To provide a bioimplant capable of controlling a rate of an antibacterial agent and an antibiotic to be eluted from the coating film. An evanescent coating film made of a calcium phosphate-based material having crystallinity of 10% to 90% is formed at a predetermined area of the bioimplant and an antibacterial agent or an antibiotic is contained in the coating film to suppress adhesion of bacteria.

Novel, lubricious coatings for medical devices are disclosed. The coatings provide improved lubricity and durability, and are readily applied in coating processes. The present invention is also directed to a novel platinum catalyst for use in such coatings. The catalyst provides for rapid curing, while inhibiting cross-linking at ambient temperatures, thereby improving the production pot life of the coatings.

A method of producing bioengineered tissue includes coating a microstructured fiber with a bioink containing a plurality of living cells. The microstructured fiber is embedded with microfluidic channels defining periodic outlet apertures, a plurality of ultrasonic transducers, at least one chemical sensor, and at least one temperature sensor. The method further includes applying the coated fiber to an anatomic model of an organ. The microfluidic channels and outlet apertures of the fiber are configured to function as an artificial blood-vessel system to the bioengineered tissue, thereby supplying building material for the proliferation of the plurality of living cells, and allowing the bioengineered tissue to mature into functional tissue.

A medical device for repairing injuries to the spinal cord or peripheral nerve has a first flexible substrate supporting first nanoparticles selected from the group consisting of silicon, carbon, gold and titanium, at least partially embedded in a binding layer joined to the first flexible substrate. Each first nanoparticle develops along a preferential direction of development. The nanoparticles are oriented so that, statistically, the preferential direction of development is parallel to a first orientation of growth. Stem cells are at least partially embedded in the binding layer. The first nanoparticles are functionalized so that stem cell differentiation along the first nanoparticles is guided in the first orientation of growth. The first flexible substrate is suitable to assume a distended configuration and a wrapped configuration in which it is wrapped around the spinal cord or peripheral nerve whereby the first orientation of growth is statistically parallel to the neuronal direction of extension of neurons of the spinal cord or peripheral nerve.

In an embodiment, a method for loading a powder substance (10) into recesses (200) provided at a stent (S) surface, the method comprises: applying compression (100) to the powder substance (10) to thereby form tablets insertable into said recesses (200), inserting the tablets into the recesses (200) of the stent (S).

A coated powder composite may include a core particle of Ca or an alloy thereof, or of Mg or an alloy thereof. One or more coating layers may be disposed about the core particle, cladding the core particle. The coated powder composite may be biodegradable.

Nitric oxide-releasing materials, methods of making nitric oxide-releasing materials, and uses of nitric oxide-releasing materials are provided. The nitric oxide-releasing materials include a mesoporous silica core and an outer surface having a plurality of nitric oxide donors. In an exemplary aspects, the nitric oxide-releasing material includes a mesoporous diatomaceous earth core, and an outer surface having a plurality of S-nitroso-N-acetyl-penicillamine groups covalently attached thereto. Uses of the nitric oxide-releasing materials can include coatings for medical devices such as catheters, grafts, and stents; wound gauzes; acne medications; and antiseptic mouthwashes; among others.

A leaflet for a prosthetic valve formed of at least one layer that includes a composite material containing at least one expanded fluoropolymer membrane having serpentine fibrils and an elastomer is provided. The fluoropolymer may be polytetrafluoroethylene. In at least one embodiment, the elastic properties are present in an axial direction the leaflet. The leaflets may be single layered or multi-layered. The leaflets may be coupled to a support structure and movable between open and closed configurations relative to the support structure to form a heart valve. The elasticity within the leaflets permits, among other things, the leaflets to bend with a reduced occurrence of wrinkles as the valve opens and closes. The elastic properties of the leaflet also, among other things, improve bending properties and reduce closure stresses, thereby extending the life of the leaflet.

A method for controlling generation of biologically desirable voids in a composition placed in proximity to bone or other tissue in a patient by selecting at least one water-soluble inorganic material having a desired particle size and solubility, and mixing the water-soluble inorganic material with at least one poorly-water-soluble or biodegradable matrix material. The matrix material, after it is mixed with the water-soluble inorganic material, is placed into the patient in proximity to tissue so that the water-soluble inorganic material dissolves at a predetermined rate to generate biologically desirable voids in the matrix material into which bone or other tissue can then grow.

A biodegradable in vivo supporting device is disclosed. In one embodiment, a coated stent device includes a biodegradable metal alloy scaffold made from a magnesium alloy, iron alloy, zinc alloy, or combination thereof, and the metal scaffold comprises a plurality of metal struts. The metal struts are at least partially covered with a biodegradable polymer coating. A method for making and a method for using a biodegradable in vivo supporting device are also disclosed.