abstract

• Objective. This study sought to evaluate the biocompatibility of Neomineral Trioxide Aggregate (Neo-MTA), MTA Repair High Plasticity (MTA-HP), and Mineral Trioxide Aggregate-Angelus white (MTA-Ang) in fibroblasts of human dental pulp. Materials and Methods. Morphology was evaluated after 24 h of incubation. LIVE/DEAD assay and cell adhesion tests were performed at 24 h of treatment. Cell proliferation assays (MTSs) and Annexin V were performed at 48 h incubation with different treatments. The expression of Col-1 and TGF-β1 was tested by endpoint PCR at 5 days of treatment. Results. Morphological changes were observed in all groups. Neo-MTA and MTA-Ang were associated with increased cell viability, and all materials induced apoptosis, with a higher percentage in the MTA-HP group than in the other groups. In the LIVE/DEAD assay, there was more damage to the cell membrane in the group of cells treated with MTA-HP than in the other groups. Conclusion. Neo-MTA and MTA-Ang presented similar biocompatibility, and both showed greater biocompatibility than MTA-HP. MTA-HP and MTA-Ang increased Col-1A gene expression, and Neo-MTA and MTA-Ang increased TGF-β1 gene expression in a similar way. © 2022 Diana María Escobar-García et al.

authors

• Escobar-García D.M.
• Flores Reyes Héctor Eduardo
• González Amaro Ana María Guadalupe
• Méndez González María Verónica
• Pozos Guillén Amaury de Jesús

publication date

• 2022-01-01

published in

• BioMed Research International  Journal

keywords

• cement; collagen type 1; lipocortin 5; mineral trioxide aggregate angelus white; neomineral trioxide aggregate; transforming growth factor beta1; unclassified drug; aluminum derivative; calcium derivative; collagen type 1; mineral trioxide aggregate; oxide; pemetrexed; root canal filling material; silicate; apoptosis; Article; biocompatibility; cell adhesion; cell membrane; cell proliferation assay; cell viability; controlled study; fibroblast; fluorescence; gene amplification; gene expression; human; human cell; human tissue; polymerase chain reaction; scanning electron microscopy; tooth pulp; drug combination; gene expression; genetics; materials testing; Aluminum Compounds; Calcium Compounds; Collagen Type I; Drug Combinations; Gene Expression; Humans; Materials Testing; Oxides; Pemetrexed; Root Canal Filling Materials; Silicates; Transforming Growth Factor beta1

Digital Object Identifier (DOI)

• 10.1155/2022/2204698

PubMed ID

• 35402617

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volume

• 2022

issue