Described herein is a nanoparticle system including a multivalent nanoparticle core having a plurality of β-hairpin peptides conjugated thereto. Also included are pharmaceutical compositions and methods of making the nanoparticle system. Further included are immunotherapy methods including administering the nanoparticle system to a subject in need thereof, such as a human cancer patient.

A testicular function-improving agent which contains microparticles derived from a culture supernatant of dental pulp-derived stem cells, adipose-derived stem cells or immortalized stem cells thereof and in which the improvement of a testicular function is improvement of the ability of a testis itself to form sperm, improvement of the function of sperm themselves obtained from a testis, improvement of the function of sperm obtained from a testis of acting on a female, rejuvenation of any of the functions that has aged with aging or activation of sperm through addition to semen taken out of the body of an animal can significantly improve a testicular function of an animal.

Compositions are provided according to aspects of the present invention that include a hydrogel and a liner, wherein a surface of the hydrogel dissociably-engages a surface of the liner. Compositions are provided according to aspects of the present invention that include a hydrogel and a hydrophobic glue, wherein at least a portion of the gel network of the hydrogel is occupied by the hydrophobic glue. Reverse coaling processes and articles of manufacture made by reverse coating processes are provided according to aspects of the present invention. Compositions are provided according to aspects of the present invention that include a hydrogel and a substrate, wherein: the hydrogel comprises a polymer network; the substrate comprises a surface comprising a polymer network; and the polymer network of the hydrogel and the polymer network of the surface are entangled.

The present disclosure includes the use of a miRNA inhibitor for treating a tauopathy associated with a decreased level of SIRT1 protein or SIRT1 gene expression, PGC-1α protein and/or PGC-α gene expression, and/or CD36 and/or CD36 gene expression.

Provided herein are polymer materials that find use in, for example, delivery of short-chain fatty acids. In particular, polymers are provided that form stable nanoscale structures and release their payload, for example, by cleavage of a covalent bond (e.g., via hydrolysis or enzymatic cleavage). The polymers are useful, for example, for delivery of payloads (e.g., SCFAs) to the intestine for applications in health and treatment of disease, and have broad applicability in diseases linked to changes in the human microbiota including inflammatory, autoimmune, allergic, metabolic, and central nervous system diseases, among others.

Several embodiments relate to engineered extracellular vesicles (EVs) using the membrane cloaking platform technology described herein, the cloaking imparting to the EVs enhanced delivery to tissues of interest, such as damaged or dysfunctional tissue. Several embodiments relate to engineering exosomes derived from cardiosphere-derived cells (CDCs) using the membrane cloaking platform technology described herein to confer enhanced tissue homing specificities, thereby leading to repair and regeneration at sites of injury. Uses of engineered EV compositions to treat diseases are also provided for in several embodiments.

The present invention relates to a drug delivery system with a micelle structure comprising a PEG.sub.2000-DSPE polymerized lipid and an APT.sub.EDB-PEG.sub.2000-DSPE polymer, and a preparation method thereof. The drug delivery system targets extra-domain B of fibronectin (EDB-FN), which is overexpressed in a brain tumor, and can pass through the blood-brain barrier (BBB) or the blood-brain tumor barrier (BBTB) to deliver a drug specifically to the brain tumor cells. In addition, the present invention can provide a pharmaceutical composition for diagnosing or treating a brain tumor, comprising the drug-loaded drug delivery system as an active ingredient. The composition can be accumulated inside the brain tumor and incorporated into the tumor cells to specifically inhibit tumor growth, and thus can be efficiently utilized for diagnosing or treating a brain tumor.

The present invention relates to a method for producing synthetic extracellular vesicles comprising a lipid bilayer including at least two lipids, one or more extracellular vesicle associated proteins, and optionally one or more nucleic acid molecules. The inventive synthetic extracellular vesicles are formed by emulsification using a mechanic emulsifier in the form of polymer shell stabilized synthetic extracellular vesicles. The inventive method allows producing synthetic extracellular vesicles miming the composition and function of natural extracellular vesicles. Therefore, synthetic extracellular vesicles with specific protein and nucleic acids compositions are also disclosed herein, as well as their therapeutic uses.

The invention relates to the treatment of cancer. In one embodiment, the present invention provides a composition comprising a micelle construct attached to a glut-1 antibody and a curcumin molecule. In another embodiment, the present invention provides a method of treating colon and/or breast cancer by administering a therapeutically effective amount of composition comprising a targeted construct attached to an inhibitor of NF-kB.

In certain embodiments allosteric inhibitors of BACE are provided. Illustrative inhibitors include but are not limited to various metformin analogs.