The present invention relates to a cover for medical injection device, said medical injection device having a hub portion defined at its distal end. The said cover includes: an outer casing formed of a first material, said outer casing having an inner wall having a circumference, an inner casing formed of a second material different from the said first material and defining a cavity capable of receiving in a sealing way at least part of the hub portion, said inner casing having an outer wall having a circumference, and being at least partly inserted within the outer casing and at least partially in contact with the inner wall of the outer casing, a Radio Frequency Identification RFID tag located between the outer casing and the inner casing, said RFID tag comprising a RFID chip connected to at least one RFID antenna, wherein the RFID tag has a width extending between 40% and 100%, 100% being excluded, of the circumference of the outer wall of the inner casing or the whole circumference of the inner wall of the outer casing and wherein the RFID tag has a length extending over at least 50% of a length of the cover. The invention also relates to a medical injection device including the said cover and a method for manufacturing said cover.

The present invention relates to cover for a medical injection device, said medical injection device having a hub portion defined at its distal end. The said cover includes an outer casing formed of a first material, said outer casing having a distal end and a proximal end,—an inner casing formed of a second material different from the said first material and defining a cavity capable of receiving in a sealing way, at least part of the hub portion, said inner casing having a distal end and a proximal end, and being at least partly inserted within the outer casing and at least partially in contact with the outer casing and—at least one substantially ring-shaped Radio Frequency Identification RFID tag embedded within the cover, said ring-shaped RFID tag including a RFID chip connected to at least one ring-shaped RFID antenna. The present invention also relates to a medical injection device and a method for manufacturing a cover.

The neck flange 3 of a tracheostomy tube is of a soft plastics such as silicone and has neck tie or suture openings 35 at opposite ends reinforced to prevent damage to the flange. The openings are reinforced by tubular inserts 38 of a harder plastics. The patient end of each insert has an enlarged, radially extending head 41 sitting flush in an enlarged recess 43 around the patient end of each opening. The opposite end of each insert also has an enlarged head 42 overlapping the flange but formed after the insert has been inserted in the flange. The opposite end head 42 may be heat formed from the end of the insert or may be a separate component clipped onto the end of the insert.

A touch panel includes: a body connected to wiring drawn out to the outside of the touch panel; a sheet member to which decoration printing is added; an adhesive that pastes the sheet member on the body and is the same size as the sheet member; and a non-adhesion film formed between the adhesive and the wiring.

Vascular treatment and methods include a plurality of self-expanding bulbs and a hypotube including interspersed patterns of longitudinally spaced rows of kerfs. Joints between woven structures and hypotubes include solder. Woven structures include patterns of radiopaque filaments measureable under x-ray. Structures are heat treated to include at least shapes at different temperatures. A catheter includes a hypotube including interspersed patterns of longitudinally spaced rows of kerfs. Heat treating systems include a detachable flange. Laser cutting systems include a fluid flow system.

The present disclosure relates to systems, apparatuses, and methods for assembling cartridges for aerosol delivery devices. The cartridges may be assembled by transporting carriages between various substations at which parts are added to a base. In another assembly method, the base may be moved between a plurality of robots which direct the base downwardly into contact with components to couple the components therewith. An inspection system may inspect the cartridges at various stages of completion.

The present disclosure is generally directed to a drive mechanism for use in a drug delivery device having a cylindrical cartridge, i.e. a handheld injection device for selecting and dispensing a number of user variable doses of a medicament. The drive mechanism includes a base element, a toothed piston rod, which is guided within and movable relative to the base portion, and a drive gear having a pinion, which is rotatably held in the base element and in meshed engagement with the toothed piston rod. The toothed piston rod includes multiple rigid rod pieces which are connected by hinges. The rigid rod pieces comprise a flat plate provided with a straight toothed rack.

A valve for use in manufacturing of implantable medical devices is insertable into a bore of the medical device during a manufacturing process. The valve is configured to remain closed while the pressure differential between an internal volume of the implantable medical device and a surrounding environment is below a particular threshold and to open when the threshold is reached, thereby allowing air or other fluids to escape from the internal volume into the surrounding environment. The valves are particularly useful during certain types of coating processes that must be performed at or near vacuum and provide an effective way to prevent ingress of coating material into the internal volume of the implantable medical device.

A system and method for gripping a cylindrical object. The system including: a housing; a plurality of gripping arms in the housing, the gripping arms in pairs each on an opposite side of a centerline plane from another; and a driving wedge in the housing and configured such that movement of the driving wedge moves each pair of gripping arms towards or away from each other while remaining equidistant from the centerline plane. The method including: opening the plurality of gripping arms against a bias by sliding a wedge in a first direction to slide the plurality of gripping arms apart while maintaining an equal predetermined distance from a part alignment position; placing a cylindrical body between the plurality of gripping arms; and closing the plurality of gripping arms by sliding the wedge in an opposite direction to allow the biasing force to close the gripping arms.

Devices and methods for delivering oxygen and other therapeutic gases to a target, such as a tissue, a tissue-engineered construct, and a wound, in a controlled and sustained manner are disclosed.