A product and method of using albumin nanoparticles for treating multiple traumas by augmenting the function or effectiveness of stem cells or precursor cells in vivo. An albumin nanoparticle suspension containing submicron albumin spheres is prepared, with the albumin spheres being capable of augmenting a function and effectiveness of stem cells or precursor cells in vivo for treating multiple traumas at the same time. A predetermined amount of the albumin nanoparticle suspension is administered to a patient before or after an onset of multiple traumas. A function of the stem or precursor cells can be augmented or improved by the albumin spheres to stimulate mobilization toward the traumas, to ameliorate an inflammatory response of the subject by decreasing an amount of RANTES endothelial production on cytokines production, and/or to improve a secretion of fractalkine. The albumin spheres can be bound with fibrinogen molecules in vitro or in vivo.

The present invention relates to compositions comprising fibrinogen gamma prime variants for use in the treatment or prevention of an infection and methods of administering the composition. The fibrinogen gamma prime variants in the composition comprise at least one fibrinogen gamma prime polypeptide chain. The compositions for use according to the invention may also comprise other fibrinogen variants. Compositions comprising fibrinogen gamma prime variants according to the invention improve survival time after infection up to more than 200 percent compared to WT fibrinogen. They may be used both therapeutically and prophylactically.

The present invention relates to compositions comprising fibrinogen gamma prime variants for use in the treatment or prevention of an infection and methods of administering the composition. The fibrinogen gamma prime variants in the composition comprise at least one fibrinogen gamma prime polypeptide chain. The compositions for use according to the invention may also comprise other fibrinogen variants. Compositions comprising fibrinogen gamma prime variants according to the invention improve survival time after infection up to more than 200 percent compared to WT fibrinogen. They may be used both therapeutically and prophylactically.

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 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 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 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.

Provided herein are methods of making an ECM gel from vascular tissue. Also provided herein are ECM compositions prepared from vascular tissue, and methods of use of those compositions, for example in treatment of aneurysms, and for vascularization or re-vascularization.

Provided herein are methods of making an ECM gel from vascular tissue. Also provided herein are ECM compositions prepared from vascular tissue, and methods of use of those compositions, for example in treatment of aneurysms, and for vascularization or re-vascularization.

The invention described herein provides methods and compositions for using recombinant AAV-based viral vectors to express any gene-of-interest (GOI), preferably from muscle and/or liver tissues, for secretion of the polypeptides encoded by the GOI into the bloodstream, thus serving as an alternative treatment regimen for diseases caused by or characterized by lack of functional GOI, or for disease caused by or characterized by a pathological antigen that can be neutralized by a neutralizing peptide encoded by the GOI, such as an immunoglobulin, antibody, or antigen-binding fragment thereof. The method/composition of the invention can be used as an alternative for enzyme replacement therapy (ERT), or for antibody-based therapy.