Chapter 5.1: Physicochemical Interactions between Enamel and Oral Fluids.

Q2 Dentistry
Jaime A Cury, Antônio Pedro Ricomini-Filho, Cinthia P M Tabchoury
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Abstract

Despite all the current knowledge in cariology, research is still being carried out nowadays trying to make dental enamel resistant to dental caries. Since enamel is mainly composed by a mineral, efforts have been put together to make it more resistant to acids produced by dental biofilm when exposed to dietary sugars. Fluoride was once thought to be a micronutrient that impacted caries resistance when incorporated in the tooth mineral, but we now know that the complex interactions at the mineral surface are most important. Every slightly soluble mineral, and enamel is no exception, has a behavior that is determined by the environment where it is located, and in the case of the dental crown, saliva and biofilm fluid play an important role. Enamel can keep in balance or lose its minerals, but it can gain them back. These processes, equilibrium, and loss or gain follow Le Chatelier's principle, and physicochemically, they are known as saturating, undersaturating, and supersaturating conditions, respectively. Saliva, and even the biofilm fluid, is supersaturated with calcium (Ca2+) and phosphate (PO43-) in relation to enamel solubility, and thus the natural tendency of enamel is to gain mineral, conferring saliva with a remineralizing property. However, the decrease in pH and the presence of free fluoride ion (F-) will determine what will happen to the enamel. While lowering the pH of the medium is an imbalance factor, fluoride at micromolar concentration reduces the acid impact. This chapter provides an updated, evidence-based understanding of the interactions between enamel and oral fluids.

第5.1章:牙釉质与口腔液体的物理化学相互作用。
尽管目前在龋齿学方面有很多知识,但目前仍在进行研究,试图使牙釉质抵抗龋齿。由于牙釉质主要是由一种矿物质组成的,所以人们一直在努力使其更能抵抗牙齿生物膜在摄入膳食糖时产生的酸。氟化物曾经被认为是一种微量营养素,当它与牙齿矿物质结合时,会影响蛀牙的抵抗力,但我们现在知道,矿物表面的复杂相互作用是最重要的。每一种微溶性矿物质,牙釉质也不例外,都有一种行为,这是由它所处的环境决定的,就牙冠而言,唾液和生物膜液起着重要的作用。牙釉质可以保持平衡或失去矿物质,但它可以重新获得矿物质。这些过程,平衡和损失或增益遵循勒夏特列原理,在物理化学上,它们分别被称为饱和、不饱和和过饱和条件。唾液,甚至是生物膜液,与牙釉质溶解度相关的钙(Ca2+)和磷酸盐(PO43-)过饱和,因此牙釉质的自然倾向是获得矿物质,赋予唾液再矿化特性。然而,pH值的下降和游离氟离子(F-)的存在将决定牙釉质的变化。降低介质的pH值是一个不平衡因素,而微摩尔浓度的氟化物则降低了酸的影响。本章提供了一种最新的、基于证据的对牙釉质和口腔液体之间相互作用的理解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Monographs in Oral Science
Monographs in Oral Science Medicine-Medicine (all)
CiteScore
3.70
自引率
0.00%
发文量
21
期刊介绍: For two decades, ‘Monographs in Oral Science’ has provided a source of in-depth discussion of selected topics in the sciences related to stomatology. Senior investigators are invited to present expanded contributions in their fields of special expertise. The topics chosen are those which have generated a long-standing interest, and on which new conceptual insights or innovative biotechnology are making considerable impact. Authors are selected on the basis of having made lasting contributions to their chosen field and their willingness to share their findings with others.
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