Exploring a new Portland cement-free calcium silicate cement -Part 1: Synthesis of dicalcium and tricalcium silicate.

IF 1.9 4区医学 Q2 DENTISTRY, ORAL SURGERY & MEDICINE

Dental materials journal Pub Date : 2025-03-01 DOI:10.4012/dmj.2024-238

Tomomi Itoh, Kohei Shintani, Takashi Horiguchi, Norihiro Sasamoto, Katsushi Okuyama, Yukimichi Tamaki, Takeshi Suwabe, Satoshi Yokose, Satoshi Kawano

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Abstract

Mineral trioxide aggregate cement is an excellent pulp-capping material; however, its base Portland cement contains highly toxic elements and is expensive. This study aimed to explore the possibility of using calcium silicate cement without Portland cement. Synthesis was attempted via firing using calcium silicate (CS), as the base material, and calcium oxide (CA). According to the chemical reaction, they were weighed and sintered in an electric furnace at a sintering temperature of 1,300ºC based on the results of thermogravimetric differential thermal analysis. The powder composition after firing was examined by X-ray diffraction analyses. Compressive tests were performed using a universal testing machine. The sintered powders were confirmed as dicalcium silicate (CS2) and tricalcium silicate (CS3); however, some peaks were detected and their compressive strengths were lower than that of CS. These results suggest that CS2 and CS3 were successfully synthesized from a mixture of CA and CS.

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三氧化二铝矿物骨料水泥是一种极佳的纸浆封盖材料，但其基材硅酸盐水泥含有剧毒元素且价格昂贵。本研究旨在探索在不使用硅酸盐水泥的情况下使用硅酸钙水泥的可能性。尝试使用硅酸钙（CS）和氧化钙（CA）作为基材，通过烧制合成。根据热重微分热分析的结果，按照化学反应将它们称重并在烧结温度为 1,300ºC 的电炉中烧结。烧结后的粉末成分通过 X 射线衍射分析进行检验。使用万能试验机进行了压缩试验。烧结后的粉末被确认为硅酸二钙（CS2）和硅酸三钙（CS3）；然而，检测到了一些峰值，它们的抗压强度低于 CS。这些结果表明，CS2 和 CS3 是由 CA 和 CS 的混合物成功合成的。

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来源期刊

Dental materials journal 医学-材料科学：生物材料

CiteScore

4.60

自引率

4.00%

发文量

102

审稿时长

3 months

期刊介绍： Dental Materials Journal is a peer review journal published by the Japanese Society for Dental Materials and Devises aiming to introduce the progress of the basic and applied sciences in dental materials and biomaterials. The dental materials-related clinical science and instrumental technologies are also within the scope of this journal. The materials dealt include synthetic polymers, ceramics, metals and tissue-derived biomaterials. Forefront dental materials and biomaterials used in developing filed, such as tissue engineering, bioengineering and artificial intelligence, are positively considered for the review as well. Recent acceptance rate of the submitted manuscript in the journal is around 30%.