A medical device is disclosed and may have a spiral shape structure that can function as a stent, such as a flow diversion stent to treat aneurysms. The medical device may have a spiral shape structure that can function as an occlusive device, for instance to occlude aneurysms. The medical device may include a shape setting structure to selectively adjust the shape of the medical device.

Described here are delivery devices for delivering one or more implants to the body, and methods of using. The delivery devices may deliver implants to a variety of locations within the body, for a number of different uses. In some variations, the delivery devices have a cannula with one or more curved sections. In some variations, a pusher may be used to release one or more implants from the cannula. In some variations, one or more of the released implants may be a self-expanding device. Methods of delivering implants to one or more sinus cavities are also described here.

An anchor configured to maximize the surface area of the anchor to improve anchor retention is disclosed. The anchor may be configured with a width that differs from a thickness of the anchor. In some embodiments, the anchor be configured as a helical ribbon defining a central lumen about a central axis extending through the helical ribbon. The helical ribbon may vary in width, thickness, central lumen diameter, or a combination thereof, along its extent. The anchor may include retention features that are configured to promote tissue and/or implant interaction for improved anchor retention.

Aspects of the disclosure include systems including a delivery device having a handle assembly, a shaft assembly having a distal portion, and a helical elongated member positioned at least partially over the shaft assembly and interconnected to the handle assembly. The system also includes a prosthesis positioned over the distal portion. The prosthesis has a stent frame having an inner surface and an outer surface, a valve structure positioned within the stent frame, and a track formed by one or more guides positioned on and extending from one of the inner or outer surfaces of the stent frame. The helical elongated member is configured to be moved in and out of the track to selectively compress or allow the prosthesis to expand. Methods of loading and delivering the prosthesis using systems of the disclosure are also disclosed.

The invention relates to a device for use in the transcatheter treatment of mitral valve regurgitation, specifically a coaptation assistance element for implantation across the valve; a system including the coaptation assistance element and anchors for implantation; a system including the coaptation assistance element and delivery catheter; and a method for transcatheter implantation of a coaptation element across a heart valve.

The present invention provides a surgical anchor comprising a screw and a coil; said coil having a conical shape, wound around the screw shaft with the first end of the coil being tapered and having a ring circumference smaller than that of the screw head and being engaged to the bottom of the screw head and the second end of the coil being flared with a larger ring circumference and positioned along the screw shaft.

Various embodiments disclosed relate to a device for insertion into the urethra for dilation. The present disclosure includes methods and devices including a device for at least partial insertion into a prostate, the device including first and second elongated members each having at least one magnetizable or magnetic element. The first and second elongated members are magnetizable to repel each other to dilate a lumen therebetween.

Ureteral or bladder catheters are provided, including (a) a proximal portion; and (b) a distal portion, the distal portion including a retention portion that includes one or more protected drainage holes, ports or perforations and is configured to establish an outer periphery or protective surface area that inhibits mucosal tissue from occluding the one or more protected drainage holes, ports or perforations upon application of negative pressure through the catheter. Systems, kits and methods for inducing negative pressure to increase renal function also are provided.

Some embodiments of the present disclosure are directed generally to systems and methods for delivering an implant to a body vessel of a patient. Such disclosed implants may be a monofilament implant, and disclosed systems for implanting the implant may be automatic. Some embodiments may enable retraction of said implant back into the delivery system following partial exteriorization of the implant from the delivery system. Some embodiments may be configured for retraction of said implant from the patient's body following complete exteriorization of the implant from the delivery system. Some of the embodiments are directed at delivering a monofilament implant for preventing embolic stroke. Other embodiments are directed at preventing pulmonary embolism, occluding a body vessel such as the left atrial appendage, occluding a body passageway such as a patent foramen ovalae, stenting a body vessel, or releasing a local therapeutic agent such as a drug or ionizing radiation.

A ringless web is configured to repair heart valve function in patients suffering from degenerative mitral valve regurgitation (DMR) or functional mitral valve regurgitation (FMR). In accordance with various embodiments, a ringless web can be anchored at one or more locations below the valve plane in the ventricle, such as at a papillary muscle, and one or more locations above the valve plane, such as in the valve annulus. A tensioning mechanism connecting the ringless web to one or more of the anchors can be used to adjust a tension of the web such that web restrains the leaflet to prevent prolapse by restricting leaflet motion to the coaptation zone and/or promotes natural coaptation of the valve leaflets.