Demonstrative validation study employing a packed column pressurized fluid chromatography method that provides assay, achiral impurities, chiral impurity, and IR identity testing for a drug substance

Assay development, assay validation, and documentation are reported here for a single packed column pressurized fluid chromatographic/ultraviolet (UV) method that provides: (1) simultaneous detection and quantification for the chiral drug, the chiral impurity and seven achiral impurities; and (2) a Fourier transform infrared (FT-IR) spectrometric identification test result for the Searle drug substance sample, xemilofiban. The separation is achieved in less than 30 min with three columns in tandem and a gradient of CO2-CH3OH. The post-column flow is split between UV (assay) and FT-IR (identification). Precision and accuracy are consistent within figures of merit obtained by liquid chromatographic-ultraviolet assays on analogous drug substances. The reported procedure combines three typical drug substance tests into one test (e.g. chiral impurities, achiral impurities, and infrared identification).

Comparison of drug substance impurity profiles generated with extended length columns during packed-column SFC

The current study assesses the effect of extending column length during gradient packed column sub/supercritical fluid chromatography (PCSFC) experiments on the detection of known and unknown impurities in a drug substance sample. Quantitative drug substance impurity profiles were generated and compared using multiple column PCSFC and HPLC conditions. Also, chromatographic figures of merit were estimated and compared for components of a standard mixture during PCSFC experiments, which used one column, four columns, and six columns in series.

Supercritical fluid extraction method development for extraction of an experimental HIV protease inhibitor drug from animal feed

Supercritical fluid extraction (SFE) was evaluated as a sample preparation procedure for the recovery of experimental drugs from animal feed preparations that are generated during long-term toxicology studies. A commercially available supercritical fluid extractor was utilized to develop and validate an off-line procedure for the recovery of an experimental HIV protease inhibitor drug from animal feed. Extracts were analyzed with a conventional reversed-phase HPLC method. Elements of the SFE method developed that are described include optimization of the system temperature and selection of the extraction media modifier. The study emphasized the performance of two-day precision and accuracy studies. Precision and accuracy studies were carried out with SC-52151 levels of 0.05, 0.1 and 1.0% (w/w) and used an internal standard quantitation format. Also, the study utilized a relatively large analytical scale extraction vessel size of 10 ml to accomodate 6 g animal feed samples.

Supercritical fluid extraction-liquid chromatography method development for a polymeric controlled-release drug formulation

We have recently been involved in the development of a method for assaying the active component in a controlled-release drug formulation, which is composed of a drug substance covalently bonded to polymer matrix. The drug substance in the formulation is the active enantiomer of misoprostol, a synthetic analog of natural prostaglandins and the active ingredient in Cytotec. Our method development consisted of a systematic evaluation of dynamic, off-line supercritical fluid extraction (SFE) as sample preparation for the formulation assay. Extracts were analyzed with normal phase and reversed-phase HPLC methods. The reversed-phase system utilized postcolumn reaction to provide selective detection of the extracted prostaglandin sample components. Several SFE parameters were investigated to optimize the recovery of the drug substance from the formulation, including sample quantity, extraction cell volume, extraction duration, supercritical carbon dioxide modifier, temperature, pressure, and collection solvent. The SFE experiments were completed with a commercially available multicell extractor. Preliminary validation studies utilized a formulation made with radiolabeled drug to determine the recovery achieved under the optimized SFE conditions and assessed the precision of replicate determinations. Analysis was completed under the optimized conditions to quantitate levels of the active component and related compounds in lots of the experimental polymeric formulation and to determine the total weight per cent extracted.

Characterization of polymorphs of a new anti-inflammatory drug

The present study demonstrates the utility of a diversified analytical approach for the characterization and quantitative analysis for two polymorphs of a new anti-inflammatory agent, (+/-)-7-[3-(4-acetyl-3-methoxy-2-propylphenoxy)propoxy-3,4-dihydro -8-propyl- 2H-1-benzopyran-2-carboxylic acid (SC-41930). The existence of two distinct crystal polymorphs of SC-41930 was qualitatively indicated through microscopy and application of thermal methods of analysis. The application of TGA was important for establishing that the two solid forms were, in fact, polymorphs, as opposed to solvated and unsolvated drug substances. The application of IR spectrometry revealed spectral features in the carbonyl stretching region, which were characteristic and unique to the two SC-41930 polymorphs. DRIFT spectrometry was implemented as the sampling method of choice to eliminate the possibility of polymorphic transformations during conventional mulling or KBr pellet sampling procedures. The DRIFT spectrometry procedure permitted development of a quantitative assay for detection of the low-melting polymorph (as an impurity) in high-melting samples. Calibration plots showed acceptable linearity of response from 0 to 25% (w/w) low-melting samples spiked into the high-melting polymorph. The performance characteristics of the method indicated good run-to-run and day-to-day consistency for its intended use.

Determination of hydroxylated aromatic compounds produced via superoxide-dependent formation of hydroxyl radicals by liquid chromatography/electrochemistry

Hydroxyl radicals may be formed in a xanthine oxidase/hypoxanthine system, where the superoxide anion radical O-.2 and H2O2 are produced. The superoxide-dependent production of the OH. radicals may be monitored by determining the amount of hydroxylated aromatic compounds formed in such a system. Liquid chromatography/electrochemistry is a powerful tool for the determination of hydroxylated aromatic compounds. A technique is presented in which aniline and phenol are hydroxylated in xanthine oxidase/hypoxanthine incubations. No sample derivatization is needed for the determinations which can be accomplished by direct injection of the incubation mixture. Detection limits for 1,2- and 1,4-hydroxylated compounds are in the picomole range.