In silico prediction of pharmaceutical degradation pathways: a benchmarking study.

Zeneth is a new software application capable of predicting degradation products derived from small molecule active pharmaceutical ingredients. This study was aimed at understanding the current status of Zeneth's predictive capabilities and assessing gaps in predictivity. Using data from 27 small molecule drug substances from five pharmaceutical companies, the evolution of Zeneth predictions through knowledge base development since 2009 was evaluated. The experimentally observed degradation products from forced degradation, accelerated, and long-term stability studies were compared to Zeneth predictions. Steady progress in predictive performance was observed as the knowledge bases grew and were refined. Over the course of the development covered within this evaluation, the ability of Zeneth to predict experimentally observed degradants increased from 31% to 54%. In particular, gaps in predictivity were noted in the areas of epimerizations, N-dealkylation of N-alkylheteroaromatic compounds, photochemical decarboxylations, and electrocyclic reactions. The results of this study show that knowledge base development efforts have increased the ability of Zeneth to predict relevant degradation products and aid pharmaceutical research. This study has also provided valuable information to help guide further improvements to Zeneth and its knowledge base.

The role of degradant profiling in active pharmaceutical ingredients and drug products.

Forced degradation studies are used to facilitate the development of analytical methodology, to gain a better understanding of active pharmaceutical ingredient (API) and drug product (DP) stability, and to provide information about degradation pathways and degradation products. In order to fulfill development and regulatory needs, this publication provides a roadmap for when and how to perform studies, helpful tools in designing rugged scientific studies, and guidance on how to record and communicate results.

Pharmaceutical impurity identification: a case study using a multidisciplinary approach.

A multidisciplinary team approach to identify pharmaceutical impurities is presented in this article. It includes a representative example of the methodology. The first step is to analyze the sample by LC-MS. If the structure of the unknown impurity cannot be conclusively determined by LC-MS, LC-NMR is employed. If the sample is unsuitable for LC-NMR, the impurity needs to be isolated for conventional NMR characterization. Although the technique of choice for isolation is preparative HPLC, enrichment is often necessary to improve preparative efficiency. One such technique is solid-phase extraction. For complete verification, synthesis may be necessary to compare spectroscopic characteristics to those observed in the original sample. Although not widely practiced, an effective means of getting valuable structural information is to conduct a degradation study on the purified impurity itself. This systematic strategy was successfully applied to the identification of an impurity in the active pharmaceutical ingredient 1-(1,2,3,5,6,7-hexahydro-s-indacen-4-yl)-3-[4-(1-hydroxy-1-methyl-ethyl)-furan-2-sulphonylurea. Identification required the use of all of the previously mentioned techniques. The instability of the impurity under acidic chromatographic conditions presented an additional challenge to purification and identification. However, we turned this acidic instability to an advantage, conducting a degradation study of the impurity, which provided extensive and useful information about its structure. The following discussion describes how the information gained from each analytical technique was brought together in a complementary fashion to elucidate a final structure.

Identification of low-level degradants from low dose tablets.

A multifaceted approach was successfully used to identify three of four unknown degradants in degraded low dose tablets. Accelerated solvent extraction (ASE) was found to be an invaluable tool in this multifaceted approach. ASE was capable of extracting four individual degradants of an active pharmaceutical component from 10 tablets into 15 mL of solvent with approximately 100% recovery for each degradant. Using ASE instead of manual extraction led to the extraction and isolation of the degradants in 1 day instead of 7 days. One of the degradants was extracted by ASE, isolated by semi-prep HPLC, and identified by LC-MS and NMR spectroscopy. The structures of two of the remaining three degradants were confirmed by synthesis of authentic samples, while the fourth degradant is yet to be identified.

A critical assessment of the ICH guideline on photostability testing of new drug substances and products (Q1B): Recommendation for revision.

The ICH guideline on photostability (ICH Topic Q1B) was published in November 1996 and has been implemented in all three regions (US, EU, and Japan). The guideline describes a useful basic protocol for testing of new drug substances and associated drug products for manufacturing, storage, and distribution, but it does not cover the photostability of drugs under conditions of patient use. The pharmaceutical industry now has considerable experience in designing and carrying out photostability studies within the context of this guideline, and issues have been identified that would benefit from the revision process. The purpose of this commentary is to accomplish the following: (i) highlight issues proposed for consideration in the ICH revision process, (ii) offer a rationale for why these issues may compromise the design of a testing protocol and/or the results of the testing program, and (iii) provide recommendations for clarification of the guideline.

Stabilization of pharmaceuticals to oxidative degradation.

A guide for stabilization of pharmaceuticals to oxidation is presented. Literature is presented with an attempt to be a ready source for data and recommendations for formulators. Liquid and solid dosage forms are discussed with options including formulation changes, additives, and packaging documented. In particular, selection of and methods for use of antioxidants are discussed including recommended levels.

Hydrolysis in pharmaceutical formulations.

This literature review presents hydrolysis of active pharmaceutical ingredients as well as the effects on dosage form stability due to hydrolysis of excipients. Mechanisms and measurement methods are discussed and recommendations for formulation stabilization are listed.