Evaluation of the Physico-mechanical Properties and Electrostatic Charging Behavior of Different Capsule Types for Inhalation Under Distinct Environmental Conditions.

Capsule-based dry powder inhaler (DPI) products can be influenced by a multitude of interacting factors, including electrostatic charging. Tribo-charging is a process of charge transfer impacted by various factors, i.e., material surface characteristics, mechanical properties, processing parameters and environmental conditions. Consequently, this work aimed to assess how the charging behavior of capsules intended for inhalation might be influenced by environmental conditions. Capsules having different chemical compositions (gelatin and hydroxypropyl methylcellulose (HPMC)) and distinct inherent characteristics from manufacturing (thermally and cold-gelled) were exposed to various environmental conditions (11%, 22% and 51% RH). Their resulting properties were characterized and tribo-charging behavior was measured against stainless steel and PVC. It was observed that all capsule materials tended to charge to a higher extent when in contact with PVC. The tribo-charging of the thermally gelled HPMC capsules (Vcaps® Plus) was more similar to the gelatin capsules (Quali-G™-I) than to their HPMC cold-gelled counterparts (Quali-V®-I). The sorption of water by the capsules at different relative humidities notably impacted their properties and tribo-charging behavior. Different interactions between the tested materials and water molecules were identified and are proposed to be the driver of distinct charging behaviors. Finally, we showed that depending on the capsule types, distinct environmental conditions are necessary to mitigate charging and assure optimal behavior of the capsules.

A new deferiprone controlled release system obtained by ultrasound-assisted compression.

OBJECTIVES: This study implements the design of an innovative dosage form using ultrasound-assisted compression of thermoplastic polymers and the development of controlled release tablets for the oral administration of deferiprone in two doses per day. METHODS: Binary matrix tablets containing deferiprone and thermoplastic polymers have been prepared using an ultrasound-assisted tableting machine. Scanning electron microscopy has been employed to determine a sintering phenomenon of the excipients. Water uptake and drug release studies have been carried out to evaluate the ability of the polymers to control the drug release. RESULTS: SEM micrographs showed that some polymers underwent the sintering process and the in vitro dissolution test showed good fit of the release data from these tablets to the zero-order kinetic model. CONCLUSIONS: Carbopol 974P and 971P have been selected as matrix forming polymers for the final formulation. The polymer percolation threshold has been exceeded with 15% w/w of polymer. Therefore, sustained release tablets have been developed with only 15% of excipient. This implies that matrix tablets containing 750 mg of API, intended for two administrations a day, can be obtained with a similar weight to those existing in the market containing 500 mg of API for three administrations a day.