1 H NMR study of the phase behavior of aqueous eutectic solutions using the inverse Laplace transform analysis of T2 relaxation.

High-field 1 H NMR T2 relaxation studies were used to characterize the changes in the physical phases of water, NaCl, and dextrose solutions over a temperature range of -65 to 15 °C. The data were analyzed with the inverse Laplace transform and with a linear fit to the logarithm of the time domain signal. Two liquid phases were detected for the NaCl and dextrose solutions at lower temperatures and assigned to low and high concentrated solution domains. The high concentrated solution domain was found to be present between -30 and -5 °C in the NaCl solution and between -55 and -5 °C in the dextrose solution. Copyright © 2017 John Wiley & Sons, Ltd.

Paclitaxel nanosuspensions for targeted chemotherapy - nanosuspension preparation, characterization, and use.

OBJECTIVE: The purpose of this work was to prepare a stable paclitaxel nanosuspension and test it for potential use as a targeted chemotherapeutic. Different particle coatings were employed to assess their impact on cellular uptake in vitro. In vivo work was then performed to demonstrate efficacy in tumor-bearing mouse models. MATERIALS AND METHOD: Paclitaxel nanosuspensions were prepared using a homogenization process and coated with excipients. Surface charge was measured by zeta potential, potency by high-performance liquid chromatography, and solubility using an in-line UV probe. Cellular uptake studies were performed via flow cytometry. In vivo experiments were performed to determine residence time, maximum tolerated dose, and the efficacy of paclitaxel nanosuspensions (Paclitaxel-NS). RESULTS: A stable paclitaxel nanosuspension was prepared and coated with various excipients. Studies in mice showed that the nanosuspension was well-tolerated and at least as effective as the IV Taxol control in prolonging mouse survival in a head and neck cancer model as well as an ovarian cancer model with a lower overall drug dose than the traditional IV administration route. CONCLUSIONS: The paclitaxel nanosuspension is suitable for cellular uptake. The nanosuspension was effective in prolonging life in two separate xenograft orthotopic murine cancer models through two separate routes of administration.

Anion effects on electrostatic charging of sterically stabilized, water insoluble drug particles.

Water-insoluble suspensions of itraconazole and budesonide were sterically stabilized using nonionic polymers (poloxamer 188 or polysorbate 80) and probed for polymer-anion interactions by measuring changes in particle zeta potential. Anions comprising a range of functionalities and aqueous solubilities were examined. Results showed that the more hydrophobic anions partitioned to the particle interface, and a simple model for predicting anion adsorption was developed from their calculated properties. Anions with a calculated Klopman water solubility less than 10 microM or a calculated log P>3.5 were adsorbed to the particle-polymer interface effectively increasing the overall particle charge. Anions of similar hydrophobicities with sulfonate or sulfate functionalities showed a much higher degree of particle charging compared with their carboxylate and phosphonate analogs at pH 9.5. In addition, the electrostatic charging of particles occurred at lower solution concentrations of sulfonate derivatives. These results suggest that the relative basicity of the oxoanion functionality may influence protonation or ion-pairing phenomena of the anions when adsorbed at the particle-polymer interface. Cetyltetramethylammonium bromide (CTAB) produced a positively charged particle consistent with the model developed for anion adsorption. Particle charging of sterically stabilized drug suspensions appeared largely independent of drug and polymer type. Anion hydrophobicity (solubility) and headgroup functionality dictated the observed charging behavior.

Aerosol based detectors for the investigation of phospholipid hydrolysis in a pharmaceutical suspension formulation.

A high performance liquid chromatography (HPLC) method was developed to quantify free fatty acids (FFA) in a pharmaceutical suspension formulated with phospholipids as stabilizing agents. Specifically, a suspension of crystalline itraconazole microparticles stabilized with Lipoid E80 was used as a model system to study the physicochemical stability of an aqueous, phospholipid-based suspension for injection. The hydrolysis of the phospholipids during storage at elevated temperatures (40 degrees C) necessitated the development of a suitable HPLC method for the determination of free fatty acid content in the suspension samples. HPLC methods using two types of aerosol detectors were investigated for the above purpose. Reversed-phase separation coupled with either an evaporative light scattering detector (ELSD) or a Corona(Plus) charged aerosol detector (CAD) was used. A comparison of the methods indicated that the CAD method provided better sensitivity, precision, recovery, and linearity for the parameters evaluated. As a result, this method was chosen for the stability study of itraconazole suspension and has been incorporated in subsequent formulation studies.