Isolation and identification of a degradation product in a capsule formulation containing the elastase inhibitor, DMP 777.

An unexpected degradation product, greater than 0.10%, was observed in a DMP 777 capsule formulation stored at 40 degrees C/75% r.h. for 3 months and 25 degrees C/60% r.h. for 2 years. The degradant of interest was prepared in quantity by refluxing the drug substance in dilute acid. A preparative HPLC method was developed to separate the various degradants and to collect each as a separate fraction. Each fraction was analyzed by the analytical HPLC gradient test method to assure positive identification of each peak and to correlate each peak to the original capsule sample. Key isolated degradation products were used for structure elucidation with mass spectrometry and NMR. The major degradant of interest in the capsule formulation was found to be a carboxylic acid resulting from the acid hydrolysis of an amide bond.

N-Arylalkyl pseudopeptide inhibitors of farnesyltransferase.

Inhibitors of Ras protein farnesyltransferase are described which are reduced pseudopeptides related to the C-terminal tetrapeptide of the Ras protein that signals farnesylation. Reduction of the carbonyl groups linking the first three residues of the tetrapeptide leads to active inhibitors which are chemically unstable. Stability can be restored by alkylating the central amine of the tetrapeptide. Studies of the SAR of these alkylated pseudopeptides with concomitant modification of the side chain of the third residue led to 2(S)-(2(S)-¿[2(S)-(2(R)-amino-3-mercaptopropylamino)-3(S)- methylpentyl]naphthalen-1-ylmethylamino¿acetylamino)-4 -methylsulfany lbutyric acid (11), a subnanomolar inhibitor. The methyl ester (10) of this compound exhibited submicromolar activity in the processing assay and selectively inhibited anchorage-independent growth of Rat1 cells transformed by v-ras at 2.5-5 microM.

Active drug substance impurity profiling part I. LC/UV diode array spectral matching.

Monitoring of drug substance impurities is routinely accomplished using HPLC. However, HPLC retention times can vary, resulting in uncertainty as to whether a peak at a new retention time is a new impurity. Because standards of the minor impurities (less than 0.1% by area) are not usually available, some method is needed to characterize each of these peaks without isolating them. This on-line characterization might be accomplished using UV diode array spectral matching. This work sought to assess the sensitivity and selectivity of UV spectral matching for monitoring the impurity profile of drugs, using as an illustration DuP 941, an anti-cancer drug under development. An ultraviolet spectral data library was generated for a number of the DuP 941 impurities in the earliest safety lot. Impurities in several subsequent lots of DuP 941 were then examined to see how well their spectral characteristics matched those of the spectra contained in the library. We found LC/UV spectral matching to be a powerful method to monitor Dup 941 impurities even down to levels well below 0.1% by area. Critical factors that were shown to influence the utility of the technique include detector sensitivity, lamp intensity, and the presence of other impurities with very similar UV spectra.

Active drug substance impurity profiling part II. LC/MS/MS fingerprinting.

Drug substance impurities are routinely monitored using HPLC. Because HPLC retention times can vary, uncertainty can arise as to whether a peak at a new retention time is a new impurity. When impurity standards are not available some method is needed to characterize the impurities on-line. This work sought to assess the ability of LC/MS/MS to generate characteristic impurity 'fingerprints', comprised of a precursor ion mass plus at least three product ion masses. MS/MS fingerprints of a drug substance, DuP 941, and three of its impurities were first generated using available standards. Experiments varying collision cell parameters showed that collision energy must be specified in order to reproducibly generate characteristic MS/MS fingerprints. MS/MS fingerprints were also generated on-line for seven impurities in the earliest safety lot of DuP 941. Several subsequent lots of DuP 941 were examined to see how well their impurity fingerprints matched those from the earlier lot. Fingerprint reproducibility was very good for all impurities examined, even down to 0.01 UV area percent for some impurities. MS/MS fingerprinting was able to distinguish two impurities from one another which were known to be positional isomers. It also permitted assignment of tentative structures to the drug impurities.

Degradation kinetics of DMP 777, an elastase inhibitor.

