Does the mixing method of AH Plus Jet affect its physicochemical and mechanical properties?

INTRODUCTION: The purpose of this study was to evaluate whether the mixing method of AH Plus Jet sealer affects its physicochemical and mechanical properties. METHODS: The properties of AH Plus Jet sealer were analyzed when mixed using either the Auto Mix Tip or manual mixing. The evaluated properties included radiopacity (n=5), initial and final setting times (n=5), flow (n=5), and solubility (n=3), following specifications outlined in ISO 6876/2012 and ADA Nº 57/2000. pH levels were measured at intervals of 3, 24, 72, and 168 hours (n=10). The push-out bond strength test was conducted using a universal testing machine and using bovine teeth (n=30). Failure modes were analyzed with stereomicroscopy. Porosity was evaluated under micro-CT (n=5) and scanning electron microscopy was also performed (n=5). One-way analysis of variance and Tukey, unpaired t-tests, or Mann-Whitney tests were used with a significance level of 5%. RESULTS: The Auto Mix exhibited a radiopacity value of 12.11 mmAl, whereas manual mixing resulted in 12.55 mmAl (P>0.05). For initial and final setting times, Auto Mix showed 901 minutes and 1779 minutes, respectively, while manual mixing recorded values of 631 minutes and 1504 minutes (P<0.05). In terms of flow, Auto Mix demonstrated higher values (25.26 mm) than manual mixing (21.71 mm) (P<0.05). No statistical differences were observed between the two methods for solubility and pH (P>0.05). Manual mixing presented a higher bond strength value (14.52 MPa) than Auto Mix (9.81 MPa) (P<0.05). The mixed failure mode was the most frequent outcome for both methods. The highest porosity was observed for Auto Mix (P<0.05). Scanning electron microscopy analysis revealed that manual mixing resulted in a smoother surface with fewer pores and smaller, more evenly distributed agglomerates compared to automatic mixing. CONCLUSION: The mixing method employed for AH Plus Jet sealer influences some physicochemical and mechanical properties of the material.

Effect of nonsteroidal anti-inflammatory drugs (NSAIDs) association on physicochemical and biological properties of tricalcium silicate-based cement

Abstract The aim of this study was to investigate the physicochemical and biological properties of an experimental tricalcium silicate-based repair cement containing diclofenac sodium (CERD). For the physicochemical test, MTA, Biodentine and CERD were mixed and cement disc were prepared to evaluate the setting time and radiopacity. Root-end cavity were performed in acrylic teeth and filled with cements to analyze the solubility up to 7 days. Polyethylene tubes containing cements were prepared and calcium ions and pH were measured at 3h, 24h, 72h and 15 days. For the biological test, SAOS-2 were cultivated, exposed to cements extracts and cell proliferation were investigated by MTT assay at 6h, 24h and 48h. Polyethylene tubes containing cements were implanted into Wistar rats. After 7 and 30 days, the tubes were removed and processed for histological analyses. Parametric and nonparametric data were performed. No difference was identified in relation to setting time, radiopacity and solubility. Biodentine released more calcium ion than MTA and CERD; however, no difference between MTA and CERD were detected. Alkaline pH was observed for all cements and Biodentine exhibited highest pH. All cements promoted a raise on cell proliferation at 24h and 48h, except CERD at 48h. Biodentine stimulated cell metabolism in relation to MTA and CERD while CERD was more cytotoxic than MTA at 48h. Besides, no difference on both inflammatory response and mineralization ability for all cement were found. CERD demonstrated similar proprieties to others endodontic cements available.

Resumo O objetivo deste estudo foi investigar as propriedades físico-químicas e biológicas de um cimento reparador experimental à base de silicato de tricálcio contendo diclofenaco de sódio (CERD). Para o teste físico-químico, MTA, Biodentine e CERD foram manipulados e discos de cimentos foram preparados para avaliar o tempo de presa e a radiopacidade. Retrocavidades foram feitas em dentes de acrílico e preenchidas com cimentos para análise de solubilidade por 7 dias. Tubos de polietileno contendo cimentos foram preparados e os íons cálcio e o pH foram mensurados às 3h, 24h, 72h e 15 dias. Para o teste biológico, SAOS-2 foram cultivadas, expostas aos extratos de cimentos e a proliferação celular foi investigada pelo ensaio de MTT às 6h, 24h e 48h. Tubos de polietileno contendo cimentos foram implantados em ratos Wistar. Após 7 e 30 dias, os tubos foram removidos e processados para análises histológicas. Dados paramétricos e não paramétricos foram realizados. Nenhuma diferença foi identificada em relação ao tempo de presa, radiopacidade e solubilidade. Biodentine liberou mais íons de cálcio do que MTA e CERD; no entanto, nenhuma diferença entre MTA e CERD foi detectada. O pH alcalino foi observado para todos os cimentos e o Biodentine exibiu o pH mais alto. Todos os cimentos promoveram aumento na proliferação celular às 24h e 48h, exceto o CERD às 48h. Biodentine estimulou o metabolismo celular em relação ao MTA e CERD, enquanto CERD foi mais citotóxico do que MTA em 48h. Além disso, nenhuma diferença foi encontrada na resposta inflamatória e na capacidade de mineralização para todos os cimentos. CERD demonstrou propriedades semelhantes a outros cimentos endodônticos disponíveis.

Effect of nonsteroidal anti-inflammatory drugs (NSAIDs) association on physicochemical and biological properties of tricalcium silicate-based cement.

The aim of this study was to investigate the physicochemical and biological properties of an experimental tricalcium silicate-based repair cement containing diclofenac sodium (CERD). For the physicochemical test, MTA, Biodentine and CERD were mixed and cement disc were prepared to evaluate the setting time and radiopacity. Root-end cavity were performed in acrylic teeth and filled with cements to analyze the solubility up to 7 days. Polyethylene tubes containing cements were prepared and calcium ions and pH were measured at 3h, 24h, 72h and 15 days. For the biological test, SAOS-2 were cultivated, exposed to cements extracts and cell proliferation were investigated by MTT assay at 6h, 24h and 48h. Polyethylene tubes containing cements were implanted into Wistar rats. After 7 and 30 days, the tubes were removed and processed for histological analyses. Parametric and nonparametric data were performed. No difference was identified in relation to setting time, radiopacity and solubility. Biodentine released more calcium ion than MTA and CERD; however, no difference between MTA and CERD were detected. Alkaline pH was observed for all cements and Biodentine exhibited highest pH. All cements promoted a raise on cell proliferation at 24h and 48h, except CERD at 48h. Biodentine stimulated cell metabolism in relation to MTA and CERD while CERD was more cytotoxic than MTA at 48h. Besides, no difference on both inflammatory response and mineralization ability for all cement were found. CERD demonstrated similar proprieties to others endodontic cements available.