Stanislaw Pikul

Application of LC-NMR and LC-MS to the identification of degradation products of a protease inhibitor in dosage formulations

LC-NMR and LC-MS were applied to the characterization of six degradation products of a protease inhibitor, N-hydroxy-1,3-di-[4-ethoxybenzenesulphonyl]-5,5-dimethyl-[1,3]c yclohexyldiazine-2-carboxamide, in a dosage formulation. A reversed-phase HPLC method was developed for the separation of the parent compound and its six degradation products. LC-MS was then utilized to obtain the molecular weight and fragmentation information using an electrospray ionization (ESI) interface in the positive ion mode. LC-NMR was employed to acquire detailed structural information using a selective solvent suppression pulse sequence in the stop flow mode. This work demonstrated the usefulness of this integrated approach for the rapid and unambiguous identification of drug compounds and their degradation products in dosage formulations.

The Next Generation of MMP Inhibitors: Design and Synthesis

ABSTRACT: Since their inception during the eighties, MMP inhibitors (MMPIs) have gone through several cycles of metamorphosis. The design of early MMPIs was based on the cleavage site of peptide substrates. The second generation contained a substituted succinate scaffold (e.g., marimastat) coupled to a modified amino acid residue. The lower molecular weight analogs with multiple substitution possibilities produced a series of MMP inhibitors with varying degrees of selectivity for various MMPs. The introduction of sulfonamides in the midnineties added a new dimension to this field. The simplicity of synthesis coupled with high potency (e.g., CGS‐27023A, AG‐3340) produced a number of clinical candidates. This review highlights some of the key features that contributed to the discovery of this novel series of MMP inhibitors.

Design and synthesis of conformationally-constrained MMP inhibitors

A novel series of conformationally constrained matrix metalloprotease inhibitors was identified. The potencies observed for these inhibitors were highly dependent upon the substitution pattern on the caprolactam ring as well as the succinate moiety.

Gas chromatographic-mass spectrometric analysis of hydroxylamine for monitoring the metabolic hydrolysis of metalloprotease inhibitors in rat and human liver microsomes

A gas chromatographic-mass spectrometric (GC-MS) method was developed for the analysis of hydroxylamine (HA) in supernatants obtained from liver microsomes. HA monitoring was used to determine the metabolic hydrolysis of two hydroxamic acid-based matrix metalloprotease inhibitors in rat and human liver microsomes. The hydrolysis of the hydroxamic acids to their corresponding carboxylic acids releases HA as a common metabolic product. HA was derivatized to acetone oxime by addition of acetone to the liver microsomal supernatant, followed by direct injection of the supernatant into the GC-MS, with detection of the oxime by selected-ion-monitoring. The method is simple, reproducible, and sensitive for the determination of the hydrolysis of hydroxamic acid compounds, where hydrolysis is the major metabolic pathway. The methodology can be used for rank ordering and selecting hydroxamic acid analogs based on their susceptibility to hydrolysis.

The development of new carboxylic acid-based MMP inhibitors derived from a cyclohexylglycine scaffold.

A series of carboxylic acids was prepared based on cyclohexylglycine scaffolds and tested for potency as matrix metalloproteinase (MMP) inhibitors. Detailed SAR for the series is reported for five enzymes within the MMP family, and a number of inhibitors such as compound 18 display low nanomolar potency for MMP-2 and MMP-13, while selectively sparing MMP-1 and MMP-7.

Zirconium tetrachloride as a convenient catalyst for the glycosylation of sterols with 2,3,4,6,6′-penta-O-acetyl-5-hydroxymethylgalactosyl fluoride

Abstract Zirconium tetrachloride was found to catalyze glycosylation of various sterols with peracetylated 5-hydroxymethylene galactosyl fluoride.

Permeability of Articular Cartilage to Matrix Metalloprotease Inhibitors

AbstractPurpose. To develop an in vitro cartilage permeation model for cartilage permeability study and to evaluate the effects of molecular hydrophilicity and cartilage location on the permeability of articular cartilage to matrix metalloprotease inhibitors. Methods. An in vitro cartilage permeation model was developed and utilized to determine the permeability of articular cartilage to the matrix metalloprotease inhibitors of different hydrophilicity. Permeability coefficients were obtained by measuring the steady-state flux of the inhibitor compounds. HPLC methods were also developed and employed for the analysis of drug levels in assay media. Results. The relationship between permeability and hydrophilicity of drug molecules was examined. Results indicated that the permeability coefficient increased with increasing hydrophilicity of the molecule. Additionally, the relationship between the permeability and the location of the cartilage section within the animal joint was investigated. Our results showed that the drug molecules penetrated faster in the surface layer cartilage than in the deep layer cartilage. Conclusions. Increasing the hydrophilicity of a molecule would increase its permeability across articular cartilage. The in vitro cartilage permeation model developed could be used to rank order drug compounds according to their cartilage permeability profiles and to aid in drug selection and development.

Oxazolidinone to succinamide: a novel rearrangement reaction

During the course of an investigative work with a monosubstituted succinic acid half-ester tethered to a chiral oxazolidinone, an unexpected disubstituted succinimide was obtained with a high degree of stereoselectivity as the major product. Subsequent investigative work confirmed the structure and further defined the scope of this rearrangement reaction.