Application of Fourier Transform for Analysis of Surface Topographic Properties of Dental Zirconia

Q4 Engineering Nano Biomedicine Pub Date : 2013-01-01 DOI:10.11344/NANO.5.85
Naoyoshi Tarumi, T. Akasaka, F. Watari
{"title":"Application of Fourier Transform for Analysis of Surface Topographic Properties of Dental Zirconia","authors":"Naoyoshi Tarumi, T. Akasaka, F. Watari","doi":"10.11344/NANO.5.85","DOIUrl":null,"url":null,"abstract":"2.2. Fracture surface The block of 3 mm high, 50 mm long with the upper surface of 2 mm width and the lower surface of 1.8 mm width was cut from zirconia cylinder and sintered at 1350◦C as recommended by Product Company. The size of cross-section of zirconia block was selected to fit to the clinical fracture case. It was fractured manually through bending by loading from upper to lower surface without any treatment on the sintered surface. Clinically derived fracture zirconia was also used as sample. 2.3. Observation Variously treated surfaces and fractured cross-sections were observed by FE-SEM (S4000: Hitachi, Tokyo, Japan). 2.4. Contact angle measurement The contact angles with water were measured for the surface of zirconia after silicone wheel, sandblast and tribochemical treatments with DMs-200 (Drop Master S series: Kyowa Interface Science Co.Ltd, Saitama, Japan) Measurements were performed 10times for each. All experimental results were evaluated by Non-repeated Measures ANOVA (n = 10) (p < 0.001). 2.5. Surface roughness measurement The surface roughness was measured using SURFCOM 1400A (Tokyo Seimitu, Japan) after the treatments with silicone wheel, sandblast, tribochemical treatments, mirror polishing and porcelain layering. 3. Results Fig. 1 shows SEM observation of smoothed zirconia surface. Fig. 1a is silicone wheel polishing, Fig. 1b is mirror polishing, and Fig. 1c is porcelain layering. The surfaces after mirror polishing were smooth except mechanically formed grooves during silicone wheel polishing. Porcelain layering was smooth except large formed grooves by bubbles. Both mirror polishing and porcelain layering look similarly smooth. Fig. 2 shows SEM observation of roughened zirconia surface, for silicone wheel polishing Fig. 2a, sandblast treatment Fig. 2b and tribochemical treatment Fig. 2c. After sandblast and tribochemical treatments, the surfaces showed several micron-sized caving with micron to submicron level irregularities. When Fig. 2b and c were compared, the latter was slightly rougher. Fig. 3 is the enlargement of roughened zirconia surface by SEM observation. Fig. 3a is tribochemical treatment, and Fig. 3b is 24-hacid treatment. 24-h acid treatment induced much more surface roughening with the 50–100 nm particulate roughness than tribochemical treatments. Fig. 4 shows the specimens of dental zirconia. Fig. 4a shows zirconia cylinder supplied for dental CAD/CAM machining and a fabricated bridge. Fig. 4b is the fractured block and matchstick behind for reference of size. Block was obtained by milling from zirconia cylinder. Fig. 4c is fractured zirconia bridge used in clinical case and d is enlargement of pontic with fracture cross-section seen as white plane in right side. Fracture occurred nearly in the center of bridge c. Fig. 5 is SEM observation of fracture cross-section, Fig. 5a clinically fractured, Fig. 5b enlargement of Fig. 5a, Fig. 5c experimentally fractured, Fig. 5d enlargement of Fig. 5b. Clinically occurred fracture exhibited the scab-like surface. For experimentally