ABSTRACT
ABSTRACT Objective Mineral Trioxide Aggregate (MTA) is a calcium silicate cement composed of Portland cement (PC) and bismuth oxide. Hydroxyapatite has been incorporated to enhance mechanical and biological properties of dental materials. This study evaluated physicochemical and mechanical properties and antibiofilm activity of MTA and PC associated with zirconium oxide (ZrO2) and hydroxyapatite nanoparticles (HAn). Material and Methods White MTA (Angelus, Brazil); PC (70%)+ZrO2 (30%); PC (60%)+ZrO2 (30%)+HAn (10%); PC (50%)+ZrO2 (30%)+HAn (20%) were evaluated. The pH was assessed by a digital pH-meter and solubility by mass loss. Setting time was evaluated by using Gilmore needles. Compressive strength was analyzed by mechanical test. Samples were radiographed alongside an aluminum step wedge to evaluate radiopacity. For the antibiofilm evaluation, materials were placed in direct contact with E. faecalis biofilm induced on dentine blocks. The number of colony-forming units (CFU mL-1) in the remaining biolfilm was evaluated. The results were submitted to ANOVA and the Tukey test, with 5% significance. Results There was no difference in pH levels of PC+ZrO2, PC+ZrO2+HAn (10%) and PC+ZrO2+HAn (20%) (p>0.05) and these cements presented higher pH levels than MTA (p<0.05). The highest solubility was observed in PC+ZrO2+HAn (10%) and PC+ZrO2+HAn (20%) (p<0.05). MTA had the shortest initial setting time (p<0.05). All the materials showed radiopacity higher than 3 mmAl. PC+ZrO2 and MTA had the highest compressive strength (p<0.05). Materials did not completely neutralize the bacterial biofilm, but the association with HAn provided greater bacterial reduction than MTA and PC+ZrO2 (p<0.05) after the post-manipulation period of 2 days. Conclusions The addition of HAn to PC associated with ZrO2 harmed the compressive strength and solubility. On the other hand, HAn did not change the pH and the initial setting time, but improved the radiopacity (HAn 10%), the final setting time and the E. faecalis antibiofilm activity of the cement.
Subject(s)
Oxides/chemistry , Zirconium/chemistry , Enterococcus faecalis/drug effects , Silicates/chemistry , Durapatite/chemistry , Calcium Compounds/chemistry , Aluminum Compounds/chemistry , Biofilms/drug effects , Nanoparticles/chemistry , Oxides/pharmacology , Solubility , Time Factors , Zirconium/pharmacology , Bismuth/pharmacology , Bismuth/chemistry , Materials Testing , Colony Count, Microbial , Analysis of Variance , Enterococcus faecalis/growth & development , Silicates/pharmacology , Durapatite/pharmacology , Calcium Compounds/pharmacology , Aluminum Compounds/pharmacology , Compressive Strength , Dental Cements/pharmacology , Dental Cements/chemistry , Drug Combinations , Hydrogen-Ion ConcentrationABSTRACT
A substituição do óxido de bismuto por óxido de zircônio (ZrO2) e a adição de nanopartículas de prata (NPsAg) pode favorecer as propriedades físico-químicas mecânicas e antimicrobianas. Capítulo 1: Foram avaliados pH, solubilidade, tempo de presa, radiopacidade e resistência à compressão. Grupos: G1 - MTA Angelus; G2 - CP/ZrO2; G3 - MTA/NPsAg; G4 -CP/ZrO2/NPsAg. O pH foi analisado em pHmetro digital, a solubilidade pela perda de massa e o tempo de presa pelo teste de Gilmore. A resistência à compressão foi avaliada em ensaio mecânico. Para análise da radiopacidade, as amostras foram radiografadas com uma escala de alumínio. Os resultados foram submetidos aos testes ANOVA e Tukey (p<0,05). O G3 apresentou aumento de pH e diminuição da solubilidade e tempo do presa inicial e final. O G4 apresentou diminuição da solubilidade e aumento da resistência à compressão. A radiopacidade dos materiais foi superior a 4 mmAl. As associações G3 e G4 apresentam propriedades físico-químicas e mecânicas adequadas. Capítulo 2: Bactérias na forma planctônica foram colocadas sobre o cimento fresco e a análise foi realizada em espectrofotômetro. Na avaliação antibiofilme, os materiais foram colocados em contato com biofilme de E. faecalis formado sobre blocos de dentina e analisados pela contagem de unidades formadoras de colônia. Os resultados foram submetidos aos testes ANOVA e Tukey (p<0,05). Na forma planctônica, melhores resultados foram encontrados no G2 e G4. Maior redução de biofilme foi apresentada pelos G3 e G4. A incorporação de NPsAg ao CP e MTA, melhora a atividade antibacteriana e antibiofilme dos materiais à base de silicato de cálcio.
The bismuth oxide replacement by zirconium oxide (ZrO2) and the addition of silver nanoparticles may improve the physicochemical, mechanic and antimicrobial properties. Chapter I: It was evaluated pH, solubility, setting time, radiopacity and compressive strength. Groups: G1-MTA Angelus; G2-PC/ZrO2; G3-MTA/NPsAg, G4-PC/ZrO2/NPsAg. The pH was measured with a digital pH meter, the solubility by the weight loss and the setting time was evaluated by Gilmore needle. Compressive strength was tested in universal testing machine. For radiopacity analysis material samples were radiographed alongside an aluminium step-wedge. The results were submitted to ANOVA and Tukey tests (p<0.05). The G3 showed a pH increase and a decrease of solubility and initial and final setting time. The G4 showed a decrease in solubility and an increase of compressive strength. All materials presented radiopacity greater than 4 mmAl. The G3 and G4 associations showed good physicochemical and mechanical properties. Chapter 2: For the first test bacterias in planktonic form were placed over fresh cement, and the analysis was performed in spectrophotometer. Also for the antibiofilm test, the samples were placed in direct contact with E. faecalis biofilm previously induced on bovine dentine and analysed by the counting of colony-forming units. The results were submitted to ANOVA and Tukey tests (p<0.05). On the planktonic form, the best results were showed by G2 and G4. The greater reduction of biofilm were showed by G3 and G4. The incorporation of NPsAg to PC and MTA improves the antibacterial and antbiofilm activity of calcium silicate cements