An apparatus for making a biocompatible three-dimensional object including at least one delivery unit arranged to deliver at least one biocompatible fluid substance towards a support body having a matrix surface to obtain a coating layer of a predetermined thickness configured for coating the matrix surface. Furthermore, a handling unit is provided arranged to provide a relative movement according to at least 3 degrees of freedom between the support body and each delivery unit. The support body is arranged to be coated by the delivered biocompatible fluid substance, in order to obtain a three-dimensional object having an object surface copying the matrix surface of the support body.

A method of manufacturing a transport refrigeration unit is provided. The method includes providing an enclosure including an outer layer and a supporter. Providing the enclosure includes supplying one of a first material and a second material to a mold. This also includes supplying the other of the first material and the second material on the one of the first material and the second material that is supplied to the mold. Also, this includes curing the first material and the second material integrally that are supplied to the mold. The first material forms into the outer layer and the second material forms into the supporter. The second material includes a plurality of reinforcing fibers.

A catheter assembly includes an inner liner made of flexible material and an outer layer having a steering mechanism. A catheter assembly is provided that includes an inner liner made of flexible material, and an outer layer having a steering mechanism that includes at least one wire and a corresponding lumen for each of the at least one wire through which the respective wire may travel. The outer layer includes a braided wire assembly that includes at least two wires braided into a wire mesh, and further includes a see-through portion positioned proximate a pull wire extraction location to facilitate extraction.

A catheter assembly includes an inner liner made of flexible material and an outer layer having a steering mechanism. A catheter assembly is provided that includes an inner liner made of flexible material, and an outer layer having a steering mechanism that includes at least one wire and a corresponding lumen for each of the at least one wire through which the respective wire may travel. The outer layer includes a braided wire assembly that includes at least two wires braided into a wire mesh, and further includes a see-through portion positioned proximate a pull wire extraction location to facilitate extraction.

A thermoplastic elastomer (TPE) resin powder includes spherical particles of a thermoplastic elastomer resin that have an average particle diameter of 50 μm to 300 μm.

A Corrosion Inhibiting Sprayable Thermoplastic (“CIST”) cover is formed by spraying melted CIST onto a mold, allowing the CIST to cure, removing the cured cover from the mold using a series of cuts if necessary, positioning the cover on a mechanical assembly whose shape is significantly identical to the mold, and fusing the cuts on the cover using heat to reform the cover on the mechanical assembly.

A Corrosion Inhibiting Sprayable Thermoplastic (“CIST”) cover is formed by spraying melted CIST onto a mold, allowing the CIST to cure, removing the cured cover from the mold using a series of cuts if necessary, positioning the cover on a mechanical assembly whose shape is significantly identical to the mold, and fusing the cuts on the cover using heat to reform the cover on the mechanical assembly.

The present invention is a unique process of manufacturing rigid members with precise “shape keeping” properties and with reflective properties pertaining to radio frequency energy, so that air, land, sea and space devices or vehicles may be constructed including parabolic reflectors formed without discrete permanent layering. Rather, such parabolic reflectors or similarly, vehicles, may be formed by homogeneous construction where discrete layering is absent, and where energy reflectivity or scattering characteristics are embedded within the homogeneous mixture of carbon nanotubes and associated graphite powders and epoxy, resins and hardeners. The mixture of carbon graphite nanofiber and carbon nanotubes generates higher electrode conductivity and magnetized attraction through molecular polarization. In effect, the rigid members may be tuned based on the application. The combination of these materials creates a unique matrix that is then set in a memory form at a specific temperature, and then applied to various materials through a series of multiple layers, resulting in unparalleled strength and durability.

The present invention is a unique process of manufacturing rigid members with precise “shape keeping” properties and with reflective properties pertaining to radio frequency energy, so that air, land, sea and space devices or vehicles may be constructed including parabolic reflectors formed without discrete permanent layering. Rather, such parabolic reflectors or similarly, vehicles, may be formed by homogeneous construction where discrete layering is absent, and where energy reflectivity or scattering characteristics are embedded within the homogeneous mixture of carbon nanotubes and associated graphite powders and epoxy, resins and hardeners. The mixture of carbon graphite nanofiber and carbon nanotubes generates higher electrode conductivity and magnetized attraction through molecular polarization. In effect, the rigid members may be tuned based on the application. The combination of these materials creates a unique matrix that is then set in a memory form at a specific temperature, and then applied to various materials through a series of multiple layers, resulting in unparalleled strength and durability.

The invention provides a system (1) and method for manufacturing a stent. A spraying device (14) sprays a polymeric suspension (16) onto a mandrel (4). During spraying of the polymeric suspension (16) onto the mandrel (4), the mandrel (4) is manipulated by a micromanipulator (8) to produce a continuous coating on the mandrel (4) having a nonuniform thickness. The polymeric coating is allowed to cure on the mandrel (4) to form the stent, which is then removed from the mandrel (4). The method can comprise embedding a filament (2) in the polymeric coating and incorporating one or more drugs in the stent.