This study was performed to assess the analyzing methods developed to detect clinically and quantitatively longitu dinal bone changes. through preliminary experiment, accuracy of Cu-Eq value conversion to the mass of HA was examined. For main experiment, 15 intraoral radiograms taken at soon, 1st, 2nd, 4th, and 6th week after implantation of mixture in extracted sites of 3 cases were user. We took the radiograms with copper step wedge as test object and HA phantom. X -ray taking was standardized by using Rinn XCP device customized directly to the individual dentition with resin bite bl ock. The images inputted by Quick scnner into computer were digitized and analyzed by NH image program, the stability of the copper equivalent trasformation and the usefulness of two analyzing methods by ROI and Reslice were examined. Obtained results as follows: 1. On the Cu equivalent images, the coefficient of variation in the measurement of Cu-Eq. value of ROI ranged from 0.05 to 0.24 and showed high reproducibility. 2. All results obtained by resliced contiguous images were coincident with those obtained from the assessment by ROI an d formation of plot profile. 3. On the stacked and resliced image at the line of interest, we could analyze directly and quantitatively the longitud inal changes at several portions by plot profile and qualitatively by surface plot. 4. Implant area showed marked resorption till 2 weeks after implantation and showed significant increase in Cu-Eq. valu e at 6th week(P<0.01) and periapical area showed increase in cu-eq. value at 6th week compared to after-operation's.
Copper ; Dentition

No abstract available.
Copper* ; Lasers, Gas*

No abstract available.
Copper* ; Myelodysplastic Syndromes*

No abstract available.
Chromium ; Copper ; Zinc

OBJECTIVE: The purpose of this study was to measure the temperature of the plugger tip of 3 cordless heat carriers set at 200°C. MATERIALS AND METHODS: Pluggers of the same taper (0.06, 0.08, 0.10) and similar tip sizes (sizes of 50 and 55) from 3 cordless heat carriers, namely SuperEndo-α2 (B & L Biotech), Friendo (DXM), and Dia-Pen (Diadent), were used and an electric heat carrier, System B (SybronEndo), was used as the control. The plugger tips were covered with customized copper sleeves, heated for 10 seconds, and the temperature was recorded with a computerized measurement system attached to a K-type thermometer at room temperature (n = 10). The data were analyzed with 2-way analysis of variance at a 5% level of significance. RESULTS: The peak temperature of the plugger tips was significantly affected by the plugger taper and by the heat carrier brand (p < 0.05). The peak temperature of the plugger tips was between 177°C and 325°C. The temperature peaked at 207°C–231°C for the 0.06 taper pluggers, 195°C–313°C for the 0.08 taper pluggers, and 177°C–325°C for the 0.10 taper pluggers. Only 5 of the 12 plugger tips showed a temperature of 200°C ± 10°C. The time required to reach the highest temperature or 200°C ± 10°C was at least 4 seconds. CONCLUSION: When using cordless heat carriers, clinicians should pay attention to the temperature setting and to the activation time needed to reach the intended temperature of the pluggers.
Copper ; Hot Temperature ; Thermometers

No abstract available.
Copper* ; Humans* ; Milk, Human* ; Zinc*

PURPOSE: The effects of step numbers of copper wedge and exposure on the coefficient of determination(r2) of the conversion equation to Cu-equivalent image and on the Cu-equivalent value(mmCu) and it's coefficient of variation measured at each copper step and the mandibular premolar area were evaluated. METHOD: Digital image analyzing system consisted of scanner, personal computer, and a stepwedge with 10 steps of 0.03mm copper in thickness as reference material was prepared for quantitative assessment of the bone mineral density. NIH image program was used for analyzing images. RESULTS: The film having moderately high film density showed the discrepancy between the real thickness and the measured Cu-equivalent value of each copper step. The Cu-equivalent image was dependent on the determinational coefficient of the conversion equation than the coefficient of variance of the measured value. CONCLUSION: Obtaining conversion equation with high coefficient of determination and proper film exposure are supposed to be neccessary for quantitative assessment of bone density. Multiple steps in the range of the corresponding copper thickness to the bone density of the area to be measured should be prepared.
Bicuspid ; Bone Density* ; Copper ; Microcomputers

No abstract available.
Cobalt* ; Copper* ; Dental Alloys* ; Nickel*

No abstract available.
Copper* ; Female ; Humans ; Intrauterine Devices*

This investigation evaluated the fracture toughness (KIC) of eight currently available core materials, and relate the fracture toughness value to fractography analysis and surface characteristics using a atomic force microscope (AFM). Single-edge notched (SEN) test specimens (n=10) and compact tension (CT) test specimens (n=10) were prepared conforming to the ASTM Standard E-399 for a high copper amalgam, three composite core materials (Core-Max II, Core Paste, Bisfil Core), two reinforced composite core materials (Ti-Core, Ti-Core Natural), a resin-modified glass ionomer core material (Vitremer), and a conventional glass ionomer core material (Ketac-Molar). The specimens were tested with an Instron Universal Testing Machine. The maximum loads were measured to calculate the fracture toughness (KIC). Thereafter, fracture surfaces of SEN specimens of each material were investigated for fractography analysis using scanning electron microscope. And, disc-shaped specimens with 1mm thickness were fabricated for each material and were investigated under AFM for surface morphology analysis. The results were as follows : 1. Bisfil Core showed the highest mean fracture toughness regardless of test methods. 2. For the tooth-colored materials, Ti-Core Natural exhibited the highest fracture toughness. 3. Ketac Molar showed a significantly low fracture toughness when compared with the amalgam and the composite resin core materials (p<0.05). 4. The fracture toughness values obtained with the single-edge notched test, except Ketac Molar, were higher than those obtained in the compact tension test. 5. SEM revealed that the fracture surface of high fracture toughness material was rougher than that of low fracture toughness material. 6. AFM revealed that the surface particles of the composite resins were smaller in size, with a lower surface roughness than the glass ionomer core materials.
Composite Resins ; Copper ; Glass ; Molar