The invention is directed to a tissue-adhesive multi-arm polymer comprising a core from which polymeric arms extent, which polymeric arms are substituted with a hydroxyl-substituted aromatic group based on compounds such as dopamine, L-DOPA, D-DOPA, tyramine, noradrenaline and/or serotonin. In addition, the invention is directed to a caprolactam blocked hydroxyl-substituted aromatic compound, suitable for the preparation of the tissue-adhesive multi-arm polymer and to the method for the preparation of the tissue-adhesive multi-arm polymer.

Disclosed are hydrogels polymerized with a biofunctional moiety, biodegradable and permanent, designed to be implantable in a mammalian body and intended to block or mitigate the formation of tissue adhesions. The hydrogels of the present invention are characterized by comprising four structural elements: a) a polymeric backbone which defines the overall polymeric morphology, b) linkage groups, c) side chains, and d) biofunctional end groups. The hydrophobicity of the various structural elements are chosen to reduce tissue adhesion and enhance the biofunctional aspect of the end groups. The morphology of these polymers are typically of high molecular weight and have shape to encourage entanglement. Useful structures include branching chains, comb or brush, and dendritic morphologies.

Hydrogels are provided that include an antimicrobial agent and a cross-linkable urethane-based polymer (CUP). Such hydrogels may be used for the controlled-release of antimicrobial agents as well as in the manufacturing of wound dressings. Wound dressings are provided that comprise a hydrogel as defined herein.

A conductive sheet comprising a conductive substrate layer and a hydrogel layer formed of a silicone hydrogel having a polymer comprising a repeat unit (A) derived from a monomer represented by Formula (I) as a gel skeleton. Provided is a conductive sheet which can maintain adhesiveness and flexibility even when used for a long period of time and can attain high biocompatibility.

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In some aspects, the present disclosure pertains to multi-arm polymers that comprise a core, a plurality of polymer segments having a first end that is covalently attached to the core and a second end comprising a moiety that comprises a reactive group, wherein the polymer segments comprise one or more free-radical-polymerizable monomers. In some aspects, systems are provided that comprise a first composition comprising such a multi-arm polymer and a second composition comprising a multifunctional compound that comprises functional groups that are reactive with the reactive groups of the multi-arm polymer. In some aspects, systems are provided that comprise crosslinked reaction products of such a multi-arm polymer and such a multifunctional compound.

In an aspect, a method for making a metal-containing material comprises steps of: forming a metal-containing hydrogel from an aqueous precursor mixture using a photopolymerization; wherein the aqueous precursor mixture comprises water, one or more aqueous photosensitive binders, and one or more aqueous metal salts; and thermally treating the metal-containing hydrogel to form the metal-containing material; wherein the metal-containing hydrogel is exposed to a thermal-treatment atmosphere during the step of thermally treating; wherein a composition of the metal-containing material is at least partially determined by a composition of the thermal-treatment atmosphere during the thermally treating step.

A method for preparing a biomass-based conductive hydrogel by 3D printing is provided. Firstly, a cellulose-based macromonomer, a rosin-based monomer, an acrylic acid monomer and an initiator are mixed in a certain proportion, stirred, and dissolved at 25-70° C. Then, diisocyanate in an amount of 5-10 wt % of a total mass of the monomers is added to the mixed solution and mixed uniformly to prepare a 3D printing photosensitive resin solution. An SLA light-curing 3D printer is used to print a hydrogel precursor 1 with a complex shape. Next, the hydrogel precursor 1 is heated to obtain a hydrogel precursor 2 with a dual-curing network. Finally, the obtained hydrogel precursor 2 is swelled in a 1-15 wt % alkaline solution at 5-60° C. for 0.1-10 hours to obtain the biomass-based conductive hydrogel.

Disclosed herein is a composition comprising a water soluble monomer or polymer; a fluorine functionalized acrylate; and a non-isocyanate urethane acrylate. Disclosed herein is a method comprising mixing a water soluble monomer or polymer, a fluorine functionalized acrylate and a non-isocyanate urethane acrylate to form a composition; and curing the composition.

A methylsilicic acid hydrogel is produced by reacting a solution of sodium methyl siliconate with a gaseous acid agent. The resulting product is vacuumised to remove residual gas, and washed with water. A significant OH-group content in the hydrogel, which results from bubbling the gaseous acid agent through the solution of sodium methyl siliconate, makes it possible to increase the selectivity of the adsorption properties when the hydrogel is used in medicine and veterinary science.

A medical device including a substrate and a hydrophilic polymer layer and satisfying the following conditions: (1) that the hydrophilic polymer layer is on at least a part of the substrate; (2) that the hydrophilic polymer layer contains: a hydrophilic polymer having an acidic group; and a compound having an acidic group and a ring structure; and (3) that a time during which a liquid film is retained on the surface of the medical device (a liquid film retention time) is 10 seconds or more after the medical device is stationarily immersed in a phosphate buffer solution, pulled up from the phosphate buffer solution, and retained in the air. The present invention provides a medical device in which a surface of a substrate is hydrophilized, and a method for manufacturing same by a simple method.