Abstract: A multi-disk spinning disk assembly for atomization and encapsulation applications. A number of disks 17a and spacers (33, 40) are stacked to form a disk stack 17 having a feed well 31 in the center core of the stack. The fluid to be atomized or encapsulated is delivered to the feed well 31. The fluid then flows into spacer channels (37, 41) within or on the surface of the spacers. The channels (37, 41) communicate the fluid toward the outer edges of the disks 17a. The disk surface past the spacers (33, 40) can have various configurations, such as teeth, weirs, or a bigger or smaller diameter, as desired for particular atomization or encapsulation characteristics.

Abstract: A multi-disk spinning disk assembly for atomization and encapsulation applications. A number of patterned disks are stacked to form a disk stack having a feed well in the center core of the stack. Each patterned disk has channels defined by spacers, with the channels and spacers being of varying depths, heights, and/or widths. The fluid to be atomized or encapsulated is delivered to the feed well. The fluid then flows into the channels, which communicate the fluid toward the outer edges of the disks. The fluid exits the disk stack from a circumferential gap, which is created by interposing spacing disks between the patterned disks.

Abstract: A multi-disk spinning disk assembly for atomization and encapsulation applications. A number of disks 17a and spacers (33, 40) are stacked to form a disk stack 17 having a feed well 31 in the center core of the stack. The fluid to be atomized or encapsulated is delivered to the feed well 31. The fluid then flows into spacer channels (37, 41) within or on the surface of the spacers. The channels (37, 41) communicate the fluid toward the outer edges of the disks 17a. The disk surface past the spacers (33, 40) can have various configurations, such as teeth, weirs, or a bigger or smaller diameter, as desired for particular atomization or encapsulation characteristics.

Abstract: A multi-disk spinning disk assembly for atomization and encapsulation applications. A number of patterned disks are stacked to form a disk stack having a feed well in the center core of the stack. Each patterned disk has channels defined by spacers, with the channels and spacers being of varying depths, heights, and/or widths. The fluid to be atomized or encapsulated is delivered to the feed well. The fluid then flows into the channels, which communicate the fluid toward the outer edges of the disks. The fluid exits the disk stack from a circumferential gap, which is created by interposing spacing disks between the patterned disks.

Abstract: This invention is directed to an apparatus and method for producing microparticles comprising pharmacologically active agents and biodegradable polymers. The apparatus includes a spinning disk containing a reservoir in the center thereof and a flat inclined surface. The apparatus optionally includes serrations and/or a flat surface beneath the periphery of the disk that is parallel to the rotational axis of the disk. The invention is also directed to a method for producing microparticles containing pharmacologically active agents, using the spinning disk apparatus. Formulations containing ophthalmically active agents are provided. Formulations exhibiting zero order release rates are also described.

Abstract: A multi-disk spinning disk assembly for atomization and encapsulation applications. A number of disks 17a and spacers (33, 40) are stacked to form a disk stack 17 having a feed well 31 in the center core of the stack. The fluid to be atomized or encapsulated is delivered to the feed well 31. The fluid then flows into spacer channels (37, 41) within or on the surface of the spacers. The channels (37, 41) communicate the fluid toward the outer edges of the disks 17a. The disk surface past the spacers (33, 40) can have various configurations, such as teeth, weirs, or a bigger or smaller diameter, as desired for particular atomization or encapsulation characteristics.

Abstract: The present disclosure relates to a microcapsule and a method of forming a microcapsule which may be used for oxygen sensitive materials. The microcapsule may comprise a shell encapsulating a core material having a surface, wherein the shell comprises a first organic or inorganic polyelectrolyte providing a plurality of cationic or anionic charges. This may then be followed by forming a first layer comprising an inorganic or organic polyelectrolyte on the microcapsule surface, where the polyelectrolyte of the first layer provides a plurality of cationic or anionic charges, opposite to the charge of the shell polyelectrolyte. This may then be followed by forming a second layer comprising a second organic or inorganic polyelectrolyte providing a plurality of cationic or anionic charges, opposite to the charge of the first layer polyelectrolyte.

