Cassette-accelerated rapid rat screen: a systematic procedure for the dosing and liquid chromatography/atmospheric pressure ionization tandem mass spectrometric analysis of new chemical entities as part of new drug discovery.

This report addresses the continuing need for increased throughput in the evaluation of new chemical entities (NCEs) in terms of their pharmacokinetic (PK) parameters by describing an alternative procedure for increasing the throughput of the in vivo screening of NCEs in the oral rat PK model. The new approach is called "cassette-accelerated rapid rat screen" (CARRS). In this assay, NCEs are dosed individually (n = 2 rats/compound) in batches of six compounds per set. The assay makes use of a semi-automated protein precipitation procedure for sample preparation in a 96-well plate format. The liquid chromatography/atmospheric pressure ionization tandem mass spectrometry (LC/API-MS/MS) assay is also streamlined by analyzing the samples as "cassettes of six". Using this new approach, a threefold increase in throughput was achieved over the previously reported "rapid rat screen".

Demonstration of the capabilities of a parallel high performance liquid chromatography tandem mass spectrometry system for use in the analysis of drug discovery plasma samples.

There is a continuing need for increased throughput in the evaluation of new drug entities in terms of their pharmacokinetic (PK) parameters. This report describes an alternative procedure for increasing the throughput of plasma samples assayed in one overnight analysis: the use of parallel high performance liquid chromatography (HPLC) combined with tandem mass spectrometry (parallel LC/MS/MS). For this work, two HPLC systems were linked so that their combined effluent flowed into one tandem MS system. The parallel HPLC/APCI-MS/MS system consisted of two Waters 2690 Alliance systems (each one included an HPLC pump and an autosampler) and one Finnigan TSQ 7000 triple quadrupole mass spectrometer. Therefore, the simultaneous chromatographic separation of the plasma samples was carried out in parallel on two HPLC systems. The MS data system was able to deconvolute the data to calculate the results for the samples. Using this system, 20 compounds were tested in one overnight assay using the rapid rat PK screening model which includes a total of 10 standards plus samples and two solvent blanks per compound tested. This application provides an additional means of increasing throughput in the drug discovery PK assay arena; using this approach a two-fold increase in throughput can be achieved in the assay part of the drug discovery rat PK screening step.

Analysis of isepamicin in human plasma by radioimmunoassay, microbiologic assay, and high-performance liquid chromatography.

Plasma concentrations of isepamicin, a new aminoglycoside antibiotic, were determined by radioimmunoassay (RIA), microbiological assay (MA), and high-performance liquid chromatography (HPLC) in healthy volunteers after administration of 7.5 mg/kg intramuscular dosages once daily for 10 days. Plasma samples were collected on days 1, 7, and 10. The limit of quantitation (LOQ) was 0.1 microg/ml for HPLC and RIA and 0.5 microg/ml for MA. The HPLC and RIA yielded superimposable plasma concentration-time curves, whereas the plasma concentrations obtained with MA appeared to be 20% to 30% lower. Regression analysis indicated good correlations among the three assays, with coefficients of correlation measuring 0.935 to 0.960 for RIA compared with HPLC, 0.925 to 0.945 for MA compared with HPLC, and 0.920 to 0.945 for RIA compared with MA.

High-performance liquid chromatographic determination and stability of 5-(3-methyltriazen-1-yl)-imidazo-4-carboximide, the biologically active product of the antitumor agent temozolomide, in human plasma.

5-(3-Methyltriazen-1-yl)-imidazo-4-carboximide (MTIC) is a highly unstable compound which is believed to be the biologically active degradation product of the antitumor agent temozolomide. An HPLC method has been developed and validated for the analysis of MTIC in human plasma. Because of the instability of MTIC, sample processing was kept to minimal. The method involved precipitation of plasma protein with methanol followed by analysis of the supernatant using reversed-phase column and UV detection at 316 nm. The linearity (r>0.99), precision (C.V.<9%) and accuracy (bias<5%) were satisfactory. The lower limit of quantitation (LOQ) was 10 ng/ml. The recovery of MTIC and internal standard was > or = 86.7%. MTIC was stable in plasma though three freeze-thaw cycles, and was stable at 4 degrees C for 1 h and at -80 degrees C for at least 70 days. MTIC may be unstable at 10 degrees C in processed samples; therefore, samples were placed in the autosampler (10 degrees C) immediately prior to injection. By using this analytical method, MTIC was quantified in plasma of cancer patients (n=12) within 0.25-12 h after oral administration of temozolomide at 150 mg/m2. The mean maximum plasma concentration (Cmax) was 211 ng/ml which was observed at a mean Tmax of 1.88 h post dose. MTIC disappeared rapidly from plasma with an apparent in vivo half-life (t1/2) of 1.9 h similar to that of temozolomide. Following in vitro incubation of MTIC in human plasma at 25 degrees C, MTIC disappearance was bioexponential with estimated t1/2 values of 25 and 60 min for the first and second phases, respectively. Therefore, the elimination t1/2 of MTIC in human in vivo (1.9 h) was controlled by the rate of its formation from temozolomide.

