Department of Pharmaceutics, National Institute of Pharmaceutical Education and Research (NIPER), Sector-67, S. A. S Nagar, Mohali, Punjab, India.
AAPS PharmSciTech. 2013 Sep;14(3):1169-77. doi: 10.1208/s12249-013-0008-4. Epub 2013 Jul 30.
The present study investigates the effect of particle size on compaction behavior of forms I and II of ranitidine hydrochloride. Compaction studies were performed using three particle size ranges [450-600 (A), 300-400 (B), and 150-180 (C) μm] of both the forms, using a fully instrumented rotary tableting machine. Compaction data were analyzed for out-of-die compressibility, tabletability, and compactibility profiles and in-die Heckel and Kawakita analysis. Tabletability of the studied size fractions followed the order; IB > IA > > IIC > IIB > IIA at all the compaction pressures. In both the polymorphs, decrease in particle size improved the tabletability. Form I showed greater tabletability over form II at a given compaction pressure and sized fraction. Compressibility plot and Heckel and Kawakita analysis revealed greater compressibility and deformation behavior of form II over form I at a given compaction pressure and sized fraction. Decrease in particle size increased the compressibility and plastic deformation of both the forms. For a given polymorph, improved tabletability of smaller sized particles was attributed to their increased compressibility. However, IA and IB, despite poor compressibility and deformation, showed increased tabletability over IIA, IIB, and IIC by virtue of their greater compactibility. Microtensile testing also revealed higher nominal fracture strength of form I particles over form II, thus, supporting greater compactibility of form I. Taken as a whole, though particle size exhibited a trend on tabletability of individual forms, better compactibility of form I over form II has an overwhelming impact on tabletability.
本研究考察了粒径对盐酸雷尼替丁晶型 I 和 II 压缩行为的影响。使用三种粒径范围[450-600(A)、300-400(B)和 150-180(C)μm]的两种形式,使用全仪器化旋转压片机进行了压缩研究。对离模可压缩性、可压性和可压缩性曲线以及模内 Heckel 和 Kawakita 分析进行了压缩数据的分析。在所有压缩压力下,研究的粒径分数的可压性顺序为:IB>IA>>IIC>IIB>IIA。在两种多晶型物中,粒径减小提高了可压性。在给定的压缩压力和粒径分数下,晶型 I 的可压性优于晶型 II。压缩性图和 Heckel 和 Kawakita 分析表明,在给定的压缩压力和粒径分数下,晶型 II 的可压缩性和变形行为大于晶型 I。粒径减小增加了两种形式的可压缩性和塑性变形。对于给定的多晶型物,较小粒径的可压性提高归因于其可压缩性增加。然而,IA 和 IB 尽管可压缩性和变形性差,但由于其较高的可压缩性,显示出比 IIA、IIB 和 IIC 更高的可压性。微拉伸测试还表明,晶型 I 颗粒的名义断裂强度高于晶型 II,因此,晶型 I 的可压缩性更高。总的来说,尽管粒径对各形式的可压性表现出一种趋势,但晶型 I 优于晶型 II 的更好可压缩性对可压性有压倒性的影响。