Abstract: The present disclosure relates to a microcapsule and a method of forming a microcapsule which may be used for oxygen sensitive materials. The microcapsule may comprise a shell encapsulating a core material having a surface, wherein the shell comprises a first organic or inorganic polyelectrolyte providing a plurality of cationic or anionic charges. This may then be followed by forming a first layer comprising an inorganic or organic polyelectrolyte on the microcapsule surface, where the polyelectrolyte of the first layer provides a plurality of cationic or anionic charges, opposite to the charge of the shell polyelectrolyte. This may then be followed by forming a second layer comprising a second organic or inorganic polyelectrolyte providing a plurality of cationic or anionic charges, opposite to the charge of the first layer polyelectrolyte.

Abstract: A barrier coating composition includes a polymer material and a structuring agent dispersed in said polymer material, wherein the structuring agent decreases oxygen or water permeability through the polymer material. The barrier coating composition can be used to coat a core component, which can be oxygen or water sensitive, to form a microencapsulated material. The microencapsulated material can be formed by microencapsulation methods, which include atomization or coacervation methods, including forming an oil emulsion of an oil phase and an aqueous phase, the oil phase including the core component and the aqueous phase including the polymer material, adding the structuring agent to one of the oil phase and the aqueous phase, mixing the oil emulsion to form desired particle sizes of the core component, forming the shell component around the core component to form the microencapsulated material, and extracting the formed microencapsulated material from the oil emulsion.

Abstract: This invention is directed to an apparatus and method for producing microparticles comprising pharmacologically active agents and biodegradable polymers. The apparatus includes a spinning disk containing a reservoir in the center thereof and a flat inclined surface. The apparatus optionally includes serrations and/or a flat surface beneath the periphery of the disk that is parallel to the rotational axis of the disk. The invention is also directed to a method for producing microparticles containing pharmacologically active agents, using the spinning disk apparatus. Formulations containing ophthalmically active agents are provided. Formulations exhibiting zero order release rates are also described.

Abstract: This invention is directed to an apparatus and method for producing microparticles comprising pharmacologically active agents and biodegradable polymers. The apparatus includes a spinning disk containing a reservoir in the center thereof and a flat inclined surface. The apparatus optionally includes serrations and/or a flat surface beneath the periphery of the disk that is parallel to the rotational axis of the disk. The invention is also directed to a method for producing microparticles containing pharmacologically active agents, using the spinning disk apparatus. Formulations containing ophthalmically active agents are provided. Formulations exhibiting zero order release rates are also described.

Abstract: A composite for retarding microbiological contamination containing a hydrophobic material containing an acid releasing agent, and a hydrophilic material containing anions that are capable of reacting with hydronium ions to generate a gas. The hydrophilic and hydrophobic materials are adjacent and substantially free of water, and the hydrophilic material is capable of generating and releasing the gas after hydrolysis of the acid releasing agent.

Abstract: A biocidal powder for sustained release of chlorine dioxide includes particles containing chlorite anions, and a hydrophobic core having the particles on a surface thereof, the hydrophobic core containing an acid releasing agent. The particles and the hydrophobic core are substantially free of water, and the particles are capable of releasing chlorine dioxide upon hydrolysis of the acid releasing agent.

Abstract: A biocidal powder for sustained release of chlorine dioxide includes particles containing chlorite anions, and a hydrophobic core having the particles on a surface thereof, the hydrophobic core containing an acid releasing agent. The particles and the hydrophobic core are substantially free of water, and the particles are capable of releasing chlorine dioxide upon hydrolysis of the acid releasing agent.

Abstract: A novel plastic composition and method for making the same comprising a host polymer having substantially uniformly distributed therethrough a non-miscible liquid crystal polymer and red amorphous phosphorus. The liquid crystal polymer is present in a concentration sufficient to encapsulate said red amorphous phosphorus such that a substantial portion of the red amorphous phosphorus does not contact the host polymer.

Abstract: Encapsulated corn kernels consisting essentially of kernels of corn suitable for popping coated over at least a portion of the outer surface thereof with an edible oleaginous substance or edible wax and thereover with an outer shell comprising an edible polymeric material and an anti-fragility and palatability enhancer; the process of making such encapsulated kernel; and microwaveable pop corn products consisting essentially of the encapsulated corn kernels in a microwaveable package.

Abstract: Encapsulated corn kernels consisting essentially of a kernels of corn suitable for popping coated over at least a portion of the outer surface thereof with an edible oleaginous substance or edible wax and thereover with an outer shell of an edible polymer. The process of making such encapsulated kernel; and microwaveable corn products consisting essentially of the encapsulated corn kernels in a microwaveable package.