The present invention relates to methods of tissue grafting and microvascular free flap transfer that involve administering a phosphodiesterase type-5 inhibitor to the tissue graft or microvascular free flap to produce a treated graft or flap, and implanting the treated graft or flap into a recipient site of a host subject.

The invention provides a non-particulate cross-linked poly--lysine polymer. The poly--lysine and cross linker are linked by amide bonds and may the cross linker has at least two functional groups capable of reacting with an alpha carbon amine of poly--lysine. The polymer is suitably insoluble in water and other solvents and is provided in macro form for example a sheet, article or fiber. The macro form polymer is useful in a wide range of applications including wound treatment, as a medical diagnostic comprising a particulate support and a functional material bound or retained by the support and solid phase synthesis of peptides, oligonucleotides, oligosaccharides, immobilization of species, cell culturing and in chromatographic separation.

The described invention provides compositions comprising at least one peptide of formula I for enhancing neurite outgrowth, neuroprotection, and nerve regeneration, and methods of use thereof.

A vascular embolization device includes a coil with a primary shape and an stretch resistant wire provided inside the coil, in which the stretch resistant wire is a multilayer strand including at least one core layer and at least one outer layer including one or more resin compositions and a biochemical active material, and the core layer is composed of a material with a tensile break strength higher than that of the outer layer. The vascular embolization device has the function of administering a biochemical active material and also has good flexibility.

Devices, systems, and methods are provided including a structure having one or more surfaces configured for internal use within a patient's body and one or more therapeutic compositions comprising one or more active substances including at least one of a chelating agent, a direct factor Xa inhibitor, a direct factor IIa inhibitor, and a factor XI/XIa inhibitor disposed in or on the structure. The structure is configured to be positioned adjacent a target site in the patient's body. The therapeutic composition is formulated to release the one or more active substances to the target site to provide one or more of inhibit clot formation, promote clot dissolution, inhibit or dissolute inflammation, inhibit vessel injury, increase time before clotting, and/or inhibit cell proliferation. Delayed or other controlled release of the therapeutic composition from the structure may be provided.

The present disclosure generally relates to the preparation and use of cell sheets. The preparation can entail culturing a plurality of stem cells on a cell culture surface of a container in a culture medium, adding a differentiation medium and a Rho-kinase (ROCK) inhibitor to the container, wherein the differentiation medium and the ROCK inhibitor are added within 2 days of one another. and detaching, from the cell culture surface, a cell sheet formed with cells differentiated from the stem cells. Alternatively, the use of the ROCK inhibitor to remove centrifuge tension can be replaced or supplemented by removal of edges of the cell sheet.

Disclosed herein are cohesive soft tissue fillers, for example, dermal and subdermal fillers, based on hyaluronic acids and optionally including proteins. In one aspect, hyaluronic acid-based compositions described herein include zero-length cross-linked moieties and optionally at least one active agent. The present hyaluronic acid-based compositions have enhanced flow characteristics, hardness, and persistence compared to known hyaluronic acid-based compositions. Methods and processes of preparing such hyaluronic acid-based compositions are also provided.

The invention is to articles of extracellular matrix. The articles comprise one or more sheets of mammalian extracellular matrix laminated together. A single sheet can be folded over and laminated on 3 sides. Two or more sheets can be laminated to each other at their edges. The sheets can further encase a composition comprising a cell or cells, such as for example, a stem cell. A single sheet can be folded over to encase a composition, or rolled to encase a composition with lamination at either end of the roll, for example. The invention also includes methods of using these articles to regenerate tissue at tissue defects, or heal wounds in damaged tissue.

A non-cellular root canal filler comprises a tetrahydroisoquinoline compound or a pharmaceutically acceptable salt thereof, or a solvate of the compound or the salt, and a dental tissue regeneration promotion kit comprises a pretreatment agent comprising a serine protease, and the non-cellular root canal filler.

Embodiments of the invention relate generally to electrospun fibers and, more particularly, to the controlled release of an active pharmaceutical ingredient (API) from electrospun fiber scaffolds (EFSs).