根状龋样病变发展的动态微观生物膜模型：脱矿和微生物特性分析。

IF 2 3区生物学 Q3 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Biofouling Pub Date : 2025-05-01 Epub Date: 2025-05-22 DOI:10.1080/08927014.2025.2507893

Tamires Timm Maske, Glenda Ávila Marques, Bruna Dalongaro Fritsch, Bruna Moraes Kremer, Maximiliano Sérgio Cenci, Pabulo Henrique Rampelotto, Rodrigo Alex Arthur

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引用次数: 0

摘要

本研究对多功能口腔模拟器（MOCS）在微生物组成、功能特征和牙本质根脱矿方面进行了研究。使用人唾液在牙本质上培养微型生物膜4,7和14天，并暴露于蔗糖和富含黏液的培养基中。通过CFU计数和16S-rRNA基因测序分析生物膜的微生物活力和组成。通过表面硬度变化百分比（%SHC）、矿物质损失（ML）和损伤深度（LD）来量化脱矿。结果显示各时间点微生物活力。7 d后，嗜酸/致酸和蛋白水解生物的丰度增加。功能谱反映了微生物组成的振荡。在不同的时间点上，观察到SHC、ML或LD的百分比没有显著差异。龋齿病变为60-70% SHC，深度为125-200µm。MOCS能够通过微生物生物膜的代谢活性诱导牙根龋变，这表明其在牙根龋病的临床前研究中具有潜在的应用前景。

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A dynamic microcosm biofilm model for root carious-like lesion development: analysis of demineralization and microbiological characterization.

This study investigated the multifunctional oral cavity simulator (MOCS) in terms of microbial composition, functional profile, and dentin root demineralization. Microcosm biofilms were grown on dentin using human saliva for 4, 7, and 14 days, with exposure to sucrose and a mucin-enriched medium. Biofilms were analyzed for microbial viability and composition through CFU count and 16S-rRNA gene sequencing. Demineralization was quantified by percentage surface hardness change (%SHC), mineral loss (ML), and lesion depth (LD). The results showed microbial viability at all time points. After 7 days, aciduric/acidogenic and proteolytic organisms increased in abundance. The functional profile reflected the oscillations in microbial composition. No significant differences in %SHC, ML, or LD were observed across the time points. Carious lesions exhibited 60-70% SHC and 125-200 µm depth. MOCS was able to induce root carious lesions as result of microcosm biofilm metabolic activity, indicating its potential use in preclinical studies on root dentin caries.

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来源期刊

Biofouling 生物-海洋与淡水生物学

CiteScore

5.00

自引率

7.40%

发文量

审稿时长

1.7 months

期刊介绍： Biofouling is an international, peer-reviewed, multi-discliplinary journal which publishes original articles and mini-reviews and provides a forum for publication of pure and applied work on protein, microbial, fungal, plant and animal fouling and its control, as well as studies of all kinds on biofilms and bioadhesion. Papers may be based on studies relating to characterisation, attachment, growth and control on any natural (living) or man-made surface in the freshwater, marine or aerial environments, including fouling, biofilms and bioadhesion in the medical, dental, and industrial context. Specific areas of interest include antifouling technologies and coatings including transmission of invasive species, antimicrobial agents, biological interfaces, biomaterials, microbiologically influenced corrosion, membrane biofouling, food industry biofilms, biofilm based diseases and indwelling biomedical devices as substrata for fouling and biofilm growth, including papers based on clinically-relevant work using models that mimic the realistic environment in which they are intended to be used.