A stent Includes a stent body formed by a strut. The stent body is cylindrically-shaped and extends in an axial direction. The stent body includes a plurality of helical portions and an annular portion. The strut is helically-shaped along the axial direction to form the plurality of helical portions and the strut is annularly-shaped in the circumferential direction to form the annular portion. Each of the plurality of helical portions has a distal end point and a proximal end point. The plurality of helical portions include a first helical portion and a second helical portion adjacent to the first helical portion in the axial direction. The annular portion is disposed between the first and second helical portions in the axial direction. At least one of the distal and proximal end points of the plurality of helical portions is directly connected to the annular portion.

A stent includes a strut formed into a cylindrical shape and extending in an axial direction. The strut includes outer peripheral portions extending around the axial and circumferential directions of the cylindrical shape. The outer peripheral portions are spaced apart from one another with gaps formed between adjacent outer peripheral portions. The strut includes a connection portion connecting the outer peripheral portions to each other in one of the gaps formed by the adjacent outer peripheral portions. The outer peripheral portions and the connection portion of the strut are integrally formed of a biodegradable polymer A portion of the strut includes a fragile portion which is snore fragile than other portions of the strut.

A stent delivery device for deploying a low column strength stent may include an inner member having a distal region and a stent receiving area disposed therein. A low column strength stent convertible between a compressed configuration and an expanded configuration may be disposed on the stent receiving area. The stent receiving area may include a soft durometer polymer configured to permit the low column strength stent to sink into the soft durometer polymer when the low column strength stent is in the compressed configuration. An outer member may be moveable between an extended position in which the outer member extends over the stent and a retracted position in which the outer member is proximal of the stent.

Devices for delivering and deploying a prosthesis are disclosed and comprise a sheath, a prosthesis disposed within a distal end portion of the sheath, and a wire having a first end coupled to the prosthesis and a second end coupled to the sheath. A body portion of the wire comprises a slack in the wire, and the sheath, prosthesis, and wire are configured so that a proximal movement of the sheath relative to the prosthesis reduces the slack in the wire, and a subsequent proximal movement of the sheath relative to the prosthesis decouples the wire from the prosthesis. Additional devices, systems, and methods are disclosed.

An intraluminal device and method of resisting migration of a device in a lumen, the lumen having muscle defining an intraluminal sphincter includes a device having a body with a size and shape of a portion of the lumen. The device further includes at least one tine extending distally from the body. The at least one tine is rigid or semi rigid. The device is deployed in the lumen with the body proximal the sphincter with respect to peristaltic movement of the lumen and with the at least one tine penetrating the muscle of the sphincter to resist distal migration.

This disclosure concerns systems and methods for tissue volume reduction and control of the flow of substances through the body. Systems according to the various embodiments of the disclosure include check valves formed from wire coils which are deployable through a tubular lumen, such as the working channel of an endoscope, or a catheter.

The invention discloses a Zn—Ga series alloy and a preparation method and application thereof, belonging to the technical field of medical alloys. The Zn—Ga series alloy includes Zn and Ga, and Ga accounts for 0-30 wt % but not including 0. The preparation method is to mix Zn and Ga or Zn, Ga and trace elements, then to obtain a Zn—Ga series alloy by coating paint after smelting or sintering. The mechanical properties of the prepared Zn—Ga series alloy meet the requirements of the strength and toughness of medical implant materials, and it can be degraded in vivo. It has the dual characteristics of biological corrosion degradation and suitable corrosion rate to provide long-term effective mechanical support.

Provided is a treatment method and medical apparatus for preventing an object that becomes a causative agent causing pathogenesis of aspiration pneumonitis from invading a lung The treatment method includes a disposing step of disposing a first instrument, which allows the object that becomes a causative agent of aspiration pneumonitis to move from an esophagus to a stomach and suppresses movement of the object from the stomach to a larynx, in the esophagus and disposing a second instrument, which suppresses the object from invading the lung, in at least the larynx.

The present invention relates to a stent delivery device having: a first support rod into which a first movable body is inserted; a fixed magnet; and a second support rod into which a second movable body is inserted, wherein a first driving magnet included in the first movable body and a second driving magnet included in the second movable body rotate relative to each other by means of the control of an external magnetic field at a predetermined angle around an axis in a first direction with respect to the fixed magnet, thereby separating a first coupling piece and a second coupling piece from a first coupling groove and a second coupling groove and enabling a stent to unfold.

Aspects of the disclosure relate methods and synthetic scaffolds for regenerating gastrointestinal tissue (e.g., esophageal tissue).