Bioactivity and Physicochemical Properties of Three Calcium Silicate-Based Cements: An In Vitro Study

Abstract EN

Objective.

This study evaluated the bioactivity and physicochemical properties of three commercial calcium silicate-based endodontic materials (MTA, EndoSequence Root Repair Material putty, and Biodentine™).

Material and Methods.

Horizontal sections of 3 mm thickness from 18 root canals of human teeth were subjected to biomechanical preparation with WaveOne Gold large rotary instruments.

The twelve specimens were filled with three tested materials (MM-MTA, EndoSequence Root Repair Material putty, and Biodentine™) and immersed in phosphate-buffered saline for 7 and 30 days.

After this period of time, each specimen of each material was processed for morphological observation, surface precipitates, and interfacial dentin using SEM.

In addition, the surface morphology of the set materials, without soaking in phosphate-buffered solution after one day and after 28 days stored in phosphate-buffered saline, was evaluated using SEM; also, the pH of the soaking water and the amount of calcium ions released from the test materials were measured by using an inductively coupled plasma-optical emission spectroscopy test.

Data obtained were analyzed using one-way analysis of variance and Tukey’s honest significant difference test with a significance level of 5%.

Result.

The formation of precipitates was observed on the surfaces of all materials at 1 week and increased substantially over time.

Interfacial layers in some areas of the dentin-cement interface were found from one week of immersion.

All the analyzed materials showed alkaline pH and capacity to release calcium ions; however, the concentrations of released calcium ions were significantly more in Biodentine and ESRRM putty than MM-MTA (P<0.05).

ESRRM putty maintained a pH of around 11 after 28 days.

Conclusion.

Compared with MM-MTA, Biodentine and ESRRM putty showed significantly more calcium ion release.

However, exposure of three tested cements to phosphate-buffered solution resulted in precipitation of apatite crystalline structures over both cement and dentin that increased over time.

This suggests that the tested materials are bioactive.