Objective(s): The world of dentistry is constantly evolving, and with the advent of 3D printing technology, the possibilities are endless. However, little is known about the effects of adding ZrO2 NPs to the denture base resin of 3D additive manufacturing technique.Aim of this study is to evaluate the behavior of resin which is used to 3D printing of denture base with the addition of ZrO2 NPs on denture adaptation property and diametral compression strength.Methods: 60 samples were printed, 30 disks for diametral compressive test and 30 denture base for denture adaptation test. Three groups per test (n=10). The control group for each test included unreinforced 3Dprinted denture base resin, and the other groups were reinforced with (2&3%) nanoZrO2; diametral compressive strength was evaluated using universal compressive testing machine, while denture adaptation was evaluated by exocad software program.Results: the study reveals significant difference in both diametral compressive strength and denture adaptation of the 3Dprinted denture base resin after adding nanoZrO2, as denture adaptation increased; the mean of diametral compression was decreasing with 2%&3% percent of ZrO2 NPs.Conclusions: addition of Zro2 NPs to 3D printed denture base resin may help in improving the material behavior as concerning mechanical and adaptation properties.
The effect of ZrO2 NPs addition on denture adaptation and diametral compressive strength of 3D printed denture base resin
Publication Date
Thu Nov 19 2020
Journal Name
Indonesian Journal Of Chemistry
Determination of Eugenol in Personal-Care Products by Dispersive Liquid-Liquid Microextraction Followed by Spectrophotometry Using <i>p</i>-Amino-<i>N,N</i>-dimethylaniline as a Derivatizing Agent
dispersive liquid-liquid microextraction
derivatizing agent
eugenol
p-amino-N
N-dimethylaniline
Two simple methods for the determination of eugenol were developed. The first depends on the oxidative coupling of eugenol with p-amino-N,N-dimethylaniline (PADA) in the presence of K3[Fe(CN)6]. A linear regression calibration plot for eugenol was constructed at 600 nm, within a concentration range of 0.25-2.50 μg.mL–1 and a correlation coefficient (r) value of 0.9988. The limits of detection (LOD) and quantitation (LOQ) were 0.086 and 0.284 μg.mL–1, respectively. The second method is based on the dispersive liquid-liquid microextraction of the derivatized oxidative coupling product of eugenol with PADA. Under the optimized extraction procedure, the extracted colored product was determined spectrophotometrically at 618 nm. A l
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