silicon and Dental-Plaque

Composite resins (CRs) are widely used as dental restorative materials for caries treatment. They cause problems of secondary caries since Streptococcus mutans stays in the dental plaque, which the surface exists and produces acidic compounds during metabolism. The dental plaque depositions are induced by the protein adsorption on the surface. Therefore, suppression of protein adsorption on the surface of the CRs is important for inhibiting the formation of plaque and secondary caries. In this study we developed a surface treatment to provide an antibiofouling nature to the CRs by chemical reaction with 2-methacryloyloxyethyl phosphorylcholine (MPC) polymers in the oral cavity during dental treatment. To carry out the photochemical reaction on the remaining polymerizable groups of CRs, we synthesized the MPC polymer with a polymerizable group in the side chain. The MPC polymer could bind on the surfaces of the CRs chemically under dental treatment procedures. The treated surface showed significant resistance to oral protein adsorption and bacterial adhesion even when the surface was brushed with a toothbrush. Thus, we concluded that the photochemical reaction of the MPC polymer with the CRs in the oral cavity was good for making an antibiofouling surface and preventing secondary caries.

Topics: Acrylic Resins; Biofouling; Composite Resins; Dental Plaque; Methacrylates; Mucins; Phosphorus; Phosphorylcholine; Photoelectron Spectroscopy; Polymers; Polyurethanes; Proton Magnetic Resonance Spectroscopy; Silicon; Spectroscopy, Fourier Transform Infrared; Streptococcus mutans; Surface Properties

Bioactive glasses contain oxides of calcium, sodium, phosphorus, and silicon in a proportion that provides the material with surface activity and concomitantly with the property of forming a strong bond with bone. Bioactive glasses have been tested as bone substitutes in different clinical situations. In an aqueous environment, Ca2+, Na+, PO4(3-) , and Si4+ are released from the glass, resulting in a rise in pH and in osmotic pressure in its vicinity. Since these are factors that potentially influence the viability of oral microorganisms at the dentogingival margin, we studied the effects of bioactive glass S53P4 on the oral microorganisms Actinobacillus actinomycetemcomitans, Porphyromonas gingivalis, Actinomyces naeslundii, Streptococcus mutans, and Streptococcus sanguis. This was done by incubating each microbe in a suspension, in the presence of bioactive glass S53P4 in powder form. A. naeslundii was found to lose its viability within 10 min under the experimental conditions. A. actinomycetemcomitans, P. gingivalis, and S. mutans lost their viability within 60 min. Also for S. sanguis a significant loss of viability was seen within 60 min, but it was the only microbe that had any viable cells left after 60 min. Thus, in aqueous solutions the powdered bioactive glass S53P4 appears to have a broad antimicrobial effect on microorganisms of both supra- and subgingival plaque. Consequently, it could be useful as an ingredient in tooth-care products that may have beneficial effects on oral health both from a cariologic and a periodontal point of view.

Topics: Actinomyces; Aggregatibacter actinomycetemcomitans; Anti-Infective Agents, Local; Bacteria; Biocompatible Materials; Bone Substitutes; Calcium; Ceramics; Colony Count, Microbial; Dental Caries; Dental Plaque; Gingiva; Humans; Hydrogen-Ion Concentration; Mouth; Ointments; Osmotic Pressure; Periodontal Diseases; Phosphates; Porphyromonas gingivalis; Silicon; Sodium; Streptococcus mutans; Streptococcus sanguis; Surface Properties; Tooth

Using an electron-probe microanalyser, the distribution of silicon and other elements in supragingival dental calculus in domestic Japanese monkeys (Macaca fuscata) was studied. In two out of four monkeys kept in animals centres, a localized silicon distribution was found in both fracture and oral surfaces of the calculi. The silicon-rich area consisting of silicon alone resembled opal, but the areas containing silicon and other metal ions such as magnesium, aluminium, potassium and iron resembled clay minerals. In eight domestic monkeys, including the four animals described above, abundant calculus deposits were found. However, in four captured wild monkeys and in one which had been kept for less than a year at an animal centre, no dental calculus was found. There was almost no dental plaque accumulation in captured wild monkeys. It is suggested that calculus formation in Japanese monkeys is dependent on length of exposure to a commercial diet.

Topics: Animal Feed; Animals; Animals, Laboratory; Animals, Wild; Calcium; Dental Calculus; Dental Plaque; Durapatite; Electron Probe Microanalysis; Female; Macaca; Magnesium; Male; Phosphorus; Silicon

Cylindrical enamel blocks with initial carious lesions were treated for one hour with Duraphat or Fluor-Protector. After removal of the fluoride varnishes the enamel blocks were kept in the mouths of 3 probands for 5 days. Plaque was allowed to accumulate on half of the enamel cylinders, while the other half was kept clean. Part of the enamel cylinders were retained as fluoridated controls. Compared with Duraphat the application of Fluor-Protector resulted in a significantly higher uptake of KOH soluble and firmly bound fluoride. During the 5 days of the experiment the amount of KOH soluble fluorides decreased in both groups. In the presence of plaque the fluoride loss was higher. The amount of firmly bound fluoride increased both in the plaque covered and in the clean enamel. The durable cariostatic effect of fluoridated varnishes seems to be due to the slow dissolution of Ca F2-like precipitates on the enamel surface and the concomitant fluoride uptake in the underlying demineralized enamel.

Topics: Dental Caries; Dental Enamel; Dental Plaque; Drug Combinations; Fluorides; Fluorides, Topical; Humans; Pit and Fissure Sealants; Polyurethanes; Silanes; Silicon; Sodium Fluoride

Topics: Adolescent; Animals; Child; Dental Caries; Dental Enamel; Dental Plaque; DMF Index; Drug Combinations; Female; Fluorides; Fluorides, Topical; Humans; Male; Paint; Polyurethanes; Rats; Rats, Inbred Strains; Saliva; Silanes; Silicon; Sodium Fluoride