TY - JOUR
T1 - Laser-induced acoustic emissions in experimental dental composites
AU - Lee, Sheng Yang
AU - Lin, Che Tong
AU - Ke, En Sheng
AU - Pan, Li Chern
AU - Huang, Haw Ming
AU - Shih, Yung Hsun
AU - Cheng, Hsin Chung
N1 - 被引用次數:2
Export Date: 9 August 2016
CODEN: BIMAD
通訊地址: Lee, S.Y.; Graduate Institute, Oral Rehabilitation Sciences, Taipei Medical College, 250 Wu-Hsing Street, Taipei, Taiwan; 電子郵件: [email protected]
化學物質/CAS: barium borosilicate; Barium Compounds; Composite Resins; Ethanol, 64-17-5; Silicates
商標: bisgma, Shin Nakamura, Japan
製造商: Aldrich, United States; Fluka, Switzerland; Shin Nakamura, Japan
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Princeton: Physical Acoustics Corporation; Lee, S.-Y., Greener, E.H., Mueller, H.J., Chiu, C.-H., Effect of food and oral simulating fluids on dentine bond and composite strength (1994) J Dent, 22, pp. 352-359; Lee, S.-Y., Greener, E.H., Mueller, H.J., Effect of food and oral simulating fluids on structure of adhesive composite systems (1995) J Dent, 23, pp. 27-35; Lee, S.-Y., Greener, E.H., Menis, D.L., Detection of leached moieties from dental composites in fluids simulating food and saliva (1995) Dent Mater, 11, pp. 348-353; Lee, S.-Y., Huang, H.-M., Lin, C.-Y., Shih, Y.-H., Leached components from dental composites in oral simulating fluids and the resultant composite strengths (1998) J Oral Rehabil, 25, pp. 575-588; Lin, C.-T., Lee, S.-Y., Keh, E.-S., Dong, D.-R., Huang, H.-M., Influence of silanization and filler fraction on aged dental composites (2000) J Oral Rehabil, , in press; Ferracane, J.L., (1983) The Correlation between the Physical Properties and Degree of Conversion on Unfilled Bis-GMA Based Dental Resin, Dissertation, , Chicago: Northwestern University; Wu, W., McKinney, J.E., Influence of chemicals on wear of dental composites (1982) J Dent Res, 61, pp. 1180-1183; McKinney, J.E., Wu, W., Chemical softening and wear of dental composites (1985) J Dent Res, 64, pp. 1326-1331; Roulet, J.-F., (1987) Degradation of Dental Polymers, pp. 60-90. , Karger: Basel; Spanner, J.C., Brown, A., Hay, D.R., Mustafa, V., Notvest, K., Pollock, A., Fundamental of acoustic emission testing - Part 4: introduction to acoustic emission signal characterization (1987) Nondestructive Testing Handbook - Acoustic Emission Testing, 5, pp. 27-33. , In: Miller RK, McIntire P, editor Columbus; American Society for Nondestructive Testing Inc; Spencer, P., Byerley, T.J., Eick, J.D., Witt, J.D., Chemical characterization of the dentin/adhesive interface by Fourier transform infrared photoacoustic spectroscopy (1992) Dent Mater, 8, pp. 10-15; Jastrzebski, Z.D., (1987) The Nature and Properties of Engineering Materials, , New York: John Wiley; Söderholm, K.-J., Influence of silane treatment and filler fraction on thermal expansion of composite resins (1984) J Dent Res, 63, pp. 1321-1326
PY - 2000
Y1 - 2000
N2 - A laser thermoacoustic technique was innovated to evaluate laser-induced acoustic emissions (AEs) in experimental dental composites aged with 75% ethanol solution. Experimental composite systems of 75/25 BisGMA/TEGDMA resin filled with 0, 12.6, 30.0, and 56.5vol% of 8-μm silanized and unsilanized BaSiO6 were analyzed. The sample size was 4.65mm (diameter)x0.5mm (thick). Aging effects of immersing in 75% ethanol for up to 14h on AEs were then evaluated. A continuous-wave CO2 laser was used to heat the samples. Acoustic emissions were collected as a function of filler fraction, laser power, silanization, and immersion time. Onset of burst-pattern acoustic signals characteristic of fracturing occurred at different laser powers for different tested groups. Acoustic emissions generally increased with laser power, in which lower laser powers produced low-amplitude (45-50 dB) signals; the amplitude distribution (50-85 dB) became more extensive as laser powers increased. After immersion, the lower laser powers could produce the same phenomenon. The higher the filler fraction, the fewer AEs generated. A large percentage AE reduction due to silanization was noted as a function of filler fraction. Unsilanized specimens showed more thermal damages than did silanized ones. Copyright (C) 2000 Elsevier Science B.V. A laser thermoacoustic technique was innovated to evaluate laser-induced acoustic emissions (AEs) in experimental dental composites aged with 75% ethanol solution. Experimental composite systems of 75/25 BisGMA/TEGDMA resin filled with 0, 12.6, 30.0, and 56.5 vol% of 8-μm silanized and unsilanized BaSiO6 were analyzed. The sample size was 4.65 mm (diameter)×0.5 mm (thick). Aging effects of immersing in 75% ethanol for up to 14 h on AEs were then evaluated. A continuous-wave CO2 laser was used to heat the samples. Acoustic emissions were collected as a function of filler fraction, laser power, silanization, and immersion time. Onset of burst-pattern acoustic signals characteristic of fracturing occurred at different laser powers for different tested groups. Acoustic emissions generally increased with laser power, in which lower laser powers produced low-amplitude (45-50 dB) signals; the amplitude distribution (50-85 dB) became more extensive as laser powers increased. After immersion, the lower laser powers could produce the same phenomenon. The higher the filler fraction, the fewer AEs generated. A large percentage AE reduction due to silanization was noted as a function of filler fraction. Unsilanized specimens showed more thermal damages than did silanized ones.
