Some embodiments relate to additive manufactured articles having passivated surfaces and related methods. The methods may comprise forming a three-dimensional (3D) article by additive manufacturing to obtain an additive manufactured 3D article comprising a magnesium component. The method may further comprise exposing the additive manufactured 3D article to a reactive gas phase comprising a fluorine component. The fluorine component from the reactive gas phase may react with the magnesium component of the additive manufactured 3D article to form a passivation layer at and below a surface of the additive manufacture 3D article.

Embodiments of the present disclosure provide for structures including an alloy of calcium, strontium, and magnesium.

The present invention relates to a method for preparation of a functionalized surface comprising the steps: a) coating of a carrier with a least one polymer selected from a polyanionic or polycationic polymer, b) addition of at least one compound to the coated carrier of step a), c) exposing the at least one polyanionic or polycationic polymer on the coated carrier of step b) to an organic solvent, resulting in compaction of the at least one polyanionic or polycationic polymer and thereby encapsulating the at least one compound, d) reversible cross-linking of the at least one polyanionic or polycationic polymer of step c) with at least one cross-linker; e) removal of the organic solvent. Furthermore, the invention relates to a functionalized surface, a functionalized surface for use in medicine and a method for releasing a compound ex vivo.

The present disclosure provides technology that can ensure excellent visibility when introducing an embolization agent and that reduces the visibility of said agent after introduction. Provided is an embolization agent having a hydrogel which contains a visualizing agent, and a reaction product of an ethylenically unsaturated monomer, a crosslinking agent, and, as necessary, a bifunctional monomer, where the swelling ratio of the embolization agent is 5-300 times, and the post-swelling CT number of the embolization agent is 50-300 HU and falls below the pre-swelling CT number of the embolization agent.

The present disclosure provides technology that can ensure excellent visibility when introducing an embolization agent and that reduces the visibility of said agent after introduction. Provided is an embolization agent having a hydrogel which contains a visualizing agent, and a reaction product of an ethylenically unsaturated monomer, a crosslinking agent, and, as necessary, a bifunctional monomer, where the swelling ratio of the embolization agent is 5-300 times, and the post-swelling CT number of the embolization agent is 50-300 HU and falls below the pre-swelling CT number of the embolization agent.

A method of producing embolic particles includes forming a master batch of embolic particles, wherein the master batch of particles includes a plurality of negatively charged loading sites. The method also includes modifying the master batch of particles to form an activated batch of particles by reacting the master patch of particles with a bridging agent. The activated batch of particles includes a plurality of activated loading sites configured to bond to a negatively charged drug.

Nonwoven resorbable pouches that at least partially enclose implantable medical devices and improved methods for producing the implantable medical device pouches are described. The nonwoven pouches may comprise one or more drugs. Implantable medical devices that are placed in the pouches prior to implantation are prevented from migrating from the site of implantation by tissue ingrowth into the pouch. Antibiotics may be incorporated into the pouches to prevent post-operative infections. The pouches may be formed in fewer steps than conventional pouches, and without polymer coatings. Nonwoven pouches can be formed in one step by dry spinning instead of using multiple processing steps. In embodiments, the nonwoven pouches are smoother on the inside than the outside to tightly fit the implantable medical devices internally while encouraging external tissue ingrowth. In embodiments, the nonwoven pouches eliminate the use of knitted or woven multifilament fibers that can trap bacteria and result in post-operative infection.

An implantable medical device includes an elongate member having a cross-sectional dimension that is less than 0.00085 inch, wherein the elongate member is made from a material comprising a platinum-tungsten alloy having a percentage of tungsten that is at least 10% by weight or alternatively the implantable medical device includes an elongate member made from a material comprising an alloy containing rhenium.

An implantable medical device includes an elongate member having a cross-sectional dimension that is less than 0.00085 inch, wherein the elongate member is made from a material comprising a platinum-tungsten alloy having a percentage of tungsten that is at least 10% by weight or alternatively the implantable medical device includes an elongate member made from a material comprising an alloy containing rhenium.

A method of producing a medical device having a substrate and a hydrophilic polymer layer, including the steps of: pretreating the substrate by placing the substrate in an alkali solution and heating the substrate at a temperature ranging from 50° C. to 100° C.; and heating a solution containing the pretreated substrate, a hydrophilic polymer having an acidic group and a hydroxyalkyl group, and an organic acid at a temperature ranging from 50° C. to 100° C. Provided is a simple method of producing a medical device imparted with hydrophilicity excellent in durability.