SCF - Engineered powders for delivery of budesonide from passive DPI devices

York, Peter, Lobo, J.M., Palakodaty, S., Schiavone, H., Clark, A., Tzannis, S.T.

January 2005

No / The objective of this study was to develop SEDS-engineered budesonide particles suitable for dry powder inhalation delivery and to evaluate their aerosol performance across a range of passive dry powder inhalers (DPI). SEDS budesonide powders were manufactured in Nektar's SCF manufacturing plant and compared to the micronized drug and commercial powder (Pulmicort Turbuhaler, AstraZeneca). Aerosol performance was evaluated by determining emitted dose (ED) by a variation of the USP method and fine particle fraction (FPF) using Andersen cascade impaction. The SCF powder dispersed best in the Turbospin and Eclipse devices, exhibiting high EDs (70%-80%) and relatively low variability (RSD 8%-13%). Regardless of the device, the SEDS material outperformed both the micronized drug and the commercial powder, while exhibiting good batch-to-batch reproducibility (RSD <5%). All powders exhibited flow rate-dependent ED, albeit for the SEDS material it was minimized at reduced fill weights. This was attributed to inadequate and variable powder clearance from the capsules at low inspiratory flow rates, which was more pronounced in the Eclipse and Cyclohaler. The results demonstrate that SEDS is an attractive particle-engineering process that may enhance pulmonary performance of budesonide and possibly facilitate development of other small molecule pulmonary products in passive DPI.

Delivery system

Corticosteroid

Antiinflammatory agent

Pharmaceutical technology

Inhaler

Intrapulmonary administration

Particle

Budesonide

Powder

High Performance Liquid Chromatography Assay Method for Simultaneous Quantitation of Formoterol and Budesonide in Symbicort Turbuhaler

Assi, Khaled H., Chrystyn, Henry, Tarsin, W.

January 2006

No / A sensitive and rapid high performance liquid chromatography method has been developed and used for the simultaneous determination of formoterol and budesonide in Symbicort Turbuhaler when assessing the aerodynamic characteristics of the emitted dose using Pharmacopoeial methods. This capability results in both time and cost saving. The mobile phase composition was acetonitrile-5 mM sodium dihydrogen orthophosphate, pH 3 (60: 40% v/v), and was passed at 1.5 ml min-1 through a C18 column with a UV detection (wavelength 214 nm). The method was shown to give good analytical performance in terms of linearity, precision (using phenylpropanolamine as an internal standard), sensitivity and solution stability. The intra-day precision for both formoterol and budesonide were 0.75% and 1.11%, respectively (n = 10). The limit of quantitation for formoterol was 10 ¿g L-1 and for budesonide was 120 ¿g L-1, and the limit of detection were 3 and 30 ¿g L-1, for both formoterol and budesonide, respectively. The method has been applied to determine the content of the emitted dose and the fine particle dose of Symbicort Turbuhaler.

Simultaneous measurement

HPLC chromatography

Corticosteroid

ß-Adrenergic receptor agonist

ß2-Adrenergic receptor

Agonist

Antiinflammatory agent

Bronchodilator

Antiasthma agent

Budesonide

Formoterol