In an example of a method for making a pulsatile delivery device, one type of charges are generated on a polymeric layer, and charges opposite the one type of charges are generated on a delivery layer including a film forming material and a predetermined substance dispersed throughout the film forming material. The charged polymeric and delivery layers are placed into contact to form a bi-layer structure. A stack with at least two bi-layer structures is formed so that the polymeric layers and the delivery layers are alternating throughout the stack. The stack is sealed so that one of the polymeric layers remains exposed.

The present invention relates to extended-release suspension composition. The present invention specifically relates to extended-release suspension composition comprising active ingredient and pharmaceutically acceptable excipients, wherein said composition is in the form of powder for suspension or a ready to use suspension. The present invention specifically relates to extended-release suspension composition comprising active ingredient and pharmaceutically acceptable excipients, wherein said composition is devoid of uncoated active ingredient-ion exchange resin complex portion and polyvinyl acetate. The present invention also relates to extended-release suspension composition comprising one or more functional barrier coatings on active ingredient-ion exchange resin complex, wherein said functional barrier coatings comprises hypromellose and/or talc.

Embodiments of the present disclosure generally relate to methods and compositions for controlling cellular expression. More specifically, embodiments described herein relate to hydrogel-encapsulated/dispersed cells, methods of forming hydrogel-encapsulated/dispersed cells, and methods of using hydrogel-encapsulated/dispersed cells for controlling production of, for example, secretomes. In an embodiment, a composition for controlling production of secretomes is provided. The composition includes, a hydrogel comprising, in polymerized form, one or more photoreactive monomers and a thiol linker, wherein at least one of the one or more photoreactive monomers comprises a methylene functional group; and one or more cells dispersed or encapsulated within the hydrogel.

The present invention provides a method of forming a coated hydrogel bead, wherein the hydrogel bead is coated via microfluidics.

This disclosure relates to microcapsule particles for targeted delivery of drugs. In certain embodiments, the particles comprise polyelectrolyte polymers, e.g., layers of anionic polymers and cationic polymers. In certain embodiments, the particles have a fibrinogen coating. In certain embodiments, the particles contain a polysaccharide core and/or a polysaccharide coating encapsulating drugs, proteins, clotting agents, coagulation factors, or anticoagulants. In certain embodiments, this disclosure contemplates methods of using particles disclosed herein to prevent or reduce onset of or duration of bleeding. In certain embodiments, this disclosure contemplates methods of using particles disclosed herein to prevent or reduce onset of blood clotting.

The present disclosure relates to a method of preparing a thin film composite layer immobilizing vesicles incorporating a transmembrane protein on a porous substrate membrane, comprising providing an aqueous solution comprising the vesicles and a di-amine or tri-amine compound, covering the surface of a porous support membrane with the aqueous solution, applying a hydrophobic solution comprising an acyl halide compound, and allowing the aqueous solution and the hydrophobic solution to perform an interfacial polymerization reaction to form the thin film composite layer.

The invention provides oral vaccine formulations which deliver an antigen in the vicinity of the distal ileum and the area of the ileal Brake and/or the appendix. These vaccines are useful in the treatment and/or prevention of variety of disorders, including viral and bacterial infections and cancers. Related methods of treatment which use the oral vaccine formulations of the invention are also provided.

Embodiments disclosed herein relate to magnetic nanoparticles having a non-narcotic analgesic, as well as methods of preparation and use thereof. A magnetically response pharmaceutical can include a core region having magnetic nanoparticles (MNPs) and a protein-based analgesic. Further, an exterior coating comprising a polymer can be formed around the core region. The magnetically responsive pharmaceutical can be administered to a recipient and directed to a target region using an external magnetic field.

The present invention provides a cannulation device for administering an active agent containing composition to the suprachoroidal space or supraciliary space. The invention provides methods of treatment of an ocular disease or condition accordingly. The invention also provides compositions for use in a method of treatment of an ocular disease or condition for delivery into the suprachoroidal space or supraciliary space.

Composite nerve guides for nerve regeneration are provided, wherein the composite guide comprise a nerve graft and a nerve conduit continuing an active agent that promote axon regeneration. The devices can provide structural supports to guide nerve regeneration and locally deliver an active agent (e.g., glial cell-line derived neurotrophic factor (GDNF) and/or glial growth factor 2 (GGF2) to injured nervous system tissue upon implantation in a subject. Methods of treatment using such devices are also provided.