A therapeutic agent which inhibits cytokines and/or inflammatory mediators for use in the treatment of a patient affected by inflammation associated with atherosclerosis and/or a thrombotic state, wherein the treatment includes the local administration of the therapeutic agent in a blood vessel by an intravascular medical device directly at the level of an atherosclerotic plaque, and/or a site of inflammation, and/or a site of a thrombotic phenomenon.

The present invention relates to polypeptides comprising at least one single domain antibody directed against vWF, vWF A1 domain, A1 domain of activated vWF, vWF A3 domain, gpIb and/or collagen, homologues of said polypeptides, and/or functional portions of said polypeptides, for the treatment for conditions which require a modulation of platelet-mediated aggregation and which overcomes the problems of the prior art. A further aspect of the invention is methods of production of said polypeptides, methods to coat devices with such polypeptides used in medical procedures (e.g. PCTA, stenting), methods and kits for screening for agents that modulate platelet-mediated aggregation and kits for the diagnosis of diseases related to platelet-mediated aggregation.

The technology described herein is directed to compositions comprising at least a first porous biomaterial layer and a second impermeable biomaterial layer and methods relating thereto. In some embodiments, the compositions and methods described herein relate to wound healing, e.g. repair of wounds and/or tissue defects.

The present disclosure provides compositions, methods, and kits that enable the in situ growth of polymers on or within a subject. In some aspects, the monomer, dopamine, polymerizes in vivo to form a polymer on a tissue. In additional aspects, the compositions, methods, and kits are useful for treating or preventing a disease or disorder.

A therapeutic bandage includes a bandage matrix and an array of microneedles extending from the bandage matrix. Each of the microneedles includes a first layer that encapsulates a first immunomodulatory compound and a second layer that encapsulates a second immunomodulatory compound. The array of microneedles is configured to guide foreign agents affected by the first immunomodulatory compound, the second immunomodulatory compound, or the first and second immunomodulatory compounds from one or more skin layers of a user to the bandage matrix such that the bandage matrix absorbs and captures the foreign agents.

The present disclosure provides click-crosslinked hydrogels and methods of use.

Certain embodiments according to the present invention provide sleeve devices suitable for a wide range of therapeutic uses. In accordance with certain embodiments, the therapeutic sleeve device includes a nanofiber fabric assembly, which defines a plurality of pores, and at least one layer of cells embedded in the nanofiber fabric assembly.

A condom for detection of STDs, including an interior condom surface having a control band and a test band, and an exterior condom surface that also has a control band and test band. Each test band allows binding and subsequent detection of STD antigens. A separate developing antibody produces a color change if bound to the antigen/antibody conjugate. The developing antibody may be present on the condom or applied separately after use.

The present disclosure provides systems and methods for delivering a gel to a surface. In one embodiment, the system may have a first vessel with a first low viscosity aqueous solution comprising a binder/crosslinking agent; and a second vessel with a second low viscosity aqueous solution comprising a gelling component. The separate first and second low viscosity aqueous solutions are sprayed onto a surface where the solutions mix forming a gel.

The present disclosure provides systems and methods for disrupting the outer membrane of an oocyst in solution and delivering the solution to an animal. The system includes a vessel containing unbroken oocysts in solution, an oocyst processing chamber, and a delivery outlet. The unbroken oocysts are moved from the vessel through the processing chamber and a portion of the oocyst membranes are disrupted releasing sporocysts, the resulting solution is moved from the processing chamber into the delivery outlet where the solution is delivered to an animal. Methods of vaccination, including vaccination against an Eimeria infection, are also provided.