attained fracture surface cracks were formed straight in most part and in some places curved or twisted into S or Ωform. Figs. 6 and 7 show the photographs and the corresponding mean and standard deviation of the contact angle with water, respectively. Fig. 6a is silicone wheel polishing, Fig. 6b is sandblast treatment, and Fig. 6c is tribochemical treatment. In Fig. 7 all these treatments showed a significant difference each other (p<0.001). The average contact angles were 91.6 ± 4.8◦ (SW), 65.6 ± 8.0◦ (SB), and 51.4 ± 4.8◦ (TC). Sandblast and tribochemical treatments had the smaller water contact angle than silicone wheel polishing. Fig. 8 shows the surface roughness of zirconia with various treatments. The measured values of mean surface roughness Ra were 0.12μm for silicone wheel polishing, 0.26 μm for sandblast treatment, 0.32μm for tribochemical treatment, 0.11 μm for mirror polishing and 1.45μm for Porcelain layering. Porcelain layering showed the largest roughness. Mirror polishing roughness had the smoothest surface. 4. Discussion 4.1. Suitable surface treatments for dental zirconia To have the good adhesion of porcelain onto zirconia, the wettability is important. Sandblast and tribochemical treatments showed the contact angle smaller than silicone wheel treatment (Figs. 6 and 7), which provides the improved wettability. This maybe mainly due to the increased surface roughness granted by sandblast and tribochemical treatments (Fig. 8). Both treatments are effective to enhance the adhesion of zirconia with resin cement to fix on teeth and for bonding of porcelain [3]. Plaque tends to attachment more easily to the rougher surfaces [4]. In the surface roughness measurement, porcelain layering showed the largest mean roughness (Ra 1.45). Only porcelain layering treatment was done manually with the human hands. During the process of condensing of porcelain powders, they contain bubbles inside. By the following glazing process, bubbles go out then the large and gradually sloped grooves are formed. This may cause the larger roughness with the longer periodicity. Except there large grooves, however, the surface is quite smooth with the much less high frequency roughness with the small periodicity. On the other hand, although Ra is smaller, SB and TC had much more high frequency roughness, which leads to the easier plaque attachment. Thus the large Ra value of PL has nothing to do with plaque attachment. From the aspect of plaque attachment, zirconia surface with the high frequency roughness without porcelain layering like SB and TC is recommended to be polished. The 24-h acid treatment done in this study deteriorated the surface (Fig. 3b). The acid treatment is used to dissolve the porcelain to replace with the new one in such cases that the matching of color shade dose not fit well. When the amount of porcelain is large, the acid treatment needs a longer time. If the acid treatment time is less than 10 min, zirconia suffers little damage. To shorten acid treatment time, it is preferable to remove porcelain mechanically as much as possible before the acid treatment. When there are possibilities to choose treatments from various ones, it is also important to pay attention to health care in working condition. Some surface treatments produce abraded powders whose nano particles may induce the health risk to human body [5]. Most treatments shown in this study were done under water spray, which decreases the risk to much lower level. 