Abstract: Compositions comprising electrospun fibers and colorimetric detection encapsulated thereto are provided. Further, methods of use of said composition, including, but not limited to in-situ detection of molecules of interest, such as explosive compounds, are provided.

Abstract: The present invention provides methods for determining malignancy in a cyst by measuring viscosity of cyst fluid while under stain. The invention further provides devices, and computer program products for determining same.

Abstract: Fibrous mats composed of polymeric fibers comprising an aromatic polymer are provided. Further, articles and methods of use of the fibrous mats, including, but not limited to filters and membranes for sampling of fluid samples, are also provided.

Abstract: A scaffold comprising electrospun decellularized ECM of an organ, wherein the decellularized ECM has a similar protein composition to native ECM of the organ. Methods of generating same are also disclosed as well as uses of same.

Abstract: Compositions and articles comprising a non-woven matrix for use as anti-microbial filters are provided. In some embodiments, the non-woven matrix comprises nanofibers suitable for capturing a droplet comprising a microbe (e.g. a virus particle). In some embodiments, the non-woven matrix comprises a biocide suitable for reducing propagation and/or inactivating a microbe.

Abstract: Compositions comprising electrospun fibers and active (e.g. pharmaceutical) agents encapsulated thereto are provided. Further, articles and methods of use of the fibers, including, but not limited to coating of medical tubing, are provided.

Abstract: A method of producing a microtube is provided. The method comprising co-electrospinning two polymeric solutions through co-axial capillaries to thereby produce the microtube, wherein a first polymeric solution of the two polymeric solutions is for forming a shell of the microtube and a second polymeric solution of the two polymeric solutions is for forming a coat over an internal surface of the shell, the first polymeric solution is selected solidifying faster than the second polymeric solution and a solvent of the second polymeric solution is selected incapable of dissolving the first polymeric solution. Also provided are electrospun microtubes.

Abstract: Compositions comprising electrospun fibers and colorimetric detection encapsulated thereto are provided. Further, methods of use of said composition, including, but not limited to in-situ detection of molecules of interest, such as explosive compounds, are provided.

Abstract: Compositions comprising electrospun fibers and pharmaceutical agents encapsulated thereto are provided. Further, articles such as medical devices and methods of use of said fibers, including, but not limited to coating of medical tubes, are provided.

Abstract: Compositions comprising electrospun fibers and colorimetric detection encapsulated thereto are provided. Further, methods of use of said composition, including, but not limited to in-situ detection of molecules of interest, such as explosive compounds, are provided.

Abstract: A method of attaching a cell or a membrane-coated particle-of-interest to a microtube is provided. The method comprising: co-electrospinning two polymeric solutions through co-axial capillaries, wherein a first polymeric solution of the two polymeric solutions is for forming a shell of the microtube and a second polymeric solution of the two polymeric solutions is for forming a coat over an internal surface of the shell, the first polymeric solution is selected solidifying faster than the second polymeric solution and a solvent of the second polymeric solution is selected incapable of dissolving the first polymeric solution and wherein the second polymeric solution comprises the cell or the membrane-coated particle-of-interest, thereby attaching the cell or the membrane-coated particle-of-interest to the microtube.

Abstract: A method of attaching a molecule-of-interest to a microtube, by co-electrospinning two polymeric solutions through co-axial capillaries, wherein a first polymeric solution of the two polymeric solutions is for forming a shell of the microtube and a second polymeric solution of the two polymeric solutions is for forming a coat over an internal surface of the shell, the first polymeric solution is selected solidifying faster than the second polymeric solution and a solvent of the second polymeric solution is selected incapable of dissolving the first polymeric solution and the second polymeric solution comprises the molecule-of-interest, thereby attaching the molecule-of-interest to the microtube. An electrospun microtube comprising an electrospun shell, an electrospun coat over an internal surface of the shell and a molecule-of-interest attached to the microtube.

Abstract: A scaffold comprising electrospun decellularized ECM of an organ, wherein the decellularized ECM has a similar protein composition to native ECM of the organ, Methods of generating same are also disclosed as well as uses of same.

Abstract: The present invention provides methods for determining malignancy in a cyst by measuring viscosity of cyst fluid while under stain. The invention further provides devices, and computer program products for determining same.

Abstract: Provided are methods of petroleum sequestration, which use electrospun microtubes capable of sequestering the petroleum from the water, and method of depleting and optionally degrading petroleum from water using floating devices which comprise the electrospun microtube attached to a floating carrier.

Abstract: A fiber-reinforced hydrogel composite is provided. The composite includes a hydrogel and a fibrous component containing a plurality of fibers. Length of each of the plurality of fibers is less than about 1,000 ?m. A method of preparing a fiber-reinforced hydrogel composite is also provided. The method includes coating a hydrogel precursor solution on a substrate to form a hydrogel precursor film, depositing the plurality of fibers onto the hydrogel precursor film, and allowing the hydrogel precursor film to form a hydrogel film, thereby forming the fiber-reinforced hydrogel composite. A scaffold containing the fiber-reinforced composite, and a tissue repair method using the fiber-reinforced composite are also provided.

Abstract: Starch-based fibers, compositions comprising same, method of preparing said starch-based fibers, kits and methods for use of said starch-based fibers including but not limited to oral delivery of cells (e.g., probiotic microorganisms) and/or molecules of interest (e.g., nutrients) are provided.

Abstract: A method of producing a microtube is provided. The method comprising co-electrospinning two polymeric solutions through co-axial capillaries to thereby produce the microtube, wherein a first polymeric solution of the two polymeric solutions is for forming a shell of the microtube and a second polymeric solution of the two polymeric solutions is for forming a coat over an internal surface of the shell, the first polymeric solution is selected solidifying faster than the second polymeric solution and a solvent of the second polymeric solution is selected incapable of dissolving the first polymeric solution.

Abstract: Compositions comprising electrospun fibers and colorimetric detection encapsulated thereto are provided. Further, methods of use of said composition, including, but not limited to in-situ detection of molecules of interest, such as explosive compounds, are provided.

Abstract: A method of attaching a cell or a membrane-coated particle-of-interest to a microtube is provided. The method comprising: co-electrospinning two polymeric solutions through co-axial capillaries, wherein a first polymeric solution of the two polymeric solutions is for forming a shell of the microtube and a second polymeric solution of the two polymeric solutions is for forming a coat over an internal surface of the shell, the first polymeric solution is selected solidifying faster than the second polymeric solution and a solvent of the second polymeric solution is selected incapable of dissolving the first polymeric solution and wherein the second polymeric solution comprises the cell or the membrane-coated particle-of-interest, thereby attaching the cell or the membrane-coated particle-of-interest to the microtube.