Abstract: Compositions containing one or more active agents, one or more bioadhesives elements, and one or more charge masking agents are described herein. In some embodiments, the one or more active agents are biomolecules or macromolecules, such as polysaccharides, proteins, peptides, or nucleic acids, which are charged at physiological pH. The one or more charge masking agents are selected based on the nature of the charge on the active agent. The compositions may also contain one or more controlled release materials, such as extended or sustained release materials or delayed release materials, in order to modify release of the active agent.

Abstract: Diuretic bioactivity profiles of phase inversion micronized furosemide and furosemide co-precipitated with Eudragit L100, and mixtures of those formulations with stock furosemide, reduced or eliminated the rapid spike in diuresis associated with immediate release formulations and maintained cumulative urine output. Of the formulations tested, each of a mixture of micronized furosemide with stock furosemide, and Eudragit L100 polymer with stock furosemide demonstrated optimal diuretic bioactivity profiles in subjects.

Abstract: Nanoparticles, compositions, and methods for the improved uptake of active agents are disclosed herein. The compositions contain a monodisperse population of nanoparticles, preferably including an active agent, where the nanoparticles are formed from a polymeric material possessing specified bioadhesion characteristics. Following enteral administration, preferably oral administration, the nanoparticles exhibit total intestinal uptakes of greater than 20%, preferably greater than 45%, more preferably greater than 65%. When compared to uptake of the same compositon in the absence of the bioadhesive polymeric material, the nanoparticles have significantly increased uptake with intestinal uptake of the increased by more than 100%, preferably even greater than 500%. Further disclosed herein is a method of producing multi-walled nanoparticles, as well as methods of using thereof. Multi-walled particles prepared using the method disclosed herein are useful for controlling the release of active agents.

Abstract: Methods, compositions, systems, devices and kits are provided for preparing and using a multi-layer polymeric microstructure composition for delivering a therapeutic agent to a subject. In various embodiments, the therapeutic agent includes at least one selected from the group of: a drug, a protein, a sugar, a carbohydrate, and a nucleotide sequence. In related embodiments, the composition is a fiber, a suture, a sphere, an implant, or a scaffold.

Abstract: The invention involves methods and products related to the micronization of hydrophobic drugs. A method of micronizing hydrophobic drugs using a set of solutions including an aqueous solution is provided. The invention also relates to products of micronized hydrophobic drugs and related methods of use.

Abstract: The invention relates to the use of one or more growth factors in a drug delivery system, optionally with an external mesh housing, to recruit and optionally harvest progenitor cells. These cells include those that normally reside in the bone marrow.

Abstract: A method of encapsulating a material includes providing a polymer solution including a solvent, and an aqueous solution including a hydrophilic material, mixing the polymer and aqueous solutions, sonicating the mixed solution to obtain a water-in-oil (W/O) emulsion, mixing the water-in-oil emulsion with an oil solution, sonicating the mixed solution to obtain a water-in-oil-in-oil (W/O/O) emulsion, and stirring the water-in-oil-in-oil emulsion in a bath to form a precipitate of encapsulated material and separate the solvent.

Abstract: An effective method for prolonging localization of therapeutics within the rat gastrointestinal tract of at least about 12 hours is provided. The method includes localization of therapeutic agents that are nanoparticulated or nanoencapsulated. Attractive forces between an orally administered magnetic dose and an external magnet were monitored and internal dose motion in real time using biplanar videofluoroscopy was visualized. Tissue elasticity was quantified as a measure of tissue health by combining data streams. The methods address safety, efficacy, and monitoring capacity of magnetically localized doses and show a platform for testing the benefits of localized drug delivery.

Abstract: An effective method for prolonging localization of therapeutics within the rat gastrointestinal tract of at least about 12 hours is provided. Attractive forces between an orally administered magnetic dose and an external magnet were monitored and internal dose motion in real time using biplanar videofluoroscopy was visualized. Tissue elasticity was quantified as a measure of tissue health by combining data streams. The methods address safety, efficacy, and monitoring capacity of magnetically localized doses and show a platform for testing the benefits of localized drug delivery.

Abstract: Diuretic bioactivity profiles of phase inversion micronized furosemide and furosemide co-precipitated with Eudragit L100, and mixtures of those formulations with stock furosemide, reduced or eliminated the rapid spike in diuresis associated with immediate release formulations and maintained cumulative urine output. Of the formulations tested, each of a mixture of micronized furosemide with stock furosemide, and Eudragit L100 polymer with stock furosemide demonstrated optimal diuretic bioactivity profiles in subjects.