4.2. Fracture of zirconia In the cross-section of experimentally fractured samples, cracks were formed straight in most part and in some places curved or twisted into S or Ω form. This suggests that crack propagation was obstructed by the fracture toughness of zirconia resulted from martensitic crystalline transformation [6,7].In clinics, complex stress is applied in mouth and it is not a simple bending deformation mode to one direction at one time. Various deformation mode of tension, bending, twist and fatigue in various directions are imposed many times for long time. Therefore fracture was progressed little by little in a long time. This resulted scab-like morphology in fracture surface. 5. Conclusions This study evaluated the surface morphology and wettability after various treatments done in the fabrication process of dental zirconia. There is the tendency that the larger surface roughness leads to better wettability, which may be one of the factors to con-tribute to the better bonding of porcelain onto the zirconia surface. References [1] M. Uo, G. Sjogren, A. Sundh, M. Goto, F. Watari, Dental Materials Journal 25 (3)(2006) 626–631. [2] P. Benetti, A.D. Della Bona, J.R. Kelly, Dental Materials 26 (2010) 743–750. [3] W.-S. Oh, C. Shen, B. Alegre, K.J. Anusavice, Journal of Prosthetic Dentistry 88 (6)(2002) 616–621 [4] M.I. Al-Marzok, H.J. Al-Azzawi, Journal of Contemporary Dental Practice 10 (6)(2009) 017–24. [5] F. Watari, N. Takashi, A. Yokoyama, M. Uo, T. Akasaka, Y. Sato, S. Abe, Y. Totsuka,K. Tohji, Journal of the Royal Society Interface 6 (2009) 371–388. [6]P. Christel, A. Meunier, M. Heller, J.P. Torre, C.N. Peille, Journal of BiomedicalMaterials Research 23 (1989) 45–61. [7] J. Tinschert, D. Zwez, R. Marx, K.J. Anusavice, Journal of Dentistry 28 (2000)529–535. Fig. 1. SEM observation of smoothed zirconia surface. (a) Silicone wheel polishing treatment, (b) mirror polishing, (c) porcelain layering. Fig. 2. SEM observation of roughened zirconia surface. (a) Silicone wheel polishing treatment, (b) sandblast treatment, (c) tribochemical treatment. Fig.3.Enlargement of roughened zirconia surface SEM. (a) Tribochemical treatment, (b) 24-h acid treatment. Fig. 4. (a) Zirconia cylinder for dental CAD/CAM and a fabricated bridge, (b) experimentally fractured block obtained by milling from zirconia cylinder, (c) fractured zirconia bridge used in clinical case, (d) enlargement of pontic with fracture cross-sections. Fig. 5. SEM observation of fracture cross-section. (a) Clinically fractured, (b) enlargement of (a), (c) experimentally fractured, (d) Enlargement of (c). Fig. 6. Contact angle measurements of zirconia surface with various treatments. (a) Silicone wheel (SW), (b) sandblast (SB), (c) tribochemical (TC). Fig. 7. Contact angle for the treatments. Fig. 8. Surface roughness of zirconia with various treatments. Application of Fourier transform for analysis of surface topographic properties of dental zirconia Naoyoshi TARUMI, Tsukasa AKASAKA, Fumio WATARI 1.Graduate School of Dental Medicine, Hokkaido University, Sapporo, Japan 2.Sapporo Dental Laboratory, Sapporo, Japan","PeriodicalId":19070,"journal":{"name":"Nano Biomedicine","volume":"5 1","pages":"85-94"},"PeriodicalIF":0.0000,"publicationDate":"2013-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nano Biomedicine","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.11344/NANO.5.85","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"Engineering","Score":null,"Total":0}
