1.Research on the relationship of interpersonal acceptance and loneliness of college students
Yaoyang WEI ; Meng XIONG ; Rensheng HAN
Chinese Journal of Behavioral Medicine and Brain Science 2008;17(5):455-456
Objective To investigate the relationship between interpersonal acceptance and loneliness of college students.Methods 510 college students were administered by interpersonal acceptance scale(IASCS)and UCLA loneliness scale.Results (1)As a whole,there exists great capable difference of interpersonal acceptance according their genders,grades(t=5.37,P<0.01,t=12.56,P<0.01).(2)Significant negative correlation exist great capable difference about the scores of loneliness between the higher and lower acceptance of college students(P<0.01).(4)Analysis of regression indicates that interpersonal acceptance has significant predictable effects on loneliness.Conclusion Interpersonal acceptance is the important factor influencing loneliness in college students.
2.Accuracy of three dimensional facial measurement system based on structured light projection
Yaoyang XIONG ; Xiaobo CHEN ; Jian SUN ; Fuqiang ZHANG ; Juntong XI
Journal of Shanghai Jiaotong University(medical Science) 2010;30(1):66-69
Objective To investigate the accuracy of three dimensional facial measurement system based on structured light projection, and explore the methods to reduce noise of the output images. Methods The known object for calibration was measured by the measurement system to correct the parameters of the system and enhance the measurement accuracy. The mechanism of noise was analysed, and the noise and sundry of the images were eliminated. Results The parameters of each assembly of system were obtained by calculation and calibrated, and the measurement accuracy (0.028 mm) of three dimensional facial measurement system based on structured light projection was increased. Application of image processing technology reduced the noise and sundry of output images. Conclusion The accuracy of three dimensional facial measurement system based on structured light projection is high. The image output is reliable, and can be clinically used in facial scanning and three dimensional reconstruction.
3.Experimental research on porous titanium implant fabricated by three-dimensional printing with different sintering temperatures
Jian SUN ; Yaoyang XIONG ; Ping CHEN ; Fuqiang ZHANG
International Journal of Biomedical Engineering 2012;(6):332-336,342
Objective The aim of this study was to evaluate the feasibility of three-dimensional printing (3DP) for the preparation of porous titanium implant and to investigate the impacts on microstructure and mechanical properties with different sintering temperatures.Methods The CAD model of the specimens was designed to be 25 mm in diameter,20 mm in height,and with 0.5 mm pore size mesh.On every cross-section,80% bonding area was designed.Titanium powder (purity of 98.5%,75 μm diameter) was selected as raw material.Polyvinyl alcohol powder (160 μm diameter) was selected as a binder,and polyvinylpyrrolidone powder was selected as an auxiliary binder.The green porous titanium implants were fabricated by 3DP followed by sintering at 1 200,1 300,1 400 ℃,separately,under the protection of argon gas.After sintering,the properties of porous titanium implants were evaluated,including the porosity,microstructure,microhardness,compressive strength and elastic modulus.Results After sintering,the specimen had uniform contraction and no obvious distortion.The specimen sintered at 1 200,1 300 and 1 400 ℃ sintering temperatures had porosity of (65.01±1.03)%,(46.73±0.73)% and (41.06±0.31)%,hardness of 115.2±0.6,148.6±1.1 and 182.8±2.1,elastic modulus of (5.9±0.5),(16.2±0.9) and (34.8±1.5) GPa,compressive strength of (81.3±4.3),(135.4±8.5) and (218.6±7.1) MPa,respectively.A porous structure with three-dimensional network of connected pores was observed under scanning electron microscope.Conclusion It is feasible to fabricate porous titanium implants by three dimensional printing technique.The mechanical properties of the porous titanium implants match well with bone tissue which has excellent biomechanical compatibility.
4.Studies on personalized porous titanium implant fabricated using three-dimensional printing forming technique.
Yaoyang XIONG ; Ping CHEN ; Jian SUN
Journal of Biomedical Engineering 2012;29(2):247-250
Three-dimensional printing (3DP) forming technology can shape personalized porous implant material with complex shape and fine structure to meet the various needs of different patients. In this paper, the green parts of porous titanium implants with diameter 25 mm x 20 mm were prepared using 3DP, and then debinded at 500 degrees C under vacuum. Finally they were sintered in the argon gas at 1 300 degrees C. The pore sizes were observed, and they were between 50-150 microm under SEM. The results of porosity, bulk density, Vickers hardness, compressive strength and elastic modulus were (44.26% +/- 2.43)%, (2.59 +/- 0.81)g/cm3, 134.2-151.6 (61.2 +/- 3.2) MPa, (3.25 +/- 1.08) GPa, respectively. That shows excellent biomechanical compatibility. It is concluded that 3DP has wide application for fabrication of personalized porous titanium implant.
Biocompatible Materials
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chemistry
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Bone Substitutes
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chemistry
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Computer-Aided Design
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Materials Testing
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Porosity
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Prostheses and Implants
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Stress, Mechanical
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Tensile Strength
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Titanium
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chemistry
5. Comparison of adaptation and microstructure of titanium upper complete denture base fabricated by selecting laser melting and electron beam melting
Ye YE ; Yaoyang XIONG ; Jiarui ZHU ; Jian SUN
Chinese Journal of Stomatology 2017;52(6):346-350
Objective:
To fabricate Ti alloy frameworks for a maxillary complete denture with three-dimensional printing (3DP) technique, such as selective laser melting (SLM) and electron beam melting (EBM), and to evaluate the microstructure of these frameworks and their adaptation to the die stone models.
Methods:
Thirty pairs of edentulous casts were divided into 3 groups randomly and equally. In each group, one of the three techniques (SLM, EBM, conventional technique) was used to fabricate Ti alloy frameworks. The base-cast sets were transversally sectioned into 3 sections at the distal of canines, mesial of first molars, and the posterior palatal zone. The gap between the metal base and cast was measured in the 3 sections. Stereoscopic microscope was used to measure the gap. Three pieces of specimens of 5 mm diameter were fabricated with Ti alloy by SLM, EBM and the traditional casting technology (as mentioned above). Scanning electron microscope (SEM) was used to evaluate the differences of microstructure among these specimens.
Results:
The gaps between the metal base and cast were (99.4±17.0), (98.2±26.1), and (99.6± 16.1) μm in conventional method; (99.4 ± 22.8), (83.1 ± 19.3), and (103.3 ± 13.8) μm in SLM technique; (248.3±70.3), (279.1±71.9), and (189.1±31.6) μm in EBM technique. There was no statistical difference in the value of gaps between SLM Ti alloy and conventional method Ti alloy group (