Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: Embodiments herein provide differential dilation stents for use in percutaneous interventions, such as transluminal bypass procedures. In some embodiments, the stents may be used in the process of creating an arteriovenous (AV) fistula during a percutaneous bypass procedure, and such stents may have two or more specialized regions that are configured to adopt a predetermined diameter, shape, and/or tensile strength upon insertion in order to suit the needs of the vessel or procedure. The disclosed stents may be used for creating and/or maintaining an arterial/venous fistula for bypass of an occlusion in a cardiac artery using a cardiac vein, or the femoral artery, for example using the tibial or popliteal vein.

Abstract: Embodiments herein provide differential dilation stents for use in percutaneous interventions, such as transluminal bypass procedures. In some embodiments, the stents may be used in the process of creating an arteriovenous (AV) fistula during a percutaneous bypass procedure, and such stents may have two or more specialized regions that are configured to adopt a predetermined diameter, shape, and/or tensile strength upon insertion in order to suit the needs of the vessel or procedure. The disclosed stents may be used for creating and/or maintaining an arterial/venous fistula for bypass of an occlusion in a cardiac artery using a cardiac vein, or the femoral artery, for example using the tibial or popliteal vein.

Abstract: Disclosed herein are extension members for use with a standard guide catheter, which extension members provide backup support against forces that would otherwise tend to dislodge the guide catheter from the branch artery during interventional cardiology devices. During use, the extension member may be deeply seated in a branch artery that branches off from a main artery when extended through the lumen of the guide catheter and beyond the distal end of the guide catheter. An expandable balloon disposed adjacent the distal tip of the extension member provides additional stabilization and backup support. Also disclosed are methods of using the extension members.

Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: Embodiments herein provide differential dilation stents for use in percutaneous interventions, such as transluminal bypass procedures. In some embodiments, the stents may be used in the process of creating an arteriovenous (AV) fistula during a percutaneous bypass procedure, and such stents may have two or more specialized regions that are configured to adopt a predetermined diameter, shape, and/or tensile strength upon insertion in order to suit the needs of the vessel or procedure. The disclosed stents may be used for creating and/or maintaining an arterial/venous fistula for bypass of an occlusion in a cardiac artery using a cardiac vein, or the femoral artery, for example using the tibial or popliteal vein.

Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: A catheterization system for treatment of a condition within a blood vessel is provided with a catheter, a balloon immediately adjacent to the distal end of the catheter, an inflation device for expanding the balloon, and a fluid injection device for injecting a treatment fluid through the central lumen of the catheter and out of the aperture at the distal end of the catheter into the treatment area. The system may include an RF wire, a hollow needle wire, a dissection tool, or a laser wire insertable through the central lumen of the catheter and selectively operable adjacent the proximal end of the catheter to apply treatment within the blood vessel.

Abstract: Catheterization systems and methods for treatment of a condition within a blood vessel are provided that include the use of a catheter, a balloon immediately adjacent to the distal end of the catheter, an inflation device for expanding the balloon, and an occlusion-penetrating device for gaining access through an occlusion. The occlusion penetrating device may include an indeflator configured to injected fluid at a high pressure, an RF wire, a hollow needle wire, a dissection tool, a laser wire, or even a very small balloon to exploit existing microchannels in the occlusion.

Abstract: A system for deploying a stent-graft from the femoral artery into the femoral vein and back into the femoral artery in order to bypass a femoral occlusion comprises a penetration catheter and a guidewire capture and stabilization catheter. The penetration catheter may be advanced contralaterally to a location above the occlusion and the capture and stabilization catheter may be introduced upwardly through the femoral vein. The penetration tool on the penetration catheter is used in multiple steps to deploy guidewires which are then used to deploy the stent-graft in the desired location.

Abstract: Disclosed herein are systems and methods for protecting a subject from embolisms during TAVI and other percutaneous valve procedures. Some embodiments include two flexible catheters designed to pass over a guidewire into two separate arteries, such as carotid or innominate arteries, each flexible catheter including a vessel blocking mechanism and a bypass feature that prevents ischemia while the vessel blocking mechanism is in use. Other embodiments include a single, bifurcated flexible catheter having two arms, each of which is configured to protect a different artery. In some embodiments, each arm includes a vessel blocking mechanism and a bypass feature that prevents ischemia while the vessel blocking mechanism is in use. In some embodiments, the systems also may include one or more concentric guidewires.