引用次数: 0

Abstract

2.2. Fracture surface The block of 3 mm high, 50 mm long with the upper surface of 2 mm width and the lower surface of 1.8 mm width was cut from zirconia cylinder and sintered at 1350◦C as recommended by Product Company. The size of cross-section of zirconia block was selected to fit to the clinical fracture case. It was fractured manually through bending by loading from upper to lower surface without any treatment on the sintered surface. Clinically derived fracture zirconia was also used as sample. 2.3. Observation Variously treated surfaces and fractured cross-sections were observed by FE-SEM (S4000: Hitachi, Tokyo, Japan). 2.4. Contact angle measurement The contact angles with water were measured for the surface of zirconia after silicone wheel, sandblast and tribochemical treatments with DMs-200 (Drop Master S series: Kyowa Interface Science Co.Ltd, Saitama, Japan) Measurements were performed 10times for each. All experimental results were evaluated by Non-repeated Measures ANOVA (n = 10) (p < 0.001). 2.5. Surface roughness measurement The surface roughness was measured using SURFCOM 1400A (Tokyo Seimitu, Japan) after the treatments with silicone wheel, sandblast, tribochemical treatments, mirror polishing and porcelain layering. 3. Results Fig. 1 shows SEM observation of smoothed zirconia surface. Fig. 1a is silicone wheel polishing, Fig. 1b is mirror polishing, and Fig. 1c is porcelain layering. The surfaces after mirror polishing were smooth except mechanically formed grooves during silicone wheel polishing. Porcelain layering was smooth except large formed grooves by bubbles. Both mirror polishing and porcelain layering look similarly smooth. Fig. 2 shows SEM observation of roughened zirconia surface, for silicone wheel polishing Fig. 2a, sandblast treatment Fig. 2b and tribochemical treatment Fig. 2c. After sandblast and tribochemical treatments, the surfaces showed several micron-sized caving with micron to submicron level irregularities. When Fig. 2b and c were compared, the latter was slightly rougher. Fig. 3 is the enlargement of roughened zirconia surface by SEM observation. Fig. 3a is tribochemical treatment, and Fig. 3b is 24-hacid treatment. 24-h acid treatment induced much more surface roughening with the 50–100 nm particulate roughness than tribochemical treatments. Fig. 4 shows the specimens of dental zirconia. Fig. 4a shows zirconia cylinder supplied for dental CAD/CAM machining and a fabricated bridge. Fig. 4b is the fractured block and matchstick behind for reference of size. Block was obtained by milling from zirconia cylinder. Fig. 4c is fractured zirconia bridge used in clinical case and d is enlargement of pontic with fracture cross-section seen as white plane in right side. Fracture occurred nearly in the center of bridge c. Fig. 5 is SEM observation of fracture cross-section, Fig. 5a clinically fractured, Fig. 5b enlargement of Fig. 5a, Fig. 5c experimentally fractured, Fig. 5d enlargement of Fig. 5b. Clinically occurred fracture exhibited the scab-like surface. For experimentally attained fracture surface cracks were formed straight in most part and in some places curved or twisted into S or Ωform. Figs. 6 and 7 show the photographs and the corresponding mean and standard deviation of the contact angle with water, respectively. Fig. 6a is silicone wheel polishing, Fig. 6b is sandblast treatment, and Fig. 6c is tribochemical treatment. In Fig. 7 all these treatments showed a