Effect of impression holding time and tray removal speed on the dimensional accuracy of impressions for artificial abutment tooth inclined.

Oral scanners allow dental impressions to be taken in a short time without the use of an impression material. However, it has been noted that high impression accuracy cannot be obtained in cases where the abutment is inclined or in cases where the span is long. Consequently, in daily clinical practice, impressions are often created using silicone impression material. When taking an impression using silicone impression material, the curing time or the removal time of the impression material are often based on the intuition of the dental staff. This study investigated the effects of impression holding time and impression tray removal speed on the dimensional accuracy of impressions. A specimen with an abutment inclined 30° to the removal direction of an impression was prepared. Four types of silicone rubber impression materials were used. Impressions were taken with two levels of holding time and two levels of removal speed using an autograph. The diameter of stone models was measured at 3, 6, and 9 mm from the baseline of each. The height of the inclined and opposite sides was also measured. Two-way analysis of variance was used to analyze data regarding the assessment of the effects of holding time and tray removal speed. The reproducibility of the impressions was affected by the volume of undercut caused by the inclined abutment. For a large undercut, longer holding times and faster tray removal speeds are recommended to reduce the deformation of silicone rubber impressions.

Comparison of diameters at the cementoenamel junction between South Asians and Japanese.

Previously, sex differences among the various tooth types in Japanese skulls were examined to facilitate choosing an implant diameter similar to the cervical diameter of each tooth, and it was found that mesiodistal diameters at the cementoenamel junction were narrower in women than in men. Also interesting and relevant to the selection of implant diameter is the possible existence of racial differences in diameters at the cementoenamel junction. The purpose of this research was to test the hypothesis that the diameter at the cementoenamel junction of the tooth differs in humans of different races. We compared 106 skulls of unknown sex collected from South Asia with the skulls of Japanese women. Our conclusions are as follows: (1) Except for the lower canine, no significant racial differences were found in the labiolingual diameter of any teeth. (2) Except for the upper canine, upper central incisor, lower second premolar, and lower first premolar, a significant racial difference was found in the mesiodistal diameter. In all teeth in which this value differed, the mesiodistal diameters of South Asians were narrower than those of Japanese women, except for the lower canine. (3) The labiolingual and mesiodistal diameters of the lower canine were significantly larger in South Asians than in Japanese women. (4) Among South Asians, no significant left/right differences were found in the diameter at the cementoenamel junction of any tooth.

The change in retentive force of magnetic attachment by abrasion.

Magnets are frequently applied to removable dentures as retentive attachments. A magnet-retained removable overdenture might be slightly shifted from side to side by eccentric movement in the mouth, and the surface of magnetic attachment may be worn as a result. However, the relationship between the retentive force of magnetic attachment and its surface abrasion has not been reported. The purpose of this research is to investigate this relationship. Ten Mgfit DX 400 magnetic attachments for natural tooth roots were used for this experiment. The magnetic attachments were embedded in autopolymerizing acrylic resin, and ten pairs of specimens were fabricated. A 5-mm repeated gliding motion was applied on each pair of specimens until 30 000, 50 000, or 90 000 cycles had been achieved. The abrasion machine was under 5 kg loading, and the slide speed was 60 times/min. The retentive force of magnetic attachment was measured with a tension gauge at (1) before gliding; (2) after 30 000 gliding cycles; (3)after 50 000 gliding cycles; or (4) after 90 000 gliding cycles. The average change of retentive force of ten magnetic attachments after 30 000, 50 000, and 90 000 gliding cycles was 0.016 N, 0.003 N, and -0.008 N, respectively. The change was statistically analyzed using a paired-sample t test, which showed that the number of gliding cycles did not affect the retentive force of magnetic attachment significantly. The surface of magnetic attachment after gliding was observed by a microscope, and the abrasion of this attachment surface is clearly seen.

[Comparison of three testing methods of fracture toughness using indirect composite].

PURPOSE: The aim of this study was to determine the adaptability of fracture toughness evaluation and the relationship between three testing methods: single-edge notched beam fracture toughness test (SENB), indentation fracture toughness test (IF), and notchless triangular prism fracture toughness test (NTP). METHODS: Two types of indirect composite, Ceramage and Estenia C&B, were used. Four types of experimental specimens were prepared under two curing conditions for each composite resin. One curing condition was only light curing and the other was heat curing after light curing. The fracture toughness value (K(Ic)) of the experimental specimens was measured by each of the three fracture toughness tests. K(Ic) of each test was compared by ANOVA and Tukey's multiple comparison test for the adaptability of fracture toughness evaluation. Then the correlation of two tests was evaluated by a simple linear regression analysis. RESULTS: Evaluation of the load-strain curve (or load-deflection curve) and fracture surface observation of SEM suggested the plane strain fracture phenomenon. K(Ic) values obtained by the three testing methods were significantly different (p<0.01). SENB could separate significantly these experimental specimens into four groups. IF could separate them into two groups. NTP could separate them into three groups. The fracture toughness evaluation of NTP was almost the same as that of SENB. The relationship between SENB and NTP showed a significant correlation (R(2)=99.7%) and its equation was NTP (K(Ic))=0.82 SENB(K(Ic))+1.05. IF did not show a significant correlation. CONCLUSION: These indirect composites tested exhibited different fracture toughnesses. This difference occurred due to the contents and curing conditions. The adaptability of fracture toughness evaluation showed different values depending on the testing method. The relationship of SENB and NTP showed a significant correlation.