Abstract: Nanoparticles, compositions, and methods for the improved uptake of active agents are disclosed herein. The compositions contain a monodisperse population of nanoparticles, preferably including an active agent, where the nanoparticles are formed from a polymeric material possessing specified bioadhesion characteristics. Following enteral administration, preferably oral administration, the nanoparticles exhibit total intestinal uptakes of greater than 20%, preferably greater than 45%, more preferably greater than 65%. When compared to uptake of the same composition in the absence of the bioadhesive polymeric material, the nanoparticles have significantly increased uptake with intestinal uptake of the increased by more than 100%, preferably even greater than 500%. Further disclosed herein is a method of producing multi-walled nanoparticles, as well as methods of using thereof. Multi-walled particles prepared using the method disclosed herein are useful for controlling the release of active agents.

Abstract: The invention involves methods and products related to the micronization of hydrophobic drugs. A method of micronizing hydrophobic drugs using a set of solutions including an aqueous solution is provided. The invention also relates to products of micronized hydrophobic drugs and related methods of use.

Abstract: A process for preparing nanoparticles and microparticles is provided. The process involves forming a mixture of a polymer and a solvent, wherein the solvent is present in a continuous phase and introducing the mixture into an effective amount of a nonsolvent to cause the spontaneous formation of microparticles.

Abstract: Methods to produce polymeric microparticles containing nanoparticles such, as pigments, dyes and other chromophores for cosmetic use, plastic surgery therapeutic use, and tattoos have been developed. The microparticles contain within the polymer a very uniform dispersion of dye particles. The methods by which the particles are made ensure a homogeneous mixture and high loading. The microparticles are made using air, one of a number of known methods such as phase inversion, solvent evaporation, and melt processing. The improvement is in the use of a method that makes, a stable dispersion of the nanoparticles in the liquid polymer before formation of the microparticles.

Abstract: The invention provides tissue marking pigment or dye particle retained within a tissue cell, the cellular cytoplasm, or one or more intracellular organelles. Also, the invention provides nanoparticles, which are phagocytosed, engulfed or otherwise entrapped by cells.

Abstract: The invention relates to the use of one or more growth factors in a drug delivery system, optionally with an external mesh housing, to recruit and optionally harvest progenitor cells. These cells include those that normally reside in the bone marrow.

Abstract: The invention is a cell aggregation device comprising a hydrogel substrate having at least one, preferably a plurality, of cell-repellant compartments recessed into the uppermost surface. Each compartment is composed of an upper cell suspension seeding chamber having an open uppermost portion and a bottom portion, and one, or more than one, lower cell aggregation recess connected to the bottom portion of the upper cell suspension seeding chamber by a port. The diameter of the port may be fully contiguous with the walls of the chambers and walls of the recesses, or the diameter of the port may be more narrow than the walls of the chamber but fully contiguous with the walls of the recesses or more narrow than both the walls of the chamber and the walls of the recesses. The upper cell suspension seeding chambers are formed and positioned to funnel the cells into the lower cell aggregation recesses through gravitational force.

Abstract: Bioadhesives coatings increase the gastrointestinal retention time of orally-ingested medicaments. Certain bioadhesive coatings producing a fracture strength of at least 100 N/m2, as measured on rat intestine, when applied to at least one surface of a pharmaceutical dosage form for oral delivery of a drug, result in a gastrointestinal retention time of at least 4 hours in a fed beagle dog model, during which the drug is released from the dosage form. Multi-layer tablets, particularly those including hydrophobic excipients, are useful in administering hygroscopic and/or deliquescent drugs. In addition, varying the amount of drug in multi-layer tablets allows the release rate of the drug to be controlled.

Abstract: The size and location of microsphere uptake/delivery are important determinants of the final biodistribution of oral microsphere systems. Formulations, kits, methods of administering the formulations, and using the kits are described herein. The formulations are oral dosage formulations. In one embodiment, the formulations contain microparticles and/or nanoparticles having a homogenous size range selected to optimize uptake in a specific region of the GI tract and target drug delivery to specific organs. In some embodiments, the dosage formulation contains an enteric coating and/or a magnetic material. In a preferred embodiment, the formulation contains a magnetic material and an active agent to be delivered, optionally the active agent is in the form of micro- or nano-particles. In some embodiments metallomucoadhesive materials and/or magnetic materials are employed as magnetic and/or mucoadhesive sources.

Abstract: A process is provided for making dry, micronized particles of an agent, such as a drug. The method includes (a) dissolving a macromolecular material, preferably a polymer, in an effective amount of a solvent, to form a solution; (b) dissolving or dispersing the agent in the solution to form a mixture; (c) freezing the mixture; and (d) drying by vacuum the mixture to form solid particles of the agent dispersed in solid macromolecular material. The micronization in this process occurs directly in a macromolecular matrix and hardening of the particles of agent by solvent removal takes place by lyophilization of the bulk matrix, which stabilizes the drug particles during hardening and prevents coalesence, thereby resulting in smaller final drug particles. The method is particularly preferred for protein agents. The process can be used in conjunction with a standard microencapsulation technique, typically following separation of the agent from the macromolecular matrix.