Jordan University of Science and Technology-Faculty of Pharmacy, PO. Box 3030, Irbid, 22110, Jordan.
Jerash University-Faculty of Pharmacy, Department of Pharmaceutical Sciences, Jerash, Jordan.
AAPS PharmSciTech. 2024 Oct 7;25(7):235. doi: 10.1208/s12249-024-02933-4.
The objective of this study was to examine the impact of the physicochemical properties of the loaded drug or excipient, the concentration of Kollidon®SR (KSR), and the mechanical characteristics of KSR compacts on their disintegration times. Using disintegration apparatus, a two-hour constraint was chosen as the process's end point. Lactose-KSR compacts subjected to the highest compression pressure and Microcrystalline cellulose-KSR compacts with KSR concentrations exceeding 30% exhibited disintegration times of less than ten minutes. Likewise, compacts containing Diltiazem HCl-KSR demonstrated brief disintegration times across all tested KSR concentrations and compression pressures. Compacts of Modafinil, Metformin HCl, and Ascorbic acid-KSR displayed disintegration times ranging from fast to moderate, contingent upon the levels of KSR and compression pressure applied. Compacts containing KSR with Aspirin, Salicylic acid, or Ibuprofen did not exhibit significant disintegration even at minimal amounts of KSR (0.5%). Theophylline-KSR tablets also showed prolonged dissolution times, even at very low concentrations of KSR. The disintegration times of Dic-KSR tablets were roughly close to an hour and were predominantly unaffected by varying KSR levels and only marginally influenced by compression pressures. It is possible to draw the conclusion that different drugs or excipients have different minimum KSR requirements to resist compacts' disintegration process. Compounds that demonstrate low solubility in water can result in extended disintegration times for KSR compacts. The melting points of these compounds, in conjunction with the Py values of the compacts and their compaction properties, could affect the disintegration process, although a precise evaluation is necessary.
本研究旨在考察载药或赋形剂的理化性质、Kollidon®SR(KSR)浓度以及 KSR 压块的机械特性对其崩解时间的影响。采用崩解仪,选择两小时作为过程的终点。在最高压缩压力下的乳糖-KSR 压块和 KSR 浓度超过 30%的微晶纤维素-KSR 压块的崩解时间不到十分钟。同样,含有地尔硫卓 HCl-KSR 的压块在所有测试的 KSR 浓度和压缩压力下都表现出短暂的崩解时间。载有莫达非尼、盐酸二甲双胍和抗坏血酸-KSR 的压块的崩解时间从快速到中等,这取决于应用的 KSR 和压缩压力水平。含有 KSR 的阿司匹林、水杨酸或布洛芬的压块即使在最小量的 KSR(0.5%)下也没有表现出明显的崩解。含 KSR 的茶碱片剂即使在非常低的 KSR 浓度下也显示出延长的溶解时间。 Dic-KSR 片剂的崩解时间大约接近一个小时,并且不受 KSR 水平变化的影响,仅受压缩压力的轻微影响。可以得出结论,不同的药物或赋形剂具有不同的最小 KSR 要求来抵抗压块的崩解过程。在水中溶解度低的化合物可能导致 KSR 压块的崩解时间延长。这些化合物的熔点,以及压块的 Py 值及其压实特性,可能会影响崩解过程,尽管需要进行精确的评估。
