Disclosed are methods and related compositions for administering a high affinity IL-2 receptor agonist in combination with immunosuppressants. The methods and compositions provided can be used for enhancing regulatory T cells, including antigen-specific regulatory T cells.

A method for producing at least one microneedle containing a vaccine for transdermal delivery of the vaccine to a patient includes preparing microparticles or nanoparticles of encapsulated vaccine by preparing a solution comprising a vaccine antigen and a biocompatible polymer matrix; and spray drying the solution to form the microparticles or nanoparticles. The method includes the further steps of preparing a film composition including at least one pre-polymer solution; preparing a suspension comprising the microparticles or nanoparticles and the film composition; loading the suspension into a 3D printer; printing, via the 3D printer, at least one microneedle made from the suspension; and, converting the pre-polymer solution into a cross-linked biopolymer by exposing the at least one microneedle to UV light. Also disclosed are microneedles containing a vaccine for transdermal delivery.

The invention provides a method for enhancing the delivery of an anti-platelet drug for the treatment of acute stroke, comprising delivering a composition comprising an anti-platelet drug and a vehicle that can reduce the binding rate of plasma proteins, so that the anti-platelet drug can achieve the effect of treating acute stroke at a low dose. By use of the neuro-protective efficacy of anti-platelet drug, the invention allows the drug to release slowly to the site of treatment by combining anti-platelet drugs with a vehicle that can reduce the binding rate of plasma proteins to effectively reduce the dose of the anti-platelet drug and consequently reduce the side effects such as hypotension caused by administration of a high dose of the anti-platelet drugs. The invention also provides a pharmaceutical composition for enhancing treatment of acute stroke and a method for treating acute stroke using the pharmaceutical composition of the invention.

Compositions comprising nanoparticles are described herein. At least a portion of the nanoparticles comprises a lipid and/or polymer which is water-insoluble, and an agent incorporated in the lipid and/or polymer. The nanoparticles are optionally associated with a surface of water-soluble particles which comprise a water-soluble compound. The polymer is optionally a polyanhydride. Further described herein are processes for preparing such compositions, comprising contacting a solution comprising the lipid and/or polymer dissolved in a non-aqueous solvent with an anti-solvent (in which the lipid and/or polymer and agent are insoluble) which is miscible with the non-aqueous solvent. Further described herein are uses of the compositions for nasal administration, and devices configured for nasal administration of the composition upon atomization.

The present invention relates to polymeric nanoparticles comprising a cytokine or a nucleic acid encoding for a cytokine, pharma-ceutical compositions comprising the same, and methods for treating certain diseases comprising administering these polymeric nanoparticles to a subject in need thereof.

Procedures for targeted treatment of kidney fibrosis include administering to a subject in need of treatment of kidney fibrosis a compound including a plurality of nanoparticle including at least one BCL-2/BCL-xl inhibitor; at least one polymer comprising a member selected from the group consisting of PLGA, PEG or PVA; and at least one targeting peptide, wherein each of the plurality of nanoparticles defines a hollow shell formed by the polymer, the at least one BCL-2/BCL-xl inhibitor is located within an interior of the hollow shell, and the at least one targeting peptide is coupled to an exterior surface of the hollow shell.

Described herein are high-boiling-point-based nanoparticles that release drugs specifically at the focus of ultrasound. The specific conjunction of the high-boiling-point-based nanoparticle formulation with low-frequency ultrasound can be used to deliver therapeutics in a safe and effective manner. The effectiveness and safety of the release is validated in vitro and in non-human primates.

A melt processed viral nanoparticle construct for delivery of virus or virus-like particles to a site of interest includes a degradable polymer matrix and a plurality of virus or virus-like particles encapsulated within the degradable polymer matrix. The nanoparticle construct upon administration to the site of interest providing a sustained release of the virus or virus-like particles and/or nanoparticles upon degradation of the polymer matrix.

A drug carrier nanoparticle has been synthesized that can specifically target the proximal tubules of the kidneys. The nanoparticles accumulate in the kidneys to a greater extent than other organs (e.g., up to 3 or more times greater in the kidney than any other organ). They can encapsulate many classes of drug molecules. The nanoparticles are biodegradable and release the drug as they degrade. The particles can sustainably release a drug within the kidneys for up to two months. The nanoparticles are useful for the treatment of diseases that affect the proximal tubules, such as heart failure, liver cirrhosis, hypertension, and renal failure; the study of relative blood flow to the renal cortex and medulla; and delivery of agents to treat gout.

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.