STATEMENT OF PROBLEM: The polymerization of dental composite resins can generate increases in intrapulpal temperature that may damage the pulp. The development of new polymerization devices such as the argon laser makes the assessment of these temperatures important. PURPOSE: This study compared increases in temperature generated by argon laser and halogen light when polymerizing a bonding system and a composite resin, and also sought to determine whether both types of polymerization lights generate temperature increases below the safe limit of 5.5 degrees C. MATERIAL AND METHODS: Thermocouples linked to a temperature reading system were positioned in the pulp chamber of 10 extracted bovine incisors. Class V cavities were prepared, etched, and filled with a 1-bottle bonding system (Single Bond) and composite resin (Z-100). The test groups were as follows (n = 5 for all groups): halogen light for bonding system (HB); halogen light for composite resin (HC); argon laser for bonding system (LB), and argon laser for composite resin (LC). The polymerization parameters were halogen light operated at 600 mW/cm2 for 40 seconds, which served as control, and argon laser operated at 200 mW for 10 seconds. Data were analyzed by a 2-way (light versus material) analysis of variance (ANOVA) (alpha = .05). RESULTS: The average temperature increases were 2.35 degrees C (HB), 2.69 degrees C (HC), 1.25 degrees C (LB), and 1.5 degrees C (LC). Significant differences between halogen light and argon laser (P = .002), but not between composite and bonding system, were demonstrated. CONCLUSIONS: The argon laser produced significantly lower increases in pulpal temperature than the halogen light, independent of the thickness of the polymerized material.
STATEMENT OF PROBLEM: The polymerization of dental composite resins can generate increases in intrapulpal temperature that may damage the pulp. The development of new polymerization devices such as the argon laser makes the assessment of these temperatures important. PURPOSE: This study compared increases in temperature generated by argon laser and halogen light when polymerizing a bonding system and a composite resin, and also sought to determine whether both types of polymerization lights generate temperature increases below the safe limit of 5.5 degrees C. MATERIAL AND METHODS: Thermocouples linked to a temperature reading system were positioned in the pulp chamber of 10 extracted bovine incisors. Class V cavities were prepared, etched, and filled with a 1-bottle bonding system (Single Bond) and composite resin (Z-100). The test groups were as follows (n = 5 for all groups): halogen light for bonding system (HB); halogen light for composite resin (HC); argon laser for bonding system (LB), and argon laser for composite resin (LC). The polymerization parameters were halogen light operated at 600 mW/cm2 for 40 seconds, which served as control, and argon laser operated at 200 mW for 10 seconds. Data were analyzed by a 2-way (light versus material) analysis of variance (ANOVA) (alpha = .05). RESULTS: The average temperature increases were 2.35 degrees C (HB), 2.69 degrees C (HC), 1.25 degrees C (LB), and 1.5 degrees C (LC). Significant differences between halogen light and argon laser (P = .002), but not between composite and bonding system, were demonstrated. CONCLUSIONS: The argon laser produced significantly lower increases in pulpal temperature than the halogen light, independent of the thickness of the polymerized material.
Authors: C Fornaini; C Bertrand; J P Rocca; P Mahler; M Bonanini; P Vescovi; E Merigo; S Nammour Journal: Lasers Med Sci Date: 2009-03-26 Impact factor: 3.161
Authors: Carlo Fornaini; Elisabetta Merigo; Paolo Vescovi; Mauro Bonanini; Walter Antonietti; Luca Leoci; Giuseppe Lagori; Marco Meleti Journal: Lasers Med Sci Date: 2014-07-03 Impact factor: 3.161
Authors: Carlo Fornaini; Marco Meleti; Mauro Bonanini; Giuseppe Lagori; Paolo Vescovi; Elisabetta Merigo; Samir Nammour Journal: ScientificWorldJournal Date: 2014-07-03