Are polywave light-emitting diodes more effective than monowave ones in the photoactivation of resin-based materials containing alternative photoinitiators? A systematic review

Objective: This systematic review aimed to analyze if using polywave light-emitting diodes (LED) to photoactivate resin-based materials (resin composites, adhesive systems, and resin cements) containing alternative photo-initiators provide better physicochemical properties than monowave ones. Material and methods: Inclusion criteria were in vitro studies that evaluated the degree of conversion, micro-hardness and flexural strength in resin-based materials containing alternative photoinitiators and light-activated with mono and polywave LEDs. Exclusion criteria were studies that evaluated the physicochemical properties of composites through any material interposed between the LED and the resin composite and studies that exclu-sively compared different modes and/or light activation times. Selection of studies, data extraction, and risk-of-bias analysis was performed. Data from selected studies were qualitatively analyzed. A systematic search was performed in June 2021 using PubMed/Medline, Embase, Scopus, and ISI Web of Science databases and grey literature without language restriction. Results: A total of 18 studies were included in the qualitative analysis. Nine studies used diphenyl (2,4,6-tri-methylbenzoyl) phosphine oxide (TPO) as an alternative photoinitiator for resin composite. Polywave LED improved the degree of conversion of resin composite compared to monowave in 9 of the included studies. Polywave LED improved the microhardness of resin composite compared to monowave in 7 of the included studies. Polywave LED improved the degree of conversion for 11 studies and microhardness of resin composite compared to monowave for 7 included studies. No differences in the flexural strength medium between poly and monowave LEDs were observed. The evidence was graded as low quality due to the high risk of bias for 11 studies. Conclusion: The existing studies, with their limitations, revealed that the polywave light-emitting diode maxi-mizes activation, resulting in a higher degree of double-bond conversion and microhardness of resin composites containing alternative photoinitiators. However, the flexural strength of these materials is not influenced by the type of light activation device.

Automated summary

This systematic review aimed to analyze if using polywave LEDs to photoactivate resin-based materials containing alternative photo-initiators provide better physicochemical properties than monowave LEDs. The results showed that polywave LEDs improved the degree of conversion and microhardness of resin composites, but had no influence on the flexural strength.