Page 135 - IJB-9-2
P. 135
International Journal of Bioprinting Design and manufacture of high-performance bone plate
was good. No obvious warpage, deformation, or molding References
defects were found. The structure between the pillars of
the porous structures was clear, the lap joint was good, and 1. Wu C, Zheng Z, Chen X, et al., 2016, Digital internal
there was little powder adhesion near the pores. There was fixation of bone plate based on 3D printing of standard
no apparent contact gap between the B-shaped plate and parts library of distal femoral fracture. China Tissue Eng Res,
the host bone as well as the H-shaped plate and the host 20(13):1895–1903.
bone; they were closely mated. The screw fixation hole was 2. Zhang C, Jia D, Li F, et al., 2021, Design and simulation of
positioned correctly and met the assembly requirements. titanium alloy lattice bone plate for 3D printing. J Shanghai
Jiaotong Univ, 55(02):170–178.
In order to further understand the design and
manufacturing of personalized biological fixation plates, 3. Xu Y, Liu B, Zhang Y, et al., 2019, Analysis of the application
follow-up studies on the design of plates with gradient porous effect of S2 alar screw in 23 cases of complex lower lumbar
and mixed porous structures, SLM-molded porous structure surgery. Fujian Med J, 41(02):37–40.
processing, as well as thermal treatment processing are 4. Zhang G, Li J, Li J, et al., 2021. Selective laser melting
needed, so as to lay the foundation for direct manufacturing molding of individualized femur implant: Design, process,
of high-performance biological fixation plates using SLM. optimization. J Bionic Eng, 18(1):128–137.
Acknowledgments 5. García-León RA, Gómez-Camperos JA, Jaramillo HY, 2021,
Scientometric review of trends on the mechanical properties
None of additive manufacturing and 3D printing. J Mater Eng
Perform, 30(7), 4724–4734.
Funding 6. Caminero MN, Gutiérrez AR, Chacón Muoz JM, et al.,
This study was funded by the Key Scientific Research 2021. Additive manufacturing of 316L stainless-steel
Projects of Colleges and Universities in Henan Province structures using fused filament fabrication technology:
(22A460006) and supported by the Analytical and Testing Mechanical and geometric properties. Rapid Prototyp J,
Center of ZKNUC for carrying out microscopic analysis. 27(3), 583–591.
7. Wu H, Li J, Wei Z, et al., 2020, Effect of processing
Conflict of interest parameters on forming defects during selective laser melting
of AlSi10Mg powder. Rapid Prototyp J, 26 (5) , 871–879.
The authors report no conflicts of interest.
8. Hu X, He M, Min L, et al., 2020, Early efficacy evaluation of
Author contributions 3D printed porous metal support prosthesis in the treatment
of Campanacci grade I and II giant cell tumor of bone in the
Conceptualization: Zhang Guoqing proximal tibia. Chin J Bone Joint Surg, 13(12):1023–1029.
Funding acquisition: Zhang Guoqing
Investigation: Zhang Guoqing, Li Junxin, Zhou Xiaoyu 9. Li Z, Xue J, 2019, Research progress on the effect of 3D
Formal analysis: Zhang Guoqing, Zhou Yongsheng printed porous titanium alloy pore structure on bone
induction. Chin J Orthop Clin Basic Res, 11(06):358–363.
Writing – original draft: Zhang Guoqing, Zhou Yongsheng
Writing – review & editing: Bai Yuchao 10. Jia D, Li F, Zhang C, et al., 2019, Design and simulation
analysis of lattice bone plate based on finite element method.
Ethics approval and consent to participate Mech Adv Mater Struct, 28(13), 1311–1321.
The bone model in this study was downloaded from the 11. Pobloth AM, Checa S, Razi H, et al., 2018,
public database of Mimics software, and the data is publicly Mechanobiologically optimized 3D titanium-mesh scaffolds
available, so ethical review is not involved. enhance bone regeneration in critical segmental defects in
sheep. Sci Transl Med, 10(423):eaam8828.
Consent for publication 12. Wang L, Kang J, Sun C, et al., 2017, Mapping porous
All authors have signed a paper publication agreement for microstructures to yield desired mechanical properties for
application in 3D printed bone scaffolds and orthopaedic
publication in the International Journal of Bioprinting.
implants. Mater Design, 133:62–68.
Availability of data 13. Kanu NJ, Patwardhan D, Gupta E, et al., 2020, Finite
element analysis of mechanical response of fracture fixation
The datasets used and/or analyzed during the current study functionally graded bone plate at paediatric femur bone
are available from the corresponding author on reasonable fracture site under compressive and torsional loadings.
request. Mater Today Proc, 38:2817–2823.
Volume 9 Issue 2 (2023) 127 https://doi.org/10.18063/ijb.v9i2.658
