Spatio-temporal temperature fields generated coronally with bulk-fill resin composites: A thermography study

Jiawei Yang; Hamad Algamaiah; David C Watts

doi:10.1016/j.dental.2021.06.008

Spatio-temporal temperature fields generated coronally with bulk-fill resin composites: A thermography study

Dent Mater. 2021 Aug;37(8):1237-1247. doi: 10.1016/j.dental.2021.06.008. Epub 2021 Jun 16.

Authors

Jiawei Yang¹, Hamad Algamaiah², David C Watts³

Affiliations

¹ Dentistry, School of Medical Sciences, University of Manchester, Manchester, UK.
² Dentistry, School of Medical Sciences, University of Manchester, Manchester, UK; Department of Restorative Dental Science, College of Dentistry, King Saud University, Riyadh, Saudi Arabia. Electronic address: dr.algamaiah@gmail.com.
³ Dentistry, School of Medical Sciences, University of Manchester, Manchester, UK; Photon Science Institute, University of Manchester, Manchester, UK. Electronic address: david.watts@manchester.ac.uk.

PMID: 34144795
DOI: 10.1016/j.dental.2021.06.008

Abstract

Objective: This study aimed to investigate the effects of (i) a high-irradiance (3s) light-curing protocol versus (ii) two standard-irradiance (10s) protocols on 2D temperature maps during intra-dental photo-irradiation within a molar cavity restored with either Ultra-Rapid Photo-Polymerized Bulk Fill (URPBF) composites or a pre-heated thermo-viscous bulk-fill composite, compared to a standard bulk-fill resin-based-composite (RBC). The specific objectives included visual assessment of the temperature maps and quantitative assessment of several temperature/time plots at four different locations.

Methods: A caries-free lower first molar cavity served as a natural tooth mold. Resin composites were placed without intermediary adhesive. Two URPBF composites (PFill; PFlow) and one pre-heated thermo-viscous bulk-fill composite (Viscalor: VC) were compared to a contemporary bulk-fill composite (One Bulk Fill: OBF). Two LED-LCU devices were used: Bluephase PowerCure (PC) and Elipar S10 (S10), with three light-irradiation protocols (PC-3s, PC-10s and S10-10s). 2D temperature maps over the entire coronal area were recorded for 120 s during and after irradiation using a thermal imaging camera. Changes at four different levels were selected from the data sets: (0, 2 and 4 mm from the cavity top and at 1 mm below the dentin cavity floor). The maximum temperature attained (T_max), the mean temperature rise (ΔT), the time (s) to reach maximum temperature and the integrated areas (°C s) under the temperature/time (T/t) plots were identified. Data were analysed via three-way ANOVA, One-way ANOVA, independent t-tests and Tukey post-hoc tests (p < 0.05).

Results: All RBCs showed qualitatively similar temperature-time profiles. PFlow reached T_max in the shortest time. PC-3s (3000 mW/cm²) generated comparable ΔT to S10-10s, except with PFill, where ΔT was greater. Despite the same irradiance (1200 mW/cm²), Elipar S10 led to higher T_max and ΔT compared to PC-10s. The highest T_max and ΔT were observed at the 2 mm level, and the lowest were at 1 mm depth into the underlying dentin.

Significance: Coronal 2D temperature maps showed rises largely confined within the bulk-fill RBC materials, with maxima at 2 mm rather than 4 mm depth indicating some extent of thermal insulation for the underlying dentin and pulp. RBCs polymerized via different irradiation protocols showed similar temperature changes. With the PC-3s protocol - also with pre-heated VC - minimal temperature rises at 1 mm within dentin suggest their clinical safety when sufficient remaining dentin thickness is present.

Keywords: Bulk-fill resin composite; High-irradiance; Pre-heating; Thermal imaging; Thermo-viscous composite; Thermographic analysis; URPBF composites.

MeSH terms

Composite Resins
Curing Lights, Dental*
Materials Testing
Polymerization
Temperature
Thermography*

Substances

Composite Resins