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蔗糖对体内菌斑和唾液脲酶水平的影响。

The effect of sucrose on plaque and saliva urease levels in vivo.

机构信息

University of Puerto Rico, School of Dental Medicine, San Juan, Puerto Rico.

出版信息

Arch Oral Biol. 2010 Mar;55(3):249-54. doi: 10.1016/j.archoralbio.2009.12.007. Epub 2010 Jan 21.

DOI:10.1016/j.archoralbio.2009.12.007
PMID:20096398
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2853032/
Abstract

OBJECTIVE

Dietary sugar exposures induce an immediate drop of the plaque pH. Based on in vitro observations, it was hypothesized that oral bacteria may rapidly respond to this environmental change by increasing the activity or expression of alkali-generating pathways, such as the urease pathway. The objective of this exploratory in vivo study was to determine the short-term effect of a brief sucrose exposure on plaque and saliva urease activity and expression, and to relate this effect to caries experience.

METHODS

Urease activity levels were measured in plaque and saliva samples collected from 20 children during fasting conditions and 30 min after rinsing with a sucrose solution. Streptococcus salivarius ureC-specific mRNA in saliva was quantified using real-time RT-PCR. The impact of host-related factors, such as age, gender, sugar consumption, salivary mutans streptococci levels and caries status on urease activity was evaluated.

RESULTS

Plaque urease activity under fasting conditions was higher in subjects with low caries and mutans streptococci levels. This difference was not observed after the sucrose exposure. The response of urease to sucrose in vivo did not depend on caries experience or salivary mutans levels. Significant increase in urease activity of plaque and saliva after exposure to sucrose was observed only in the subjects who had low urease levels at baseline.

CONCLUSIONS

The findings of this exploratory study suggest that plaque urease activity may have an important long-term influence in caries development but not during a cariogenic challenge.

摘要

目的

饮食中的糖暴露会立即降低菌斑 pH 值。基于体外观察结果,我们假设口腔细菌可能会通过增加产碱途径(如脲酶途径)的活性或表达来快速应对这种环境变化。本探索性体内研究的目的是确定短期蔗糖暴露对菌斑和唾液脲酶活性和表达的短期影响,并将这种影响与龋齿经历联系起来。

方法

在 20 名儿童空腹时和用蔗糖溶液漱口 30 分钟后收集菌斑和唾液样本,测量其中的脲酶活性水平。使用实时 RT-PCR 定量唾液中唾液链球菌 ureC 特异性 mRNA。评估宿主相关因素(如年龄、性别、糖摄入量、唾液变形链球菌水平和龋齿状况)对脲酶活性的影响。

结果

空腹时,龋齿和变形链球菌水平较低的受试者菌斑脲酶活性较高。这种差异在蔗糖暴露后并未观察到。体内蔗糖对脲酶的反应并不取决于龋齿经历或唾液变形链球菌水平。仅在基线脲酶水平较低的受试者中观察到暴露于蔗糖后菌斑和唾液脲酶活性的显著增加。

结论

这项探索性研究的结果表明,菌斑脲酶活性可能对龋齿的发展有重要的长期影响,但在致龋挑战期间没有影响。

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