This invention provides methods for producing a polymer particle which contains unusually high negative charges on the surface of the particle. Preferably, the polymer is pharmaceutically acceptable. The negative charges can be conferred by chemical groups such as carboxyl, sulfonate, nitrate, fluorate, chloride, iodide, persulfate, and many others, with carboxyl group being preferred. The invention also provides polymer particle produced by the methods of the invention.

This invention provides methods for producing a polymer particle which contains unusually high negative charges on the surface of the particle. Preferably, the polymer is pharmaceutically acceptable. The negative charges can be conferred by chemical groups such as carboxyl, sulfonate, nitrate, fluorate, chloride, iodide, persulfate, and many others, with carboxyl group being preferred. The invention also provides polymer particle produced by the methods of the invention.

Disclosed herein are methods for modulating an amount or activity of a gene or a gene product in a cell. The methods herein may comprise contacting a cell with a therapeutic agent assembled with a lipid composition, which lipid composition may comprise a dendrimer or dendron which may comprise one or more degradable diacyl group, in which may result in modulating the amount or activity of the gene or the gene product in the cell. The therapeutic agent modulating a gene or gene product in a cell may be sufficient to treat a disease or disorder in a subject. Further disclosed herein are pharmaceutical compositions, kits, and lipid compositions for modulating an amount or activity of a gene or a gene product in a cell.

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 present invention relates to a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body for magnetic resonance imaging and magnetic thermotherapy. According to the present invention, a superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body which has target directionality and a high density of ultrafine gold nanoparticles uniformly coupled to the surface of protein nanoparticles can be fabricated with neither a separate surface stabilization process nor a separate target directionality conferring process. Hence, the superparamagnetic gold nanoparticle cluster-protein nanoparticle fusion body according to the present invention is superior to conventional gold nanoparticles in terms of biocompatibility and has excellent target directionality as well as being identified to have a temperature elevation potential in an alternating magnetic field and a functionality as a T2-MRI contrast medium thanks to the superparamagnetism property of the ultrafine gold nanoparticles.

The present invention relates, inter alia, to certain anti-M(H)DM2/4 antibodies (including chimeric and humanized antibodies) or antigen-binding fragments thereof, pharmaceutical compositions comprising anti-M(H)DM2/4 antibodies or antigen-binding fragments thereof, antibody-drug conjugates comprising anti-M(H)DM2/4 antibodies or antigen-binding fragments thereof bound to a cytotoxic drug, and the use of such antibodies, fragments, compositions and conjugates for treating cancer and/or for preventing metastases. For example, described herein are certain antibodies (including chimeric and humanized antibodies) or antigen-binding fragments thereof that specifically bind to extracellularly accessible epitopes of M(H)DM2/4 and inhibit tumor growth in vivo, pharmaceutical compositions comprising such antibodies or fragments, antibody-drug conjugates comprising such antibodies or fragments, and the use of such antibodies, fragments, compositions and conjugates for treating cancer or for preventing metastasis.

Compositions and methods for treating traumatic brain injury (TBI) are presented. Novel dendriplexes are formed from poly(amidoamine) (PAMAM) dendrimers complexed with shRNA encoding DNA plasmids encapsulating shRNA encoding chemokine ligand 20 (CCL20) gene, chemokine receptor 6 (CCR6) gene, or a combination thereof. The dendriplexes are dually administered, both intranasally and intravenously, prior to administration of stem cells, such as human mesenchymal stem cells (hMSCs) for the treatment of traumatic brain injury (TBI). Administration of the dendriplexes prior to stem cell administration resulted in a decrease in neurodegeneration, neuroinflammation, microgliosis and astrogliosis. In addition, a synergistic increase in brain derived trophic factor (BDNF) was shown by administration of the combination of dendriplex and stem cell administration.

The present invention discloses a method for synthesizing a new ferrihydrite nano-photosensitizer, comprising steps of: weighing 303 mg of Fe(NO.sub.3).sub.3.9H.sub.2O solid dissolved fully in 30 ml of distilled water to prepare a 0.75 mM of Fe(NO3)3 solution in water; adding PEG solid to the solution in water by stirring to fully dissolve at a molar ratio of PEG to Fe.sup.3+ of 1:1-1:50; stirring the obtained solution under heating at 75° C. in a water bath for 10-50 minutes, and then immediately cooling in an ice bath after removing; centrifuging and washing the cooled mixed solution at high speed under low temperature with the supernatant discarded, to obtain pellets as PEG-modified ferrihydrite nanoparticles (PEG-Fns). The PEG-Fns synthesized in the present invention can be controllably induced and reduced by blue light to release Fe.sup.2+, and then produce ⋅OH through Fenton reaction of Fe.sup.2+ and H.sub.2O.sub.2 in the cell, which induces cell oxidative damage, thereby achieving controllable anticancer and antibacterial purposes.

Cationic polymers are provided for delivering anionic active agents, preferably in the form or nanoparticles and other nanostructures. The polymer can be a polycation homopolymer or a copolymer containing a polycation block. The polycations and polycation containing polymers can contain dicarboxylic acid ester units and units of (α-amino acid)-α,ω-alkylene diester units. The nanoparticles can contain high loadings of anionic active agents, with sustained release of the active agents. Methods of making the polycations and polycation containing polymers are provided. Methods of making the nanoparticles and formulating them for administration to an individual in need thereof are also provided.

A protein nanocage formulation with enhanced mucus penetration capability and colloidal stability provides controlled delivery of therapeutic, prophylactic, or diagnostic agents to tumors. A dense coating of a surface altering agent such as polyethylene glycol on self-assembled protein nanocages enhances the rapid and uniform distribution of the formulation at mucosal tissues following topical administration, enhances circulation time following intravenous administration, and enhances penetration into hypoxic tumor cores. The density and the molecular weight of surface altering agents are selected to allow the protein nanocages to also bind to tumor cell receptors and release chemotherapeutic agents after tumor cell uptake. Agents delivered in the formulation have better efficacy compared to carrier-free agents. A method of making the protein nanocage formulation with enhanced mucus penetration and colloidal stability is also provided.