Email Alert | RSS

北京大学学报(医学版) ›› 2021, Vol. 53 ›› Issue (5): 995-1001. doi: 10.19723/j.issn.1671-167X.2021.05.031

• 论著 • 上一篇    下一篇

对比传统成像与数字成像对牙科复合树脂X射线阻射性的影响

李媛,林红(),张铁军   

  1. 北京大学口腔医学院·口腔医院,口腔材料研究室,口腔医疗器械检验中心 国家口腔医学中心 国家口腔疾病临床医学研究中心 口腔数字化医疗技术和材料国家工程实验室 国家药品监督管理局口腔材料重点实验室, 北京 100081
  • 收稿日期:2019-09-11 出版日期:2021-10-18 发布日期:2021-10-11
  • 通讯作者: 林红 E-mail:Hong196lin@sina.com
  • 基金资助:
    国家重点研发计划项目(2018YFB1106905)

Comparative study on radio-opacity of dental composite resin materials’determination using film imaging and digital imaging

LI Yuan,LIN Hong(),ZHANG Tie-jun   

  1. Department of Dental Materials & Dental Medical Devices Testing Center, Peking University School and Hospital of Stomatology & National Center of Stomatology & National Clinical Research Center for Oral Diseases & National Engineering Laboratory for Digital and Material Technology of Stomatology & NMPA Key Laboratory for Dental Materials, Beijing 100081, China
  • Received:2019-09-11 Online:2021-10-18 Published:2021-10-11
  • Contact: Hong LIN E-mail:Hong196lin@sina.com

RICH HTML

 880   

PDF (PC)

147

摘要:

目的: 分别采用传统胶片成像和数字成像测试牙科复合树脂材料的X射线阻射性,对比3种不同成像方式对X射线阻射性的影响。方法: 将临床常用的14种牙科复合树脂,分别制备成厚度为1.0 mm,直径15 mm的圆片。对同一个圆片试样,分别采用传统胶片成像(使用E速胶片)、数字成像(荧光成像板)和电荷耦合元件(charge-coupled device, CCD)口内X射线传感器,在相同的曝光条件下(管电压 65 kV,电流 7 mA,距离 300 mm,照射时间0.25 s),以楔状阶梯铝板作为参照物拍摄X线片。对于传统胶片成像获得的胶片,使用光密度计测量试样和楔状阶梯铝板各阶梯图像的光密度。对于数字成像获得的数字图像,输出到Adobe Photoshop®灰度分析软件,分析试样和楔状阶梯铝板各阶梯图像的平均灰度值。分别绘出楔状阶梯铝板各台阶的光密度/灰度值与其厚度相对应的曲线,并根据试样的实际测量厚度的光密度/灰度值,计算等效铝板厚度,以此评价牙科复合树脂材料的X射线阻射性。结果: 同一个试样片,传统胶片成像和其他两种数字成像测得的等效铝板厚度,14种复合树脂相比差异均有统计学意义(P<0.05),且两种数字成像测得的等效铝板厚度均大于传统胶片成像测得值。两种数字成像测得的等效铝板厚度也有差异,且多数复合树脂用CCD口内X射线传感器测得的等效铝板厚度大于荧光成像板测得值。同一样品,采用同一成像方式拍照,3次曝光获得的等效铝板厚度不同,其中荧光成像板测得的等效铝板厚度标准差最大,而CCD口内X射线传感器测得的等效铝板厚度标准差最小。14种复合树脂间,Tetric N-Ceram复合树脂和Te-Econom Plus复合树脂用传统胶片成像、荧光成像板拍照获得的等效铝板厚度值显著大于其他树脂。结论: 基于临床意义设计的3种传感器测得的等效铝板厚度值会根据传感器种类不同而改变,CCD口内X射线传感器测得值,荧光成像板测得值>传统胶片成像测得值,并且即使使用同一传感器,多次曝光获得的等效铝板厚度值也不同,其中荧光成像板测得的等效铝板厚度值标准差大于传统胶片成像和CCD口内X射线传感器测得值。在评价复合树脂的X射线阻射性时,3种传感器都可以检测复合树脂的X射线阻射性,但无论采用何种传感器,等效铝板厚度值均应符合ISO 4049: 2019标准的规定,该树脂才可以判定为合格产品,材料才适用于临床。

