A method and device for localized treatment of tissues or organs that were exposed to ischemia and reperfusion (IR) injury, in order to reduce their structural damage and loss of function. The method further includes intra-arterial treatment of transplanted tissues or organs, which are exposed to similar damage of IR and are at risk of impaired function. Leptin antagonist is administered as a bolus injection directly into a re-opened artery, which supplies blood to the tissue or organ involved, immediately after reperfusion. In some cases, after administering a bolus injection of leptin antagonist, the effect of leptin antagonist in the involved organ can be prolonged by deploying a double function drug eluting stent, which elutes leptin antagonist into the lumen, e.g., by sustained release, while eluting antiproliferative drug into the vessel wall to prevent local stenosis, which may appear due to stent deployment.

Compositions comprising an isolated peptide, which may for example optionally comprise a sequence selected from the group consisting of YDYNWY (SEQ ID NO: 1), YDYNLY (SEQ ID NO: 2), FDYNFY (SEQ ID NO: 3), FDYNLY (SEQ ID NO: 4), FDYNWY (SEQ ID NO: 5), YDWNLY (SEQ ID NO: 6), YDWHLY (SEQ ID NO: 7), and WDYNLY (SEQ ID NO: 8), extracted from organisms such as aquatic organisms and moss or any other sequence described herein, and methods of using same, including for treatment of or prevention of formation of microbial biofilms and against adhesion of a cell to a surface.

In some aspects, the present invention provides surgical procedures that comprise applying compositions into and/or onto tissue, including supporting tissues (e.g., ligaments, connective tissue, muscles, etc.) for pelvic organs, among other tissues. In other aspects, the present disclosure pertains to compositions that are useful for performing such procedures. In still other aspects, the present disclosure pertains to kits that are useful for performing such procedures.

Provided herein relates to high molecular weight silk-based materials, compositions comprising the same, and processes of preparing the same. The silk-based materials produced from high molecular weight silk can be used in various applications ranging from biomedical applications such as tissue engineering scaffolds to construction applications. In some embodiments, the high molecular weight silk can be used to produce high strength silk-based materials. In some embodiments, the high molecular weight silk can be used to produce silk-based materials that are mechanically strong with tunable degradation properties.

The present invention relates to compounds and their use in the treatment of lesions, in tissue regeneration and/or tissue engineering. The compounds act as substrates for enzymes having transglutaminase activity and are suitable for their immobilization and/or attached therapeutic or diagnostic molecules on extracellular matrix (ECM) or synthetic ECM-derived materials, in particular for the immobilization of myostatin inhibitors.

Disclosed are a spiral coated stent with controllable gradient degradation, a preparation method thereof and an application thereof. The spiral coated stent with controllable gradient degradation is composed of a degradable medical polyurethane and a degradable magnesium alloy material, wherein the degradable medical polyurethane contains a following chemical structure: PCL-PEG-PCL, wherein a molecular weight of the PEG is 200 to 1,000 and the molecular weight of the PCL is 200 to 10,000, and the degradable magnesium alloy material is of a spiral stent structure; and physical properties of the spiral coated stent with controllable gradient degradation need to satisfy the following technical parameters that: a breaking strength needs to be no less than 1 N, a pressure resistance needs to be no less than 2 N, and a degradation characteristic of the magnesium alloy after surface treatment shows gradient degradation with different time.

A microneedle or microneedle device includes a microneedle body extending from a base to a penetrating tip formed from a silk fibroin based material, which is easy to fabricate and highly biocompatible. The microneedle device can include one or more microneedles mounted to a substrate. The silk fibroin can include active agents to be transported into or across biological barriers such as skin, tissue and cell membranes. The silk fibroin microneedles can be fully or partially biodegradable and/or bioerodible. The silk fibroin is highly stable, affords room temperature storage and is implantable. The silk fibroin structure can be modulated to control the rate of active agent delivery.

The present invention relates to a VHH which binds to a growth factor or is an antagonist for a growth factor, or binds to an implant.

The present invention relates to a biologically active medical device, which includes a matrix seeded with progenitor cells, and then covered by ciliated tissue. The matrix is capable of enabling cellular migration. The ciliated tissue is ependymal cells that express at least one of tight junctional complexes, zonula adherens, and gap junctions. The progenitor cells include subpendymal progenitor cells. In some cases the progenitor cells include stem cells, and the ciliated tissue includes at least one of Choroid cells, tanacytes, and circumventricular organs. In some embodiments, the medical device is oriented into a tubular structure in order to form a cerebrospinal shunt. Additional cells and structures may be imbedded within the matrix, such as glia, endothelial cells, stem cells, and blood vessels. The medical device may also be incorporated into a bioreactor including a flexible inner tube defining an anthropomorphically shaped lumen.

The present invention relates to a biologically active medical device, which includes a matrix seeded with progenitor cells, and then covered by ciliated tissue. The matrix is capable of enabling cellular migration. The ciliated tissue is ependymal cells that express at least one of tight junctional complexes, zonula adherens, and gap junctions. The progenitor cells include subpendymal progenitor cells. In some cases the progenitor cells include stem cells, and the ciliated tissue includes at least one of Choroid cells, tanacytes, and circumventricular organs. In some embodiments, the medical device is oriented into a tubular structure in order to form a cerebrospinal shunt. Additional cells and structures may be imbedded within the matrix, such as glia, endothelial cells, stem cells, and blood vessels. The medical device may also be incorporated into a bioreactor including a flexible inner tube defining an anthropomorphically shaped lumen.