Interactions and effects of a stannous-containing sodium fluoride dentifrice on oral pathogens and the oral microbiome.

Numerous studies have investigated the effects of stannous ions on specific microbes and their efficacy in reducing dental plaque. Nonetheless, our understanding of their impact on the oral microbiome is still a subject of ongoing exploration. Therefore, this study sought to evaluate the effects of a stannous-containing sodium fluoride dentifrice in comparison to a zinc-containing sodium fluoride dentifrice and a control group on intact, healthy oral biofilms. Utilizing the novel 2bRAD-M approach for species-resolved metagenomics, and FISH/CLSM with probes targeting periodontal and caries associated species alongside Sn2+ and Zn2+ ions, we collected and analyzed in situ biofilms from 15 generally healthy individuals with measurable dental plaque and treated the biofilms with dentifrices to elucidate variations in microbial distribution. Although significant shifts in the microbiome upon treatment were not observed, the use of a stannous-containing sodium fluoride dentifrice primarily led to an increase in health-associated commensal species and decrease in pathogenic species. Notably, FISH/CLSM analysis highlighted a marked reduction in representative species associated with periodontitis and caries following treatment with the use of a stannous-containing sodium fluoride dentifrice, as opposed to a zinc-containing sodium fluoride dentifrice and the control group. Additionally, Sn2+ specific intracellular imaging reflected the colocalization of Sn2+ ions with P. gingivalis but not with other species. In contrast, Zn2+ ions exhibited non-specific binding, thus suggesting that Sn2+ could exhibit selective binding toward pathogenic species. Altogether, our results demonstrate that stannous ions could help to maintain a healthy oral microbiome by preferentially targeting certain pathogenic bacteria to reverse dysbiosis and underscores the importance of the continual usage of such products as a preventive measure for oral diseases and the maintenance of health.

Laboratory screening evaluation of the safety of low pH oral care rinse products to dental enamel.

PURPOSE: To assess the hard tissue safety of a variety of low pH oral care rinses to dental enamel in a newly developed screening method. METHODS: Bovine enamel specimens were subjected to a cycling model that consisted of commercial mouthrinse product exposures and artificial saliva soaks based on a previously published screening method. The effect of test products on the surface of treated specimens was measured using surface microhardness (SMH). Results are presented as the change in SMH (between sound enamel baseline and cycling final). An assortment of rinse products were assessed relative to distilled water (positive control) and 1% citric acid (negative control). A priori, a product was considered safe if the change in measured SMH values over the course of six treatment cycles was both significantly greater than the negative control and was not significantly different from the positive control. A non-inferiority statistical test was applied to create a quantitative rule defining product safety. RESULTS: Products tested included two rinses with a pH in excess of 5.5, and eight with a pH less than 5.5. Four of the rinses included fluoride, while six did not. Analyses showed that all of the rinse products tested passed the non-inferiority acceptance criteria. One of the 10 marketed oral care rinses failed to meet the a priori criteria needed to be considered safe as the product was significantly better than the negative control but also significantly lower than the positive control treatment. This product had the lowest pH of all products tested and did not contain fluoride. Application of the non-inferiority statistical test showed the questionable product passing safety criteria. As a proposed method for a screening tool, further testing would be recommended based on these results. CLINICAL SIGNIFICANCE: An in vitro enamel safety screening method was applied as an assessment of the enamel demineralization safety to a number of oral care rinse products. Surface microhardness, coupled with a non-inferiority statistical evaluation, provided a reasonable approach for detecting potential product issues. Products failing this screening laboratory method may require additional testing to verify their safety on hard tissues.

A fluoride activated methylene blue releasing platform for imaging and antimicrobial photodynamic therapy of human dental plaque.

We report a F- activated methylene blue (MB) releasing platform for imaging and antimicrobial photodynamic therapy (aPDT). By utilizing this platform, one of the selected probes, FD-F3, displays a remarkable near-infrared fluorescence and absorption increase towards F- with good selectivity and low detection limit. This probe has been successfully applied for visualizing F- and performing F- activated aPDT in naturally grown human plaque biofilms.

