Described herein are compositions of antibodies and carrier proteins and methods of making and using the same, in particular, as a cancer therapeutic. Also described are lyophilized compositions of antibodies and carrier proteins and methods of making and using the same, in particular, as a cancer therapeutic.

The invention relates to a continuous method for producing inorganic or organic nanoparticles having multiple nuclei functionalised with proteins, using a T-type reactor that operates at high pressure, the primary particles that form the nuclei of the nanoparticles being smaller than 10 nm and said primary particles being immersed in a proteinaceous matrix that forms the nanoparticle in sizes of between 30 nm and 500 nm. The invention also relates to the nanoparticles produced by means of said method.

The invention in suitable embodiments is directed to dynamic bio-nanoparticle elements and bio-nanoparticle platforms employing such bio-nanoparticle elements. In one aspect, one or more elements of one or more types, formed from isolated, synthetic and or recombinant amino acid residues comprising in whole or in part one or more types of Clathrin and or Coatomer I/II proteins of one or more isoforms, execute one or more functions and or effect one or more ends, in vivo and or in vitro.

An oral solid dosage form containing nanoparticles is made by (a) reducing the particle size of at least one pharmaceutically active ingredient dispersed in a solution containing fish gelatin to form a nanosuspension and (b) freeze-drying the nanosuspension of step (a) to form the oral solid dosage form.

The present invention is directed to a nanoparticle including: a core of a metal chelating polymer, wherein the core is coated with at least two layers of magnetic metal oxide, which are further coated with a protein layer, and at least one active agent bound within or to the nanoparticle, methods for directing or targeting the nanoparticle via a magnetic field to a target tissue, and a computer program for efficiently generating the proper magnetic field for driving the nanoparticle to or into a given target tissue.

The present invention relates to prevention and/or treatment of diseases or disorders associated with a damaged or leaky vasculature in a subject. The present invention provides for methods, combinations and pharmaceutical compositions for preventing and/or treating a disease or disorder associated with a damaged or leaky vasculature in a subject, using, inter alia, an effective amount of a nanoparticle comprising an inner core comprising a non-cellular material, an outer surface comprising a cellular membrane derived from a platelet; and optionally an agent for preventing, treating, diagnosing, or prognosing the disease or disorder and/or monitoring prevention or treatment of the disease or disorder. Exemplary diseases or disorders include hemorrhage (bleeding), cardiovascular diseases or disorders, diseases or disorders associated with narrowing of a blood vessel, tumors or cancers.

Described herein are polymeric drug-carrying nanogels that are capable of targeting to P-selectin for the treatment of cancer and other diseases and conditions associated with P-selectin. Furthermore, in certain embodiments, the nanogels presented here offer a drug release mechanism based on acidic pH in the microenvironment of a tumor, thereby providing improved treatment targeting capability and allowing use of lower drug doses, thereby reducing toxicity.

This disclosure relates to nanoparticle drug delivery systems composed of casein (CN) coated nanoparticles, e.g., iron oxide nanoparticles coated with an inner layer and an out layer comprising the milk protein casein. In certain embodiments, drug molecules are incorporated into an inner polymeric layer coating the nanoparticles, which are subsequently coated with a casein containing outer layer, i.e., a layer-by-layer (LBL) construction. Oral administration of these casein coated nanoparticles are contemplated as experiments indicated sufficiently stability in conditions that simulate the conditions of the gut. Drugs that were loaded into the nanoparticle systems were released when the casein outer layer was gradually degraded in the presence of an intestinal protease meant to simulate conditions of the intestine.

Described herein are methods, formulations and kits for treating a patient with cancer with nanoparticle complexes comprising a carrier protein, a binding agent and paclitaxel and optionally co-treated with an anti-PD-L1 antibody.

Disclosed herein are improved compositions and methods involved in treating hematologic cancers, i.e., cancers that begin in blood-forming tissue, such as the bone marrow, or in the cells of the immune system. The compositions comprise complexes containing albumin-containing nanoparticles (e.g., ABRAXANE® nanoparticles) and antibodies. The compositions are used to effect hematologic cancer cell death.