Reactive metabolite formation has been associated with drug-induced liver, skin, and hematopoietic toxicity of many drugs that has resulted in serious clinical toxicity, leading to clinical development failure, black box warnings, or, in some cases, withdrawal from the market. In vitro and in vivo screening for reactive metabolite formation has been proposed and widely adopted in the pharmaceutical industry with the aim of minimizing the property and thus the risk of drug-induced toxicity (DIT). One of the most common screening methods is in vitro thiol trapping of reactive metabolites. Although it is well-documented that many hepatotoxins form thiol adducts, there is no literature describing the adduct formation potential of safer drugs that are widely used. The objective of this study was to quantitatively assess the thiol adduct formation potential of 50 drugs (10 associated with DIT and 40 not associated) and document apparent differences in adduct formation between toxic and safer drugs. Dansyl glutathione was used as a trapping agent to aid the quantitation of adducts following in vitro incubation of drugs with human liver microsomes in the presence and absence of NADPH. Metabolic turnover of these drugs was also monitored by LC/UV. Overall, 15 out of the 50 drugs screened formed detectable levels of thiol adducts. There were general trends toward more positive findings in the DIT group vs the non-DIT group. These trends became more marked when the relative amount of thiol adducts was taken into account and improved further when dose and total daily reactive metabolite burdens were considered. In conclusion, there appears to be a general trend between the extent of thiol adduct formation and the potential for DIT, which would support the preclinical measurement and minimization of the property through screening of thiol adduct formation as part of an overall discovery optimization paradigm.
The pharmacokinetics of didanosine (2',3'-dideoxyinosine) after intravenous and oral administration were evaluated in an open, escalating-dose phase I study in patients with acquired immunodeficiency syndrome (AIDS) or severe AIDS-related complex. Didanosine was administered twice a day for 2 weeks as an intravenous infusion of 60 minutes duration at doses ranging from 0.4 to 16.5 mg/kg, followed by 4 weeks of oral treatment at twice the intravenous dose. Serial blood and urine samples were obtained on the first and final day of intravenous administration and after the first oral dose, as well as at steady state. Didanosine demonstrated linear pharmacokinetic behavior over the dose ranges of 0.4 to 16.5 mg/kg intravenously and 0.8 to 10.2 mg/kg orally. There was no indication of significant changes in pharmacokinetic parameters with repeated administration. The apparent elimination half-life after oral administration was approximately 1.4 hour. Renal clearance values exceeded the glomerular filtration rate, indicating that active tubular secretion of didanosine occurs. Bioavailability of didanosine when administered as a solution with an antacid was approximately 43% for doses from 0.8 to 10.2 mg/kg in patients with AIDS and advanced AIDS-related complex. Bioavailability of didanosine from the citrate-phosphate-buffered solution, the formulation currently used in phase II and expanded access studies, was comparable to the formulation used in the phase I trials.
Radiolabeled compounds are excellent investigative tools and widely used to carry out ADME studies during drug discovery and development stages. The most commonly used radioisotopes are 14C and 3H. 3H materials are generally easier to synthesize than 14C materials. Therefore, a variety of probes and substrates used in in vitro assays are labeled with 3H. Since synthesis of 14C material requires intensive resources, it is usually not available until after a molecule is considered for potential development or after the molecule enters the development phase. Improvement in the technology in radiochemistry has enabled the use of radiolabeled compounds earlier in pre-clinical and clinical development to address mechanistic issues. For in vitro studies, radiolabeled probes are utilized to test affinity with various transporters, to perform metabolism comparison among species and to assess possible formation of reactive metabolites. For in vivo studies, radiolabeled compounds are employed to identify and elucidate metabolites formed, to investigate the extent of absorption, bioavailability, tissue distribution, mass balance, routes of excretion, and pre-systemic metabolism. Due to the significant impact of radiolabeled studies on drug development, these studies will be performed earlier than have been in the past and will continue to be an integral part of drug discovery and development.
