The present technology is directed to composition that may be formulated for parenteral administration, where the position includes a plurality of nanoparticles and optionally a pharmaceutically acceptable carrier. Each nanoparticle of the plurality includes a glatiramoid and one or more of a polyinosine-polycytidylic acid (Poly(LC)), a plasmid DNA (pDNA), a CpG oligodeoxynucleotide (CpG ODN), or a combination of any two or more thereof.

Nanoparticles can be useful for delivering therapeutic agents, such as anticancer agents to diseased cells. The nanoparticles include a carrier polypeptide and a cargo, which can be bind through electrostatic interactions to form a nanoparticle composition. An exemplary composition comprises nanoparticles comprising a carrier polypeptide comprising a penton base segment and a binding segment: and a polypeptide cargo comprising a tag segment that binds to the binding segment of the carrier poly peptide through an electrostatic interaction. An exemplary carrier polypeptide comprises a person base segment and a negatively-charged binding segment, which can bind to a positively charged cargo. The carrier polypeptide can also include a cell-targeting segment which can target the nanoparticle to a cell. Compositions comprising nanoparticles can be administered to a subject for the treatment of disease, such as cancer.

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 (-amino acid)-,-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.

Particulate constructs stabilized by amphiphilic copolymers and comprising at least one active coupled to a hydrophobic moiety provide sustained release of the active in both in vitro and in vivo environments.

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.

Disclosed herein are compositions comprising nanoparticle complexes comprising albumin-bound paclitaxel and an anti-VEGF antibody, wherein the ratio of albumin-paclitaxel to antibody is between 2:1 and 1:25. Additionally disclosed herein are methods using the compositions of the present invention, such as for treating a VEGF-expressing cancer in a mammal, for example, skin cancer.

Blood-brain barrier permeable peptide compositions that contain variable antigen binding domains from camelid and/or shark heavy-chain only single-domain antibodies are described. The variable antigen binding domains of the peptide compositions bind to therapeutic and diagnostic biomarkers in the central nervous system, such as the amyloid-beta peptide biomarker for Alzheimer's disease. The peptide compositions contain constant domains from human IgG, camelid IgG, and/or shark IgNAR. The peptide compositions include heavy-chain only single-domain antibodies and compositions with one or more variable antigen binding domain bound to one or more constant domains.

Alcohol intoxication causes serious diseases, whereas current treatments are mostly supportive and unable to remove alcohol efficiently. Upon alcohol consumption, alcohol is sequentially oxidized to acetaldehyde and acetate by the endogenous alcohol dehydrogenase and aldehyde dehydrogenase, respectively. We disclose a hepatocyte-mimicking antidote for alcohol intoxication through the co-delivery of the nanocapsules of alcohol oxidase (AOx), catalase (CAT), and aldehyde dehydrogenase (ALDH) to the liver, where AOx and CAT catalyze the oxidation of alcohol to acetaldehyde, while ALDH catalyzes the oxidation of acetaldehyde to acetate. Administered to alcohol-intoxicated mice, the antidote rapidly accumulates in the liver and enables a significant reduction of the blood alcohol concentration. Moreover, blood acetaldehyde concentration is maintained at an extremely low level, significantly contributing to liver protection. Such an antidote, which can eliminate alcohol and acetaldehyde simultaneously, holds great promise for the treatment of alcohol intoxication and poisoning.

The invention relates to methods of targeted drug delivery of antiviral compounds, including, chemical agents (like nucleoside analogs or protease inhibitors) and nucleic acid based drugs (like DNA vaccines, antisense oligonucleotides, ribozymes, catalytic DNA (DNAzymes) or RNA molecules, siRNAs or plasmids encoding thereof). Furthermore, the invention relates to targeted drug delivery of antiviral compounds to intracellular target sites within cells, tissues and organs, in particular to target sites within the central nervous system (CNS), into and across the blood-brain barrier, by targeting to internalizing uptake receptors present on these cells, tissues and organs. Thereto, the antiviral compounds, or the pharmaceutical acceptable carrier thereof, are conjugated to ligands that facilitate the specific binding to and internalization by these receptors.

The present invention relates to compositions comprising B-cell maturation antigen-directed nanoparticles and methods for using the same.