Remineralizing Potential of a Low Fluoride Toothpaste with Sodium Trimetaphosphate: An in situ Study

Takeshita, Eliana Mitsue; Danelon, Marcelle; Castro, Luciene Pereira de; Cunha, Robson Frederico; Delbem, Alberto Carlos Botazzo

doi:10.1159/000449358

Cited by 21 publications

(18 citation statements)

References 33 publications

(49 reference statements)

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“…One way to reduce the potential risk of fluorosis while maintaining the anticaries efficacy of conventional dentifrices is to partly replace fluoride with polyphosphate salts like sodium trimetaphosphate (STMP), calcium glycerophosphate, or hexametaphosphate [da Camara et al, 2016;Takeshita et al, 2016;Zaze et al, 2014]. Among the polyphosphates, STMP is seen to be the most effective anticaries agent with an ability to not only inhibit demineralization, but also to enhance remineralization [Freire et al, 2016;Takeshita et al, 2011].…”

Section: Fluoride Boostersmentioning

confidence: 99%

“…The protective barrier against acid diffusion created by the adsorption of STMP on enamel does not seem to hinder the diffusion of Ca 2+ and F -ions into the enamel. In situ models have shown that supplementation of a low-fluoride product with STMP produced similar remineralization effects to a 1,100-ppm fluoride formulation Takeshita et al, 2016], while the addition of STPM to conventional fluoride dentifrices and varnishes significantly enhanced their remineralization of artificial caries lesions Manarelli et al, 2015].…”

Section: Fluoride Boostersmentioning

confidence: 99%

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State of the Art Enamel Remineralization Systems: The Next Frontier in Caries Management

2018

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The principles of minimally invasive dentistry clearly dictate the need for clinically effective measures to remineralize early enamel caries lesions. While fluoride-mediated remineralization is the cornerstone of current caries management philosophies, a number of new remineralization strategies have been commercialized or are under development that claim to promote deeper remineralization of lesions, reduce the potential risks associated with high-fluoride oral care products, and facilitate caries control over a lifetime. These non-fluoride remineralizing systems can be broadly categorized into biomimetic enamel regenerative technologies and the approaches that repair caries lesions by enhancing fluoride efficacy. This paper discusses the rationale for non-fluoride remineralization and the mechanism of action, challenges, and evidence behind some of the most promising advances in enamel remineralization therapies.

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Section: Fluoride Boostersmentioning

confidence: 99%

Section: Fluoride Boostersmentioning

confidence: 99%

State of the Art Enamel Remineralization Systems: The Next Frontier in Caries Management

2018

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“…Remineralization is believed to occur by the transfer of mineral ions, such as calcium and phosphate, from saliva, plaque fluid, or an external source to the surface of solid-state mineral, therefore promoting ion deposition into crystal voids caused by demineralization ( Elkassas and Arafa, 2014 ). Various modalities of fluoride ( Brighenti et al, 2006 ; Majithia et al, 2016 ), casein phosphopeptides and amorphous calcium phosphate (ACP) ( Poggio et al, 2013 ; Gupta et al, 2016 ), sodium trimetaphosphate ( Takeshita et al, 2016 ), and some natural products ( Zhang et al, 2015 ; Cardoso et al, 2016 ) have been reported to promote remineralization of incipient demineralized lesions. In particular, fluoride dentifrices are widely used for caries prevention and reversal.…”

Section: Introductionmentioning

confidence: 99%

Remineralization Efficacy of an Amelogenin-Based Synthetic Peptide on Carious Lesions

et al. 2018

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Objective: The aim of this study was to evaluate the remineralization efficacy of an amelogenin-based peptide on initial enamel carious lesions in vitro. Furthermore, we attempted to provide insights into the possible mechanism of the remineralization, including determining the calcium-binding properties of the peptide and its effects on calcium phosphate mineralization.Methods: The peptide comprising the N-terminus and the C-terminus of porcine amelogenin was synthesized by Synpeptide Co., Ltd. Fifty specimens were randomly assigned to five immersing treatment groups for 12 days: remineralizing medium only; 12.5 μg/mL peptide + remineralizing medium; 25 μg/mL peptide + remineralizing medium; 50 μg/mL peptide + remineralizing medium; fluoride + remineralizing medium. After immersion, mean mineral loss before and after remineralization of each specimen was determined using micro-CT. Mean mineral gain after remineralization was calculated. Calcium binding properties were measured by Isothermal titration calorimetry (ITC). TEM and Fourier transform-infrared were used to determine the effects of the peptide on calcium phosphate mineralization.Results: A significant decrease in mineral loss after remineralization process in all groups was observed (p < 0.05). Treatment in remineralizing medium resulted in the lowest mineral gain while the fluoridated treatment exhibited the highest mineral gain among all groups. Inclusion of synthetic peptide in the remineralizing medium exhibited a higher mineral gain and the gain of 50 μg/mL group was greater than that of the 25 μg/mL group. No significant difference in mineral gain was observed between the remineralizing medium only group and the 12.5 μg/mL peptide group (p > 0.05). ITC values showed that the Ca2+-binding affinity of the peptide is about 9.914 × 104M−1. Furthermore, the peptide was found to inhibit calcium phosphate precipitation and stabilize amorphous calcium phosphate formation for more than 2 h and finally transform into ordered hydroxyapatite crystals.Conclusion: Specific concentrations of the amelogenin-based synthetic peptide promoted in vitro remineralization, with higher concentrations exhibiting significantly greater remineralization. This study presented evidence suggesting that the peptide may act as a Ca2+carrier as well as a regulating factor. When the stabilizing calcium and phosphorus ions bind with the peptide they become biologically available for the remineralization of deeper carious lesions, while also regulated by the peptide to transform into ordered hydroxyapatite crystals.

