Your search keyword '"Nolan, Lorraine"' showing total 2 results

1. Particle engineering of materials for oral inhalation by dry powder inhalers. II—Sodium cromoglicate

Author

Nolan, Lorraine M., Li, Jianhe, Tajber, Lidia, Corrigan, Owen I., and Healy, Anne Marie

Subjects

*INHALERS, *DRUG design, *PHARMACEUTICAL powders, *RESPIRATORY therapy, *ORAL medicine, *SPRAY drying, *NANOPARTICLES, *POROUS materials

Abstract

Abstract: Sodium cromoglicate is an antiasthmatic and antiallergenic drug used in inhalation therapy and commonly administered by a dry powder inhaler. In the present study we sought to examine the feasibility of producing nanoporous microparticles (NPMPs) of this hydrophilic material by adaptation of a spray drying process previously applied to hydrophobic drugs, and to examine the physicochemical and in vitro deposition properties of the spray dried particles in comparison to a commercial product. The storage stability of successfully prepared NPMPs was assessed under a number of conditions (4°C with dessicant, 25°C at 60% relative humidity and 25°C with dessicant). Spray dried sodium cromoglicate was amorphous in nature. NPMPs of sodium cromoglicate displayed superior aerodynamic properties resulting in improved in vitro drug deposition, as assessed by Andersen Cascade Impactor and twin impinger studies, in comparison to the commercial product, Intal®. Deposition studies indicated that porosity and sphericity were important factors in improving deposition properties. The optimum solvent system for NPMP production was water:methanol:n-butyl acetate, as spherical NPMPs spray dried from this solvent system had a higher respirable fraction than non-spherical NPMPs of sodium cromoglicate (spray dried from methanol:n-butyl acetate), non-porous sodium cromoglicate (spray dried from water) and micronised sodium cromoglicate (Intal®). While particle morphology was altered by storage at high humidity (60% RH) and in vitro deposition performance deteriorated, it was possible to maintain NPMP morphology and aerosolisation performance by storing the powder with dessicant. [ABSTRACT FROM AUTHOR]

Published

2011

2. Excipient-free nanoporous microparticles of budesonide for pulmonary delivery

Author

Nolan, Lorraine M., Tajber, Lidia, McDonald, Bernard F., Barham, Ahmad S., Corrigan, Owen I., and Healy, Anne Marie

Subjects

*EXCIPIENTS, *GLUCOCORTICOIDS, *DRUG delivery systems, *POROUS materials, *NANOPARTICLES, *SPRAY drying, *AMMONIUM carbonate, *AEROSOLS

Abstract

Abstract: The aim of this study was to investigate the application of a spray-drying process for the production of nanoporous microparticles (NPMPs) to budesonide, and to characterise the particles produced in terms of their suitability for pulmonary delivery. Budesonide was spray dried with and without ammonium carbonate from ethanol/water or methanol/water solutions. The solid-state characteristics and micromeritic (particle size, density, surface area) properties of spray dried powders were assessed. In vitro deposition studies were performed to assess aerosol performance. The densities of the NPMPs were significantly lower and the surface areas significantly higher than for non-porous spray dried or micronised material. NPMPs of budesonide demonstrated improved aerosolisation properties compared to spray dried non-porous, micronised material and two budesonide commercial products. All spray dried materials were amorphous in nature. The glass transition temperature (∼90°C) was sufficiently high to suggest good physical stability at room temperature. When stored at 25°C/60% RH NPMPs showed a reduced tendency to recrystallise compared to the equivalent non-porous spray dried powder. The physical stability and amorphous nature of NPMPs was retained, under these storage conditions for at least one year and the in vitro aerosolisation properties were not affected by the storage conditions. Excipient-free porous microparticles, prepared by the novel process described, show good potential for drug delivery by oral inhalation with improved in vitro deposition properties compared to non-porous particles. [Copyright &y& Elsevier]

Published

2009