Pharmacokinetics of Sch 34343 in rats and dogs.

The pharmacokinetics of 14C-Sch 34343 were studied in rats and dogs following intravenous and intramuscular dosing. In both species, it was rapidly absorbed after intramuscular dosing. The serum AUC for total radioactivity and for intact drug after intramuscular dosing were similar to those obtained after intravenous dosing. Following both routes of drug administration, the elimination of half-life (T 1/2 beta) was 7 min in rats and 25-32 min in dogs. Following intravenous dosing of 14C-Sch 34343 to rats, radioactivity in tissues disappeared rapidly with time indicating no tissue accumulation. Highest concentrations of radioactivity were seen in the kidney. Liver, lung, skin and heart appeared to have concentrations of radioactivity similar to those of blood. Sch 34343 was excreted rapidly and primarily into the urine in both rats and dogs. After either route of dosing, urinary excretion of total radioactivity ranged from 84 to 93% and that of intact Sch 34343 from 41 to 51% of the dose, respectively. In addition, the effect of pretreatment with probenecid on the pharmacokinetics in rats and dogs and in anephric rats were also evaluated. Pretreatment with probenecid prolonged the elimination half-life in both rats and dogs. Anephric rats had a longer half-life than normal rats.

The excretion of rosaramicin in breast milk.

The excretion of rosaramicin, a macrolide antibiotic, was studied in the breast milk of ten lactating women. Breast milk and serum samples were collected for 48 hours after a single 250-mg oral dose of rosaramicin. Mean serum half-life, apparent volume of distribution, and oral clearance were 4.4 hours, 3.41 L/kg, and 6.34 mL/min/kg, respectively. Mean milk/serum ratio was 0.12 and the total amount of drug recovered over the first ten hours was 6.25 micrograms, approximately 0.0025% of the dose. A positive correlation between breast milk volume and breast milk clearance was found, suggesting that the amount of drug received by a nursing infant will depend on the volume of milk produced by the mother. Drug-induced toxicity from the parent drug is unlikely to occur in nursing infants since the amount of rosaramicin that a nursing infant could ingest is small.

Bioavailability of orally administered propiram fumarate in humans.

Propiram bioavailability was determined in 10 healthy volunteers after a single role administration of 50 mg (base equivalent) of propiram fumarate in tablet or solution dosage from in a randomized crossover design. The plasma drug concentration-time curve revealed a one-compartment open model with first-order absorption kinetics. There were no statistically significant differences (P greater than 0.05) between all of the measured pharmacokinetic parameters obtained from the tablet and the solution with the exception of the absorption lag time (tlag), where the tablet had a significantly longer tlag. The drug given as a tablet or solution was absorbed rapidly after oral administration with an apparent absorption rate constant of 3.7 hr-1 for both dosage forms. The Cmax value (308 ng/ml for the tablet and 342 ng/ml for the solution) was attained at approximately 1 hr after oral administration. The elimination half-life was 5.2 hr for the tablet and 4.4 hr for the solution, and the apparent distribution volume was 2.31 liters/kg for the tablet and 1.94 liters/kg for the solution. Total body clearance was much greater than renal clearance, indicating extensive metabolic clearance for both dosage forms. The study showed that propiram administered as the tablet was bioequivalent to the solution.

Effect of dexamethasone on monoamine oxidase inhibiton by iproniazid in rat brain.

Chronic (6 days) dexamethasone administration caused a slight decrease of rat brain MAO enzyme activity which was reflected by lower levels of 14C-homovanillic acid (HVA) and increased levels of 14C-3-methoxytyramine (3MT) following intracisternal injections of 14C-dopamine (DA). Opposite results with dexamethasone were obtained in iproniazid (MAO-inhibited)-treated rats. In these animals, brain MAO enzyme activity was significantly increased by dexamethasone. This effect increased with the duration of dexamethasone treatment and appeared to be dose dependent. In the brain areas tested (hypothalamus, midbrain, cerebellum, pons and medulla, olfactory, rest of brain) increases of MAO enzyme activity were also indicated by lower levels of 14C-3MT and increased levels of 14C-HVA formed from intracisternally injected radiolabeled DA. Treatment with other glucocorticoids (16alpha-methyldichlorisone, 16beta-methylprednisone and prednisolone) had a similar effect on 14C-DA metabolism. On the other hand, desoxycorticosterone, progestone, estradiol and testosterone, did not exhibit this property. The data indicate that chronic glucocorticoid treatment may have a slight inhibitory effect on brain MAO and also has the ability to partially reverse or antagonize the inhibition of MAO caused by iproniazid.