In silico study of hyposalivation and sugar exposure on biofilm dysbiosis

JADA foundational science Pub Date : 2023-01-01 DOI:10.1016/j.jfscie.2022.100019

David Head PhD , Philip D. Marsh PhD , Deirde Devine PhD , Livia M.A. Tenuta DDS, MS, PhD

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Abstract

Background

Dental caries develops under actively sugar-fermenting dental biofilms, but the most successful control methods available only target mineral loss. Reduced salivary flow rates (hyposalivation) significantly exacerbate caries progression by lessening sugar and acid clearance near tooth surfaces. Maintaining dental biofilm symbiosis (health) under hyposalivation requires knowledge of the impact of acid inhibition under given dietary regimens.

Methods

An individual-based mathematical model was used to predict biofilm dysbiosis under normal or hyposalivatory conditions by regulating the frequency of sugar intake and inhibiting microbial glycolysis, reducing the acid challenge to the tooth mineral. The impact of pH-dependent (stronger inhibition at lower pH [eg, fluoride]) and pH-independent (general percentage reduction in acid production) strategies on pH near the tooth surface during sugar intake, and the corresponding compositional changes in the biofilm, were quantified.

Results

Under normal saliva flow, reducing the frequency of sugar intake and increasing the inhibition of acid production by pH-dependent or pH-independent strategies could prevent bacterial dysbiosis and prevent the biofilm from having a caries-associated (dysbiotic) to a health-associated (symbiotic) composition. However, under hyposalivatory conditions, dysbiosis occurred beyond 2 sugar intakes per day, and the degree of inhibition of glycolysis required to prevent dysbiosis was not feasible with available therapeutics.

Conclusions

Model data predict that to counteract the drastic effect of hyposalivation on biofilm dysbiosis, it will be essential to significantly reduce the frequency of fermentable sugar intake and any direct inhibition of bacterial metabolism.

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低盐度和糖暴露对生物膜生态失调的影响

牙齿蛀牙是在活跃的糖发酵的牙齿生物膜下发生的，但目前最成功的控制方法只针对矿物质的损失。唾液流动速率降低(唾液分泌不足)通过减少牙齿表面附近的糖和酸清除，显著加剧龋齿的进展。在低盐度下维持牙齿生物膜共生(健康)需要了解在给定饮食方案下酸抑制的影响。方法采用基于个体的数学模型，通过调节糖的摄入频率，抑制微生物糖酵解，减少酸对牙矿物质的挑战，预测正常或低唾液条件下的生物膜失调。研究人员量化了pH依赖性(在较低pH下有更强的抑制作用[例如，氟化物])和pH非依赖性(产酸的一般百分比减少)策略对糖摄入过程中牙齿表面附近pH的影响，以及生物膜中相应的组成变化。结果在唾液流量正常的情况下，通过ph依赖或ph不依赖的策略减少糖的摄入频率和增加对酸的产生的抑制，可以防止细菌生态失调，防止生物膜由与龋齿相关的(生态失调)组成向与健康相关的(共生)组成转变。然而，在低唾液条件下，每天摄入超过2个糖就会发生生态失调，而用现有的治疗方法来防止生态失调所需的糖酵解抑制程度是不可行的。结论模型数据预测，为了抵消低盐度对生物膜失调的剧烈影响，有必要显著减少可发酵糖的摄入频率和任何直接抑制细菌代谢的方法。

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

JADA foundational science Dentistry, Oral Surgery and Medicine

自引率

0.00%

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审稿时长

103 days