Systemic effect of mineral aggregate-based cements: histopathological analysis in rats

Abstract Objective: Several studies reported the local tissue reaction caused by mineral aggregate-based cements. However, few studies have investigated the systemic effects promoted by these cements on liver and kidney when directly applied to connective tissue. The purpose of this in vivo study was to investigate the systemic effect of mineral aggregate-based cements on the livers and kidneys of rats. Material and Methods: Samples of Mineral Trioxide Aggregate (MTA) and a calcium aluminate-based cement (EndoBinder) containing different radiopacifiers were implanted into the dorsum of 40 rats. After 7 and 30 d, samples of subcutaneous, liver and kidney tissues were submitted to histopathological analysis. A score (0-3) was used to grade the inflammatory reaction. Blood samples were collected to evaluate changes in hepatic and renal functions of animals. Results: The moderate inflammatory reaction (2) observed for 7 d in the subcutaneous tissue decreased with time for all cements. The thickness of inflammatory capsules also presented a significant decrease with time (P<.05). Systemically, all cements caused adverse inflammatory reactions in the liver and kidney, being more evident for MTA, persisting until the end of the analysis. Liver functions increased significantly for MTA during 30 d (P<.05). Conclusion: The different cements induced to a locally limited inflammatory reaction. However, from the systemic point of view, the cements promoted significant inflammatory reactions in the liver and kidney. For MTA, the reactions were more accentuated.

Red LED Photobiomodulates the Metabolic Activity of Odontoblast-Like Cells

Abstract Phototherapy has been indicated as an adjunctive treatment for tissue repair, including the pulp tissue. However, there are no defined irradiation parameters, which is a great challenge to the clinical use of phototherapy. The aim of this study was to evaluate the effect of phototherapy with red LED on odontoblast-like MDPC-23 cells, using different parameter settings. Cells were seeded (104 cells/cm²), incubated for 12 h in complete DMEM and then the culture medium was replaced by DMEM supplemented with 0.5% FBS. After 12 h incubation, irradiations were performed (630±10 nm) using a LEDTable device with a 20 or 40 mW/cm² power density and 2 J/cm² energy dose. The cells were irradiated 1 or 3 times, at 1 min intervals. Non-irradiated cells served as control. The cells were evaluated for viability (MTT assay), total protein dosage (Lowry method) and number of viable cells (Trypan blue). The data (n=12 per group) were submitted to Kruskal-Wallis and Mann-Whitney tests (p=0.05). A single irradiation with 20 or 40 mW/cm² enhanced cell viability, which was negatively affected after 3 consecutive irradiations. Cells irradiated only once with 20 mW/cm² produced more proteins compared with those irradiated with 40 mW/cm². Reduction in the number of viable cells occurred only after 3 consecutive irradiations with 40 mW/cm². In conclusion, red LED was capable of biomodulating the metabolic activities of cultured MDPC-23 odontoblast-like cells. The best cell biostimulation was obtained when a single irradiation with 2 J/cm2 energy dose and 20 mW/cm2 power density was delivered to the pulp cells.

Resumo Fototerapia tem sido indicada como um tratamento adjuvante para o reparo de tecidos, incluindo o tecido pulpar. Entretanto, não há parâmetros de irradiação definidos, o que representa um grande desafio para o uso clínico da fototerapia. O objetivo deste estudo foi avaliar o efeito da fototerapia com LED vermelho em células MDPC-23 com fenótipo odontoblastóide, usando vários parâmetros. As células foram semeadas (104 células/cm2), incubadas por 12 h em DMEM completo e então o meio de cultura foi trocado por DMEM com 0,5% SFB. Após 12 h de incubação, as irradiações foram realizadas (630±10 nm) usando um dispositivo com densidade de potência de 20 ou 40 mW/cm2 e dose de energia de 2 J/cm2. As células foram irradiadas 1 ou 3 vezes, com intervalos de 1 min. Células não irradiadas serviram como controle. Foram avaliadas a viabilidade (ensaio de MTT), dosagem de proteína total (método de Lowry) e número de células viáveis (ensaio de Trypan blue). Os dados (n=12 por grupo) foram submetidos aos testes de Kruskal-Wallis e Mann-Whitney (p=0,05). Uma única irradiação com 20 ou 40 mW/cm2 aumentou a viabilidade celular, a qual foi negativamente afetada após 3 irradiações. Células irradiadas apenas uma vez com 20 mW/cm2 produziram mais proteínas comparadas com aquelas irradiadas com 40 mW/cm2. Redução no número de células viáveis ocorreu apenas após 3 irradiações com 40 mw/cm2. Em conclusão, o LED vermelho foi capaz de biomodular a atividade metabólica de células MDPC-23. A melhor bioestimulação celular foi obtida quando uma única irradiação com dose de energia de 2 J/cm2 e densidade de potência de 20 mW/cm2 foi administrada às células pulpares.

Efeito citotóxico de um novo cimento de ionômero de vidro modificado porresina aplicado sobre células odontoblastóides / Cytotoxic effects of a current resin-modified glass-ionomer cement applied onodontoblast-like cells

O objetivo deste estudo foi comparar os efeitos citotóxicos do cimento de ionômero de vidro modificadopor resina VitrebondTM e da sua nova formulação VitrebondTM Plus quando aplicados em contatocom células de linhagem odontoblástica MDPC-23...

The aim of this study was to evaluate the cytotoxic effects of the resin-modified glass-ionomer liningcement VitrebondTM and its new formulation VitrebondTM Plus when applied to an immortalized odontoblast-cell line MDPC-23...