Impact of feed counterion addition and cyclone type on aerodynamic behavior of alginic-atenolol microparticles produced by spray drying

[Display omitted] The inhalatory route has emerged as an interesting non-invasive alternative for drug delivery. This allows both pulmonary (local) and systemic treatments (via alveolar absorption). Further advantages in terms of stability, dose and patient preference have often lead researchers to...

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Bibliographic Details
Published in:European journal of pharmaceutics and biopharmaceutics 2016-12, Vol.109, p.72-80
Main Authors: Ceschan, Nazareth Eliana, Bucalá, Verónica, Ramírez-Rigo, María Verónica, Smyth, Hugh David Charles
Format: Article
Language:English
Subjects:
Administration, Inhalation
Aerosols
Alginates - administration & dosage
Alginates - chemistry
Animals
Antihypertensive Agents - chemistry
Atenolol
Atenolol - administration & dosage
Atenolol - chemistry
Desiccation
Drug Delivery Systems
Dry Powder Inhalers
Freeze Drying
Glucuronic Acid - administration & dosage
Glucuronic Acid - chemistry
Hexuronic Acids - administration & dosage
Hexuronic Acids - chemistry
Humans
Hydrogen-Ion Concentration
In vitro deposition
Inhalatory administration
Ionic interaction
Lactose - chemistry
Lung - drug effects
Microscopy, Electron, Scanning
Microspheres
Particle Size
Powders
Pressure
Spray-drying
Viscosity
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Summary:[Display omitted] The inhalatory route has emerged as an interesting non-invasive alternative for drug delivery. This allows both pulmonary (local) and systemic treatments (via alveolar absorption). Further advantages in terms of stability, dose and patient preference have often lead researchers to focus on dry powder inhaler delivery systems. Atenolol is an antihypertensive drug with low oral bioavailability and gastrointestinal side effects. Because atenolol possesses adequate permeation across human epithelial membranes, it has been proposed as a good candidate for inhalatory administration. In a previous work, atenolol was combined with alginic acid (AA) and microparticles were developed using spray-drying (SD) technology. Different AA/atenolol ratios, total feed solid content and operative variables were previously explored. In order to improve particle quality for inhalatory administration and the SD yield, in this work the AA acid groups not neutralized by atenolol were kept either free or neutralized to pH∼7 and two different SD cyclones were used. Particle morphology, flow properties, moisture uptake and in vitro aerosolization behavior at different pressure drops were studied. When the AA acid groups were neutralized, particle size decreased as a consequence of the lower feed viscosity. The SD yield and in vitro particle deposition significantly increased when a high performance cyclone was employed, and even when lactose carrier particles were not used. Although the in vitro particle deposition decreased when the storage relative humidity increased, the developed SD powders showed adequate characteristics to be administered by inhalatory route up to storage relative humidities of about 60%.
ISSN:0939-6411
1873-3441
DOI:10.1016/j.ejpb.2016.09.020