关键词: X射线阻射性, 复合树脂, 数字成像, 传统成像

Abstract:

Objective: To compare the effects of different imaging methods on radio-opacity. Digital imaging and traditional film imaging were used to determine the radio-opacity of dental composite resin materials. Methods: Fourteen dental composite resins commonly used in clinic were prepared for disc samples with thickness of 1 mm and diameter of 15 mm respectively. The aluminum step wedge was used as the reference and the disc samples were irradiated with X-rays by the traditional film imaging, phosphor imaging plate and charge-coupled device(CCD) intra-oral X-ray sensor respectively. Exposure was set at 65 kV and 7 mA, with 300 mm focus to film distance and the exposure time was 0.25 s. After developing and fixing the film, the optical density of the image of the sample and that of each step of the aluminum step wedge were measured using the densitometer. The digital image file was exported to grey scale analysis software of Adobe Photoshop® to measure the average grey value in the sample image and aluminum step wedge image. The curves were drawn corresponding to the optical density/gray value of each step of the aluminum step wedge and its thickness, and the equivalent thickness of the aluminum plate was calculated according to the optical density/gray value of the actual measured thickness of the sample, so as to evaluate the radio-opacity of dental composite resin material. Results: For the same sample, the aluminum equivalent measured by traditional film imaging and two other digital imagings had significant differences among the 14 composite resins (P<0.05), and the aluminum equivalent measured by the two digital imagings were greater than that of the traditional film. Moreover the aluminum equivalent measured by the two digital imagings was also different, and the aluminum equivalent measured by the CCD intra-oral X-ray sensor in most composite resins was larger than that measured by phosphor imaging plate. The same sample was photographed with the same imaging method, and the aluminum equivalent was different after three exposures. The standard deviation of aluminum equivalent measured by phosphor imaging plate was the largest, while that measured by CCD intra-oral X-ray sensor was the smallest. Among the 14 dental composite resin materials, the aluminum equivalent of Tetric N-Ceram and Te-Econom Plus measured by traditional film imaging and phosphor imaging plate was significantly higher than other composite resins. Conclusion: Based on clinical significance, three kinds of sensors designed to measure the radio-opacity of dental composite resin, the value of aluminum equivalent will change according to different types of sensors. The aluminum equivalent measured by CCD intra-oral X-ray sensor was higher than that measured by phosphor imaging plate, and the aluminum equivalent measured by phosphor imaging plate was higher than that measured by traditional film imaging. Moreover, even though the same sensor was used, the aluminum equivalent measured by multiple exposures was different. The standard deviation of the aluminum equivalent measured by phosphor imaging plate was greater than that measured by traditional film imaging and CCD intra-oral X-ray sensor. The three sensors in this study could be used for evaluating the radio-opacity of dental composite resin materials. But no matter what kind of sensor was used to measure the radio-opacity of dental composite resin, it complied to ISO 4049: 2019 standard, the materials were suitable for clinical use.

Key words: Radio-Opacity, Dental composite resin, Digital imaging, Film imaging

中图分类号: 

  • R783.1

表1

研究材料"

Number Material name Manufacturer Filler Filler content/%
1 Esthet·X·flow DENTSPLY, USA Barium fluoroaluminosilicate glass, silica 61
2 SDR-Flow DENTSPLY, USA Barium aluminoborosilicate strontium, alumino-
fluorosilicate		 68
3 Revolution Formula 2 Kerr, USA Glass filler 60
4 Tetric N-Flow Ivoclar vivadent, Liechtenstein Barium glass, ytterbium fluoride, silica 63
5 Tetric N-Ceram Ivoclar vivadent, Liechtenstein Barium glass, ytterbium fluoride, silica 80.5
6 Spectrum TPH3 DENTSPLY, USA Barium borosilicate, barium fluoride
aluminosilicate, silica		 75
7 Clearfil Majesty Kuraray, Japan Barium glass, light silicic anhydride 78
8 Kuraray ES2 Kuraray, Japan Barium glass, light silicic anhydride 78
9 Light cured composite resin Suizhong Honghai Barium glass 60
10 Charisma diamond Heraeus Kulzer, Germany Barium, aluminum silica cluster filler 64
11 Filtek Z250 3M, USA Zirconia, silica 78
12 WAVE MV SDI, Australia Inorganic filler 65
13 Te-Econom Plus Ivoclar vivadent, Liechtenstein Barium glass, barium aluminum fluorosilicate,
silica, mixed oxide, ytterbium fluoride		 76
14 BEAUTIFIL Ⅱ SHOFU, Japan Aluminum borosilicate fluoride glass, aluminum
oxide		 >70

