The method, characterized in that, the powdered chitosan is dissolved in water to obtain a 5% solution, into which a 70-90% acetic acid is added and after the formation of the blank intramedullary nail and carrying a coagulating bath and neutralization bath it is subjected to a crosslinking bath in a solution formed from 0.5 to 2% of sodium tri-polyphosphate and 0.5% to 3% Na3PO4 for 24 to 48 hours in temperature of 50° C. to 140° C. and then it is subjected to the drying process, for a period of 6 to 10 days, and finally the surface of the blank is treated to form the intramedullary nail. The surface treatment is carried out until the surface of the intramedullary nail contains at least 20%-40% of the pore of the depth of 0.1 mm to 1 mm.

A medical device comprising a syringe barrel, a plunger, and an injectable viscous lifting agent containing a coloring agent loaded in the syringe barrel. The injectable viscous lifting agent is sterilized by a sterilization process, such as an autoclaving process, while inside the syringe barrel. The injectable viscous lifting agent is adapted for injection between an upper mucosal layer and a lower layer at a target treatment site such that the upper mucosal layer separates from the lower layer and the upper mucosal layer is elevated.

A stent-graft comprising a tubular, radially self-expandable, braided structure comprising elongate bioabsorbable filaments, a bioabsorbable adhesive means, and a permanent graft disposed and adhered with the adhesive means to at least a portion of the structure and forming a stent-graft assembly, the permanent graft and the tubular structure are coextensive along at least a portion of the stent-graft.

A stent-graft comprising a tubular, radially self-expandable, braided structure comprising elongate bioabsorbable filaments, a bioabsorbable adhesive means, and a permanent graft disposed and adhered with the adhesive means to at least a portion of the structure and forming a stent-graft assembly, the permanent graft and the tubular structure are coextensive along at least a portion of the stent-graft.

A staple cartridge comprising a tissue thickness compensator is disclosed. The tissue thickness compensator comprises an uncompressed height, a compressed height, an outer encasement, and tubular structures aligned along the longitudinal axis. The tubular structures are configured to collapse when pressure is applied to the tissue thickness compensator by tissue during the firing motion.

A staple cartridge comprising a tissue thickness compensator is disclosed. The tissue thickness compensator comprises an uncompressed height, a compressed height, an outer encasement, and tubular structures aligned along the longitudinal axis. The tubular structures are configured to collapse when pressure is applied to the tissue thickness compensator by tissue during the firing motion.

The present inventions are directed to shear-thinning and stabilizing hydrogels, especially for use in drug delivery and therapy. Various embodiments provide settable, shear-thinning hydrogels, each hydrogel comprising a hydrophilic polymer network, said hydrophilic polymer network comprising non-covalent crosslinks and at least one set of chemical moieties being capable of participating in at least one chemical covalent cross-linking reaction. In certain embodiments, these settable shear-thinning hydrogels are triggerable to cross-link by the application of a stimulus.

The present inventions are directed to shear-thinning and stabilizing hydrogels, especially for use in drug delivery and therapy. Various embodiments provide settable, shear-thinning hydrogels, each hydrogel comprising a hydrophilic polymer network, said hydrophilic polymer network comprising non-covalent crosslinks and at least one set of chemical moieties being capable of participating in at least one chemical covalent cross-linking reaction. In certain embodiments, these settable shear-thinning hydrogels are triggerable to cross-link by the application of a stimulus.

The invention relates to a method for producing a storable molded body made of bacterial cellulose and a molded body produced according to the method. A preferred method includes providing a molded body made of bacterial cellulose. Optionally, mechanically pressing the entire molded body or parts of the molded body at temperatures in the range of 10° C. to 100° C. and pressures in the range of 0.01 to 1 MPa for a pressing time of 10-200 min. Treating the molded body with a solution of 20% by weight to 50% by weight of glycerol and 50% by weight to 80% by weight of a C1-C3-alcohol/water mixture. Drying the treated molded body.

A method for preparing non-free radical photo-crosslinked hydrogels includes: dissolving component A that is a polymer derivative modified with o-nitrobenzyl phototrigger in a biocompatible medium to obtain solution A; dissolving component B that is a polymer derivative containing hydrazide, hydroxylamine or primary amine in a biocompatible medium to obtain solution B; mixing solution A and solution B to obtain a precursor solution of hydrogel; under light irradiation, crosslinking aldehyde generated from the o-nitrobenzyl with the hydrazine, hydroxylamine or primary amine to obtain a hydrogel by forming hydrazone, oxime or schiff base, respectively. A kit for preparation and application of the hydrogel in tissue repair, beauty therapy, and cells, proteins or drugs carriers is also described. The method or kit can achieve in situ photo-gelling on tissue surface or in situ forming thin gel on wounds in clinical treatment of wounds.