The present invention relates to compositions and methods for delivering an oligonucleotide-functionalized nanoparticle.

The present invention provides an improved process for preparing microparticles containing glatiramer acetate having low levels of residual organic solvent(s), in particular dichloromethane. The microparticles are incorporated into long acting parenteral pharmaceutical compositions in depot form that are suitable for subcutaneous or intramuscular implantation or injection, and that may be used to treat multiple sclerosis.

A magnetic nanoparticle including a TRPV1 agonist, as well as methods of preparation and use, are described herein. A magnetically responsive pharmaceutical can include a core region having a magnetic nanoparticle (MNPs) and a TRPV1 protein agonist. 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.

A self-heating sealant or adhesive may be formed using multi-compartment microcapsules dispersed within a sealant or adhesive. The multi-compartment microcapsules produce heat when subjected to a stimulus (e.g., a compressive force, a magnetic field, or combinations thereof). In some embodiments, the multi-compartment microcapsules have first and second compartments separated by an isolating structure adapted to rupture in response to the stimulus, wherein the first and second compartments contain reactants that come in contact and react to produce heat when the isolating structure ruptures. In some embodiments, the multi-compartment microcapsules are shell-in-shell microcapsules each having an inner shell contained within an outer shell, wherein the inner shell defines the isolating structure and the outer shell does not allow the heat-generating chemistry to escape the microcapsule upon rupture of the inner shell.

The invention pertains to a method of monitoring the membrane permeabilization of a liposome and the incidental release of a compound of interest. The method utilizes liposomes comprising a thermosensitive lipidic membrane encapsulating the product of interest and superparamagnetic nanoparticles having the electrostatic surface charge below 20 mV or above +20 mV when measured in an aqueous medium at physiological pH. In one embodiment, the method comprises the steps of: a) measuring relaxation time (T2*); b) heating the liposome at Tm or above Tm; c) measuring T2* after step b); d) obtaining the transverse relaxivity (r.sub.2*) values from the T2* values obtained from step a) and step c); and e) determining the ratio of r.sub.2* before and after the heating step b). A ratio above 1.5 indicates the liposome membrane permeabilization and the incidental release of the product of interest.

Magnetic drug-loaded polymeric particles are used in a transscleral drug delivery method. In the synthesis process of the aforementioned magnetic drug-loaded polymeric particles, therapeutic agents, along with a magnetic agent are encapsulated in a polymer. The aforementioned magnetic drug-loaded particles can be placed near the outer surface of the sclera, and then a magnetic field can be applied in front of the eye to pull these magnetic drug-loaded particles to the outer surface of the sclera, where these particles adhere to the outer surface of the sclera and thus, the orbital clearance of the particles is eliminated or reduced.

With externally applied magnetic fields, we will concentrate in vivo diamagnetic Bismuth particles or unipolar magnetic particles as a confined locus, then push the locus to move to a tumor, shape it to the tumor, then use near IR to heat the particles so to destroy the tumor by thermal ablation or hyperthermia treatment. We will then cause the locus to move to other tumors, and repeat the process, so to destroy all tumors and cure the cancer.

The present invention provides nanoparticles including a metallic core having a length along each axis of from 1 to 100 nanometers and a coating disposed on at least part of the surface of the metallic core, wherein the coating comprises polydopamine, along with methods for making and using such nanoparticles. The metallic core may be gold, silver or iron oxide and the polydopamine coating may have other substances bound to it, such as silver, targeting ligands or antibodies, or other therapeutic or imaging contrast agents. The disclosed nanoparticles can be targeted to cells for treating cancer or bacterial infections, and for use in diagnostic imaging.

There is provided a method of producing microparticles using an emulsion based synthesis route including: Providing a first fluid phase and a second fluid phase, wherein the first fluid phase is a continuous phase and the second fluid phase is a dispersed phase comprising a dispersed material, wherein the continuous phase is immiscible with the dispersed phase; Mixing the first continuous phase and the second dispersed phase in the presence of a surfactant in a shear device to form an emulsion of droplets of controllable size and having a narrow drop size distribution; Drying the emulsion to form microparticles of controllable size and having narrow size distribution, and wherein the microparticles may comprise spherical, crumpled, dimpled, porous or hollow microparticles morphology. Also provided is a system including shear device and drying arrangement. Also provided are micro particles of controllable size and morphology formed by the method.

The present invention relates to prevention and/or treatment of infection by a platelet-targeting microbe in a subject. The present invention provides for methods, combinations and pharmaceutical compositions for preventing and/or treating (and/or related uses) infection by a platelet-targeting microbe in a subject, using, inter alia, an effective amount of a nanoparticle comprising a) an inner core comprising a non-cellular material, b) an outer surface comprising a cellular membrane derived from a platelet; and optionally c) an agent for preventing said infection, treating said infection, diagnosing said infection, prognosing said infection and/or monitoring prevention or treatment of said infection. Exemplary platelet-targeting infections include infections by a bacterium, a virus, a fungus and/or a parasite.