Penetration and bactericidal efficacy of two oral care products in an oral biofilm model.

PURPOSE: To investigate the immediate penetration and bactericidal effect of two oral care products marketed in China on an intact natural plaque biofilm model at different time points. METHODS: Eight subjects (aged 20 to 30 years; Turesky Plaque Index Score 2 to 3) were enrolled in the study according to the inclusion criteria. Plaque accumulators were worn by the subjects for 6 and 48 hours for harvesting the dental biofilm. Then the biofilms from different groups were stained with the LIVE/DEAD BacLight fluorescence system to investigate the changes in thickness and fluorescence intensity of living bacteria in biofilm 5 and 15 minutes post-treatment with a mouthrinse containing 0.074% cetylpyridinium chloride (1-minute treatment) or a toothpaste supernatant containing 1.16% stannous chloride (2-minute treatment). In addition, a specific Sn2+ probe was utilized to evaluate the penetration of Sn2+ in the biofilm. Fluorescent images were collected using confocal laser scanning microscopy. Analysis of covariance was used for statistical analyses. All comparisons were two-sided using a 5% level of significance. RESULTS: The thickness of generated plaque biofilm increased gradually from 7.352±4.22 µm at 6 hours to 16.73±7.38 µm at 48 hours (P< 0.05), whereas the thickness and fluorescence intensity of living bacteria stayed unchanged over time. After the treatment of toothpaste supernatant, the ratios of living bacteria thickness and fluorescence intensity of 6- and 48-hour plaque biofilm were significantly decreased (P< 0.05). Treatment of mouthrinse reduced the ratio of living bacteria thickness, but showed no significant impact on overall fluorescence intensity of living bacteria. For 48-hour biofilm, toothpaste supernatant significantly reduced fluorescence intensity of living bacteria from outer layer through inner layer, whereas the mouthrinse showed bactericidal effect only in the outer layer and middle layer. A wide distribution of Sn2+ was shown in the biofilm with the treatment of the tested toothpaste. CLINICAL SIGNIFICANCE: This biofilm model proved to be useful and appropriate for pre-clinical testing of anti-plaque agents. A brief exposure of the biofilm to the tested toothpaste produced significant losses in bacteria viability across outer-middle-inner layers. The tested mouthrinse exerted its bactericidal effect mostly in outer and middle layers of biofilm. The penetration of Sn2+ in the biofilm performed an important function in the bactericidal effect of the toothpaste.

Modulation of partition and localization of perfume molecules in sodium dodecyl sulfate micelles.

The influence of perfume molecules on the self-assembly of the anionic surfactant sodium dodecyl sulfate (SDS) and their localization in SDS micelles have been investigated by ζ potential, small angle X-ray scattering (SAXS), one- and two-dimensional NMR and isothermal titration microcalorimetry (ITC). A broad range of perfume molecules varying in octanol/water partition coefficients P are employed. The results indicate that the surface charge, size and aggregation number of the SDS micelles strongly depend on the hydrophobicity/hydrophilicity degree of perfume molecules. Three distinct regions along the log P values are identified. Hydrophilic perfumes (log P < 2.0) partially incorporate into the SDS micelles and do not lead to micelle swelling, whereas hydrophobic perfumes (log P > 3.5) are solubilized close to the end of the hydrophobic chains in the SDS micelles and enlarge the micelles with higher ζ potential and a larger aggregation number. The incorporated fraction and micelle properties show increasing tendency for the perfumes in the intermediate log P region (2.0 < log P < 3.5). Besides, the molecular conformation of perfume molecules also affects these properties. The perfumes with a linear chain structure or an aromatic group can penetrate into the palisade layer and closely pack with the SDS molecules. Furthermore, the thermodynamic parameters obtained from ITC show that the binding of the perfumes in the intermediate log P region is more spontaneous than those in the other two log P regions, and the micellization of SDS with the perfumes is driven by entropy.