An intraluminal filtration device for embolic protection includes a device body and each of a coarse filter and a fine filter, for filtering larger-size and smaller-size particles, respectively. The device body includes a body wall extending circumferentially around the longitudinal axis, and being formed at least in part of an organic gel.

A catheter for prevention of stroke by diverting and filtering the blood flow to carotid and vertebral arteries is provided. The catheter includes at least one balloon with an outer mesh cover that expands upon the balloon inflation and collapses upon balloon deflation. Partial inflation of balloons provides for full mesh expansion in the target vessel with resulting capturing and retrieval of embolic particles. The inflation of the balloon in the aortic arch or head vessels expands the balloon associated filtering mesh leading to both filtering and deflection of embolic particles from the cerebral circulation, while balloon deflation triggers the mesh collapse and promotes its recapturing and retrieval while minimizing the risk of spillage of captured emboli.

An endovascular microvalve device for use in a vessel during a therapy procedure includes an outer catheter, an inner catheter displaceable within the outer catheter, and a filter valve coupled to the distal ends of the inner and outer catheters. The valve is constructed of a braid of elongate first filaments coupled together at their proximal ends in a manner that the first filaments are movable relative to each other along their lengths. A filter is provided to the braid formed by electrostatically depositing or spinning polymeric second filaments onto the braided first filaments. The lumen of the inner catheter delivers a therapeutic agent beyond the valve. The device is used to provide a therapy in which a therapeutic agent is infused into an organ.

A distal stabilizer for use for catheter delivery in a biological lumen, the distal stabilizer comprising: a thread-like delivery member; and a locking device that extends from a distal end of the thread-like delivery member and is capable of locking onto an inner wall of the biological lumen with an expanding force. The distal stabilizer is usable in a catheter delivery operation including: releasing the locking device, which has been loaded in a first catheter while being in a reduced diameter state, from a distal end of the first catheter, thereby causing the locking device to lock onto the inner wall; and advancing a catheter including a second catheter having an inner diameter larger than the first catheter toward a distal side while the locking device remains locked on the inner wall. The distal stabilizer is configured such that after completion of the catheter delivery operation, the locking device is reduced in diameter to be resheathed into one of the catheters, and the distal stabilizer is removed out of the biological lumen.

Devices, systems, and methods for treating the pancreas are disclosed herein. For example, some aspects of the technology are directed to a method for treating a medical condition affecting the pancreas of a human patient, wherein the method comprises implanting an occlusive device within the pancreatic duct to induce atrophy of pancreatic tissue.

A catheter for prevention of stroke by diverting and filtering the blood flow to carotid and vertebral arteries is provided. The catheter includes at least one balloon with an outer mesh cover that expands upon the balloon inflation and collapses upon balloon deflation. Partial inflation of balloons provides for full mesh expansion in the target vessel with resulting capturing and retrieval of embolic particles. The inflation of the balloon in the aortic arch or head vessels expands the balloon associated filtering mesh leading to both filtering and deflection of embolic particles from the cerebral circulation, while balloon deflation triggers the mesh collapse and promotes its recapturing and retrieval while minimizing the risk of spillage of captured emboli.

A catheter according to an embodiment of the present disclosure includes a mesh member, a first hollow shaft, a front end tip, a guiding film, and a core wire. The mesh member has a tubular shape and is radially expandable and contractable. The guiding film is formed with a stretchable material and is disposed on the mesh member, the guiding film having a front end located between a base end of the front end tip and a front end of the first hollow shaft. A thickness of a base end of the guiding film is larger than a thickness of the front end of the guiding film.

A medical device to be inserted into a blood vessel for effectively removing an object flowing in a biological lumen while reducing the burden on the living body includes an elongated shaft portion, and an expansion portion which is an elastically deformable cylindrical body having a plurality of gaps and in which a proximal portion or a distal portion of the cylindrical body is interlocked with the shaft portion. The expansion portion has a ring-shaped or annular bent portion which protrudes toward a proximal side position radially outside the expansion portion in a bent state of being bent along an axial direction, and an axial length of a second portion from the bent portion to a proximal end of the expansion portion is shorter than an axial length of a first portion from the bent portion to the distal end of the expansion portion.

The present disclosure relates to an implantable device having a frame and a flow restrictor. The frame includes a central portion and an end portion on either end of the frame. The flow restrictor is disposed within a lumen of the frame. The flow restrictor is configured to transition between a collapsed configuration and a deployed configuration. The flow restrictor may include a porosity configured to reduce fluid flow through the flow restrictor without completely occluding fluid flow.

A filter (10) includes a proximal end (1), a distal end (2) and a main filter body connected between the proximal end (1) and the distal end (2). The main filter body has a first filter unit (3) and a second filter unit (4), both being conical mesh structures, as well as multiple intermediate connection posts (5) connecting the first filter unit and the second filter unit. The intermediate connection posts (5) have provided thereon support posts (6). A support post (6) includes a transition segment (61) extending from an intermediate connection post (5) to a blood vessel wall, and a support segment bent and extending from the transition segment (61), and at least partially abutting the blood vessel wall. The support segment has a main body (62) bent and extending from the end of the transition segment (61) and a flexible segment (63) bent and extending from the main body (62). A diameter of at least a portion of the flexible section (63) along a length thereof is smaller than a diameter of the main body (62), thereby increasing flexibility of the support section and preventing the support section from puncturing the blood vessel wall.