图1

传统胶片成像3次曝光获得的X线片"

图2

荧光成像板3次曝光获得的X线片"

图3

CCD口内X射线传感器3次曝光获得的X线片"

图4

典型的二阶多项式回归曲线图"

表2

等效铝板厚度值"

Number Material name Aluminum equivalent/mm, x ?±s
E-film Phosphor imaging plate CCD
1 Esthet·X·flow 1.40±0.00 1.93±0.06 2.93±0.06
2 SDR-Flow 2.27±0.06 2.60±0.10 3.03±0.06
3 Revolution Formula 2 1.20±0.00 1.77±0.12 2.37±0.06
4 Tetric N-Flow 2.30±0.10 2.83±0.06 3.30±0.00
5 Tetric N-Ceram 3.50±0.10 3.83±0.12 4.67±0.06
6 Spectrum TPH3 1.97±0.06 3.07±0.12 4.73±0.06
7 Clearfil Majesty 1.00±0.00 1.50±0.10 2.27±0.06
8 Kuraray ES2 1.00±0.00 1.20±0.10 2.20±0.00
9 Light cured composite resin 1.53±0.06 2.23±0.06 2.70±0.00
10 Charisma diamond 1.83±0.06 2.80±0.17 3.60±0.00
11 Filtek Z250 2.07±0.06 2.67±0.15 2.60±0.00
12 WAVE MV 1.30±0.10 1.63±0.06 1.60±0.00
13 Te-Econom Plus 3.03±0.06 3.57±0.06 3.50±0.00
14 BEAUTIFIL Ⅱ 2.07±0.06 2.53±0.06 2.47±0.06
[1] Poorterman JHG, Aartman IHA, Kalsbeek H. Underestimation of the prevalence of approximal caries and inadequate restorations in a clinical epidemiological study [J]. Community Dent Oral, 1999, 27(5):331-337.
pmid: 10503793
[2] Mjor IA. The location of clinically diagnosed secondary caries [J]. Quintessence Int, 1998, 29:313-317.
[3] Soares CJ, Rosatto CMP, Carvalho VF, et al. Radiopacity and porosity of bulk-fill and conventional composite posterior restorations-digital X-ray analysis [J]. Oper Dent, 2017, 42(6):616-625.
doi: 10.2341/16-146-L pmid: 28976845
[4] Tarcin B, Gumru B, Peker S, et al. Evaluation of radiopacity of bulk-fill flowable composites using digital radiography [J]. Oper Dent, 2016, 41(4):424-431.
doi: 10.2341/15-153-L pmid: 27045286
[5] Watts DC, McCabe JF. Aluminium radiopacity standards for dentistry: an international survey [J]. J Dent, 2006, 27(1):73-78.
doi: 10.1016/S0300-5712(98)00025-6
[6] 全国口腔材料和器械设备标准化技术委员会. 牙科学测定材料的X射线阻射性试验方法:YY/T 1646-2019 [S]. 北京: 中国标准出版社, 2019: 1.
[7] Gurdal P, Akdeniz BG. Comparison of two methods for radiometric evaluation of resin-based restorative materials [J]. Dentomaxillofac Radiol, 1998, 27(4):236-239.
doi: 10.1038/sj.dmfr.4600357
[8] Hara AT, Serra MG, Rodrigues JA. Radiopacity of glass-ionomer composite resin hybrid materials [J]. Braz Dent J, 2001, 12(2):85-89.
