Tamper-proof tablets for distinction between counterfeit and originator drugs through PEG coding.

Counterfeit drugs are a major threat to public health. Current efforts focus on serialization of the secondary packaging which do not allow to trace the individual unit. As a proof of concept, we intended to mark each tablet for its unambiguous recognition. Spiking monodisperse PEGs into tablet coating solutions at concentrations as low as 3 ppm was instrumental to "write" a code into each tablet film which was readily read upon isolation and LC-MS/MS analysis. Different qualities and amounts of monodisperse polyethylene glycols can be used for coding solid drug products. The approach is limited to cases in which PEGs are not present for formulation purposes as excipients, as coding against this background was unfeasible.

Simple and rapid high performance liquid chromatography method for the determination of polidocanol as bulk product and in pharmaceutical polymer matrices using charged aerosol detection.

Currently, neither the European nor the United States Pharmacopoeia provide a method for the determination of polidocanol (PD) content despite the fact that PD, besides being an excipient, is also used as an active pharmaceutical ingredient. We therefore developed a method where the PD content was determined using a Kinetex C18 column operated at 40°C with water-acetonitrile (15:85, v/v) as mobile phase. A Corona(®) charged aerosol detector was employed for the detection of PD that is lacking a suitable UV chromophore. The method was fully validated. Additionally, the method was applied for the determination of PD release from a pharmaceutical polymer matrix consisting of poly-ɛ-caprolactone and poly(lactic-co-glycolic acid) and PD.

Fatty acid composition analysis in polysorbate 80 with high performance liquid chromatography coupled to charged aerosol detection.

The fatty acid (FA) composition of polysorbate 80 (PS80), a sorbitan oleic acid ester copolymerized with about 20mole of ethylene oxide, is typically characterized by gas chromatography. Here, an alternative method was developed. After saponification with potassium hydroxide the FA fraction was collected with liquid-liquid extraction using methyl-tert-butyl ether. HPLC in combination with a Corona® charged aerosol detector (CAD) was applied for the separation and detection. The method was fully validated in terms of specificity, repeatability, limits of quantification, linearity, range, accuracy and robustness. The characterization of 16 different PS80 batches demonstrated variability regarding their FA composition, with e.g. the amount of oleic acid ranging from 67.8±0.7% to 96.6±1.4%. Furthermore, we identified petroselinic acid, a double-bond positional isomer to oleic acid in all batches, an FA not known to pharmacopoeias at present. In addition, 11-hydroxy-9-octadecenoic acid, an oxidation product of oleic acid was identified. Structure elucidation was performed by means of HPLC-MS/MS. In addition, the method was expanded to the evaluation of the free FAs. Having determined the entire FA composition, the acid value according to EP and USP can be calculated.

Predicting critical micelle concentration and micelle molecular weight of polysorbate 80 using compendial methods.

This manuscript addresses the capability of compendial methods in controlling polysorbate 80 (PS80) functionality. Based on the analysis of sixteen batches, functionality related characteristics (FRC) including critical micelle concentration (CMC), cloud point, hydrophilic-lipophilic balance (HLB) value and micelle molecular weight were correlated to chemical composition including fatty acids before and after hydrolysis, content of non-esterified polyethylene glycols and sorbitan polyethoxylates, sorbitan- and isosorbide polyethoxylate fatty acid mono- and diesters, polyoxyethylene diesters, and peroxide values. Batches from some suppliers had a high variability in functionality related characteristic (FRC), questioning the ability of the current monograph in controlling these. Interestingly, the combined use of the input parameters oleic acid content and peroxide value - both of which being monographed methods - resulted in a model adequately predicting CMC. Confining the batches to those complying with specifications for peroxide value proved oleic acid content alone as being predictive for CMC. Similarly, a four parameter model based on chemical analyses alone was instrumental in predicting the molecular weight of PS80 micelles. Improved models based on analytical outcome from fingerprint analyses are also presented. A road map controlling PS80 batches with respect to FRC and based on chemical analyses alone is provided for the formulator.

Protein release from electrospun nonwovens: improving the release characteristics through rational combination of polyester blend matrices with polidocanol.

Nonwoven scaffolds consisting of poly-ε-caprolactone (PCL), poly(lactic-co-glycolic acid) (PLGA) and polidocanol (PD), and loaded with lysozyme crystals were prepared by electrospinning. The composition of the matrix was varied and the effect of PD content in binary mixtures, and of PD and PLGA content in ternary mixtures regarding processability, fiber morphology, water sorption, swelling and drug release was investigated. Binary PCL/PD blend nonwovens showed a PD-dependent increase in swelling of up to 30% and of lysozyme burst release of up to 45% associated with changes of the fiber morphology. Furthermore, addition of free PD to the release medium resulted in a significant increase of lysozyme burst release from pure PCL nonwovens from approximately 2-35%. Using ternary PCL/PD/PLGA blends, matrix degradation could be significantly improved over PCL/PD blends, resulting in a biphasic release of lysozyme with constant release over 9 weeks, followed by constant release with a reduced rate over additional 4 weeks. Based on these results, protein release from PCL scaffolds is improved by blending with PD due to improved lysozyme desorption from the polymer surface and PD-dependent matrix swelling.

Influence of the capillary diameter on the separation efficiency and sensitivity: a systematic approach.

In this study, the influence of the capillary inner diameter (id) on the efficiency and sensitivity of a capillary zone electrophoresis separation was investigated. Four local anaesthetic drugs (lidocaine, prilocaine hydrochloride, procaine and tetracaine) were separated with a validated method using capillaries of different id. The separation parameter N and the resolution of the critical peak pair were monitored. It was found that N increases in tighter capillaries, while sensitivity decreases indicated by the increased detection limit for lidocaine. This loss in sensitivity can partially be compensated by loading more sample into the capillary by means of an increased injection time and pressure. However, when it comes to the evaluation of the drug quality according to a monograph in the European Pharmacopoeia, we cannot recommend to vary the capillary id in order to meet the system suitability criteria.

Charged aerosol detection in pharmaceutical analysis.

Due to its wide field of application, sensitivity, wide range of linearity and the applicability to gradient elution, the most common detection technique for HPLC nowadays is UV/vis spectrophotometry. However, UV/vis detection comes to its limits when the analytes are lacking suitable chromophors or exhibit very different UV responses. In the past years, different types of evaporation/aerosol based HPLC detectors have been developed to fill this gap in HPLC detection. Amongst those, the corona-charged aerosol detector (CAD) is one of the most powerful and versatile representatives. In the recent past a variety of papers have been published, demonstrating the potential of the CAD in different fields of analytical chemistry. This paper is intended to provide an overview of the key performance characteristics and manifold applications for HPLC-CAD in the field of pharmaceutical analysis.