增龄对人牙本质失水收缩的重要性

汪饶饶; 毛霜霜; 依赖恩·隆伯格; 德温·阿罗拉; 张东升

doi:10.3879/j.issn.1000-0887.2012.03.005

增龄对人牙本质失水收缩的重要性

doi: 10.3879/j.issn.1000-0887.2012.03.005

1.
同济大学附属第十人民医院,上海 200072;2.上海大学力学系,上海 200444;3.上海市力学在能源工程中的应用重点实验室,上海 200072;4.马里兰大学口腔外科学院健康促进与政策研究室,巴尔的摩 21201,美国;5.马里兰大学机械学院,巴尔的摩 21201,美国;6.马里兰大学医学院牙髓学、修复学和牙科手术学系,巴尔的摩 21201,美国

基金项目: 国家自然科学基金资助项目(11172161);上海市重点学科建设基金资助项目(S30106);上海市教委重点基金资助项目(12ZZ092);口腔疾病研究国家重点实验室(四川大学)开放基金资助项目(SKLODSCU2009KF03);上海市科委基金资助项目(10410701900;11195820900;10ZR1423400);美国国立牙科和颅面研究基金资助项目（R01-DE016904）

详细信息

通讯作者:
汪饶饶(1959—), 男, 江西上饶人, 主任医师,博士(联系人.Tel:+86-21-66301726;Fax:+86-21-66301725;E-mail:raoraowang@hotmail.com).

中图分类号: Q66;R780.2
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出版历程
- 收稿日期: 2011-12-23
- 修回日期: 2012-01-13
- 刊出日期: 2012-03-15

Importance of Aging to the Dehydration Shrinkage of Human Dentin

1.
¹Tenth People’s Hospital of Tongji University, Shanghai 200072, P.R.China;²Department of Mechanics, Shanghai University, Shanghai 200444, P.R.China;³Shanghai Key Laboratory of Mechanics in Energy Engineering, Shanghai 200072, P.R.China;⁴Department of Health Promotion and Policy Baltimore College of Dental Surgery, University of Maryland, Baltimore, MD 21201;⁵Department of Mechanical Engineering, University of Maryland Baltimore County, Baltimore, MD 21201;⁶Department of Endodontics, Prosthodontics, and Operative Dentistry Baltimore College of Dental Surgery, University of Maryland, Baltimore, MD 21201

摘要

摘要: 牙本质内的矿物质随着年龄的增长呈现增长的趋势．由于矿物质与蛋白胶原比例的改变，可能导致牙本质脱水时氢键强度和收缩程度的变化．因此，该研究的目的是确定牙本质收缩随年龄增长的量变．将磨牙牙本质的冠部制成试件，青年组：23≤age≤34，老年组：52≤age≤62，贮存在水或Hanks平衡盐溶液（HBSS）中．利用数字图像相关法(DIC)观察牙本质试件在自由空气状态下的尺寸变化过程．结果表明青年人的牙本质不管在哪个方向或存储时间上，其收缩都明显大于老年人(p<0.01)．平行于牙本质小管方向上的应变从牙髓腔侧到釉牙本质界(DEJ)侧依次递增，而垂直于牙本质小管方向的应变则依次递减．即从牙髓腔侧到DEJ牙本质收缩的各向异性增强，该现象在青年人牙本质中尤其明显．
- 牙本质 /
- DIC /
- 矿物成分 /
- 硬化症 /
- 收缩
Abstract: There was an increase in the mineral content of human dentin with aging. Due to the consequent changes in mineral to collagen ratio, this process may influence the degree of hydrogen bonding that occurs with loss of water and the extent of shrinkage as a result of dehydration. Thus, the objective of this investigation was to quantify the differences in dehydration shrinkage of human dentin with patient age. Specimens of coronal dentin were prepared from the molars of young (23≤age≤34) and old (52≤age≤62) patients and then maintained in storage solutions of water or Hanks balanced salt solution(HBSS). Dimensional changes of the dentin specimens occurring over periods of free convection were evaluated using microscopic digital image correlation(DIC). Results distinguished that the shrinkage of young dentin is significantly larger than that for old dentin, regardless of orientation and period of storage (p<0.01).Strains parallel to the tubules increased with proximity to the dentin enamel junction(DEJ) whereas the shrinkage strains in the transverse direction were largest in deep dentin (i.e. near the pulp). The degree of anisotropy in shrinkage increased from the pulp to the DEJ and was largest in young dentin.
- dentin /
- DIC /
- mineral content /
- sclerosis /
- shrinkage

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