pmid: 11445919
[9] Tanomaru-Filho M, Jorge EG, Guerreiro TJ, et al. Radiopacity evaluation of new root canal filling materials by digitalization of images [J]. J Endod, 2007, 33(3):249-251.
doi: 10.1016/j.joen.2006.08.015
[10] 孙涛. DR成像技术的临床应用分析 [J]. 临床医药文献杂志, 2015, 2(8):1523.
[11] 温建伟. CR与DR性能影像特点及其临床应用的比较研究 [J]. 中国继续医学教育, 2016, 8(14):53-54.
[12] Arita ES, Silveira GP, Cortes AR, et al. Comparative study between the radiopacity levels of high viscosity and of flowable composite resins, using digital imaging [J]. Eur J Esthet Dent, 2012, 7(4):430-438.
[13] Filling and restorative materials. ISO 4049: 2019 [S/OL]. [2021-04-13]. https://www.iso.org/obp/ui/#iso:std:iso:4049:ed-5:v1:en .
[14] Lachowski KM, Botta SB, Lascala CA, et al. Study of the radio-opacity of base and liner dental materials using a digital radiography system [J]. Dentomaxillofac Radiol, 2013, 42(2):20120153.
doi: 10.1259/dmfr.20120153
[15] Rasimick BJ, Gu S, Deutsch AS, et al. Measuring the radiopacity of luting cements, dowels, and core build-up materials with a digital radiography system using a CCD sensor [J]. J Prosthodont, 2007, 16(5):357-364.
pmid: 17559533
[16] Akcay I, Ilhan B, Dundar N. Comparison of conventional and digital radiography systems with regard to radiopacity of root canal filling materials [J]. Int Endod J, 2012, 45(8):730-736.
doi: 10.1111/j.1365-2591.2012.02026.x pmid: 22458866
[17] R Kapila, Y Matsuda, K Araki, et al. Radiopacity measurement of restorative resins using film and three digital systems for comparison with ISO 4049 international standard [J]. Bull Tokyo Dent Coll, 2015, 56(4):207-214.
doi: 10.2209/tdcpublication.56.207
[18] 赵信义. 口腔材料学 [M]. 北京: 人民卫生出版社, 2020: 77.
[19] 王亮亮. CR、DR系统的图像质量控制及影响因素 [J]. 黑龙江医药, 2017, 30(2):426-427.
[1] 杨洋,浦婷婷,陈立,谭建国. 比较两种改良式印章法辅助后牙树脂牙合贴面修复的形态准确性[J]. 北京大学学报(医学版), 2021, 53(5): 977-982.
[2] 穆海丽,田福聪,王晓燕,高学军. 玻璃体和通用型复合树脂耐磨性的临床对照研究[J]. 北京大学学报(医学版), 2021, 53(1): 120-125.
[3] 于鹏,王晓燕. 填料折射率与比例对复合树脂折射率和透明度的影响[J]. 北京大学学报(医学版), 2020, 52(4): 790-793.
[4] 唐仁韬,李欣海,于江利,冯琳,高学军. 复合树脂与玻璃陶瓷微拉伸粘接强度的体外研究[J]. 北京大学学报(医学版), 2020, 52(4): 755-761.