A high-pressure liquid chromatographic assay was developed for the quantitative analysis of a new cephalosporin, BMY-28142, in plasma and urine. The plasma method involved protein precipitation with acetonitrile and trichloroacetic acid followed by extraction of the acetonitrile into dichloromethane. After centrifugation, the organic phase was discarded, the aqueous solution was injected into a reverse-phase column, and peaks were detected at 280 nm. The urine method involved dilution of a urine sample with sodium acetate buffer (pH 4.25) and direct injection into the high-pressure liquid chromatography system. The assay validation data indicate that the assays for BMY-28142 in plasma and urine were specific, accurate, and reproducible. The analytical methods were applied to the determination of protein binding in human serum and to a pharmacokinetic study in rats. The results of the protein-binding study indicated that BMY-28142 was 16.3% bound to human serum proteins. In the pharmacokinetic study in rats, the maximum level in plasma of 38.7 ,ug/ml was achieved at 2.33 h after administration of a subcutaneous dose of 100 mg/kg. The levels in the plasma then declined with an elimination half-life of about 0.56 h. The mean values for the steady-state volume of distribution and total body clearance were 0.46 liters/kg and 11.9 ml/min per kg, respectively. The 0-to 24-h excretion of intact BMY-28142 in urine accounted for 88.6% of the dose.
Aurora A kinase orchestrates multiple key activities, allowing cells to transit successfully into and through mitosis. MLN8237 (alisertib) is a selective Aurora A inhibitor that is being evaluated as an anticancer agent in multiple solid tumors and heme-lymphatic malignancies. The antitumor activity of MLN8237 when combined with docetaxel or paclitaxel was evaluated in in vivo models of triple-negative breast cancer grown in immunocompromised mice. Additive and synergistic antitumor activity occurred at multiple doses of MLN8237 and taxanes. Moreover, significant tumor growth delay relative to the single agents was achieved after discontinuing treatment; notably, durable complete responses were observed in some mice. The tumor growth inhibition data generated with multiple dose levels of MLN8237 and paclitaxel were used to generate an exposure-efficacy model. Exposures of MLN8237 and paclitaxel achieved in patients were mapped onto the model after correcting for mouse-to-human variation in plasma protein binding and maximum tolerated exposures. This allowed rank ordering of various combination doses of MLN8237 and paclitaxel to predict which pair would lead to the greatest antitumor activity in clinical studies. The model predicted that 60 and 80 mg/m 2 of paclitaxel (every week) in patients lead to similar levels of efficacy, consistent with clinical observations in some cancer indications. The model also supported using the highest dose of MLN8237 that can be achieved, regardless of whether it is combined with 60 or 80 mg/m 2 of paciltaxel. The modeling approaches applied in these studies can be used to guide dose-schedule optimization for combination therapies using other therapeutic agents. Mol Cancer Ther; 13(9); 2170-83. Ó2014 AACR.
The objectives of this study were to assess the safety and tolerance of cefprozil, to characterize the pharmacokinetics of cefprozil after adiinistration of multiple doses of the drug, and to compare these pharmacokinetic parameters with those obtained with cefaclor. The volunteers received 28 doses of 250, 500, or 1,000 mg of cefprozil or 500 mg of cefaclor every 8 h for 10 days. Serial blood samples and the total volume of urine voided by each individual were collected for pharmacokinetic evaluation on days 1, 5, and 10. Both cephalosporins were well tolerated after multiple oral dosing. The greater than that of cefaclor. The half-life of cefprozil was also twofold longer than that observed for cefaclor. Although the urinary recovery of cefaclor (75% of dose) was significantly higher than that of cefprozil (61% of dose), the concentrations of cefprozil in urine remained significantly higher than those of cefaclor from 2 to 8 h postdosing. If the therapeutic concept is maintained that levels of beta-lactam antibiotics in plasma should exceed the MIC for the offending organisms over a period that approximates the dosing interval, then cefprozil would appear to be suitable for twice-daily administration, whereas cefaclor should probably be administered three or even four times a day.
Absolute oral bioavailability and disposition characteristics of irbesartan, an angiotensin II receptor antagonist, were investigated in 18 healthy young male volunteers. Subjects received [14C] irbesartan as a 30-minute intravenous infusion (50 mg), [14C] irbesartan orally as a solution (50 mg or 150 mg), or irbesartan capsule (50 mg). Irbesartan was rapidly and almost completely absorbed after oral administration, and exhibited a mean absolute oral bioavailability of 60% to 80%. Mean total body clearance was approximately 157 mL/min, and renal clearance was 3.0 mL/min. Volume of distribution at steady state was 53 L to 93 L, and terminal elimination half-life was approximately 13 to 16 hours. Hepatic extraction ratio was low (0.2). There were no major circulating metabolites, and approximately 80% of total plasma radioactivity was attributable to unchanged irbesartan. Regardless of route of administration, approximately 20% of dose was recovered in urine and the remainder in feces.
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