Philippe Begat scite author profile

The aim of the study was to investigate the specific inf luence of force control agents (FCAs) (leucine, lecithin and magnesium stearate) on the interfacial properties of a salbutamol sulphatelactose dry powder inhaler formulation. The inf luence of FCAs on the cohesive and adhesive force balance was directly assessed via an atomic force microscopy (AFM) colloid probe technique, with a recently developed cohesive-adhesive balance (CAB) graphical analysis procedure. Coprocessing of constituent particles was conducted by a novel dry mechanical fusion method (Mechanofusion). The in vitro deposition profile of the model salbutamol sulphate formulations was investigated using a Monohaler ® DPI device with a next generation impactor (NGI) apparatus. The CAB-graph analysis of a salbutamol sulphate-lactose binary system suggested a predisposition for an interactive mixture. However, the reduced intermixing coefficient (F drug-lactose /F drug-drug ) suggested that a significant amount of energy would be required to overcome the strong adhesive interaction for efficient dispersion of the drug from a lactose surface. The processing of lactose with leucine, lecithin or magnesium stearate, prior to formulating with the drug, significantly reduced the adhesive interactions of the salbutamol with modified lactose samples. The CAB analyses indicated that the reduced intermixing coefficients shifted to such an extent that cohesive drug interactions dominated. These dramatic shifts in the balance of forces were shown to lead to poor blend homogeneity and potential for significant segregation between drug and carrier particles. Conversely, the conditioning of salbutamol sulphate with leucine, lecithin and magnesium stearate, which modified both the adhesive and cohesive interactions, formed homogenous interactive blends with advantageously weaker drug-lactose interactions. Formulations with pre-conditioned drug, in contrast to conditioned lactose, offered the best drug delivery performances. The use of the colloid AFM technique in combination with the cohesive-adhesive balance (CAB) approach provided a very accurate means of predicting dry powder formulation behaviour and the specific inf luence of particulate interactions on aerosol performance.

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The Effect of Mechanical Processing on Surface Stability of Pharmaceutical Powders: Visualization by Atomic Force Microscopy

Begat

Young

Edge

et al. 2003

Journal of Pharmaceutical Sciences

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The Role of Force Control Agents in High-Dose Dry Powder Inhaler Formulations

Begat

Morton

Shur

et al. 2009

Journal of Pharmaceutical Sciences

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Philippe Begat

The Cohesive-Adhesive Balances in Dry Powder Inhaler Formulations I: Direct Quantification by Atomic Force Microscopy

The Cohesive-Adhesive Balances in Dry Powder Inhaler Formulations II: Influence on Fine Particle Delivery Characteristics

The Influence of Force Control Agents on the Cohesive-Adhesive Balance in Dry Powder Inhaler Formulations

The Effect of Mechanical Processing on Surface Stability of Pharmaceutical Powders: Visualization by Atomic Force Microscopy

The Role of Force Control Agents in High-Dose Dry Powder Inhaler Formulations

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