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“…One way to reduce the potential risk of fluorosis while maintaining the anticaries efficacy of conventional dentifrices is to partly replace fluoride with polyphosphate salts like STMP, calcium glycerophosphate, or hexametaphosphate [da Camara et al, 2016;Takeshita et al, 2016;Zaze et al, 2014]. Among the polyphosphates, STMP is seen to be the most effective anticaries agent with an ability to not only inhibit demineralization but also enhance remineralization [Freire et al, 2016;Takeshita et al, 2011].…”

Section: Polyphosphates Sodium Trimetaphosphate (Stmp)mentioning

confidence: 99%

“…The protective barrier against acid diffusion created by the adsorption of STMP on enamel does not seem to hinder the diffusion of Ca 2+ and Fions into the enamel. In situ models have shown that supplementation of a lowfluoride product with STMP produced similar remineralization effects to 1100 ppm fluoride formulation [Danelon et al, 2013;Takeshita et al, 2016], while the addition of STPM to conventional fluoride dentifrices and varnishes significantly enhanced their remineralization of artificial caries lesions [Danelon et al, 2015;Manarelli et al, 2015].…”

Section: Polyphosphates Sodium Trimetaphosphate (Stmp)mentioning

confidence: 99%

Ecological approaches to dental caries prevention: Alteration of biofilms by natural products and casein-phosphopeptide-amorphous calcium phosphate

Philip¹

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Background: Dental caries is today widely recognised to be a biofilm-mediated disease triggered by dysbiosis in the resident oral microbiome. Despite the evolution of caries aetiological theories, disease preventive strategies are still largely dependent on the physicochemical effects of fluoride on the demineralization-remineralization caries equilibrium. The inability of fluoride to significantly influence the cariogenic bacterial challenge and reverse the microbial dysbiosis is one of the reasons the disease persists in many high caries-risk individuals and population groups. Countering the microbiome dysbiosis with conventional oral microbiocides is not recommended as their broadspectrum antimicrobial effects will eliminate even health-associated plaque microflora. Comprehensive caries management protocols need to encompass agents that not only influence the de-/remineralization balance, but also include measures that can have a beneficial modulating effect on the ecology of the dental plaque microbiome. Objectives: The overall aims of this PhD project were to examine whether selected natural products and novel remineralizing agents like casein phosphopeptide-amorphous calcium phosphate (CPP-ACP) can disrupt key virulence properties of cariogenic bacteria without broadly affecting microbial viability. The study also aimed to explore whether any virulence inhibitory effects of cariostatic natural products and CPP-ACP could translate into beneficial ecological effects both in in vitro biofilm models and in a clinical environment. Methods: A literature review was performed to identify natural products with potential cariostatic effects for investigation in this study. Agar diffusion and broth microdilution assays were used to assess whether any of the selected natural products could inhibit the growth of planktonic cultures of a caries-associated bacteria species (Streptococcus mutans) without affecting the viability of a healthassociated oral commensal bacterial species (Streptococcus sanguinis). Based on the results of the planktonic bacterial culture study, specific natural products were further selected to explore their effects on cariogenic biofilm virulence properties. The biofilm studies were conducted in an active attachment in vitro model using monospecies S. mutans biofilms, dual-species S. mutans-Candida albicans biofilms, and saliva-derived polymicrobial biofilms growing in a cariogenic environment. The natural products were assessed for their effects on biofilm metabolic activity, acidogenicity,

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Remineralizing Potential of a Low Fluoride Toothpaste with Sodium Trimetaphosphate: An in situ Study

Cited by 21 publications

References 33 publications

State of the Art Enamel Remineralization Systems: The Next Frontier in Caries Management

State of the Art Enamel Remineralization Systems: The Next Frontier in Caries Management

Remineralization Efficacy of an Amelogenin-Based Synthetic Peptide on Carious Lesions

Ecological approaches to dental caries prevention: Alteration of biofilms by natural products and casein-phosphopeptide-amorphous calcium phosphate

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