An endovascular system employs a lever structure to deploy an embolic device at a target site in the vasculature of a patient. The endovascular system comprises an elongate tubular member provided with a lever structure and an elongate detachment wire to assert an effort to the proximal portion of a lever member outwardly, thereby generating a load to the distal portion of the lever member inwardly to allow the lever structure to engage and secure the embolic device. The elongate detachment wire is disengageable from the lever structure to remove the effort asserted to the proximal portion of the lever member, thereby removing the load off the distal portion of the lever member to allow the lever structure to disengage and release the embolic device.

Systems, apparatus, and methods are described for treatment of varicocele and associated conditions. In some embodiments, systems, apparatus, and methods described herein can include forming one or more fluid connections or fistulas between blood vessels such as a gonadal vein (e.g., spermatic vein, ovarian vein) and surrounding veins. In some embodiments, systems, apparatus, and methods described herein can include occluding one or more blood vessels such as a gonadal vein (e.g., spermatic vein, ovarian vein). In some embodiments, systems, apparatus and methods described herein relate to flow diverters, replacement valves, etc., e.g., for treatment of varicocele and associated conditions.

Apparatus and methods are disclosed for occluding an anatomical structure including an occlusion apparatus having first and second beams and at least one connector for connecting the respective ends of the beams together. The occlusion apparatus may be adapted for use in a deployment device having a pair of jaws and optionally having a respective pair of shuttle bodies for releasably connecting an occlusion apparatus to the jaws while in an open position and for releasing the occlusion device from the jaws while in a closed position. A system for occluding an anatomical structure is also disclosed that includes an occlusion apparatus and a deployment device for holding the occlusion apparatus in an open position for locating the occlusion device adjacent the anatomical structure to be occluded and then moving the occlusion apparatus to a closed position and locking the occlusion apparatus in the closed position.

An apparatus includes a shaft including a distal shaft end. The apparatus also includes a sleeve slidably coupled to the shaft. The sleeve includes a distal sleeve end. The apparatus further includes a colpotomy cup fixedly secured to the distal sleeve end, and an inflatable balloon positioned over the shaft near the distal shaft end such that the inflatable balloon is configured to manipulate an anatomical structure via movement of the shaft. The apparatus also includes at least one sensor configured to detect at least one of a fluid pressure within the inflatable balloon or a force acting upon the inflatable balloon. The at least one sensor is configured to generate at least one feedback signal based on the detected at least one of a fluid pressure or a force.

Implantable therapeutic devices and methods for endovascular placement of devices at a target site, such an opening at a neck of an aneurysm, are disclosed. Selected embodiments of the present technology have closures that at least partially occlude the neck of an aneurysm to stabilize embolic or coagulative treatment of the aneurysm.

Disclosed are a telescopic assembly and an occlusion mechanism. The telescopic assembly includes a rotating shaft, a telescopic piece, and a connecting piece; two spiral orbits extending in an axis direction are disposed on the circumferential side of the rotating shaft, and the spiral orbits are rotatably intersected with each other and communicate on tail ends to form a closed orbit; the telescopic piece sleeves around the rotating shaft; the connecting piece is movably connected to the telescopic piece, and the other end of the connecting piece moves in a spiral orbit groove all the time during movement; and with the rotation of the rotating shaft, the connecting piece drives the telescopic piece to do reciprocating movement along an axis so that the automatic telescopic movement of the telescopic piece is achieved. The telescopic assembly pushes a first rocking bar and a second rocking bar to achieve an occlusion action.

In some aspects, the present disclosure provides a delivery device for delivering a detachable medical implant that comprises an elongated delivery member and a first engagement portion. The first engagement portion comprises a first proximal-facing surface, a first distal-facing surface, and a first lumen that is configured to accommodate an activation wire, wherein at least 50% of a surface area of the first proximal-facing surface is angled away from a proximal end of the first engagement portion. In other aspects, the present disclosure provides a medical delivery system comprising: such a delivery device; an implantable device comprising a medical device portion and a second engagement portion, the second engagement portion comprising a second lumen configured to accommodate an activation wire, a second proximal-facing surface and a second distal-facing surface; and an activation wire. Other aspects pertain to methods of medical device delivery using such a medical delivery system.

A medical device system may include an elongate shaft having a lumen extending from a proximal end to a distal end, a proximal release wire, and a distal release wire. The proximal release wire may extend distally from a proximal end configured to remain outside the body to a distal end and may be slidably disposed within the lumen of the elongate shaft. The distal release wire may extend distally from a proximal end to a distal end and may be slidably disposed within the lumen of the elongate shaft. The proximal end of the distal release wire may be slidably coupled to the distal end of the proximal release wire. The distal release wire may be configured to releasably attach a medical device to the distal end of the elongate shaft.

A system for manipulating a guide catheter within a patient's nasal passages or sinus cavities includes a guide catheter formed from an elongate flexible member having a lumen passing there through. A wire guide is slidably disposed within the lumen of the guide catheter. The system further includes a steering member fixedly secured to a proximal end of the wire guide and a proximal hub secured to a proximal end of the guide catheter. The system further includes a recessed handle having a first recess for fixedly receiving the proximal hub of the guide catheter and a second recess for receiving the steering member, the second recess being dimensioned to permit axial and rotational movement of the steering member while disposed in the second recess.

Intrasaccular devices and methods of implanting the devices in an aneurysm are described. The device includes an expandable body comprising a plurality of elongate filamentary elements each having a first and a second end. Each of the plurality of elongate filamentary elements extends from a first end of the device to a second end of the device and back to the first end of the device. The first and second ends of each of the plurality of elongate members are coupled at the first end of the device in a hub. The device may further include a defect spanning structure made of a mesh. The defect spanning structure may be located around a proximal portion of the expandable body, and may be disposed exteriorly to an outer surface of the expandable body