This invention relates generally to anellosomes and compositions and uses thereof.

Described herein are compositions and techniques related to generation and therapeutic application of artificial synapses. Artificial synapses are engineered extracellular vesicles, including exosomes, which incorporate sticky binders on their surface to anchor signaling domains against biological targets, such as receptors. These engineered additives can be organized in genetic vector constructs, expressed in mammalian cells, wherein the sticky binders attach to extracellular vesicles such as exosomes, thereby presenting their joined signaling domains which are rapidly taken up by recipient cells. Artificial synapses adopt the hallmark biophysical and biochemical features of extracellular vesicles, allowing for rapid deployment and scale-up. Importantly, this strategy can allow for kinetically favorable signal generation and signal propagation. This includes, for example, increasing density of agonist presentation to support receptor clustering—an onerous barrier for traditional receptor targeting strategies.

The present invention refers to a composition comprising a viral protein or fragment thereof, wherein the viral protein or fragment thereof is enclosed within a self-assembling protein nanocapsule, preferably ferritin, and wherein the viral protein, or fragment thereof is selected from a virus of the Togaviridae family. The viral protein or fragment thereof may also further be selected from a virus of the alphavirus subfamily.

This disclosure relates to ionizable lipid-based lipid nanoparticles for delivery of mRNA encoding glucose-6-phosphatase. Lipid nanoparticle/mRNA therapies of the invention increase and/or restore deficient levels of glucose-6-phosphatase expression and activity in subjects and are useful for the treatment of glycogen storage disease type 1a (GSD-Ia). Lipid nanoparticle/mRNA therapies of the invention increase glucose production and reduce the abnormal accumulation of glycogen and glucose-6-phosphate associated with GSD-Ia.

The present invention is related to compositions containing extracellular vesicles (exosomes) and methods of using the same for increasing lifespan of fetus, viability of fetus, or viability of newborn, for treating inflammation in uterus and/or fetus, for delaying preterm birth, or for treating a condition related to inflammation in uterus and/or fetus, wherein the extracellular vesicles comprising a nuclear factor kappa beta (NF-κB) inhibitor and a photo-specific binding protein.

The present invention relates to compositions for the delivery of molecules such as a peptide, a nucleic acid and/or a small molecule drug. In particular, the present invention relates to an extracellular vesicle (EV) loaded with a peptide, a nucleic acid and/or a small molecule drug, along with methods of producing said EV.

Described herein are compositions and techniques related to generation and therapeutic application of artificial synapses. Artificial synapses are engineered extracellular vesicles, including exosomes, which incorporate sticky binders on their surface to anchor signaling domains against biological targets, such as receptors. These engineered additives can be organized in genetic vector constructs, expressed in mammalian cells, wherein the sticky binders attach to extracellular vesicles such as exosomes, thereby presenting their joined signaling domains which are rapidly taken up by recipient cells. Artificial synapses adopt the hallmark biophysical and biochemical features of extracellular vesicles, allowing for rapid deployment and scale-up. Importantly, this strategy can allow for kinetically favorable signal generation and signal propagation. This includes, for example, increasing density of agonist presentation to support receptor clustering—an onerous barrier for traditional receptor targeting strategies.

Described herein are novel methods for fractionating and isolating platelets, platelet- and extracellular vesicle-derived growth factors, exosomes, globulins, fibrinogen and albumin, and methods of using the isolated platelets, platelet and extracellular vesicle-derived growth factors, exosomes, globulins, fibrinogen and albumin for regenerating tissue in a subject, treating fibrinogenemia or a clotting deficiency in a subject, treating ischemia and hypoxia, treating dry-eye syndrome, an orthopedic disorder, or a dental disorder in a subject. Also described herein are growth media for culturing mammalian (e g , human) cells.

The present disclosure provides ghost nanovesicles (gNVs) that are deficient in cytosolic components. Methods of making such vesicles and therapeutic uses of such vesicles are also provided. The gNVs may be used in preventing or treating conditions that may benefit from administration of the gNVs. Such conditions include conditions that involve inflammation.

The invention relates to bacteriophage means, namely intracorporal bacteriophage means, nasopharyngeal and pulmonary bacteriophage means, cutaneous bacteriophage means, and bacteriophage suture means, and in addition a two-syringe bacteriophage means, a nasopharyngeal and pulmonary bacteriophage means device, and a bacteriophage sensitive testing application.