Your search keyword '"YUAN Xin-hua"' showing total 4 results

1. Finite element analysis of anatomic plate fixation for proximal clavicular fractures.

Author

ZHENG Yi, ZHANG Jia-kai, WU Jun-long, and YUAN Xin-hua

Published

2024

2. Digital study on proximal clavicle anatomical plate based on 3D printing technology.

Author

ZHENG Yi, ZHENG Xing-guo, ZHANG Jia-kai, Jun-long, and YUAN Xin-hua

Published

2024

3. [Finite element analysis of anatomic plate fixation for proximal clavicular fractures].

Author

Zheng Y, Zhang JK, Wu JL, and Yuan XH

Subjects

Humans, Male, Adult, Finite Element Analysis, Clavicle surgery, Clavicle injuries, Bone Plates, Fracture Fixation, Internal methods, Fractures, Bone surgery

Abstract

Objective: To explore establishment and finite element analysis of personalized proximal clavicular anatomical plate screw fixation model., Methods: A 40-year-old male healthy volunteer was selected and the finite element analysis modules of 3D reconstruction software Mimics 15.01, Hypermesh 2019 and Abaqus 2020 were used. The finite element model of anatomic plate at the proximal clavicle was established, and a vertical load of 250 N was applied to the distal end of long axis of clavicle about 15 mm, then the overall structure, plate and screw displacement cloud image, Mises stress distribution were observed., Results: The displacement distribution of the overall structure shows the maximum displacement was distributed on the distal clavicle. Under the four conditions of normal upper limb weight, longitudinal clavicle fracture, oblique fracture and shoulder impact violence during fall, longitudinal clavicle fracture and oblique fracture, the maximum displacement were 1.04 mm, 1.03 mm, 1.35 mm and 1.33 mm, respectively. The displacement cloud map of titanium alloy steel plate showed the largest displacement was distributed near the distal clavicular bone, and the maximum displacement were 0.89 mm, 0.88 mm, 1.10 mm and 1.09 mm, respectively. The displacement cloud map of titanium alloy screw showed the largest displacement was distributed at the root of the distal screw, and the maximum displacement were 0.88 mm, 0.87 mm, 1.08 mm and 1.06 mm, respectively. Mises stress distribution showed the maximum stress was mainly distributed on titanium alloy plates and screws, and the stress on the clavicle was very small. Mises stress distribution cloud showed the maximum Mises stress was distributed at the second row of screw holes near the clavicle, and the maximum Mises stress were 673.1, 678.1, 648.5, 654.4 MPa, respectively. The maximum stresses of titanium alloy screws were 414.5, 417.4, 415.8 and 419.7 MPa, respectively., Conclusion: The biomechanical changes of personalized proximal clavicular anatomical plates are demonstrated by using 3D finite element method to provide biomechanical data for personalized proximal clavicular anatomical plates.

Published

2024

4. [Digital study on proximal clavicle anatomical plate based on 3D printing technology].

Author

Zheng Y, Zheng XG, Zhang JK, Wu JL, and Yuan XH

Subjects

Male, Humans, Middle Aged, Retrospective Studies, Clavicle diagnostic imaging, Clavicle surgery, Printing, Three-Dimensional, Bone Plates, Fracture Fixation, Internal methods, Fractures, Bone diagnostic imaging, Fractures, Bone surgery

Abstract

Objective: To explore feasibility of 3D metal printing technology combined with virtual design proximal clavicle anatomical plate., Methods: A 52-year-old male healthy volunteer was retrospectively selected to design proximal clavicle anatomical plate system by using Mimics15.01,NX12.0 and other software. STL data were input into 3D printer to print 1:1 clavicle model and proximal clavicle anatomical plate. The fit of the plate was tested in vitro and the accuracy of screw position was evaluated by imaging. Printing time of model,nail path design and fabrication time of the anatomical plate at proximal clavicle were recorded., Results: The 3D metal printing proximal clavicle anatomical plate fitted well to clavicle model,orientation of proximal clavicle locking screw was accurate,and X-ray and CT scan showed the screw position was good. Printing time of model,the time of nail path design,and the time of making anatomical plate of proximal clavicle were 120,15 and 300 min respectively., Conclusion: The proximal clavicular anatomical plate system based on 3D metal printing technology could achieve good lamination of proximal clavicular fracture plate and precise screw placement,providing a new and accurate surgical method for the treatment of the proximal clavicular fracture.

Published

2024