AB - A laser thermoacoustic technique was innovated to evaluate laser-induced acoustic emissions (AEs) in experimental dental composites aged with 75% ethanol solution. Experimental composite systems of 75/25 BisGMA/TEGDMA resin filled with 0, 12.6, 30.0, and 56.5vol% of 8-μm silanized and unsilanized BaSiO6 were analyzed. The sample size was 4.65mm (diameter)x0.5mm (thick). Aging effects of immersing in 75% ethanol for up to 14h on AEs were then evaluated. A continuous-wave CO2 laser was used to heat the samples. Acoustic emissions were collected as a function of filler fraction, laser power, silanization, and immersion time. Onset of burst-pattern acoustic signals characteristic of fracturing occurred at different laser powers for different tested groups. Acoustic emissions generally increased with laser power, in which lower laser powers produced low-amplitude (45-50 dB) signals; the amplitude distribution (50-85 dB) became more extensive as laser powers increased. After immersion, the lower laser powers could produce the same phenomenon. The higher the filler fraction, the fewer AEs generated. A large percentage AE reduction due to silanization was noted as a function of filler fraction. Unsilanized specimens showed more thermal damages than did silanized ones. Copyright (C) 2000 Elsevier Science B.V. A laser thermoacoustic technique was innovated to evaluate laser-induced acoustic emissions (AEs) in experimental dental composites aged with 75% ethanol solution. Experimental composite systems of 75/25 BisGMA/TEGDMA resin filled with 0, 12.6, 30.0, and 56.5 vol% of 8-μm silanized and unsilanized BaSiO6 were analyzed. The sample size was 4.65 mm (diameter)×0.5 mm (thick). Aging effects of immersing in 75% ethanol for up to 14 h on AEs were then evaluated. A continuous-wave CO2 laser was used to heat the samples. Acoustic emissions were collected as a function of filler fraction, laser power, silanization, and immersion time. Onset of burst-pattern acoustic signals characteristic of fracturing occurred at different laser powers for different tested groups. Acoustic emissions generally increased with laser power, in which lower laser powers produced low-amplitude (45-50 dB) signals; the amplitude distribution (50-85 dB) became more extensive as laser powers increased. After immersion, the lower laser powers could produce the same phenomenon. The higher the filler fraction, the fewer AEs generated. A large percentage AE reduction due to silanization was noted as a function of filler fraction. Unsilanized specimens showed more thermal damages than did silanized ones.
KW - Acoustic emissions
KW - Dental composites
KW - Laser
KW - Silanization
KW - Barium compounds
KW - Carbon dioxide lasers
KW - Continuous wave lasers
KW - Laser beam effects
KW - Plastics fillers
KW - Reinforced plastics
KW - Laser-induced acoustic emissions
KW - camphorquinone
KW - filler
KW - methacrylic acid dimethylaminoethyl ester
KW - polymer
KW - resin cement
KW - silicate
KW - triethylene glycol dimethacrylate
KW - unclassified drug
KW - article
KW - carbon dioxide laser
KW - drug analysis
KW - drug formulation
KW - evoked auditory response
KW - in vitro study
KW - materials testing
KW - priority journal
KW - technique
KW - Acoustics
KW - Barium Compounds
KW - Composite Resins
KW - Equipment Design
KW - Ethanol
KW - Heat
KW - Immersion
KW - Lasers
KW - Materials Testing
KW - Microspheres
KW - Silicates
U2 - 10.1016/S0142-9612(00)00043-0
DO - 10.1016/S0142-9612(00)00043-0
M3 - Article
SN - 0142-9612
VL - 21
SP - 1399
EP - 1408
JO - Biomaterials
JF - Biomaterials
IS - 13
ER -