Abstract: Extended-release microsphere formulations comprising lurasidone are provided. In one aspect, the microsphere formulations are characterized in that the lurasidone is released in vivo in humans over a period of about 30 days. Methods for making and using the formulations are also provided.

Abstract: Extended-release injectable microsphere formulations comprising ketamine are provided. Methods for making and using the microsphere formulations are also provided.

Abstract: Various examples of systems and methods for making microspheres, microparticles, and emulsions are provided. In one example, a system and method for forming microspheres comprises: pumping a dispersed phase liquid and a continuous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase liquid and continuous phase liquid to a high shear environment within the impeller pump's pump chamber. In another example, a system and method for forming an emulsion comprises: pumping a dispersed phase liquid and an inner aqueous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase and the inner aqueous phase to a high shear environment within the impeller pump's pump chamber.

Abstract: Various examples of systems and methods for making microspheres, microparticles, and emulsions are provided. In one example, a system and method for forming microspheres comprises: pumping a dispersed phase liquid and a continuous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase liquid and continuous phase liquid to a high shear environment within the impeller pump's pump chamber. In another example, a system and method for forming an emulsion comprises: pumping a dispersed phase liquid and an inner aqueous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase and the inner aqueous phase to a high shear environment within the impeller pump's pump chamber.

Abstract: Various examples of systems and methods for making microspheres, microparticles, and emulsions are provided. In one example, a system and method for forming microspheres comprises: pumping a dispersed phase liquid and a continuous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase liquid and continuous phase liquid to a high shear environment within the impeller pump's pump chamber. In another example, a system and method for forming an emulsion comprises: pumping a dispersed phase liquid and an inner aqueous phase liquid into a levitating magnetic impeller pump to subject the dispersed phase and the inner aqueous phase to a high shear environment within the impeller pump's pump chamber.

Abstract: Polymer and drug containing compositions and method of preparing such compositions are disclosed. The dispersed phase formulation has a polymer, a pharmaceutically or biologically active agent and a small fraction of low pKa acid additive. Stable, filter sterilizable, non-gelling solutions containing GnRH analogues at least at levels typically used in sustained release formulations and a method of increasing solubility of a high level of a GnRH analogue or a freeze-dried antgonist of GnRH in a polymer containing solution are also disclosed. The amount of the acid additive in the polymer solution is such that it is sufficient to increase the solubility of the high level of the GnRH analogue in the polymer solution without affecting the release characteristics of the microspheres prepared therefrom.

Abstract: Various embodiments of a method of preparing sustained release microparticles are described. In one embodiment, the method includes the steps of forming a dispersed phase of an active agent in a polymer and combining the dispersed phase with a continuous phase to form a microparticle dispersion. The method further includes the step of adding a measured amount of a dilution composition to the microparticle dispersion. It has been found herein that the various embodiments for preparing sustained release microparticles using various amounts of the dilution composition alters the release rate of the sustained microparticle for the specific active agent.

Abstract: A method of making a sustained release microsphere formulation, wherein the release rate of a bioactive ingredient is manipulated by controlling the crystallinity of said bioactive ingredient, includes the steps of combining the active ingredient and an encapsulating polymer in at least one solvent, or mixtures thereof, to form a dispersed phase and processing the dispersed phase without filtering, filtering the combined dispersed phase with a hydrophobic or a hydrophilic filter, or filtering the active ingredient and encapsulating polymer individually with a hydrophobic or hydrophilic filter before combining them to form the dispersed phase. The dispersed phase is then combined with a continuous phase to form the microsphere formulation.

Abstract: A sustained release microsphere formulation with a high drug load may be formed by a continuous oil-in-water emulsion process by combining an organic dispersed phase with an aqueous continuous phase. The dispersed phase may include an encapsulating polymer, a primary solvent, such as dichloromethane, a pharmaceutically effective amount of an active agent having a solubility relative to the dispersed phase, and a co-solvent, such as benzyl alcohol, which is capable of increasing the solubility of the active agent relative to the dispersed phase. The continuous phase may include an aqueous solution of polyvinyl alcohol and water.

Abstract: A sustained release microsphere formulation with a high drug load may be formed by a continuous oil-in-water emulsion process by combining an organic dispersed phase with an aqueous continuous phase. The dispersed phase may include an encapsulating polymer, a primary solvent, such as dichloromethane, a pharmaceutically effective amount of an active agent having a solubility relative to the dispersed phase, and a co-solvent, such as benzyl alcohol, which is capable of increasing the solubility of the active agent relative to the dispersed phase. The continuous phase may include an aqueous solution of polyvinyl alcohol and water.

Abstract: The invention relates to compositions suitable for the delivery and/or stabilization of biologically active substances. The compositions comprise a sublimable matrix material and the biologically active agent to be delivered. The compositions can be used as drug delivery systems to treat a wide variety of diseases or as systems for the protection and stabilization of such substances. Also disclosed are methods for preparing compositions of the present invention.

