Ti–Ge binary alloy system developed as potential dental materials
Identifieur interne : 003612 ( Main/Exploration ); précédent : 003611; suivant : 003613Ti–Ge binary alloy system developed as potential dental materials
Auteurs : Wen-Jiao Lin [République populaire de Chine] ; Ben-Li Wang [République populaire de Chine] ; Ke-Jin Qiu [République populaire de Chine] ; Fei-Yu Zhou [République populaire de Chine] ; Li Li [République populaire de Chine] ; Jun-Pin Lin [République populaire de Chine] ; Yan-Bo Wang [République populaire de Chine] ; Yu-Feng Zheng [République populaire de Chine]Source :
- Journal of Biomedical Materials Research Part B: Applied Biomaterials [ 1552-4973 ] ; 2012-11.
Descripteurs français
- Wicri :
- topic : Alliage, Biomatériau, Corrosion, Titane.
English descriptors
- KwdEn :
- Acta, Acta biomater, Alloy, Alloy system, Alloying, Alloying additions, Alloying elements, Alloying elements content, Alloys changes, Alloys compd, Alloys display, Alloys show, Appl biomater, Astra tech, Berlin heidelberg, Binary, Binary alloy system, Binary alloys, Binary alloys figure, Biomater, Biomaterials, Biomed, Biomed mater, Biomedical, Biomedical applications, Biomedical materials research, Broblast cells, Cast alloys, Cell viability, Clinical dentistry, Contract grant number, Contract grant numbers, Contract grant sponsor, Corroded surfaces, Corrosion, Corrosion behavior, Corrosion mechanism, Corrosion resistance, Cytotoxicity, Cytotoxicity grade, Cytotoxicity test, Cytotoxicity tests, Days culture, Days immersion, Deformation behavior, Dent, Dent mater, Dental alloys, Dental applications, Dental cast alloys, Dental implants, Dental materials, Detection limit, Dietary supplement, Diffraction patterns, Dmem medium, Electrochemical, Electrochemical corrosion behavior, Electrochemical measurements, Electrochim acta, Excellent corrosion resistance, Experimental alloys, Experimental materials, Experimental results, Extraction medium, Fuayama mayer saliva, Germanium dioxide, Gold alloys, Grain boundary, Hardness, Higher corrosion resistance, Human osteosarcoma cells, Immersion, Immersion solutions, Immersion test, Implant, Implant dentistry, Lactic, Lactic acid, Light weight, Mater, Mechanical properties, Microstructure, Online issue, Open circuit, Oral environment, Osteosarcoma cells, Passivation, Phase constitution, Precipitation phase, Present study, Research report figure, Room temperature, Saliva, Secondary phase, Single phase, Small amount, Surface area, Tensile properties, Tensile strength, Tio2, Titanium, Titanium alloys, Unlubricated condition, Unlubricated conditions, Uoridated saliva, Uoride, Uoride concentration, Volume fraction, Weak peaks, Weight losses, Wiley periodicals.
- Teeft :
- Acta, Acta biomater, Alloy, Alloy system, Alloying, Alloying additions, Alloying elements, Alloying elements content, Alloys changes, Alloys compd, Alloys display, Alloys show, Appl biomater, Astra tech, Berlin heidelberg, Binary, Binary alloy system, Binary alloys, Binary alloys figure, Biomater, Biomaterials, Biomed, Biomed mater, Biomedical, Biomedical applications, Biomedical materials research, Broblast cells, Cast alloys, Cell viability, Clinical dentistry, Contract grant number, Contract grant numbers, Contract grant sponsor, Corroded surfaces, Corrosion, Corrosion behavior, Corrosion mechanism, Corrosion resistance, Cytotoxicity, Cytotoxicity grade, Cytotoxicity test, Cytotoxicity tests, Days culture, Days immersion, Deformation behavior, Dent, Dent mater, Dental alloys, Dental applications, Dental cast alloys, Dental implants, Dental materials, Detection limit, Dietary supplement, Diffraction patterns, Dmem medium, Electrochemical, Electrochemical corrosion behavior, Electrochemical measurements, Electrochim acta, Excellent corrosion resistance, Experimental alloys, Experimental materials, Experimental results, Extraction medium, Fuayama mayer saliva, Germanium dioxide, Gold alloys, Grain boundary, Hardness, Higher corrosion resistance, Human osteosarcoma cells, Immersion, Immersion solutions, Immersion test, Implant, Implant dentistry, Lactic, Lactic acid, Light weight, Mater, Mechanical properties, Microstructure, Online issue, Open circuit, Oral environment, Osteosarcoma cells, Passivation, Phase constitution, Precipitation phase, Present study, Research report figure, Room temperature, Saliva, Secondary phase, Single phase, Small amount, Surface area, Tensile properties, Tensile strength, Tio2, Titanium, Titanium alloys, Unlubricated condition, Unlubricated conditions, Uoridated saliva, Uoride, Uoride concentration, Volume fraction, Weak peaks, Weight losses, Wiley periodicals.
