Disclosed herein is a formulation comprising an extracellular vesicle (EV), and a therapeutic active agent induced or embedded in the EV. According to preferred embodiments of the present disclosure, the EV is isolated from umbilical cord mesenchymal stem cells, and the active agent may be a growth factor, an immune-modulating agent, a small molecule, an siRNA, cDNA or a plant ingredient; for example, curcumin. Also disclosed herein are methods for producing the present formulation, and uses of the present formulation in the treatment of various diseases.

This application relates to cell delivery articles and methods for delivering cells into the body in a manner that allows them to incorporate into surrounding tissue and express cell products. The cell delivery articles are generally capable of maintaining viability of the cells for a period of time that allows such incorporation to occur. Additionally, a cell delivery article may include a bio-ghost coating that prevents the cell delivery article from being recognized by the immune system, and/or minimizes or prevents development of fibrotic tissue which can interfere with nutrients and oxygen entering the cell delivery article and reaching the cells. A cell delivery article may be formulated for delivery by various routes of administration.

The present invention relates to a composition for preventing or treating cancer, the composition containing IL-2 surface expression-extracellular vesicles as an active ingredient. According to the present invention, immune cells, in which useful cytokines have been expressed on the cell surface, and extracellular vesicles, preferably small extracellular vesicles (sEV), which are derived from the immune cells and have useful cytokines expressed on the surface were prepared using a lentiviral vector containing a cytokine-linker-a PDGF receptor transmembrane domain, and it was found that the extracellular vesicles increased proliferation and activity of cytotoxic T cells thereby increasing anti-cancer immune efficacy. Thus, the extracellular vesicles having the efficacy can be usefully utilized as a pharmaceutical composition for preventing or treating cancer, a pharmaceutical composition for co-administration with an anticancer drug, or a composition for delivering a drug or a physiologically active material.

Provided herein are methods of treating a tumor comprising administering (i) a composition comprising an extracellular vesicle and a STING agonist, e.g., exosome encapsulating STING agonists, in combination with (ii) an IL-12 moiety.

A method for synthesizing cell membrane-biomimetic nanotherapeutics can include coating core particles with cell membrane materials using flash nanocomplexation (FNC). FNC is a turbulent mixing and self-assembly method that can produce cell membrane-coated nanotherapeutics in a reproducible and scalable manner. The FNC-produced cell membrane-coated particles demonstrate lower aggregation, polydispersity, and zeta potential, than nanoparticles prepared by conventional coating methods, such as conventional bulk-sonication. As such, the present method achieves more complete, homogeneous and controllable coating than conventional bulk-sonication methods.

The disclosure provides a hybrid membrane camouflaged nanomedicine loaded with oxidative phosphorylation inhibitor and preparation method thereof. The nanomedicine comprises an inner core and an outer shell coated on the periphery of the inner core. The inner core is a ROS-responsive drug-loaded nanoparticle, and the drug loaded by the ROS-responsive nanocarrier is an oxidative phosphorylation inhibitor. The outer shell is a hybrid membrane of mitochondrial membrane and cancer cell membrane. The nanomedicines can cross the BBB and reach tumor sites by the homologous targeting of cancer cell membrane, and then they can homologously target and enter mitochondria by the mitochondrial membrane. Subsequently, under the high-level ROS environment of the mitochondria, the ROS responsive drug-loaded nanoparticle releases the oxidative phosphorylation inhibitor due to the swell and degradation of the inner core, so that the safe and efficient targeted GBM therapy is achieved.

Disclosed herein are compositions and methods comprising extracellular vesicles comprising nucleic acid that target genes, leading to macrophage polarization of tumor associated macrophages. In certain embodiments, disclosed herein are methods and compositions for increasing macrophage polarization for the treatment of cancer.

Compositions and methods for treating cancer are provided. In particular, the compositions comprise an anti-neoplastic agent and either an interferon type I agonist or an interferon type II agonist, or a combination of an interferon type I agonist and an interferon type II agonist.

The present disclosure relates to nanoparticles containing cellular membrane and uses thereof. The nanoparticle comprises an interior compartment (or an inner core) and an outer surface (or shell) comprising a cellular membrane derived from a cell, said interior compartment (or an inner core) not providing a solid support to said cellular membrane in said outer surface (or shell). The present disclosure also relates to processes of making the nanoparticles. The present disclosure further relates to compositions comprising the nanoparticles and methods of using the nanoparticles.

Disclosed herein are neural extracellular vesicles (EVs) and methods of using these EVs in the treatment of spinal cord injury, stroke, and traumatic brain injury and neurodegenerative disease.