Evaluación in Vitro de la Biocompatibilidad de Cuatro Cementos Selladores con Osteoblastos Humanos / In vitro Evaluation of Four Sealer Cements Biocompatibility with Human Osteoblasts

RESUMEN: El correcto sellado apical es un paso importante durante el tratamiento de conductos, para esto, se utilizan puntas de gutapercha y cemento sellador, de este último existen diversas formulaciones químicas en el mercado, por lo cual es importante tomar en cuenta los efectos que estas pueden tener en el proceso de cicatrización periapical. El propósito de este estudio fue evaluar la biocompatibilidad de cuatro cementos selladores con diferente composición química con osteoblastos humanos. Se prepararon extractos de cementos selladores a con dos concentraciones (10 mg/mL y 40 mg/mL) y dos tiempos de exposición (10 min y 8 h), estos fueron colocados en contacto con osteoblastos humanos para evaluar la proliferación y citotoxicidad a 24, 72 y 96 h con sus respectivos controles y blancos. Se realizó un análisis estadístico con ANOVA de un factor y la prueba de comparaciones múltiple de Bonferroni. Los resultados obtenidos, tanto en el ensayo de citotoxicidad como en el de proliferación, indicaron que el cemento a base de resina no es biocompatible con osteoblastos. El cemento a base de poli-dimetilxilosano fue el único que no mostró citotoxicidad a ningún de tiempo de exposición y concentración examinadas en este estudio.

ABSTRACT: Correct apical sealing is an important step during root canal treatment, hence, gutta-percha points and sealant are used. There are several chemical compositions on the market, so it is important to evaluate the effects of these in the periapical healing process. The aim of this study was to evaluate the biocompatibility of four sealer cements with different chemical composition placed in contact with human osteoblast. Different extracts were prepared at two concentrations (10 mg/mL and 40 mg/mL) and two exposure times (10 min and 8 h) these were placed in contact with human osteoblast to evaluate cytotoxicity and proliferation at 24, 48 and 72 h with their respective controls and blanks. A statistical analysis was performed with ANOVA of one factor and Bonferroni post hoc. Results obtained in cytotoxicity and proliferation assays, indicated that the resinbased cement is not biocompatible with osteoblast. The poly-dimethylxilosanbased cement was the only that did not show cytotoxicity at any time of exposure and concentration examined in this study.

Glucose-6-phosphate dehydrogenase deficiency in northern Mexico and description of a novel mutation.

Glucose-6-phosphate dehydrogenase deficiency (G6PD) is the most common enzyme pathology in humans; it is X-linked inherited and causes neonatal hyperbilirubinaemia, chronic nonspherocytic haemolytic anaemia and drug-induced acute haemolytic anaemia. G6PD deficiency has scarcely been studied in the northern region of Mexico, which is important because of the genetic heterogeneity described in Mexican population. Therefore, samples from the northern Mexico were biochemically screened for G6PD deficiency, and PCR-RFLPs, and DNA sequencing used to identify mutations in positive samples. The frequency of G6PD deficiency in the population was 0.95% (n = 1993); the mutations in 86% of these samples were G6PD A(-202A/376G), G6PDA(-376G/968C) and G6PD Santamaria(376G/542T). Contrary to previous reports, we demonstrated that G6PD deficiency distribution is relatively homogenous throughout the country (P = 0.48336), and the unique exception with high frequency of G6PD deficiency does not involve a coastal population (Chihuahua: 2.4%). Analysis of eight polymorphic sites showed only 10 haplotypes. In one individual we identified a new G6PD mutation named Mexico DF(193A>G) (rs199474830), which probably results in a damaging functional effect, according to PolyPhen analysis. Proteomic impact of the mutation is also described.