Abstract
As‐cast Ti–xGe (x = 2, 5, 10, 20 wt %) binary alloys were produced in this work, and various experiments were carried out to investigate the microstructure, mechanical properties, in vitro electrochemical and immersion corrosion behaviors as well as cytotoxicity with as‐cast pure Ti as control, aiming to study the feasibility of Ti–xGe alloy system as potential dental materials. The microstructure of Ti–xGe alloys changes from single α‐Ti phase to α‐Ti + Ti5Ge3 precipitation phase with the increase of Ge content. Mechanical tests show that Ti–5Ge alloy has the best comprehensive mechanical properties. The corrosion behavior of Ti–xGe alloys in artificial saliva with different NaF and lactic acid addition at 37°C indicates that Ti–2Ge and Ti–5Ge alloys show better corrosion resistance to fluorine‐containing solution. The cytotoxicity test indicates that Ti–xGe alloy extracts show no obvious reduction of cell viability to L‐929 fibroblasts and MG‐63 osteosarcoma cells, similar to pure Ti which is generally acknowledged to be biocompatible. Considering all these results, Ti–2Ge and Ti–5Ge alloys possess the optimal comprehensive performance and might be used as potential dental materials. © 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 2012.
Url:
DOI: 10.1002/jbm.b.32793
Affiliations:
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<term>Alloying</term>
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<term>Alloys compd</term>
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<term>Alloys show</term>
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<term>Grain boundary</term>
<term>Hardness</term>
<term>Higher corrosion resistance</term>
<term>Human osteosarcoma cells</term>
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<term>Immersion test</term>
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<term>Mechanical properties</term>
<term>Microstructure</term>
<term>Online issue</term>
<term>Open circuit</term>
<term>Oral environment</term>
<term>Osteosarcoma cells</term>
<term>Passivation</term>
<term>Phase constitution</term>
<term>Precipitation phase</term>
<term>Present study</term>
<term>Research report figure</term>
<term>Room temperature</term>
<term>Saliva</term>
<term>Secondary phase</term>
<term>Single phase</term>
<term>Small amount</term>
<term>Surface area</term>
<term>Tensile properties</term>
<term>Tensile strength</term>
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<term>Titanium</term>
<term>Titanium alloys</term>
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<term>Unlubricated conditions</term>
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<term>Weight losses</term>
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<term>Alloying elements</term>
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<term>Cytotoxicity</term>
<term>Cytotoxicity grade</term>
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<term>Days immersion</term>
<term>Deformation behavior</term>
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<term>Dental alloys</term>
<term>Dental applications</term>
<term>Dental cast alloys</term>
<term>Dental implants</term>
<term>Dental materials</term>
<term>Detection limit</term>
<term>Dietary supplement</term>
<term>Diffraction patterns</term>
<term>Dmem medium</term>
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<term>Electrochemical corrosion behavior</term>
<term>Electrochemical measurements</term>
<term>Electrochim acta</term>
<term>Excellent corrosion resistance</term>
<term>Experimental alloys</term>
<term>Experimental materials</term>
<term>Experimental results</term>
<term>Extraction medium</term>
