Effect of composite shade, increment thickness and curing light on temperature rise during photocuring

Journal of Dentistry

Volumn 35, Issue 3, 2007, Pages 238-245

  Al Qudah, A A ^a   Mitchell, C A ^b   Biagioni, P A ^b   Hussey, D L ^b  

^a JORDAN UNIVERSITY OF SCIENCE AND TECHNOLOGY   (Jordan)

^b QUEEN'S UNIVERSITY BELFAST   (United Kingdom)

Author keywords

Composite increment thickness; Curing units; Resin composite; Shade; Temperature rise; Thermography

Indexed keywords

BIOMEDICAL AND DENTAL MATERIALS; POLITEF; POLYMER; RESIN; SPECTRUM COMPOSITE RESIN; UNCLASSIFIED DRUG;

ARTICLE; CHEMISTRY; COLOR; EQUIPMENT DESIGN; HEAT; HUMAN; ILLUMINATION; INSTRUMENTATION; MATERIALS TESTING; RADIATION EXPOSURE; SURFACE PROPERTY; TEMPERATURE; THERMAL CONDUCTIVITY; TIME;

COLOR; COMPOSITE RESINS; DENTAL MATERIALS; EQUIPMENT DESIGN; HEAT; HUMANS; LIGHTING; MATERIALS TESTING; POLYMERS; POLYTETRAFLUOROETHYLENE; SURFACE PROPERTIES; TEMPERATURE; THERMAL CONDUCTIVITY; TIME FACTORS;

EID: 33846634243     PISSN: 03005712     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jdent.2006.07.012     Document Type: Article

References (27)

1. In: Ferracane J.L. (Ed). Materials in dentistry: principles and applications (1995), Lippincott, Philadelphia
2. Hansen E.K., and Asmussen E. Correlation between depth of cure and temperature rise of a light-activated resin. Scandanavian Journal of Dental Research 101 (1993) 176-179
3. Porko C., and Hietala E.-L. Pulpal temperature change with visible light curing. Operative Dentistry 26 (2001) 181-185
4. Al-Qudah A.A., Mitchell C.A., Biagioni P.A., and Hussey D.L. Thermographic investigation of contemporary resin-containing dental materials. Journal of Dentistry 33 (2005) 593-602
5. Stewardson D.A., Shortall A.C., Harrington E., and Lumley P.J. Thermal changes and cure depths associated with a high intensity light activation unit. Journal of Dentistry 32 (2004) 643-651
6. Kleverlaan C.J., and de Gee A.J. Curing efficiency and heat generation of various resin composites cured with high-intensity halogen lights. European Journal of Oral Science 112 (2004) 84-88
7. Asmussen E., and Peutzfeldt A. Temperature rise induced by some light emitting diode and quartz-tungsten-halogen curing units. European Journal of Oral Science 113 (2005) 96-98
8. Viadyanathan J., and Viadyanathan T.K. Computer-controlled differential calorimetry of dental composites. IEEE Transcripts of Biomedical Engineering 131 (1991) 319-325
9. McCabe J.F. Cure performance of light-activated composites by differential thermal analysis (DTA). Dental Materials 1 (1985) 231-234
10. Viadyanathan J., Viadyanathan T.K., Wang Y., and Viswanadhan T. Thermoanalytical characterization of visible light cured composites. Journal of Oral Rehabilitation 19 (1992) 49-64
11. Hussey D.L., Biagioni P.A., and Lamey P.J. Thermographic measurement of temperature change during resin composite polymerization in vivo. Journal of Dentistry 23 (1995) 267-271
12. Lloyd C.H., Joshi A., and McGlynn E. Temperature rises produced by light sources and composites during curing. Dental Materials 2 (1986) 170-174
13. Arikawa H., Fujii K., Kanie T., and Inoue K. Light transmittance characteristics of light-cured composite resins. Dental Materials 14 (1998) 405-411
14. Swartz M.L., Phillips R.W., and Rhodes B. Visible light-activated resins-depth of cure. Journal of the American Dental Association 106 (1983) 634-637
15. McCabe J.F., and Wilson H.J. The use of differential scanning calorimetry for the evaluation of dental materials. I. Cements, cavity lining materials and anterior restorative materials. Journal of Oral Rehabilitation 7 (1980) 103-110
16. Lloyd C.H. A differential thermal analysis (DTA) for the heats of reaction and temperature rises produced during the setting of tooth coloured restorative materials. Journal of Oral Rehabilitation 11 (1984) 111-121
17. McCabe J.F., and Carrick T.E. Output from visible-light activation units and depth of cure of light-activated composites. Journal of Dental Research 68 (1989) 1534-1539
18. Myers M.L., Caughman W.F., and Rueggeberg F.A. Effect of restoration composition, shade, and thickness on the cure of a photoactivated resin cement. Journal of Prosthodontics 3 (1994) 149-157
19. Kawaguchi M., Fukushima T., and Miyazaki K. The relationship between cure depth and transmission coefficient of visible-light-activated resin composites. Journal of Dental Research 73 (1994) 516-521
20. Watts D.C., Haywood C.M., and Smith R. Thermal diffusion through composite restorative materials. British Dental Journal 154 (1983) 101-103
21. Peutzfeldt A. Correlation between recordings obtained with a light-intensity tester and degree of conversion of a light-curing resin. Scandanavian Journal of Dental Research 102 (1994) 73-75
22. Hannig M., and Bott B. In-vitro pulp chamber temperature rise during composite resin polymerization with various light-curing sources. Dental Materials 15 (1999) 275-281
23. Parr G.R., and Rueggeberg F.A. Spectral analysis of commercial LED dental curing lights. Journal for Dental Research 81 special issue (2002) 88
24. Ozturk B., Ozturk A.N., Usumez A., Usumez S., and Ozer F. Temperature rise during adhesive and resin composite polymerization with various light curing sources. Operative Dentistry 29 (2004) 325-332
25. Danesh G., Davids H., Duda S., Kaup M., Ott K., and Schafer E. Temperature rise in the pulp chamber induced by a conventional halogen light-curing source and a plasma arc lamp. American Journal of Dentistry 17 (2004) 203-208
26. Knezevic A., Tarle Z., Meniga A., Sutalo J., and Pichler G. Influence of light intensity from different curing units upon composite temperature rise. Journal of Oral Rehabilitation 32 (2005) 362-367
27. Zach L., and Cohen G. Pulp response to externally applied heat. Oral Surgery, Oral Medicine, Oral Pathology 19 (1965) 515-530