Material-Sparing Approach to Predict Tablet Capping Under Processing Compression Conditions Based on Mechanical and Molecular Properties Derived from Compaction Simulation and Crystal Structural Analysis

IF 3.4 4区 医学 Q2 PHARMACOLOGY & PHARMACY
Pratap Basim, Harsh S. Shah, Robert Sedlock, Bhavin V. Parekh, Rutesh H. Dave
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Abstract

Present study evaluates the usability of compaction simulation-based mechanical models as a material-sparing approach to predict tablet capping under processing compression conditions using Acetaminophen (APAP) and Ibuprofen (IBU). Measured mechanical properties were evaluated using principal component analysis (PCA) and principal component regression (PCR) models. PCR models were then utilized to predict the capping score (CS) from compression pressure (CP). APAP formulations displayed a quadratic correlation between CS and CP, with CS rank order following CP of 200MPa < 300MPa < 100MPa, indicating threshold compression pressure (TCP) limit between 200 and 300 MPa, resulting in higher CS at 300 than 200 MPa regardless of increased CP. IBU formulations displayed a linear correlation between CS and CP, with CS rank order following CP of 100MPa < 200MPa < 300MPa, indicating TCP limit between 100 and 200 MPa, resulting in higher CS at 200 and 300 than 100 MPa regardless of increased CP. Molecular models were developed as validation methods to predict capping from CP. Measured XRPD patterns of compressed tablets were linked with calculated Eatt and d-spacing of slip planes and analyzed using variable component least square methods to predict TCP triggering cleavage in slip planes and leading to capping. In APAP and IBU, TCP values were predicted at 245 and 175 MPa, meaning capped tablets above these TCP limits regardless of increased CP. A similar trend was observed in CS predictions from mechanical assessment, confirming that compaction simulation-based mechanical models can predict capping risk under desired compression conditions rapidly and accurately.

Graphical Abstract

Abstract Image

基于压实模拟和晶体结构分析得出的机械和分子特性的材料比较法,用于预测加工压缩条件下的片剂封盖。
本研究评估了以压实模拟为基础的机械模型的可用性,该模型是一种节省材料的方法,可用于预测使用对乙酰氨基酚(APAP)和布洛芬(IBU)的片剂在加工压缩条件下的压盖情况。使用主成分分析 (PCA) 和主成分回归 (PCR) 模型对测量的机械性能进行评估。然后利用 PCR 模型从压缩压力 (CP) 预测封盖得分 (CS)。APAP 配方显示出 CS 与 CP 之间的二次相关性,CS 在 CP 值为 200MPa < 300MPa < 100MPa 时排序,表明阈值压缩压力(TCP)限制在 200 和 300 MPa 之间,因此无论 CP 值是否增加,300 MPa 时的 CS 值均高于 200 MPa。IBU 配方的 CS 值与 CP 值呈线性相关,CS 值的排名顺序为 CP 值 100MPa < 200MPa < 300MPa,表明阈值压缩压力(TCP)极限在 100 和 200 MPa 之间,因此无论 CP 值如何增加,200 和 300 MPa 时的 CS 值均高于 100 MPa。开发了分子模型作为验证方法来预测 CP 的封盖。将测量到的压缩片剂 XRPD 图样与计算出的滑移面 Eatt 和 d 间距联系起来,并使用变分最小二乘法进行分析,以预测 TCP 触发滑移面裂解并导致封盖。在 APAP 和 IBU 中,预测的 TCP 值分别为 245 和 175 MPa,这意味着无论 CP 是否增加,封盖片剂都会超过这些 TCP 限制。机械评估的 CS 预测值也呈现出类似的趋势,这证实了基于压实模拟的机械模型可以快速准确地预测理想压缩条件下的压盖风险。
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来源期刊
AAPS PharmSciTech
AAPS PharmSciTech 医学-药学
CiteScore
6.80
自引率
3.00%
发文量
264
审稿时长
2.4 months
期刊介绍: AAPS PharmSciTech is a peer-reviewed, online-only journal committed to serving those pharmaceutical scientists and engineers interested in the research, development, and evaluation of pharmaceutical dosage forms and delivery systems, including drugs derived from biotechnology and the manufacturing science pertaining to the commercialization of such dosage forms. Because of its electronic nature, AAPS PharmSciTech aspires to utilize evolving electronic technology to enable faster and diverse mechanisms of information delivery to its readership. Submission of uninvited expert reviews and research articles are welcomed.
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