Abstract: Disclosed herein are systems and methods for protecting a subject from embolisms during TAVI percutaneous valve procedures, coronary bypass surgery and heart valve surgery. Various embodiments include an intravascular embolism protection device that includes an elongated, compliant frame made from a material having a shape-memory function, and a mesh material coupled to the elongated, compliant frame, the mesh material having a pore size selected to allow blood to pass therethrough while retaining potential emboli. In some embodiments, the embolism protection device has a collapsed state wherein device is configured to fit within the lumen of a support catheter and an expanded state wherein the embolism protection device is configured to cover a plurality of arterial branch ostias.

Abstract: Wire systems for the ablation of occlusions within blood vessels are provided. Systems include one or more wires configured for percutaneous insertion in a blood vessel, the wires configured to ablate an occlusion within the blood vessel. In some embodiments, a wire is gradually tapered near its distal end so that it can be used to pierce occlusions. In some cases, it may be used to dilate existing microchannels within occlusions. In some embodiments, a capture device is inserted towards the occlusion from either the same or opposite side as the tapered wire, and is used to draw the wire through the occlusion.

Abstract: Embodiments herein provide systems and methods for the treatment of hypertension. In various embodiments, methods and devices are provided that may be used to treat hypertension in a subject by applying energy, such as radio frequency (RF), microwave, ultrasound, or cryo energy, to one or more renal sympathetic and/or parasympathetic nerves, thereby selectively denervating the renal sympathetic and/or parasympathetic nerves. An exemplary system in accordance with the present disclosure may include a plurality of wires or one or more flexible mesh elements that are extendable from a catheter to expand and contact the inner wall of a conduit at a plurality of points. Additionally, in various embodiments the disclosed methods and devices may be used not only in the renal arteries, but also in the renal veins and/or in the renal pelvis and/or ureter.

Abstract: Embodiments herein provide differential dilation stents for use in percutaneous interventions, such as transluminal bypass procedures. In some embodiments, the stents may be used in the process of creating an arteriovenous (AV) fistula during a percutaneous bypass procedure, and such stents may have two or more specialized regions that are configured to adopt a predetermined diameter, shape, and/or tensile strength upon insertion in order to suit the needs of the vessel or procedure. The disclosed stents may be used for creating and/or maintaining an arterial/venous fistula for bypass of an occlusion in a cardiac artery using a cardiac vein, or the femoral artery, for example using the tibial or popliteal vein.

Abstract: A stent system is provided for percutaneous insertion in an artery of a main stent which may include at least one peripheral fenestration defined through the stent wall. The peripheral fenestration may be configured to be expanded in situ to receive a peripheral stent. The stent system also may include a peripheral stent configured to be inserted into the peripheral fenestration of the main stent. The peripheral stent may extend, when inserted in the peripheral fenestration, generally perpendicular to the longitudinal axis of the main stent. The stent system may further include a guidewire, insertable through the peripheral aperture, for maneuvering the main stent into place in the artery. The guidewire may be tapered toward its distal end. The stent system may also include a dilation device for dilating the peripheral stent within the peripheral aperture.

Abstract: Disclosed herein are systems and methods for protecting a subject from embolisms during TAVI and other percutaneous valve procedures. Some embodiments include two flexible catheters designed to pass over a guidewire into two separate arteries, such as carotid or innominate arteries, each flexible catheter including a vessel blocking mechanism and a bypass feature that prevents ischemia while the vessel blocking mechanism is in use. Other embodiments include a single, bifurcated flexible catheter having two arms, each of which is configured to protect a different artery. In some embodiments, each arm includes a vessel blocking mechanism and a bypass feature that prevents ischemia while the vessel blocking mechanism is in use. In some embodiments, the systems also may include one or more concentric guidewires.

Abstract: Disclosed herein are methods and devices for small-vessel access to the vasculature for vascular and cardiac procedures such as diagnostics and interventions, particularly methods and devices for radial, brachial, popliteal, pedal, carotid and/or axillary access to the vasculature. These methods and devices permit vascular and cardiac procedures to be carried out through small vessels, such as the radial or brachial arteries, with a reduced number of steps for the physician and reduced pain and trauma for the patient. As such, the devices and methods may improve a number of outcomes for the patient, such as by reducing the risk of bleeding complications and increasing the speed with which the patient resumes ambulation and other activities following the procedure.