PURPOSE: The objective was to evaluate the degradation profile of the elastase inhibitor DMP 777 and lay the foundation for formulation development. METHODS: The pKa was determined by potentiometric titration in mixed-aqueous solvents. The degradation kinetics were studied as a function of pH, buffer concentration, ionic strength, methanol concentration and temperature using a stability-indicating HPLC assay. The degradation products were identified by LC-MS, NMR, and by comparison with authentic samples. RESULTS: The pKa for the protonated piperazine nitrogen was estimated to be 7.04. The pH-rate profile is described by specific acid-, water-, and specific base-catalyzed pathways. The pH of maximum stability is in the range of 4 to 4.5 where water is the principal catalyst in the reaction. Buffer catalysis, primary salt effects and medium effects were observed. The proposed mechanism for acid catalyzed degradation is the rarely observed AAL1 which involves alkyl-nitrogen heterolysis. The driving force for the reaction appears to lie in the stability of the benzylic carbocation. The proposed mechanism for base catalyzed degradation is BAC2 which involves beta-lactam ring opening. The beta-lactam ring of DMP 777, a monolactam, appears to be as reactive as that in benzylpenicillin in the KOH controlled region where a similar mechanism of hydrolysis should be operative. A contributing factor to this increased reactivity may lie in the reduced basicity of the beta-lactam nitrogen making it a good leaving group. CONCLUSIONS: The degradation profile indicates that development of a solution dosage form of DMP 777 with adequate shelf-life stability at room temperature is feasible.

Pseudodipeptide inhibitors of protein farnesyltransferase.

A series of pseudodipeptide amides are described that inhibit Ras protein farnesyltransferase (PFTase). These inhibitors are truncated versions of the C-terminal tetrapeptide (CAAX motif) of Ras that serves as the signal sequence for PFTase-catalyzed protein farnesylation. In contrast to CAAX peptidomimetics previously reported, these inhibitors do not have a C-terminal carboxyl moiety, yet they inhibit farnesylation in vitro at < 100 nM. Despite the absence of the X residue in the CAAX motif, which normally directs prenylation specificity, these pseudodipeptides are greater than 100-fold selective for PFTase over type 1 protein geranylgeranyltransferase.

Sulfonylmethanesulfonamide inhibitors of carbonic anhydrase.

A series of sulfonylmethanesulfonamide derivatives is described, which are inhibitors of carbonic anhydrase (CA). The most potent of these is the racemic fluoro sulfone 9, which inhibits carbon dioxide hydration catalyzed by human CA II (CA-II) with an IC50 of 3 nM. Binding competition studies versus dansylamide indicate that the enantiomers of 9 have different affinities for CA-II, with equilibrium dissociation constants of 3.6 and 0.6 nM. QSAR analysis suggests that the key factors involved in achieving high affinity in this series are sulfonamide acidity, hydrophobicity, and minimization of steric demands at the carbon atom adjacent to the sulfonamide group.

Topically active carbonic anhydrase inhibitors. 4. [(Hydroxyalkyl)sulfonyl]benzene and [(hydroxyalkyl)sulfonyl]thiophenesulfonamides.

For several decades a tantalizing goal for the treatment of primary open-angle glaucoma has been the development of a topically active carbonic anhydrase inhibitor. Recent results from several research groups indicate that considerable progress has been made toward this objective. In this report, we present the design and synthesis of (hydroxyalkyl)sulfonyl-substituted benzene- and thiophenesulfonamides. These compounds exhibit inhibition of carbonic anhydrase II in the nanomolar range and lower intraocular pressure in the alpha-chymotrypsinized rabbit model of ocular hypertension after topical instillation.

Topically active carbonic anhydrase inhibitors. 3. Benzofuran- and indole-2-sulfonamides.

Derivatives of benzofuran- and indole-2-sulfonamide were prepared for evaluation as topically active ocular hypotensive agents. These compounds were found to be excellent inhibitors of carbonic anhydrase and to lower intraocular pressure in a rabbit model of ocular hypertension. However, the development of these compounds for clinical use was precluded by the observation that they cause dermal sensitization in guinea pigs. A correlation between electrophilicity, as assessed by in vitro reactivity with reduced glutathione, and dermal sensitization potential was further documented.