Preclinical Efficacy and Safety of the Novel Antidiabetic, Antiobesity MetAP2 Inhibitor ZGN-1061.

Methionine aminopeptidase 2 (MetAP2) inhibition is a promising approach to treating diabetes, obesity, and associated metabolic disorders. Beloranib, a MetAP2 inhibitor previously investigated for treatment of Prader-Willi syndrome, was associated with venous thrombotic adverse events likely resulting from drug effects on vascular endothelial cells (ECs). Here, we report the pharmacological characterization of ZGN-1061, a novel MetAP2 inhibitor being investigated for treatment of diabetes and obesity. Four weeks of subcutaneous administration of ZGN-1061 to diet-induced obese (DIO) insulin-resistant mice produced a 25% reduction in body weight, primarily due to reduced fat mass, that was comparable to beloranib. ZGN-1061 also produced improvements in metabolic parameters, including plasma glucose and insulin, and, in HepG2 cells, initiated gene changes similar to beloranib that support observed in vivo pharmacodynamics. In vitro studies in ECs demonstrated that ZGN-1061 effects on EC proliferation and coagulation proteins were greatly attenuated, or absent, relative to beloranib, due to lower intracellular drug concentrations, shorter half-life of inhibitor-bound MetAP2 complex, and reduced cellular enzyme inhibition. In dogs, ZGN-1061 was more rapidly absorbed and cleared, with a shorter half-life than beloranib. Unlike beloranib, ZGN-1061 did not increase coagulation markers in dogs, and ZGN-1061 had a greatly improved safety profile in rats relative to beloranib. In conclusion, ZGN-1061 and beloranib demonstrated similar efficacy in a mouse model of obesity, while ZGN-1061 had a markedly improved safety profile in multiple in vitro and in vivo models. The lower duration of exposure characteristic of ZGN-1061 is expected to provide a meaningfully enhanced clinical safety profile.

In vitro and in vivo studies to characterize the clearance mechanism and potential cytochrome P450 interactions of anidulafungin.

Anidulafungin is a novel semisynthetic echinocandin with potent activity against Candida (including azole-resistant isolates) and Aspergillus spp. and is used for serious systemic fungal infections. The purpose of these studies was to characterize the clearance mechanism and potential for drug interactions of anidulafungin. Experiments included in vitro degradation of anidulafungin in buffer and human plasma, a bioassay for antifungal activity, in vitro human cytochrome P450 inhibition studies, in vitro incubation with rat and human hepatocytes, and mass balance studies in rats and humans. Clearance of anidulafungin appeared to be primarily due to slow chemical degradation, with no evidence of hepatic-mediated metabolism (phase 1 or 2). Under physiological conditions, further degradation of the primary degradant appears to take place. The primary degradation product does not retain antifungal activity. Anidulafungin was not an inhibitor of cytochrome P450 enzymes commonly involved in drug metabolism. Mass balance studies showed that anidulafungin was eliminated in the feces predominantly as degradation products, with only a small fraction (10%) eliminated as unchanged drug; fecal elimination likely occurred via biliary excretion. Only negligible renal involvement in the drug's elimination was observed. In conclusion, the primary biotransformation of anidulafungin is mediated by slow chemical degradation, with no evidence for hepatic enzymatic metabolism or renal elimination.

Pharmacokinetics and lung tissue concentrations of tulathromycin, a new triamilide antibiotic, in cattle.

The pharmacokinetics of the new triamilide antibiotic tulathromycin was investigated in two cattle studies. Following a single subcutaneous injection, the drug was rapidly absorbed and bioavailability was excellent. High and persistent levels of the drug in lung tissue were observed as well. These attributes are advantageous for an antimicrobial drug indicated for the treatment of bacterial and mycoplasmal respiratory diseases in cattle.

An analytical method for the analysis of tulathromycin, an equilibrating triamilide, in bovine and porcine plasma and lung.