Abstract: Polymer and drug containing compositions and method of preparing such compositions are disclosed. The dispersed phase formulation has a polymer, a pharmaceutically or biologically active agent and a small fraction of low pKa acid additive. Stable, filter sterilizable, non-gelling solutions containing GnRH analogs at least at levels typically used in sustained release formulations and a method of increasing solubility of a high level of a GnRH analog or a freeze-dried antgonist of GnRH in a polymer containing solution are also disclosed. The amount of the acid additive in the polymer solution is such that it is sufficient to increase the solubility of the high level of the GnRH analog in the polymer solution without affecting the release characteristics of the microspheres prepared therefrom.

Abstract: The invention relates to compositions suitable for the delivery and/or stabilization of biologically active substances. The compositions comprise a sublimable matrix material and the biologically active agent to be delivered. The compositions can be used as drug delivery systems to treat a wide variety of diseases or as systems for the protection and stabilization of such substances. Also disclosed are methods for preparing compositions of the present invention.

Abstract: This disclosure features a system for processing microspheres. A vessel contains a suspension of solidified microspheres comprising polymer and an active agent. A hydrocyclone has a fluid inlet, a first fluid outlet and a second fluid outlet. The fluid inlet is in fluid communication with the vessel and receives the suspension. The second fluid outlet contains a flow of the suspension having concentrated microspheres. The first fluid outlet contains a flow of a relatively large amount of liquid compared to the flow from the second fluid outlet. Also featured is a method of processing the microspheres using the hydrocyclone.

Abstract: Polymer and drug containing compositions and method of preparing such compositions are disclosed. The dispersed phase formulation has a polymer, a pharmaceutically or biologically active agent and a small fraction of low pKa acid additive. Stable, filter sterilizable, non-gelling solutions containing GnRH analogues at least at levels typically used in sustained release formulations and a method of increasing solubility of a high level of a GnRH analogue or a freeze-dried antgonist of GnRH in a polymer containing solution are also disclosed. The amount of the acid additive in the polymer solution is such that it is sufficient to increase the solubility of the high level of the GnRH analogue in the polymer solution without affecting the release characteristics of the microspheres prepared therefrom.

Abstract: Polymer and drug containing compositions and method of preparing such compositions are disclosed. The dispersed phase formulation has a polymer, a pharmaceutically or biologically active agent and a small fraction of low pKa acid additive. Stable, filter sterilizable, non-gelling solutions containing GnRH analogues at least at levels typically used in sustained release formulations and a method of increasing solubility of a high level of a GnRH analogue or a freeze-dried antagonist of GnRH in a polymer containing solution are also disclosed. The amount of the acid additive in the polymer solution is such that it is sufficient to increase the solubility of the high level of the GnRH analogue in the polymer solution without affecting the release characteristics of the microspheres prepared therefrom.

Abstract: Antagonistic peptides of GnRH having improved water solubility are disclosed. These peptides are capable of suppressing serum testosterone levels in vivo to chemical castration levels of ?0.5 ng/ml. Stable, filter sterilizable, non-gelling solutions containing the GnRH antagonists at least at levels typically used in sustained release formulations also are disclosed, as is a method of increasing the solubility of GnRH antagonist in a polymer containing dispersed phase, which method comprises addition of an acid to the dispersed phase.

Abstract: This disclosure features a system for processing microspheres. A vessel contains a suspension of solidified microspheres comprising polymer and an active agent. A hydrocyclone has a fluid inlet, a first fluid outlet and a second fluid outlet. The fluid inlet is in fluid communication with the vessel and receives the suspension. The second fluid outlet contains a flow of the suspension having concentrated microspheres. The first fluid outlet contains a flow of a relatively large amount of liquid compared to the flow from the second fluid outlet. Also featured is a method of processing the microspheres using the hydrocyclone.

Abstract: This disclosure features microspheres and a method of making them. The microspheres are for sustained release of an octreotide compound with a low initial burst, comprising a poly(D,L-lactide-co-glycolide) polymer matrix and an octreotide compound dispersed in the polymer matrix. The microspheres release less than 1% of a total amount of the octreotide compound within 1 hour at 37° C. and pH 7.4.

Abstract: Various embodiments of a method of preparing sustained release microparticles are described. In one embodiment, the method includes the steps of forming a dispersed phase of an active agent in a polymer and combining the dispersed phase with a continuous phase to form a microparticle dispersion. The method further includes the step of adding a measured amount of a dilution composition to the microparticle dispersion. It has been found herein that the various embodiments for preparing sustained release microparticles using various amounts of the dilution composition alters the release rate of the sustained microparticle for the specific active agent.