An oral dissolving film containing nano- or micro-encapsulated bioactive material and methods of forming the film. The film may be prepared by dispensing a mixture of a film-forming agent, a crosslinking agent, a solution of nano- or micro-encapsulated bioactive material, and a photoinitiator into a plurality of wells in a tray using a 3D printer. The dispensed material is exposed to radiation in order to crosslink the material and form a film.

The present disclosure relates to a composition for the use in the fields of cancer, immunotherapy and biotechnology. Particularly it relates to the field of gellan gum hydrogel-like particles for artificial antigen presentation in immunotherapy.

Methods and compositions that provide an environment that promotes enhanced protein expression and/or folding are provided. More particularly, engineered thermostable ferritin assemblies capable of encapsulating polypeptides, nucleic acids or small molecules, which includes a modified ferritin subunit which lacks an unstructured carboxy-terminal sequence are provided. Methods and compositions for delivery of protein therapeutics are also provided.

The present invention provides pharmaceutical compositions comprising solid nanoparticles, wherein the solid nanoparticles comprise i) an effective amount of a therapeutically active agent, wherein the therapeutically active agent is a substantially water insoluble prodrug; and ii) a biocompatible polymer.

Described herein are methods, formulations and kits for treating a patient with triple-negative breast cancer with nanoparticle complexes comprising a carrier protein (e.g., albumin), paclitaxel and a binding agent specific for a target antigen expressed by the cells (e.g., an anti-VEGF antibody).

The presently-disclosed subject matter relates to compositions of dual layer encapsulated cells, dual layer encapsulated stem cells. The presently-disclosed subject matter further relates to methods for improving retention of cells in vivo at a site of injury.

Disclosed herein, in certain embodiments, are recombinant Arc and endogenous Gag polypeptides, and methods of using recombinant Arc and endogenous Gag polypeptides.

This disclosure provides particles that are suitable for remotely-triggered therapy for cancer and microbial infection. In an embodiment, this disclosure provides a particle heater comprising a carrier admixed with a material that interacts with an exogenous source; wherein the material absorbs and converts the energy from the exogenous source into heat, then the heat travels outside the particle heater to induce localized hyperthermia at a temperature sufficient to selectively kill unwanted cells, and further wherein the particle heater structure is constructed such that it passes the Extractable Cytotoxicity Test.

Disclosed herein are multifunctional nanoparticle compositions. The compositions can be useful for the treatment of cancer by enhancing the anti-tumor effectiveness of radiation directed to a tissue, cell or a tumor and the methods of use thereof. The multifunctional nanoparticle composition comprises a metal oxide nanoparticle core; a functional coating on the surface of the metal oxide nanoparticle core; and a matrix carrier in which the coated nanoparticle is embedded.

Disclosed are nanoparticle compositions comprising nanoparticles prepared from denatured, cross-linked albumin and a therapeutic agent for treating a neutrophil-mediated inflammation, and methods of treating neutrophil-mediated inflammation using the compositions.