Near infrared (NIR)-spectroscopy and in-vitro dissolution absorption system 2 (IDAS2) can help detect changes in the quality of generic drugs.

While Health authorities in Panama strive to increase generic drug use to contain the rising costs of medicines, there is still hesitation to embrace generic drugs. Thus, regulators and drug companies need to ensure the quality, safety and efficacy of generic drugs. One prevailing concern is the absence of control over lot-to-lot changes, which may impact consistent therapeutic performance. The objective of this work was to determine whether near-infrared spectroscopy (NIR) could detect product changes. Calibration models were built using reference (standard) tablets of two products: Virax® (200 mg acyclovir) and Amlopin® (5 mg amlodipine). Then, to assess the sensitivity of NIR to product changes we compared reference versus deliberately-modified formulations of these products. Comparisons were made using principal component analysis (PCA) and partial least squares-discriminant analysis (PLS-DA) of NIR spectra. Several modified lots were different from reference lots, and 3D score plots showed greater discrimination by PLS-DA than PCA. The Kth nearest neighbor scores (KNN) of the modified batches were used to classify formulations as identical or not identical versus the reference. In addition, the differences detected by NIR were correlated with different in vitro dissolution and/or permeation in the in vitro dissolution absorption system 2 (IDAS2): NIR and IDAS2 yielded the same rank-order of difference for the modified lots tested. This study suggests that NIR and IDAS2 can help detect lots of generic drugs that differ from the reference lots. This strategy may help regulatory agencies in developing countries to safeguard patients against lot-to-lot changes in generic products.

A differential equation based modelling approach to predict supersaturation and in vivo absorption from in vitro dissolution-absorption system (idas2) data.

In vitro dissolution tests are widely used to monitor the quality and consistency of oral solid dosage forms, but to increase the physiological relevance of in vitro dissolution tests, newer systems combine dissolution and permeation measurements. Some of these use artificial membranes while others (e.g., in the in vitro dissolution absorption system 2; IDAS2), utilize cell monolayers to assess drug permeation. We determined the effect of the precipitation inhibitor Hypromellose Acetate Succinate (HPMCAS) on the supersaturation/permeation of Ketoconazole and Dipyridamole in IDAS2 and its effect on their absorption in rats. Thus the main objectives of this study were to determine: (1) whether dissolution and permeation data from IDAS2 could be used to predict rat plasma concentration using an absorption model and (2) whether the effect of the precipitation inhibitor HPMCAS on supersaturation and permeation in IDAS2 was correlated with its effect on systemic absorption in the rat. Predicted drug concentrations in rat plasma, generated using parameters estimated from IDAS2 dissolution/permeation data and a mathematical absorption model, showed good agreement with measured concentrations. While in IDAS2, the prolongation of Ketoconazole's supersaturation caused by HPMCAS led to higher permeation, which paralleled the higher systemic absorption in rats, Dipyridamole showed no supersaturation and, thus, no effect of HPMCAS in dissolution or permeation in IDAS2 and no effect on Dipyridamole absorption in rats. The ability of IDAS2 to detect supersaturation following a pH-shift supports the potential value of this system for studying approaches to enhance intestinal absorption through supersaturation and the accuracy of plasma concentration predictions in rats suggest the possibility of combining IDAS2 with absorption models to predict plasma concentration in different species.

In vitro dissolution absorption system (IDAS2): Use for the prediction of food viscosity effects on drug dissolution and absorption from oral solid dosage forms.

Existing in vitro dissolution or permeation models to predict food effect are mainly based on Pharmacopeias' compendial media, which specify such variables as pH, bile salts, lipolytic enzymes, and phospholipids content. However, the viscosity of food in the gastrointestinal (GI) tract is not taken into account, although it can affect both the dissolution of the oral solid dosage form and absorption of the released drug. Here, a new in vitro dissolution absorption system (IDAS2) is utilized, which comprises a dissolution apparatus USP2 (DISTEK) equipped with specially constructed permeability chambers containing Caco-2 monolayers, thereby allowing dissolution and transepithelial absorption to be ascertained simultaneously. The IDAS2 was used to evaluate the effect of medium viscosity on both the dissolution of oral solid dosage forms and absorption of released drugs. Such information, which is not ordinarily determined in dissolution and permeation studies, will be helpful to the formulators developing robust oral dosage forms. Commercially available solid dosage forms of ten model drugs from across all BCS classifications were used in this evaluation: metoprolol, minoxidil, and propranolol from BCS class 1; carbamazepine, ketoprofen, and simvastatin from BCS class 2; atenolol and ranitidine from BCS class 3; and acetazolamide and saquinavir from BCS class 4. The study revealed the applicability of IDAS2 as a tool for in vitro screening of dissolution and absorption of intact oral solid products to predict food viscosity effect. The most profound viscosity effect on dissolution and absorption was observed of solid dosage forms for the BCS class 2 compounds carbamazepine and simvastatin. A higher medium viscosity significantly slowed down the dissolution rate of tested BSC class 4 compounds acetazolamide and saquinavir, without significant effect on their absorption. The solid dosage forms least affected by the viscosity of the medium tested were the BCS class 1 compounds minoxidil and propranolol.