Toshio Hongo

Mechanical properties of orthodontic wires made of super engineering plastic

Most orthodontic equipment is fabricated from alloys such as stainless steel, Co-Cr and Ni-Ti because of their excellent elastic properties. In recent years, increasing esthetic demands, metal allergy and interference of metals with magnetic resonance imaging have driven the development of non-metallic orthodontic materials. In this study, we assessed the feasibility of using three super engineering plastics (PEEK, PES and PVDF) as orthodontic wires. PES and PVDF demonstrated excellent esthetics, although PEEK showed the highest bending strength and creep resistance. PEEK and PVDF showed quite low water absorption. Because of recent developments in coloration of PEEK, we conclude that PEEK has many advantageous properties that make it a suitable candidate for use as an esthetic metal-free orthodontic wire.

Increase in the levels of chaperone proteins by exposure to β-estradiol, bisphenol A and 4-methoxyphenol in human cells transfected with estrogen receptor α cDNA

We examined changes in the levels of chaperone proteins to evaluate the toxic effects of environmental chemicals in human cells in vitro. Some chaperones are up-regulated by estrogenic chemicals, but the effect is not necessarily dependent on the receptor. Thus we also investigated whether a chemical-induced change in chaperone protein expression is human estrogen receptor (hER)-dependent or not, using cultured human cell lines transfected with hERalpha cDNA or an empty vector. In the hERalpha-expressed cells, the protein levels of the heat shock protein 27 (HSP27), the glucose-regulated protein 78 (GRP78/BiP), and GRP94 increased after exposure to beta-estradiol (E(2)) (from 10(-9)M to 10(-6)M) and bisphenol A (BPA) (from 10(-6)M to 10(-5)M). On the other hand, the increase was not observed in the cells without hERalpha expression. These results suggest that the E(2)- and BPA-induced increase in the protein levels were hERalpha dependent. We next examined the effect of four phenolic chemicals similar in structure to BPA, and found that among them, 4-methoxyphenol (from 10(-6)M to 10(-5)M) increased the levels of the chaperone proteins with hERalpha dependency. Thus the human cultured cells would be suitable for evaluating whether an increase in chaperone proteins occurs upon exposure to environmental chemicals and whether the effect is ER-dependent.

Novel metal allergy patch test using metal nanoballs

BackgroundPatch tests are often used in the clinical diagnosis of metal allergies. In currently available patch tests, high concentrations of metal salt solutions are used. However, diagnosis accuracy can be influenced not only by acute skin reactions to high concentrations of metal salt, but also by skin reactions to other components present in the patch or to pH changes. In this study, we developed Ni nanoparticles (termed “nanoballs”) for use in patch-test solutions.FindingsHighly soluble, spherical Ni nanoballs were prepared using plasma electrolysis. The Ni released from the nanoballs permeated through a dialysis membrane, and the nanoball-containing solution’s pH was maintained constant. Ni ions were released slowly at low concentrations in a time-dependent manner, which contrasted the rapid release observed in the case of a commercial patch test. Consequently, in the new test system, reactions caused by high concentrations of metal salts were avoided.ConclusionsBy exploiting the high specific surface area of Ni nanoballs, we obtained an effective dissolution of Ni ions that triggered Ni allergy in the absence of direct contact between the nanoballs and mouse skin. This novel patch system can be applied to other metals and alloys for diagnosing various types of metal-induced contact dermatitis.

A method to visualize transdermal nickel permeation in mouse skin using a nickel allergy patch

Metal patch test is often used in clinical settings when metal-induced contact dermatitis is suspected. However, the transdermal permeation behavior of metal ions from the patch test remains unclear. Current patch tests using high concentrations of metal salt solutions have some side effects, e.g. acute skin reactions to high concentrations of metal salt. To resolve these, estimating metal ion transdermal permeation is wished. In this study, synchrotron radiation X-ray fluorescence (SR-XRF) and micro-focused particle-induced X-ray emission (micro-PIXE) were used to visualize the time-dependent Ni permeation in mouse skin. The cross-sectional diffusion of Ni was visualized in a time-dependent manner. Our results indicate that maximum Ni permeation occurs after 24 h of patch treatment, and the permeated Ni content was high in the epidermis and spread into the dermis beyond the basal layer. This method may be useful to determine the appropriate solution concentration and duration of administration for the patch test.

Rare Earth Oxide Containing Filler for Dental Composite Resin

A composite resin (CR) with photo-polymerization is widely used for dental filling material. Because of their good esthetics, the visual inspection of restored teeth becomes difficult. In this study, the fluorescent glass/ceramics fillers containing rare earth oxides — which are well-known fluorescent materials — was prepared and applied in CR to enhance visual inspection capability with small influence in color. Eu2O3-containing Y2O3 filler (Y2O3:Eu) prepared with homogeneous coprecipitaion method showed clear fluorescence at 614nm with near ultraviolet light (385nm) excitation. The fluorescence intensity of the prepared Y2O3:Eu filler increased with increase of Eu content in the Y2O3 filler upto 15mol% of Eu content. The composite resin was prepared with the mixed filler of Y2O3:Eu filler and the conventional glass filler. The content of Y2O3:Eu was varied between 0 to 40wt% of mixed filler. The prepared composite resin also showed clear fluorescence with quite small affect to the color change and the Vickers hardness of composite resin. Therefore, the prepared rare earth oxide containing Y2O3 filler was applicable as the filler of dental composite resin.