significant difference each other (p<0.001). The average contact angles were 91.6 ± 4.8◦ (SW), 65.6 ± 8.0◦ (SB), and 51.4 ± 4.8◦ (TC). Sandblast and tribochemical treatments had the smaller water contact angle than silicone wheel polishing. Fig. 8 shows the surface roughness of zirconia with various treatments. The measured values of mean surface roughness Ra were 0.12μm for silicone wheel polishing, 0.26 μm for sandblast treatment, 0.32μm for tribochemical treatment, 0.11 μm for mirror polishing and 1.45μm for Porcelain layering. Porcelain layering showed the largest roughness. Mirror polishing roughness had the smoothest surface. 4. Discussion 4.1. Suitable surface treatments for dental zirconia To have the good adhesion of porcelain onto zirconia, the wettability is important. Sandblast and tribochemical treatments showed the contact angle smaller than silicone wheel treatment (Figs. 6 and 7), which provides the improved wettability. This maybe mainly due to the increased surface roughness granted by sandblast and tribochemical treatments (Fig. 8). Both treatments are effective to enhance the adhesion of zirconia with resin cement to fix on teeth and for bonding of porcelain [3]. Plaque tends to attachment more easily to the rougher surfaces [4]. In the surface roughness measurement, porcelain layering showed the largest mean roughness (Ra 1.45). Only porcelain layering treatment was done manually with the human hands. During the process of condensing of porcelain powders, they contain bubbles inside. By the following glazing process, bubbles go out then the large and gradually sloped grooves are formed. This may cause the larger roughness with the longer periodicity. Except there large grooves, however, the surface is quite smooth with the much less high frequency roughness with the small periodicity. On the other hand, although Ra is smaller, SB and TC had much more high frequency roughness, which leads to the easier plaque attachment. Thus the large Ra value of PL has nothing to do with plaque attachment. From the aspect of plaque attachment, zirconia surface with the high frequency roughness without porcelain layering like SB and TC is recommended to be polished. The 24-h acid treatment done in this study deteriorated the surface (Fig. 3b). The acid treatment is used to dissolve the porcelain to replace with the new one in such cases that the matching of color shade dose not fit well. When the amount of porcelain is large, the acid treatment needs a longer time. If the acid treatment time is less than 10 min, zirconia suffers little damage. To shorten acid treatment time, it is preferable to remove porcelain mechanically as much as possible before the acid treatment. When there are possibilities to choose treatments from various ones, it is also important to pay attention to health care in working condition. Some surface treatments produce abraded powders whose nano particles may induce the health risk to human body [5]. Most treatments shown in this study were done under water spray, which decreases the risk to much lower level. 4.2. Fracture of zirconia In the cross-section of experimentally fractured samples, cracks were formed straight in most part and in some places curved or twisted into S or Ω form. This suggests that crack propagation was obstructed by the fracture toughness of zirconia resulted from martensitic crystalline transformation [6,7].In clinics, complex stress is applied in mouth and it is not a simple bending deformation mode to one direction at one time. Various deformation mode of tension, bending, twist and fatigue in various directions are imposed many times for long time. Therefore fracture was progressed little by little in a long time. This resulted scab-like morphology in fracture surface. 