This thesis contains two parts. In the first part, four kinds of dental baseplates were obtained after curing at 70 ¢XC in water bath or curing in microwave oven. Pressure vent polymerizing Meta-cera (PVPM) methods were performed at 500 watts using Y-Z flask, then the specimens in the flasks were cooled in two different ways. Additionally, the samples in GC FRP flask were separately cured by three different microwave-energy powers: 85, 255 or 595 watts. Each of these curing conditions has six specimens. Adaptation, porosity, and fracture strength of these specimens were evaluated. Optilon-399, a rubber-toughed dental baseplate, was chosen to study the effect of curing conditions on the morphology of the stained specimens using transmission electron microscope (TEM). The results indicate that dispersed rubber- enriched phase is observed. Most of the dispersed phase has a mean-diameter ranging from 210 to 1440 nm and smaller domains have a mean-diameter of 80-100 nm. These dispersed domains observed in TEM micrographs are statistically analyzed and compared using one-way analysis of variance (ANOVA) method. The specimens cured in water bath (reference) have the largest mean-diameter, 456 ¡Ó 131 nm, for the dispersed phase. There is no significant difference in mean-diameters between the reference method and 595-watts method. Mean-diameters of the specimens (408~442 nm) cured by the other four methods are significantly less than that of the reference method. Differences are also found among three different microwave-energy powers. Mean-diameter increases from 408 to 432 to 454 nm and the number of domains drops from 35.7 to 34.1 to 32.1 per TEM micrograph when microwave-energy power increases from 85 to 255 to 595 watts. However, 595-watts specimens have the problem of porosity and 85-watts specimens have the highest adaptation discrepancy. Therefore, 255-watts specimens have a relatively high fracture strength (388 kgf versus 354 or 369 kgf). There is no difference in mean-diameter (440 versus 442 nm) and the number of domains (32.9 per TEM micrograph) between PVPM systems. Low adaptation discrepancy and no porosity result in a higher fracture strength (395 and 381 kgf) compared with the reference method (284kgf). From this study, PVPM method in a bench cooled type is suggested to prepare dental baseplates.
In the second part, restorative materials for tooth were polymerized and cured using a blue light emitting diode (LED) unit. Five kinds of light-curing hybrid composite resins (Premisa, Esthet-X micro matrix restorative, Z100 Restorative, Filtek Z250 and Filtek Z350) were processed by four different operating modes of LED as follows: control mode- 500 mW/cm2 for 20 s; pulse cure mode - 500 mW/cm2 for 10s, 0 mW/cm2 for 10s, then 500 mW/cm2 for the next 10 s; soft-start (ramp) mode- initially 600 mW/cm2 for 10 s, then jump to 1400 mW/cm2 for 10 s; turbo (high) mode-1400 mW/cm2 for 10 s. Each of light-curing dental materials and LED operating modes has six specimens. Temperature variation of resins in a period of 60 s was measured during and after activating the light. Vicker¡¦s hardness of both top and bottom sides of specimens after curing was measured. Both temperature rise and hardness of specimens are statistically analyzed and compared using two-way ANOVA method. Soft-start mode induced an average temperature rise of 7.70 ¡Ó 0.77 ¢XC which is significantly (P<0.05) higher than the other three modes. Pulse cure mode yielded average 4.49 ¡Ó 0.84 ¢XC rise which is lowest (P<0.05). There is no difference in temperature rise between control and turbo modes (P>0.05). Comparing five dental materials, Z350 had an average temperature rise of 7.04 ¡Ó 1.10¢XC that is the highest and significantly different from the other materials (P<0.05). Average temperature rise of the other materials was about 5.3 ¢XC without significant difference, except Premise versus Z100. Both top and bottom sides¡¦ hardness of the cured specimens are determined by dental materials (P<0.05), not by LED operating modes (P>0.05). Z100 has the highest hardness (top: 181.6¡Ó8.9kgf/mm2, bottom: 149.1¡Ó6.0 kgf/mm2). Hardness decreases in the order of Z250, Esthet-X, Premise, Z350. Additionally, the results of isothermal polymerization and curing of resins at 165 ¢XC for 3 hr indicate that the high temperature rise (7 ¢XC) of Z350 resins is due to the high exothermic enthalpy (- 61 J/g). The trend of temperature rise of other dental materials can also be explained from the exothermic value which is measured using differential scanning calorimeter (DSC). Degree of polymerization conversion of resins after light-curing was also evaluated using DSC. Z100 specimens yielded the complete conversion (100%) for all of LED operating modes. From the viewpoints of complete conversion and high hardness, it is suggested to process Z100 specimens in a pulse cured mode because the temperature rise is only 4.65 ¢XC.
| Identifer | oai:union.ndltd.org:NSYSU/oai:NSYSU:etd-0724107-163540 |
| Date | 24 July 2007 |
| Creators | Wang, Pei-yu |
| Contributors | Ming-Hwa Jen, Jin-Long Hong, Chi Wang, Ming Chen |
| Publisher | NSYSU |
| Source Sets | NSYSU Electronic Thesis and Dissertation Archive |
| Language | Cholon |
| Detected Language | English |
| Type | text |
| Format | application/pdf |
| Source | http://etd.lib.nsysu.edu.tw/ETD-db/ETD-search/view_etd?URN=etd-0724107-163540 |
| Rights | withheld, Copyright information available at source archive |
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