A catheter includes a handle with torqueing and steering mechanisms. The torqueing mechanism includes a rotatable nosecone and a bearing coupled to the nosecone to be rotatable therewith. The bearing is concentrically disposed over a shaft of the catheter. The steering mechanism includes a rack coupled to the bearing to be slideable therewith and a pull wire having a proximal end attached to the bearing and a distal end attached to a distal portion of the shaft. Rotation of the nosecone causes an entire length of the shaft to rotate and axial movement of the rack tensions the pull wire to bend the distal portion of the shaft. A valve relief component is slidingly disposed over the shaft and is configured to dock onto the handle when not in use.

The present invention provides a delivery device for medical implants. The delivery device has a detachable structure and includes a handle (3) and a catheter assembly (1) that are separated from each other. The handle (3) and the catheter assembly (1) are connected by a transmission shaft (2). By configuring the handle (3) and the catheter assembly (1) to be separated from each other, the catheter assembly (1) has less weight than that of a traditional delivery assembly, so that the operator can position the medical implant and adjust the position of the medical implant by moving only the catheter assembly (1). The catheter assembly (1) is lighter in weight and smaller in size, which improves the stability, precision and accuracy of the operation. Moreover, the impact of vibration and/or movement of the handle (3) on the catheter assembly (1) are avoided, which further improves the stability and thus the quality of the operation.

Prosthesis deployment devices are disclosed herein. In some embodiments, the prosthesis deployment device comprises an elongate delivery catheter assembly configured for electrosurgery and also configured to retain and deploy a prosthesis. Kits comprising the prosthesis deployment devices with a prosthesis loaded into a prosthesis pod of the device are disclosed herein as well as methods of using the prosthesis deployment devices.

A system for delivering a replacement heart valve implant may include the implant including an expandable framework and leaflets coupled to the framework, and a delivery device including a handle and an elongate catheter extending from the handle. The catheter includes an outer sheath and an inner shaft movably disposed within the outer sheath. The implant is releasably coupled to the inner shaft. The inner shaft includes an orientation lumen extending longitudinally within the inner shaft, the orientation lumen being offset from a central guidewire lumen of the inner shaft. The delivery device includes an orientation mandrel disposed within the orientation lumen, the orientation mandrel extending distally from the handle to a distal end proximate a closed distal end of the orientation lumen. The orientation mandrel is operably coupled to an orientation mechanism of the handle configured to apply compressive force or tensile force to the orientation mandrel.

A hemostasis valve for use with catheters in intravascular procedures. The hemostasis valve comprising a sealable fluid channel that bifurcates from a single distal lumen to two proximal lumens. An upper proximal lumen may include a funnel shaped opening to improve aspiration potential. Rotating locking mechanisms are attachable at the ends of the hemostasis valve to interlock coaxial devices or to form seals around coaxial devices. Injection molding may be used to manufacture a hemostasis valve and its components. A mold and core pins may impart external and internal shapes to a molten polymer. Once the polymer has cooled, the molded component is separated from any pins or molds and attached to other molded components to form an assembled hemostasis valve.

A drive assembly for a catheter procedure includes a body configured to receive a percutaneous device where the body has a first end and a second end. A distal pinch is configured to releasably engage the percutaneous device. A proximal pinch is positioned on the first end of the body and is configured to releasably engage the percutaneous device. A linear drive mechanism is coupled to the body and configured to move the body to cause linear movement of the percutaneous device in a first direction while the proximal pinch is disengaged from the percutaneous device and the distal pinch is engaged with the percutaneous device.

Various systems, devices, and methods for endovascular implants and placement thereof are disclosed. The implants include a proximal implant segment, a distal implant segment, connector struts connecting the proximal implant segment to the distal implant segment, and a side opening between the proximal implant segment and the distal implant segment. The implants can be used to create an arteriovenous fistula or connect one vessel of the body to another by placement of the proximal implant segment and the distal implant segment within the vessels to be connected. The implants can include one or more anchors for securing the implant in place with respect to the vessels of the body it is connecting. The implants can also include a continuous strut or ring at a distal edge of the proximal implant segment. Also disclosed are methods for percutaneous placement of the implants, and a device for percutaneous delivery.

A steerable catheter, such as a dilator, includes an elongated shaft including a proximal end portion and a distal end portion, an end effector disposed at the distal end portion of the shaft, and a handle disposed at the proximal end portion of the shaft. The end effector includes a dilation portion disposed proximate the distal end portion of the shaft, a transition portion disposed distally on the dilation portion, and a distal tip portion disposed distally on the transition portion. The tip portion is movable relative to the dilation portion. The handle includes a tip portion steering actuator enabling a user to steer the tip portion. The tip portion has a tip portion diameter. The dilation portion has a dilation portion diameter which is greater than the tip portion diameter. The transition portion tapers from the tip portion diameter to the dilation portion diameter.

Methods for the rapid retraction of trans-catheter heart valve delivery systems are provided. A rapid retraction trans-catheter heart valve delivery system comprises a catheter based delivery system. The delivery system has internal mechanisms that allow for the controlled deployment of a heart valve prosthesis, as well as mechanisms that allow for quickly closing the catheter once the heart valve prosthesis has been implanted. This rapid retraction ability allows for reduced procedural durations and thus reduced risk to the patient.

A prosthetic valve may be used to repair a diseased or otherwise damaged heart valve such as the mitral valve. The prosthetic valve may include atraumatic anchor tabs which may be radiopaque or echogenic. A cinching mechanism may also be coupled to the prosthetic valve to control radial expansion of the prosthetic valve. The cinching mechanism may include a wire lasso or a belt. The prosthetic valve may include an expandable frame which has a reduced number of strut connection nodes to allow a lower profile collapsed configuration and tighter crimping. The commissure posts of the prosthetic valve may extend beyond an edge of the ventricular skirt portion of the device.