A delivery device includes a handle, a sheath distally extending from the handle, a capsule distally extending from the sheath, and a pull wire having a proximal end attached to the handle and a distal end attached to the capsule. The sheath defines a central lumen there-through and has a longitudinally-extending lumen formed within a wall of the sheath. The capsule has a tubular body with an intermediate region having a plurality of ribs and a plurality of slots defined therein. The capsule includes an indented segment defined on the tubular body, the indented segment being disposed radially inward relative to the tubular body. The pull wire is tensioned to bend the capsule. The pull wire is slidably disposed within the longitudinally-extending lumen of the sheath and along an inner surface of the tubular body of the capsule with a portion of the pull wire crossing over an outer surface of the indented segment.

Aspects of the disclosure include delivery devices for transcatheter delivery of a cardiac implant. Delivery devices can include a handle assembly as well as a piston mount connected to the handle assembly and having a distal portion terminating at a nose cap. The distal portion includes a stop extending radially from and fixed to the distal portion. The delivery device further includes a capsule assembly including a biasing element for selectively sheathing the implant and a plurality of retraction members secured about a distal end of the biasing element to control deployment of the implant. In various examples, the biasing element is a helical compression spring and the implant is a prosthetic tricuspid heart valve. Methods of loading a delivery device and delivering an implant are also disclosed.

An expandable sheath is disclosed herein, which has a first polymeric layer and a braided layer positioned radially outward of the first polymeric layer. The braided layer includes a plurality of filaments braided together. The expandable sheaths further include a resilient elastic layer positioned radially outward of the braided layer. The elastic layer is configured to apply radial force to the braided layer and the first polymeric layer. The expandable sheath further includes a second polymeric layer positioned radially outward of the elastic layer and bonded to the first polymeric layer such that the braided layer and the elastic layer are encapsulated between the first and second polymeric layers. Methods of making and using the devices disclosed herein are also disclosed, as are crimping devices that may be used in methods of making the devices disclosed herein.

Distal tips for use with delivery catheters are disclosed that are configured to facilitate deflection of the catheters as they are advanced through the vasculature to a desired treatment site. Distal tips so configured realize one or more of the objectives of safer, more accurate steering of the catheter through the vasculature.

The disclosure is directed to a pre-loaded stent graft delivery device. The pre-loaded stent graft delivery device includes a guide wire catheter having a guide wire lumen therethrough; and a handle assembly disposed at a distal end of the guide wire catheter. The handle assembly includes a proximal handle, a rotational handle, a slot, and a sheath follower. The proximal handle, including a manifold including at least one side port, is disposed at a proximal end of the handle assembly. The slot is disposed inside the rotational handle, and is fixed and remains stationary relative to the proximal handle. The sheath follower is disposed slidably in the slot and fixed to a distal portion of a sheath. The rotational handle includes an internal thread mechanically coupled with the sheath follower, so that, when the rotational handle rotates toward a first rotational direction, the sheath is pulled to move distally.

A delivery catheter comprises an inner shaft and an outer sheath. A stent-graft is held on a region of the inner shaft. An enlarged diameter distal region of the outer sheath constrains the stent-graft. Its retraction allows the stent-graft to deploy. A finger wheel on a handle is used to retract the outer sheath and is coupled to a sliding block with cable(s). The sliding block is coupled to the outer sheath and is held within a sliding track. The wheel can be actuated to tension the cable(s) and deform latch(es) coupled to sliding block, freeing them from slot(s) in the sliding track and allowing retraction of the sliding block and the outer sheath. A reinforcement sleeve is coupled to a smaller diameter proximal region of the outer sheath. A gap between the outer sheath distal region and the reinforcement sleeve allows the distal outer shaft region to be retracted.

A delivery system for delivering a stent to a body lumen. The delivery system includes a tubular member having an expandable stent disposed about the outer surface of the inner tubular member. The stent is maintained in a radially compressed configuration with a removable sheath. The sheath can be released using a variety of techniques.

A stent delivery device that can be inserted into an endoscope. The device includes a guide catheter including a guide tube, an operating wire, and a joint portion that joins the guide tube and the wire. The device also includes a pusher catheter including a first tube through which the wire is inserted and a second tube through which the guide tube is inserted. The device may include a bite prevention portion that can prevent the wire from biting into an inner surface of the second tube. In a state where a distal end of the pusher catheter protrudes from the endoscope channel and the channel includes a curved portion in a curved state, a proximal end of the guide tube, which includes the joint portion, and/or the bite prevention portion can be positioned proximal of a proximal end of the curved portion in the endoscope channel.

Disclosed are systems, methods, and devices for percutaneous retrieval of objects, such as endovascular devices, from an internal body space. The present inventions have vascular, non-vascular (gastrointestinal), and surgical (laproscopic) applications. The inventions include a retrieval end having one or more compressed states and an expanded state, the retrieval end adopting the expanded state when the retrieval end is deployed into a subject's internal body space, the retrieval end having a mouth through which an object can be passed into an interior space within the retrieval end when the retrieval end is in the expanded state, the mouth being adjustable between an opened state and a closed state; wherein when at least a portion of the retrieval end of the inner sheath is transitioned to a compressed state following capture of the object, the retrieval end exerts an inward force that at least partially collapses or compresses the object.

Embodiments of the present disclosure provide a delivery device for controlling the release of a stent in a stepwise manner, including: a core assembly, an outer sheath, which is hollow and mounted around an outer periphery of the core assembly, with a delivering gap being defined therebetween which has a distal space for receiving the folded stent; and a stent restraining assembly, configured to restrain a released part of the stent to be partly unfolded when the stent is in a partly released state in such a way to restrain an outer diameter of the released part of the stent, and to make the stent be fully unfolded when the stent is in a completely released state. Embodiments of the present disclosure further provide a delivery system for controlling the release of a stent in a stepwise manner. The present disclosure facilitates adjust the position of the stent.