6):1518–1530.
  • Cossetto DJ, Gouda AD. 2011. Uncemented tibial fixation total knee arthroplasty. J Arthroplasty. 26(1):41–44.
  • Deng Z, Zhou C, Fan Y, Peng J, Zhu X, Pei X, Yin G, Zhang X. 2016. Design and characterization of porous titanium scaffold for bone tissue engineering. Rare Met Mater Eng. 09:2287–2292.
  • Gu D, Shen Y. 2008. Processing conditions and microstructural features of porous 316L stainless steel components by DMLS. Appl Surf Sci. 255(5):1880–1887.
  • Han C, Li Y, Wang Q, Wen S, Wei Q, Yan C, Hao L, Liu J, Shi Y. 2018. Continuous functionally graded porous titanium scaffolds manufactured by selective laser melting for bone implants. J Mech Behav Biomed Mater. 80:119–127.
  • Huang K, Si-Yuan HE, De-Ping HE. 2010. Compression and energy absorption properties of gradual porous aluminum alloy. Mater Mech Eng. 34(1):77.
  • Jian-Hua YU, Zhang TL, Yan-Min BU. 2005. Revision of total hip arthroplasty using uncemented extensive porous-coated femoral components. Chin J Orthop. 25(2):110–114.
  • Karageorgiou V, Kaplan D. 2005. Porosity of 3D biomaterial scaffolds and osteogenesis. Biomaterials. 26(27):5474–5491.
  • Li YH. 2008. Biocompatibility of hip prosthesis materials. J Clin Rehabil Tissue Eng Res. 12(39):7699–7702.
  • Ning Y. 2008. Porosity of Biomaterials and Bone Ingrowth. Chin J Biomed Eng. 27(4):612–613.
  • Peng W, Shen Y. 2007. Porous 316 stainless steel of lotus root-shape fabricated by selective laser sintering. Rare Met Mater Eng. 36(6):1070–1073.
  • Su HJ, Wei KC, Guo W, Ma LW, Yu RL, Zhang B, Zhang J, Liu L, Fu HZ. 2013. New development of laser rapid forming and its application in high performance materials processing. Chin J Nonferrous Met. 23(6):1567–1574.
  • Shen YF, Gu DD, Wu P. 2013. Development of porous 316L stainless steel with controllable microcellular features using selective laser melting. Met Sci J. 24(12):1501–1505.
  • Spector M, Michno MJ, Smarook WH, Kwiatkowski GT. 1978. A high-modulus polymer for porous orthopedic implants: biomechanical compatibility of porous implants. J Biomed Mater Res. 12(5):665–677.
  • Xiao D-M. 2013. Modeling of porous structure of implants and direct manufacturing by selective laser melting [doctoral dissertation]. South China University of Technology, 1–2.
  • Xiao D-M, Yang Y-Q, Su X-B, Wang D, Luo Z-y. 2012. Topology optimization of microstructure and selective laser melting fabrication for metallic biomaterial scaffolds. Trans Nonferrous Met Soc China. 22(10):2554–2561.
  • Xiao-Wei Z, Yan-Li W, Li C. 2014. Research on mechanical properties and the parameters of porous metal medium. Mater. Sci. Eng. 2:55–59.
  • Xu JL, Bao LZ, Liu AH, Jin XJ, Tong YX, Luo JM, Zhong ZC, Zheng YF. 2015. Microstructure, mechanical properties and superelasticity of biomedical porous NiTi alloy prepared by microwave sintering. Mater Sci Eng C Mater Biol Appl. 46:387–393.
  • Xu Z-J, Wang QH, Li J-R. 2016. Rapid 3D modeling of porous metal fiber sintered felt with multi-scale morphology. J Softw. 27:2622–2631.
  • Yánez A, Herrera A, Martel O, Monopoli D, Afonso H. 2016. Compressive behaviour of gyroid lattice structures for human cancellous bone implant applications. Mater Sci Eng C. 68:445–448.

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