Tulathromycin is a novel member of the triamilide class of antibiotics that was developed as a safe and effective single-dose treatment of bovine and porcine respiratory disease. An accurate and precise analytical method was developed for the extraction and measurement of tulathromycin in livestock plasma and lung homogenates. Analytes were solid-phase extracted onto a weak cation exchanger after aqueous dilution of samples and addition of heptadeutero-tulathromycin as an internal standard. Following HPLC with a narrow bore C8 column, quantitative detection of tulathromycin was accomplished by monitoring the transition of a doubly charged precursor ion to a singly charged product ion by tandem mass spectrometry using a triple quadrupole mass spectrometer. Procedures were validated for a dynamic range of 0.1 to 25 ng on column. Observed accuracies were between 90 and 110% of nominal and precision (RSD) varying 7% or less. Response and stability experiments showed that deuterated tulathromycin did not parallel the chemical behavior of tulathromycin. Applicability of the method to livestock studies was tested with plasma and lung samples from cattle and swine dosed with tulathromycin at multiple doses. The results demonstrated that the analytical method performed well in a range of sample concentrations spanning over 3 orders of magnitude and provided dose-exposure relationships for cattle and swine.

The Effect of Urinary pH and Flow Rate on the Renal Elimination of Zopolrestat and Zopolrestat Glucuronide in Humans.

Zopolrestat is an aldose reductase inhibitor that may be useful in the treatment of diabetic complications by reducing flux through the polyol pathway. The plasma half-life of zopolrestat in man is approximately 30 h, and approximately 45% of an orally administered 1000-mg dose is eliminated in the urine as unchanged drug. Because active secretion accounts for much of the renal clearance for zopolrestat, a carboxylic acid with a pK(a) of 5.46, the effect of urinary pH and flow rate on renal clearance of drug was investigated in a series of studies. Renal clearance of zopolrestat following oral administration of 200 mg was determined in normal male volunteers under basal conditions and after treatment with NH(4)Cl and NaHCO(3) to alter urinary pH. Plasma concentrations of zopolrestat were similar under basal and NaHCO(3) treatment but were approximately twofold higher under NH(4)Cl treatment. However, the half-life of zopolrestat under NH(4)Cl treatment (29.5 h) was similar to the half-life of zopolrestat in untreated subjects. Renal clearance decreased by a factor of 2.54 for each unit decrease in urinary pH. In a second study, there was no effect of urine flow rate on renal clearance following an oral dose of 400 mg. Renal elimination of zopolrestat and zopolrestat glucuronide was also examined in volunteers with normal urine flow dosed at either 600 or 1000 mg/day. Whereas renal clearance of zopolrestat decreased with decreasing urinary pH, renal elimination of zopolrestat glucuronide was not affected by pH.

Pharmacokinetics in Non-Insulin-Dependent Diabetics of the Aldose Reductase Inhibitor, Zopolrestat.

The pharmacokinetics of zopolrestat have been examined in non-insulin-dependent diabetic patients after oral administration of a single dose of 1000 mg zopolrestat. T(max) ranged from 2 to 4 h with a mean C(max) of 100 &mgr;g ml(minus sign1). Mean plasma half-life of zopolrestat was 26.9 h. The same patients were also administered oral doses of 1000 mg day(minus sign1) for 10 consecutive days. Mean T(max) was 4.3 h and mean C(max) was 208 &mgr;g ml(minus sign1). Plasma accumulation, the ratio of AUC((0--24)) for the last dose to AUC((0--24)) for the first dose, was 2.67. Apparent oral clearance was 5.71 ml min(minus sign1) and apparent volume of distribution was 12.9 L. The mean urinary excretion of unchanged drug over the 24-h period following the last dose was 36% of the dose while another 7% of the dose appeared in the urine as an acylglucuronide of zopolrestat. Renal clearance of zopolrestat was 1.82 ml min(minus sign1). Binding of zopolrestat to plasma proteins exceeded 99% and was concentration dependent.