a Department of Pharmaceutical Technology and Biopharmaceutics , University of Bonn , Bonn , Germany.
b Product Manager Special Salts , Jungbunzlauer Ladenburg GmbH , Ladenburg , Germany.
Drug Dev Ind Pharm. 2018 Oct;44(10):1631-1641. doi: 10.1080/03639045.2018.1483389. Epub 2018 Jul 4.
Tricalcium citrate (TCC) was characterized as a tableting excipient for direct compression (DC) and dry granulation (DG).
Brittle materials usually lead to tablets of inferior mechanical strength compared to plastic deforming materials. A brittle material exhibiting a high tabletability with the ability to retain that behavior during recompression would represent a valuable alternative to the commonly used microcrystalline cellulose.
Tablets of TCC and other common fillers were directly compressed for the purpose of compression analysis including Heckel analysis, speed dependency, and lubricant sensitivity. DG by roller compaction of TCC was first simulated via briquetting and experiments were subsequently repeated on a roller compactor.
TCC appears as an excellent flowing powder of large agglomerates consisting of lower micron to submicron platelets. Despite the brittle deformation mechanism identified in the Heckel analysis, TCC demonstrated a very high mechanical strength up to 11 MPa in conjunction with an astonishingly low solid fraction of 0.85 at a compression pressure of 400 MPa. This was seen along with hardly any speed and lubricant sensitivity. Nevertheless, disintegration time was very short. TCC tablets suffered only a little from the re-compression: a slight loss in tensile strength of 1-2 MPa was observed for granules produced via roller compaction.
TCC was found to be suitable for DC as a predominantly brittle deforming filler, nevertheless demonstrating an enormous hardness yield while being independent of lubrication and tableting speed. TCC furthermore retained enough bonding capacity after DG to maintain this pronounced tabletability.
柠檬酸三钙(TCC)被特性化为直接压缩(DC)和干法造粒(DG)的片剂赋形剂。
脆性材料通常会导致片剂的机械强度比塑性变形材料差。具有高可压性并在重新压缩过程中保持这种行为的脆性材料将成为常用微晶纤维素的有价值替代品。
TCC 及其它常见填充剂的片剂直接压缩,目的是进行压缩分析,包括 Heckel 分析、速度依赖性和润滑剂敏感性。通过滚压将 TCC 进行 DG 首先通过压块进行模拟,然后在滚压机上重复进行实验。
TCC 表现为一种极好的大团聚体流动粉末,由较小的微米到亚微米薄片组成。尽管在 Heckel 分析中确定了脆性变形机制,但 TCC 表现出非常高的机械强度,高达 11MPa,同时在 400MPa 的压缩压力下,惊人的低固体分数为 0.85。这与几乎没有速度和润滑剂敏感性有关。然而,崩解时间非常短。TCC 片剂在重新压缩时仅受到轻微影响:通过滚压制成的颗粒的拉伸强度略有损失 1-2MPa。
TCC 被发现适合作为主要为脆性变形的填充剂用于 DC,尽管在不依赖于润滑和压片速度的情况下表现出巨大的硬度屈服。TCC 在后 DG 中仍保持足够的结合能力,以维持这种明显的可压性。
