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The Role of Biofilm on Margin Stability and the Development of Secondary Caries

生物膜对边缘稳定性和继发龋发展的作用

基本信息

批准号：
8513301
负责人：
Shelton Ray Taylor
金额：
$ 8.19万
依托单位：
TEXAS ENGINEERING EXPERIMENT STATION
依托单位国家：
美国
项目类别：
财政年份：
2010
资助国家：
美国
起止时间：
2010-09-10 至 2014-08-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/8513301
关键词：
Acrylates Adolescent Adult Affect Artificial Saliva Biocompatible Materials Biomaterials Research Chemicals Chemistry Child Chronic Disease Clinic Clinical Research Clinical Trials Composite Dental Resin Composite Resins Dental Dental Research Dental Restoration Failure Dental caries Dentistry Development Dimensions Environment Esters Fatigue Frequencies Frozen Sections Human Hydrolysis In Vitro Individual Interferometry Investigation Ions Kinetics Laboratories Lead Lesion Life Measurement Measures Mechanics Methods Microbial Biofilms Microelectrodes Modeling Monitor Plant Resins Polymers Property Research Resolution Role Saliva Scanning Services Severities Shapes Spectroscopy, Fourier Transform Infrared Structure Surface System Techniques Testing Time Tooth structure United States Vertebral column base in vivo microbial microleakage multidisciplinary oral bacteria polymerization programs public health relevance research study restoration sensor submicron theories time use tool

项目摘要

DESCRIPTION (provided by applicant): More than 70% of carious lesions (now over 125 million per year) are restored with acrylate-based resin composites which have a median service-life of less than 6 years (vs. 15 years for amalgam). The major reason for replacing these restorations is because of secondary caries, but the reason these lesion develop more rapidly on resin-based composites is unclear. Previous clinical studies on the relationship of the margin gap to the development of secondary caries have resulted in equivocal results due to the complexity of interacting variable and the inability to accurately monitor gap dimensions. More controlled in vitro experiments have focused on amalgams and not resin-based composites. This research will investigate a commercial acrylate-based resin dental composite and relevant polymer systems with the following specific aims: (1) to determine the role of the microgap in the development of secondary caries in human teeth, (2) to define how gap dimension controls the occluded chemistry within the gap, and (3) to determine how the occluded chemistry impacts the structure and properties of the resin and composite. This will be accomplished in a 4 year research effort with a multidisciplinary team and newly available measurement tools and techniques. Restorations with naturally formed microgaps and model restorations with precisely controlled microgap dimensions will be exposed to a realistic, controlled in vitro environment consisting of a consortium of oral bacteria relevant to caries in artificial saliva. The effects of the microbial biofilm on the tooth and the composite surface near the cavosurface margin and on the microgap dimensions will be monitored non-destructively with submicron resolution with a new interferometric technique, Super Resolution Vertical Scanning Interferometry. The relationship of gap dimensions, the activity of the different bacterial strains, and frequency and severity of secondary caries will be determined. In addition, the pH and Ca2+ concentration within the microgap will be measured as a function of depth and time with micro-sensor techniques that are new to dental research. Finally, the direct effect of the occluded microgap chemistry on the resin composite properties and chemistry will be examined using dynamic mechanical testing, fatigue measurements, and a newly developed minibeam technique, as well as FTIR to determine if there is direct evidence of backbone scission by hydrolysis. The successful completion of this research will conclusively test a leading theory for secondary caries in resin-based composites, critically examine the efficacy of these materials for use in dentistry, and develop new, more precise tools for biomaterial investigations in the laboratory and the clinic. PUBLIC HEALTH RELEVANCE: Resin-based dental composites are the principle material used to restore over 120 million cavities each year in the US, but have a very limited service-life that is 40% of an amalgam. This program will use newly available tools and experimental methods to critically evaluate the efficacy of these materials for use in dentistry. New, more precise methods will be developed for biomaterial investigations in the laboratory and the clinic.

描述（由申请人提供）：超过 70% 的龋齿病变（目前每年超过 1.25 亿个）是用丙烯酸酯基树脂复合材料修复的，其中位使用寿命不到 6 年（而汞合金的中位使用寿命为 15 年）。更换这些修复体的主要原因是继发龋，但这些病变在树脂基复合材料上发展得更快的原因尚不清楚。由于相互作用变量的复杂性以及无法准确监测间隙尺寸，先前关于边缘间隙与继发龋发展关系的临床研究导致了模棱两可的结果。更多受控的体外实验集中在汞合金上，而不是树脂基复合材料上。本研究将研究商用丙烯酸酯树脂牙科复合材料和相关聚合物系统，其具体目标如下：(1) 确定微间隙在人类牙齿继发龋发展中的作用，(2) 定义间隙尺寸如何控制间隙内的闭塞化学物质，(3) 确定闭塞化学物质如何影响树脂和复合材料的结构和性能。这将通过多学科团队和新可用的测量工具和技术的 4 年研究工作来完成。具有自然形成的微间隙的修复体和具有精确控制的微间隙尺寸的模型修复体将暴露于由人工唾液中与龋齿相关的口腔细菌群组成的真实的、受控的体外环境中。微生物生物膜对牙齿和腔体表面边缘附近的复合材料表面以及对微间隙尺寸的影响将通过新的干涉技术（超分辨率垂直扫描干涉测量）以亚微米分辨率进行非破坏性监测。将确定间隙尺寸、不同菌株的活性以及继发龋齿的频率和严重程度的关系。此外，微间隙内的 pH 值和 Ca2+ 浓度将通过牙科研究中全新的微传感器技术作为深度和时间的函数进行测量。最后，将使用动态机械测试、疲劳测量和新开发的微型光束技术以及 FTIR 来检查闭塞微间隙化学对树脂复合材料性能和化学的直接影响，以确定是否存在水解导致主链断裂的直接证据。这项研究的成功完成将最终测试树脂基复合材料中继发龋齿的领先理论，严格检查这些材料在牙科中的功效，并为实验室和临床的生物材料研究开发新的、更精确的工具。公共健康相关性：树脂基牙科复合材料是美国每年修复超过 1.2 亿个蛀牙的主要材料，但其使用寿命非常有限，仅为汞合金的 40%。该计划将使用新的工具和实验方法来严格评估这些材料在牙科中的功效。将开发新的、更精确的方法用于实验室和临床的生物材料研究。