A method includes combining nicotine with a liquid carrier to form a liquid mixture and spray drying the liquid mixture to form a first plurality of particles. The first pluralities of particles are then milled to form a second plurality of particles.

The present disclosure generally relates to a method for reducing the toxicity of inhaled polymyxins as a therapeutic agent comprising the step of co-administration of an aminoglycoside; a method for improving the aerosolization of an aminoglycoside comprising the step of combination formulation with a polymyxin; and a process for manufacturing a dry powder composition comprising a polymyxin and aminoglycoside. Pharmaceutical compositions and methods of treatment for lung infections are within the scope of this invention.

Embodiments described herein relate generally to compounds comprising allyl lactide residues. One aspect described herein relates generally to a compound or a pharmaceutically acceptable salt thereof, comprising allyl lactide residues and lactide residues, wherein the compound or pharmaceutically acceptable salt thereof is substantially free of valerolactone residues. Another aspect relates to a method of incorporating a drug into a compound, comprising: (i) providing a compound or a pharmaceutically acceptable salt thereof, comprising allyl lactide residues and lactide residues, wherein the compound or pharmaceutically acceptable salt thereof is substantially free of valerolactone residues; (ii) incubating the compound and a drug in the presence of a solvent for an incubation period to form a drug-loaded compound; and (iii) separating the drug-loaded compound from the solvent.

The present disclosure relates to a continuous process for impregnating active pharmaceutical ingredients (API) onto porous carriers, including the steps of introducing a porous carrier into a first feeder; continuously directing the porous carrier from the first feeder into a continuous blender, wherein the continuous blender comprises one or more nozzles; continuously introducing a solution comprising an API dissolved in solvent into the continuous blender through the one or more nozzles to form API-impregnated porous carrier; and continuously drying the API-impregnated porous carrier using a fluidized bed dryer to form a powder. The present disclosure also relates to a continuous process for manufacturing pharmaceutical drug products using continuously manufactured API-impregnated porous carriers. The present disclosure also relates to a continuous pharmaceutical drug manufacturing process that includes API-impregnated porous carriers as a raw material.

According to one embodiment of the present invention, granules having a high content of an active ingredient and a high uniformity of particle size are provided. Alternatively, according to one embodiment of the present invention, a preparation containing granules having a high content of an active ingredient and a high uniformity of particle size is provided. According to one embodiment of the present invention, a granule is provided that comprises a nuclear material, a melt component layer arranged on a surface of the nuclear material, and an active ingredient-containing layer arranged on a surface of the melt component layer, wherein the melt component layer contains a first melt component and the active ingredient-containing layer contains an active ingredient and a second melt component or a polymer having compatibility with the first melt component.

Object of the present invention is a drug delivery system comprising a decellularized corneal stroma scaffold having dispersed within and/or bound to its surface microparticles containing at least one pharmaceutically active molecule dispersed in a matrix having a composition consisting for at least 70% of polylactic co-glycolic acid (PLGA).

A process for making multiparticulates, comprising providing a molten feed comprising an active ingredient and an excipient, and providing a spinning disc sprayer comprising a rotating disc having a feed-receiving surface driven from above by a hollow drive shaft, wherein axes of rotation of the hollow drive shaft and rotatable disc are coaxial and a downward end of the hollow drive shaft is disposed with a distributor for regulating flow of the molten feed into the well, the distributor and the well together configured for providing a substantially radial, uniform outward flow of the molten feed across the feed-receiving surface.

The present invention relates to a process for preparing a solid composition comprising at least one active ingredient and at least one excipient comprising: i) mixing said at least one active ingredient and said at least one excipient in a granulator to obtain wet granules; ii) spreading wet granules on a tray and let stand for 2 to 24 hours between 15 and 25° C.; iii) compressing granules obtained after step ii) with a tablet press; and iv) collecting the solid composition. The invention further relates a solid composition obtained by such process.

This invention relates to high drug load compositions of medium chain triglycerides (MCT), and to methods for treatment with such compositions at amounts effective to elevate ketone body concentrations so as to treat conditions associated with reduced neuronal metabolism, for example Alzheimer's disease.

The present disclosure is directed to methods for tuning the release profile of a biologic disposed in a hydrogel. Parameters that can be used for the tuning include a molar ratio of a nucleophilic group to an electrophilic group, the number of the nucleophilic groups in the first precursor, the number of the electrophilic groups in the second precursor, the molecular weight of the first precursor, the molecular weight of the second precursor, a weight ratio of the biologic and excipient to the hydrogel, a weight percentage of the biologic in a solid state formulation, and a ratio of surface area to volume of the hydrogel. The methods described herein allow the formation of hydrogel with different release profiles suitable for different therapeutic applications.