90 research outputs found
Preparation of Large Quantities of Powdered Enamel
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/67378/2/10.1177_00220345650440023201.pd
Mechanisms of Enamel Dissolution in Acid Buffers
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/66717/2/10.1177_00220345650440020501.pd
Synchronized Crystal Dissolution Behavior for Tooth Enamel and Synthetic (NBS) Hydroxyapatite
The synchronized crystal dissolution hypothesis previously proposed to explain the unusual dissolution behavior of human dental enamel and hydroxyapatite in partially saturated acidic media has been critically examined with dissolution-dialysis transport experiments. The findings are in accord with the hypothesis. A model based upon a variable effective solubility for the hydroxyapatite crystal is proposed.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/67380/2/10.1177_00220345770560040701.pd
The Retardation of Enamel Dissolution Rates by Adsorbed Long-Chain Ammonium Chlorides
Dissolution rate studies were conducted with hydroxyapatite and enamel in the presence of adsorbed surfactants. In general, the ability of the surfactant to retard the dissolution rate was directly related to its ability to adsorb onto apatite. Cetylpyridinium chloride adsorbed poorly onto apatite, and its influence on the dissolution rate was marginal. The long-chain protonated amines were much more effective as rate retarding agents, sometimes of the order of 1,000-, to 10,000-fold. These compounds were also found to adsorb much more strongly. A systematic dependence of the dissolution rate on chain length was found for these amines.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/68179/2/10.1177_00220345690480040301.pd
Particle motion and stain removal during simulated abrasive tooth cleaning
Stain removal from teeth is important both to prevent decay and for appearance. This is usually achieved using a filament-based toothbrush with a toothpaste consisting of abrasive particles in a carrier fluid. This work has been carried out to examine how these abrasive particles interact with the filaments and cause material removal from a stain layer on the surface of a tooth. It is important to understand this mechanism as while maximum cleaning efficiency is required, this must not be accompanied by damage to the enamel or dentine substrate. In this work simple abrasive scratch tests were used to investigate stain removal mechanism of two abrasive particles commonly used in tooth cleaning, silica and perlite. Silica particles are granular in shape and very different to perlite particles, which are flat and have thicknesses many times smaller than their width. Initially visualisation studies were carried out with perlite particles to study how they are entrained into a filament/counterface contact. Results were compared with previous studies using silica. Reciprocating scratch tests were then run to study how many filaments have a particle trapped at one moment and are involved in the cleaning process. Stain removal tests were then carried out in a similar manner to establish cleaning rates with the two particle types. Perlite particles were found to be less abrasive than silica. This was because of their shape and how they were entrained into the filament contacts and loaded against a counterface. With both particles subsurface damage during stain removal was found to be minimal. A simple model was built to predict stain removal rates with silica particles, which gave results that correlated well with the experimental data
The kinetics and mechanisms of reactions of human tooth enamel in buffered solutions of high fluoride concentrations
The experimental results were quantitatively compared with the theory based on a physical model representing the reaction and with the experiments involving synthetic hydroxyapatite discs. The experimental initial rates self-consistently compared well with the theoretical predictions. An analysis of the experimental initial rate data yielded a reaction constant, [kappa], for the reaction representing apatite dissolution and calcium fluoride precipitation. It is proposed that the value for [kappa] is a result of both supersaturation with respect to calcium fluoride and undersaturation with respect to apatite at the apatite-calcium fluoride reaction sites. This finding is also consistent with the analysis of the experiments with synthetic apatite discs.Important similarities and significant differences were found between the experiments with the enamel sections and with synthetic apatite discs. The experiments with the synthetic apatite discs were reported to proceed "normally" as predicted by the physical model over the entire course of the reaction. In contrast to these findings, while the initial rates of the enamel-fluoride reaction were found to proceed relatively rapidly and according to the theoretical predictions, the rates at later times were drastically reduced. This "choking off" was observed to be most severe in the experiments at low pH and high fluoride concentrations, and little or no "choking oft" was observed at low fluoride concentrations and high pH.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/22291/1/0000731.pd
Unusual Dissolution Behavior of Tooth Enamel and Synthetic HAP Crystals Under High Partial Saturation Conditions
The dissolution behavior of enamel and synthetic hydroxyapatite in acidic media possessing a high degree of partial saturation was found to be neither simple surface dissolution nor linear with time. Instead, a repetitive, stepwise dissolution pattern was observed. To explain this phenomenon, a model based upon a hypothesis that the crystals dissolve in a synchronized fashion was proposed.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/66946/2/10.1177_00220345770560051201.pd
Modifications in Glass Ionomer Cements: Nano-Sized Fillers and Bioactive Nanoceramics.
Glass ionomer cements (GICs) are being used for a wide range of applications in dentistry. In order to overcome the poor mechanical properties of glass ionomers, several modifications have been introduced to the conventional GICs. Nanotechnology involves the use of systems, modifications or materials the size of which is in the range of 1-100 nm. Nano-modification of conventional GICs and resin modified GICs (RMGICs) can be achieved by incorporation of nano-sized fillers to RMGICs, reducing the size of the glass particles, and introducing nano-sized bioceramics to the glass powder. Studies suggest that the commercially available nano-filled RMGIC does not hold any significant advantage over conventional RMGICs as far as the mechanical and bonding properties are concerned. Conversely, incorporation of nano-sized apatite crystals not only increases the mechanical properties of conventional GICs, but also can enhance fluoride release and bioactivity. By increasing the crystallinity of the set matrix, apatites can make the set cement chemically more stable, insoluble, and improve the bond strength with tooth structure. Increased fluoride release can also reduce and arrest secondary caries. However, due to a lack of long-term clinical studies, the use of nano-modified glass ionomers is still limited in daily clinical dentistry. In addition to the in vitro and in vivo studies, more randomized clinical trials are required to justify the use of these promising materials. The aim of this paper is to review the modification performed in GIC-based materials to improve their physicochemical properties
- …