[5] 李贝贝,邸萍. CAD/CAM钛合金表面处理工艺联合树脂粘接剂对硬质复合树脂粘接强度和耐久性的影响[J]. 北京大学学报(医学版), 2019, 51(1): 111-114.
[6] 郭惠杰,高承志, 林斐,刘伟,岳林. 唾液污染对复合树脂间粘接强度的影响[J]. 北京大学学报(医学版), 2017, 49(1): 96-100.
[7] 林斐, 刘伟, 闫鹏, 岳林. 复合树脂间粘接的微拉伸强度研究[J]. 北京大学学报(医学版), 2015, 47(1): 124-128.
[8] 蔡雪, 聂杰, 王祖华, 田洪琰, 赵莹, 王晓燕. 洞缘形态对复合树脂颜色匹配的影响[J]. 北京大学学报(医学版), 2015, 47(1): 120-123.
[9] 田福聪,王晓燕,高学军. 不同粘接系统用于楔状缺损直接修复的临床观察[J]. 北京大学学报(医学版), 2014, 46(1): 58-61.
[10] 袁慎坡, 林红, 潘硕, 娄丽丽, 徐永祥. Polident义齿清洁剂对义齿基托树脂性能的影响[J]. 北京大学学报(医学版), 2012, 44(6): 946-949.
[11] 徐永祥, 韩建民, 林红. 自黏性流动树脂的性能研究[J]. 北京大学学报(医学版), 2012, 44(2): 303-306.
[12] 高博韬, 郑刚, 林红, 徐永祥. 实时动态分析牙科光固化复合树脂固化收缩的新方法[J]. 北京大学学报(医学版), 2011, 43(6): 895-899.
[13] 韩冰, 董艳梅, 王晓燕, 高学军. 光照模式对复合树脂聚合收缩率和表面硬度的影响[J]. 北京大学学报(医学版), 2011, 43(5): 770-773.
[14] 赵奇*, 薛世华*, 吴艳, 王世明. 应用龈色树脂修复前牙颈部缺损的临床评价[J]. 北京大学学报(医学版), 2011, 43(1): 44-47.
[15] 韩冰, 王晓燕, 高学军. 光功率密度对光固化复合树脂耐老化性能的影响[J]. 北京大学学报(医学版), 2011, 43(1): 58-61.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] 田增民, 陈涛, Nanbert ZHONG, 李志超, 尹丰, 刘爽. 神经干细胞移植治疗遗传性小脑萎缩的临床研究(英文稿)[J]. 北京大学学报(医学版), 2009, 41(4): 456 -458 .
[2] 郭岩, 谢铮. 用一代人时间弥合差距——健康社会决定因素理论及其国际经验[J]. 北京大学学报(医学版), 2009, 41(2): 125 -128 .
[3] 成刚, 钱振华, 胡军. 艾滋病项目自愿咨询检测的技术效率分析[J]. 北京大学学报(医学版), 2009, 41(2): 135 -140 .
[4] 卢恬, 朱晓辉, 柳世庆, 郑杰, 邱晓彦. 白细胞介素2促进宫颈癌细胞系HeLaS3免疫球蛋白G的表达[J]. 北京大学学报(医学版), 2009, 41(2): 158 -161 .
[5] 袁惠燕, 张苑, 范田园. 离子交换型栓塞微球及其载平阳霉素的制备与性质研究[J]. 北京大学学报(医学版), 2009, 41(2): 217 -220 .
[6] 徐莉, 孟焕新, 张立, 陈智滨, 冯向辉, 释栋. 侵袭性牙周炎患者血清中抗牙龈卟啉单胞菌的IgG抗体水平的研究[J]. 北京大学学报(医学版), 2009, 41(1): 52 -55 .
[7] 董稳, 刘瑞昌, 刘克英, 关明, 杨旭东. 氯诺昔康和舒芬太尼用于颌面外科术后自控静脉镇痛的比较[J]. 北京大学学报(医学版), 2009, 41(1): 109 -111 .
[8] 祁琨, 邓芙蓉, 郭新彪. 纳米二氧化钛颗粒对人肺成纤维细胞缝隙连接通讯的影响[J]. 北京大学学报(医学版), 2009, 41(3): 297 -301 .
[9] Jian-wei GU, Emily YOUNG, Zhi-jun PAN, Kevan B. TUCKER, Megan SHPARAGO, Min HUANG, Amelia Purser BAILEY. SD大鼠长期高盐饮食可导致其高血压并改变肾细胞因子基因表达谱[J]. 北京大学学报(医学版), 2009, 41(5): 505 -515 .
[10] 李宏亮*, 安卫红*, 赵扬玉, 朱曦. 妊娠合并高脂血症性胰腺炎行血液净化治疗1例[J]. 北京大学学报(医学版), 2009, 41(5): 599 -601 .
ISSN 1671-167X
CN 11-4691/R
主管单位:中华人民共和国教育部
主办单位:北京大学
地址: 北京市海淀区学院路38号 北京大学医学部 《北京大学学报(医学版)》
邮编:100191
电话:010-82801551
Email: xbbjb2@bjmu.edu.cn

《北京大学学报(医学版)》
微信公众号
版权所有 © 2018 《北京大学学报(医学版)》编辑部