5. Conclusions This study evaluated the surface morphology and wettability after various treatments done in the fabrication process of dental zirconia. There is the tendency that the larger surface roughness leads to better wettability, which may be one of the factors to con-tribute to the better bonding of porcelain onto the zirconia surface. References [1] M. Uo, G. Sjogren, A. Sundh, M. Goto, F. Watari, Dental Materials Journal 25 (3)(2006) 626–631. [2] P. Benetti, A.D. Della Bona, J.R. Kelly, Dental Materials 26 (2010) 743–750. [3] W.-S. Oh, C. Shen, B. Alegre, K.J. Anusavice, Journal of Prosthetic Dentistry 88 (6)(2002) 616–621 [4] M.I. Al-Marzok, H.J. Al-Azzawi, Journal of Contemporary Dental Practice 10 (6)(2009) 017–24. [5] F. Watari, N. Takashi, A. Yokoyama, M. Uo, T. Akasaka, Y. Sato, S. Abe, Y. Totsuka,K. Tohji, Journal of the Royal Society Interface 6 (2009) 371–388. [6]P. Christel, A. Meunier, M. Heller, J.P. Torre, C.N. Peille, Journal of BiomedicalMaterials Research 23 (1989) 45–61. [7] J. Tinschert, D. Zwez, R. Marx, K.J. Anusavice, Journal of Dentistry 28 (2000)529–535. Fig. 1. SEM observation of smoothed zirconia surface. (a) Silicone wheel polishing treatment, (b) mirror polishing, (c) porcelain layering. Fig. 2. SEM observation of roughened zirconia surface. (a) Silicone wheel polishing treatment, (b) sandblast treatment, (c) tribochemical treatment. Fig.3.Enlargement of roughened zirconia surface SEM. (a) Tribochemical treatment, (b) 24-h acid treatment. Fig. 4. (a) Zirconia cylinder for dental CAD/CAM and a fabricated bridge, (b) experimentally fractured block obtained by milling from zirconia cylinder, (c) fractured zirconia bridge used in clinical case, (d) enlargement of pontic with fracture cross-sections. Fig. 5. SEM observation of fracture cross-section. (a) Clinically fractured, (b) enlargement of (a), (c) experimentally fractured, (d) Enlargement of (c). Fig. 6. Contact angle measurements of zirconia surface with various treatments. (a) Silicone wheel (SW), (b) sandblast (SB), (c) tribochemical (TC). Fig. 7. Contact angle for the treatments. Fig. 8. Surface roughness of zirconia with various treatments. Application of Fourier transform for analysis of surface topographic properties of dental zirconia Naoyoshi TARUMI, Tsukasa AKASAKA, Fumio WATARI 1.Graduate School of Dental Medicine, Hokkaido University, Sapporo, Japan 2.Sapporo Dental Laboratory, Sapporo, Japan
查看原文
分享 分享
微信好友 朋友圈 QQ好友 复制链接
本刊更多论文
傅立叶变换在牙科氧化锆表面形貌分析中的应用
2.2. 从氧化锆圆筒上切下高3mm,长50mm,上表面宽2mm,下表面宽1.8 mm的块体,按照产品公司推荐1350℃烧结。选择适合临床骨折病例的氧化锆块截面尺寸。在未对烧结表面进行任何处理的情况下,由上至下表面通过人工弯曲加载进行断裂。临床来源的断裂氧化锆也作为样本。2.3. 用FE-SEM (S4000: Hitachi, Tokyo, Japan)观察了不同处理的表面和断裂截面。2.4. 接触角测量采用DMs-200 (Drop Master S系列:Kyowa Interface Science Co.Ltd .,埼玉,日本)对经过硅轮、喷砂和摩擦化学处理的氧化锆表面进行与水的接触角测量,每种测量10次。所有实验结果采用非重复测量方差分析(n = 10) (p < 0.001)。2.5. 表面粗糙度测量采用SURFCOM 1400A (Tokyo Seimitu, Japan)测量表面粗糙度,经过硅胶轮、喷砂、摩擦化学处理、镜面抛光和陶瓷分层处理。3.图1为氧化锆表面光滑后的SEM观察。图1a为硅轮抛光,图1b为镜面抛光,图1c为瓷片分层。镜面抛光后表面光滑,除硅轮抛光时机械形成的凹槽外。除气泡形成的大凹槽外,瓷层光滑。镜面抛光和瓷器分层看起来都很光滑。图2为氧化锆表面粗化后的SEM观察,硅胶轮抛光图2a,喷砂处理图2b,摩擦化学处理图2c。在喷砂和摩擦化学处理后,表面出现了几个微米大小的崩落,并具有微米到亚微米级别的不规则性。对比图2b和图c,后者略粗糙。图3为扫描电镜观察氧化锆表面粗化后的放大图。图3a为摩擦化学处理,图3b为24酸处理。与摩擦化学处理相比,酸处理24 h可使表面粗糙度达到50 ~ 100 nm。