Evaluation of the influence of light-curing units on the degree of conversion in depth of a bulk-fill resin

Fernanda-Midori Tsuzuki; Lidiane-Vizioli-de Castro Hoshino; Larissa-Coelho-Pires Lopes; Francielle Sato; Mauro-Luciano Baesso; Raquel-Sano-Suga Terada

Ayuda

Evaluation of the influence of light-curing units on the degree of conversion in depth of a bulk-fill resin

Fernanda-Midori Tsuzuki ^[2] ; Lidiane-Vizioli de Castro-Hoshino ^[1] ; Larissa-Coelho-Pires Lopes ^[1] ; Francielle Sato ^[1] ; Mauro-Luciano Baesso ^[1] ; Raquel-Sano-Suga Terada ^[1]
1. [1] Universidade Estadual de Maringá
  
  Universidade Estadual de Maringá
  
  Brasil
2. [2] Postgraduate student, Department of restorative dentistry, Dental Materials area, Campinas State University (FOP/Unicamp), Piracicaba, Brazil
Localización: Journal of Clinical and Experimental Dentistry, ISSN-e 1989-5488, Vol. 12, Nº. 12 (December), 2020, págs. 1117-1123
Idioma: inglés
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Resumen
- It is known that bulk-fill have been widely studied and used by dentists in the clinic. However, the use of light-curing units that do not have the ability to adequately light-cure these materials at the appropriate depth can affect their clinical performance. The aim of this study was evaluating the influence of 5 different light curing units (LCUs) on the degree of conversion (DC) of a bulk-fill resin at depths of 0 to 4 mm and determined the effect of using 20s exposure and 40s.
  
  Cylinders of composite were made in a stainless steel matrix (n=10). The specimens were exposed from the top surface using 5 LCUs: Valo® Cordless (VA); Radii Plus (RA); Emitter.D (EM), Biolux Plus (BI), Woodpecker® (WO). The emission wavelength and the power density was determined. After the photoactivation, the Raman vibrational modes were calculated taking as reference the peaks at 1,601 (aromatic bonds C=C) and 1,640 cm-1 (aliphatic bonds C=C).
  
  The largest difference in DC in 20s, comparing the values obtained in the first and last layer is for BI, with a variation from 61.24% to 53.86%. Comparing the LCUs, the last layer in 40s DC values are 57.40% (BI), 58.21% (WO), 58.97% (VA), 60.90% (RA) and 62.42% (EM). The higher the dose (J/cm²) and the close the λmax is to the maximum CQ absorption length (λmax ~ 470 nm) the better the DC value.
  
  There was a significant difference in the DC values between the LCUs with increasing depth of the bulk-fill increments. Results indicate significant differences in DC among the different LCUs as well as enhanced DC when using 40s exposure compared to 20s. It is suggested that for DC improvement using lower power photoactivator increase the exposure time the exposure time should be 20s to 40s.