<term>Fuayama mayer saliva</term>
<term>Germanium dioxide</term>
<term>Gold alloys</term>
<term>Grain boundary</term>
<term>Hardness</term>
<term>Higher corrosion resistance</term>
<term>Human osteosarcoma cells</term>
<term>Immersion</term>
<term>Immersion solutions</term>
<term>Immersion test</term>
<term>Implant</term>
<term>Implant dentistry</term>
<term>Lactic</term>
<term>Lactic acid</term>
<term>Light weight</term>
<term>Mater</term>
<term>Mechanical properties</term>
<term>Microstructure</term>
<term>Online issue</term>
<term>Open circuit</term>
<term>Oral environment</term>
<term>Osteosarcoma cells</term>
<term>Passivation</term>
<term>Phase constitution</term>
<term>Precipitation phase</term>
<term>Present study</term>
<term>Research report figure</term>
<term>Room temperature</term>
<term>Saliva</term>
<term>Secondary phase</term>
<term>Single phase</term>
<term>Small amount</term>
<term>Surface area</term>
<term>Tensile properties</term>
<term>Tensile strength</term>
<term>Tio2</term>
<term>Titanium</term>
<term>Titanium alloys</term>
<term>Unlubricated condition</term>
<term>Unlubricated conditions</term>
<term>Uoridated saliva</term>
<term>Uoride</term>
<term>Uoride concentration</term>
<term>Volume fraction</term>
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<term>Weight losses</term>
<term>Wiley periodicals</term>
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<front><div type="abstract" xml:lang="en">As‐cast Ti–xGe (x = 2, 5, 10, 20 wt %) binary alloys were produced in this work, and various experiments were carried out to investigate the microstructure, mechanical properties, in vitro electrochemical and immersion corrosion behaviors as well as cytotoxicity with as‐cast pure Ti as control, aiming to study the feasibility of Ti–xGe alloy system as potential dental materials. The microstructure of Ti–xGe alloys changes from single α‐Ti phase to α‐Ti + Ti5Ge3 precipitation phase with the increase of Ge content. Mechanical tests show that Ti–5Ge alloy has the best comprehensive mechanical properties. The corrosion behavior of Ti–xGe alloys in artificial saliva with different NaF and lactic acid addition at 37°C indicates that Ti–2Ge and Ti–5Ge alloys show better corrosion resistance to fluorine‐containing solution. The cytotoxicity test indicates that Ti–xGe alloy extracts show no obvious reduction of cell viability to L‐929 fibroblasts and MG‐63 osteosarcoma cells, similar to pure Ti which is generally acknowledged to be biocompatible. Considering all these results, Ti–2Ge and Ti–5Ge alloys possess the optimal comprehensive performance and might be used as potential dental materials. © 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 2012.</div>
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<name sortKey="Qiu, Ke In" sort="Qiu, Ke In" uniqKey="Qiu K" first="Ke-Jin" last="Qiu">Ke-Jin Qiu</name>
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<name sortKey="Wang, Yan O" sort="Wang, Yan O" uniqKey="Wang Y" first="Yan-Bo" last="Wang">Yan-Bo Wang</name>
<name sortKey="Zheng, Yu Eng" sort="Zheng, Yu Eng" uniqKey="Zheng Y" first="Yu-Feng" last="Zheng">Yu-Feng Zheng</name>
<name sortKey="Zheng, Yu Eng" sort="Zheng, Yu Eng" uniqKey="Zheng Y" first="Yu-Feng" last="Zheng">Yu-Feng Zheng</name>
<name sortKey="Zheng, Yu Eng" sort="Zheng, Yu Eng" uniqKey="Zheng Y" first="Yu-Feng" last="Zheng">Yu-Feng Zheng</name>
<name sortKey="Zheng, Yu Eng" sort="Zheng, Yu Eng" uniqKey="Zheng Y" first="Yu-Feng" last="Zheng">Yu-Feng Zheng</name>
<name sortKey="Zhou, Fei U" sort="Zhou, Fei U" uniqKey="Zhou F" first="Fei-Yu" last="Zhou">Fei-Yu Zhou</name>
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