Nanosuspension formulation of itraconazole eliminates the negative inotropic effect of SPORANOX in dogs.

Previously, it was observed that a nanosuspension formulation of itraconazole was more efficacious and yet less acutely toxic in rats as compared with the conventional solution formulation, SPORANOX (itraconazole) Injection. The present study compares the two formulations with respect to specifically myocardial contractility in conscious dogs. Motivation for doing so is highlighted by the black-box warning in the package insert for SPORANOX (itraconazole) Injection, which warns of negative inotropic effects. Conscious dogs, instrumented with a high-fidelity pressure transducer in the left ventricle, were placed in a sling for dosing and cardiac monitoring. Test and control articles were administered intravenously via a peripheral vein, and left ventricular parameters were measured continuously through 60 min from the start of dosing. As expected, SPORANOX (itraconazole) Injection caused a significant reduction in myocardial contractility as determined by the contractility index. In contrast, the itraconazole nanosuspension administered at twice the dose and at twice the rate of infusion did not result in significant changes in myocardial contractility. A novel formulation technology applied to itraconazole completely prevented the negative inotropic effect observed in conscious dogs as compared with SPORANOX (itraconazole) Injection.

A rapid assay for icodextrin determination in plasma and dialysate.

Icodextrin is a glucose polymer osmotic agent used to achieve sustained ultrafiltration during long peritoneal dialysis dwells. Previous assays for icodextrin in plasma and dialysate samples involved laborious methods, such as gel permeation chromatography with post-column derivatization of the eluted glucose polymers. We developed and validated a simple and more rapid assay for icodextrin using amyloglucosidase to hydrolyze all glucose polymers to glucose. Glucose was determined pre- and post-hydrolysis using a glucose hexokinase assay, and icodextrin concentration was calculated as the difference between glucose levels before and after hydrolysis. The complete hydrolysis of icodextrin to glucose was confirmed using anion exchange chromatography. Recovery studies using icodextrin powder added to plasma or dialysate showed 100% +/- 15% recovery for plasma concentrations from 10 mg/dL to 800 mg/dL and for dialysate concentrations from 50 mg/dL to 800 mg/dL. The percent relative standard deviation (%RSD) based on multiple replicates was within 6%, except at plasma icodextrin concentrations of 10 mg/dL and below. This simple and reliable assay has been used routinely in our laboratory to analyze thousands of plasma and dialysate samples from patients using Extraneal peritoneal dialysis solution (Baxter Healthcare Corporation, Deerfield, IL, U.S.A.).