图4为牙齿氧化锆试样。图4a显示了用于牙科CAD/CAM加工的氧化锆圆柱体和制作的桥架。图4b为破碎块和后面火柴棍的尺寸参考。以氧化锆圆筒为原料,经铣削加工得到砌块。图4c为临床病例中使用的断裂的氧化锆桥,图d为桥体扩大,右侧骨折截面为白色平面。图5为断裂截面的SEM观察,图5a为临床断裂,图5b为图5a的放大图,图5c为实验断裂,图5d为图5b的放大图。临床上发生的骨折表现为痂状表面。实验得到的断口表面裂纹大部分是直的,有些地方弯曲或扭曲成S形或Ωform。图6和图7分别为与水接触角的照片及对应的平均值和标准差。图6a为硅轮抛光,图6b为喷砂处理,图6c为摩擦化学处理。如图7所示,各处理间差异均有统计学意义(p<0.001)。平均接触角为91.6±4.8◦(SW)、65.6±8.0◦(SB)和51.4±4.8◦(TC)。喷砂和摩擦化学处理的水接触角比硅轮抛光小。图8显示了不同处理的氧化锆表面粗糙度。平均表面粗糙度Ra测量值分别为:硅轮抛光0.12μm、喷砂处理0.26 μm、摩擦化学处理0.32μm、镜面抛光0.11 μm、陶瓷分层1.45μm。瓷层的粗糙度最大。镜面抛光粗糙度表面最光滑。4. 4.1讨论。为了使瓷与氧化锆具有良好的附着力,润湿性是很重要的。喷砂和摩擦化学处理的接触角比硅胶轮处理的小(图6和7),从而改善了润湿性。这可能主要是由于喷砂和摩擦化学处理增加了表面粗糙度(图8)。这两种处理都有效地增强了氧化锆与树脂水泥的附着力,以固定在牙齿上,并有助于瓷[3]的粘合。牙菌斑更容易附着在粗糙的表面上。在表面粗糙度测量中,瓷层的平均粗糙度最大,Ra为1.45。只有瓷器分层处理是用人手手工完成的。瓷粉在凝结过程中,其内部含有气泡。 通过下面的上釉工艺,气泡消失,然后形成大而逐渐倾斜的凹槽。这可能导致较大的粗糙度和较长的周期。然而,除了有较大的凹槽外,表面非常光滑,高频粗糙度小,周期性小。另一方面,虽然Ra较小,但SB和TC具有更高的高频粗糙度,这导致斑块更容易附着。因此PL的大Ra值与斑块附着无关。从斑块附着的角度来看,建议抛光SB、TC等具有高频粗糙度且无瓷层的氧化锆表面。在本研究中,24小时的酸处理使表面恶化(图3b)。在色度搭配不好的情况下,采用酸处理将瓷溶解以更换新瓷。当瓷量较大时,酸处理需要的时间较长。如果酸处理时间小于10分钟,氧化锆受到的损害很小。为缩短酸处理时间,最好在酸处理前尽量机械脱瓷。当有可能从各种治疗方法中选择治疗方法时,注意工作条件下的保健也很重要。某些表面处理会产生研磨粉末,其纳米颗粒可能对人体健康造成危害。本研究中显示的大多数治疗都是在喷水下进行的,这大大降低了风险。4.2. 在实验断裂试样的横截面上,裂纹大部分呈直线状,部分弯曲或扭曲成S形或Ω形。这表明氧化锆的马氏体结晶转变产生的断裂韧性阻碍了裂纹扩展[6,7]。在临床上,口腔受到的是复杂的应力,而不是一次向一个方向的简单弯曲变形模式。长时间多次施加不同方向的拉伸、弯曲、扭转和疲劳等多种变形方式。因此,骨折在很长一段时间内逐渐发展。这导致断口表面出现结痂状形态。5. 结论本研究评价了氧化锆牙体制备过程中不同处理对其表面形貌和润湿性的影响。表面粗糙度越大,表面润湿性越好,这可能是陶瓷与氧化锆表面结合效果越好的原因之一。参考文献[10]吴明明,郭绍仁,A. Sundh, M. Goto, F. Watari,牙科材料杂志25(3)(2006)626-631。[10]陈建军,陈建军,陈建军,中华口腔医学杂志,2010,(4):743 - 755。[3] W.-S。吴志强,沈志强,吴志强,吴志强,中华口腔医学杂志88 (6)(2002)616-621 bbbj . M.I. Al-Marzok,中华口腔医学杂志10(6)(2009)017-24。[10] Watari F., Takashi N., Yokoyama A., Uo M.,赤坂T.,佐藤Y., Abe S., Totsuka Y.,K。Tohji,《英国皇家学会界面学报》(2009)371-388。[6] P。Christel, A. Meunier, M. Heller, J.P. Torre, C.N. Peille, Journal BiomedicalMaterials Research 23(1989) 45-61。[10]陈建军,陈建军,陈建军,陈建军,中华口腔医学杂志28(2000):529-535。图1所示。光滑氧化锆表面的SEM观察。(a)硅胶轮抛光处理,(b)镜面抛光,(c)陶瓷分层。图2所示。粗糙氧化锆表面的SEM观察。(a)硅轮抛光处理,(b)喷砂处理,(c)摩擦化学处理。图3。粗糙氧化锆表面扫描电镜放大图。(a)摩擦化学处理,(b) 24小时酸处理。图4所示。(a)牙科CAD/CAM用氧化锆柱体和人造桥体,(b)实验用氧化锆柱体铣削得到的断裂块,(c)临床用断裂的氧化锆桥体,(d)断裂截面放大的桥体。图5所示。断裂截面的SEM观察。(a)临床骨折,(b) (a)放大,(c)实验骨折,(d) (c)放大。不同处理氧化锆表面接触角的测量。(a)硅胶轮(SW), (b)喷砂(SB), (c)摩擦化学(TC)。图7所示。治疗的接触角。图8所示。不同处理的氧化锆表面粗糙度。傅里叶变换在牙氧化锆表面形貌分析中的应用2.北海道大学口腔医学研究生院,日本札幌札幌牙科实验室,日本札幌
本文章由计算机程序翻译,如有差异,请以英文原文为准。
求助全文
约1分钟内获得全文 去求助
来源期刊
Nano Biomedicine
Nano Biomedicine Engineering-Biomedical Engineering
CiteScore
0.30
自引率
0.00%
发文量
0
期刊最新文献
The Double-edged Effect of Silver Nanoparticles is Determined by Their Physical Characteristics Desorption and Ionization of Amino Acid Compounds Observed by Negative Ion Mode Surface-Assisted Laser Desorption/Ionization Mass Spectrometry (SALDI-MS) using Titanium Oxide Nanoparticles Effects of Alzheimer's Disease on the Ability of Titanium Surface to Induce Hard Tissue Differentiation Cell Viability of C60 Fullerene with Three-dimensional Culture using Glass Fiber and Two-dimensional Culture Tophaceous Pseudogout in the Temporomandibular Joint: A case report
×
引用
GB/T 7714-2015
复制
MLA
复制
APA
复制
导出至
BibTeX EndNote RefMan NoteFirst NoteExpress
×
×
提示
您的信息不完整,为了账户安全,请先补充。
现在去补充
×
提示
您因"违规操作"
具体请查看互助需知
我知道了
×
提示
现在去查看 取消
×
提示
确定
0
微信
客服QQ
Book学术公众号 扫码关注我们
反馈
×
意见反馈
请填写您的意见或建议
请填写您的手机或邮箱
已复制链接
已复制链接
快去分享给好友吧!
我知道了
×
扫码分享
扫码分享
Book学术官方微信
Book学术文献互助
Book学术文献互助群
群 号:481959085
Book学术
文献互助 智能选刊 最新文献 互助须知 联系我们:info@booksci.cn
Book学术提供免费学术资源搜索服务,方便国内外学者检索中英文文献。致力于提供最便捷和优质的服务体验。
Copyright © 2023 Book学术 All rights reserved.
ghs 京公网安备 11010802042870号 京ICP备2023020795号-1