A device and system for thermally affecting tissue that includes a balloon catheter with a reduced distal length for ease of navigation and that also includes a balloon that is more resistant to bursting and delamination. The balloon may include a proximal neck generally attached to an elongate body and a distal neck generally attached to a shaft disposed within the elongate body. The distal neck is turned inward to extend within the balloon chamber and the proximal neck may either extend within the chamber or extend proximally away from the balloon chamber. Alternatively, the device may include an inner balloon and an outer balloon, the distal necks of both being turned inward and extending within the inner balloon chamber. The proximal necks may both also be turned inward to extend within the chamber or the proximal neck of the outer balloon may extend away from the balloon chamber.

Apparatus, systems, and methods are provided for repairing heart valves through percutaneous transcatheter delivery and fixation of annuloplasty rings to heart valves via a trans-apical approach to accessing the heart. A guiding sheath may be introduced into a ventricle of the heart through an access site at an apex of the heart. A distal end of the guiding sheath can be positioned retrograde through the target valve. An annuloplasty ring arranged in a compressed delivery geometry is advanced through the guiding sheath and into a distal portion of the guiding sheath positioned within the atrium of the heart. The distal end of the guiding sheath is retracted, thereby exposing the annuloplasty ring. The annuloplasty ring may be expanded from the delivery geometry to an operable geometry. Anchors on the annuloplasty ring may be deployed to press into and engage tissue of the annulus of the target valve.

Neuromodulation cryotherapeutic devices and associated systems and methods are disclosed herein. A cryotherapeutic device configured in accordance with a particular embodiment of the present technology can include an elongated shaft having distal portion and a supply lumen along at least a portion of the shaft. The shaft can be configured to locate the distal portion intravascularly at a treatment site proximate a renal artery or renal ostium. The supply lumen can be configured to receive a liquid refrigerant. The cryotherapeutic device can further include a cooling assembly at the distal portion of the shaft. The cooling assembly can include an applicator in fluid communication with the supply lumen and configured to deliver cryotherapeutic cooling to nerves proximate the target site when the cooling assembly is in a deployed state.

Systems, devices, and methods for electroporation ablation therapy are disclosed, with the system including a pulse waveform signal generator for medical ablation therapy, and an endocardial ablation device includes at least one electrode for ablation pulse delivery to tissue. The signal generator may deliver voltage pulses to the ablation device in the form of a pulse waveform. The system may include a cardiac stimulator for generation of pacing signals and for sequenced delivery of pulse waveforms in synchrony with the pacing signal.

Apparatus, systems, and methods are provided for repairing heart valves through percutaneous transcatheter delivery and fixation of annuloplasty rings to heart valves via a trans-apical approach to accessing the heart. A guiding sheath may be introduced into a ventricle of the heart through an access site at an apex of the heart. A distal end of the guiding sheath can be positioned retrograde through the target valve. An annuloplasty ring arranged in a compressed delivery geometry is advanced through the guiding sheath and into a distal portion of the guiding sheath positioned within the atrium of the heart. The distal end of the guiding sheath is retracted, thereby exposing the annuloplasty ring. The annuloplasty ring may be expanded from the delivery geometry to an operable geometry. Anchors on the annuloplasty ring may be deployed to press into and engage tissue of the annulus of the target valve.

A catheter system for cryoablation is described that comprises: a catheter, which extends along its longitudinal axis; at least one cryoballoon which surrounds the catheter around its entire circumference and forms a filling lumen; a cooling lumen, which is separate from the filling lumen, within the cryoballoon, wherein the cooling lumen is arranged at the outer region of the cryoballoon away from the longitudinal axis of the catheter; at least one filling conduit which extends within the catheter and terminates in the filling lumen; and at least one cooling conduit which extends within the catheter and terminates in the cooling lumen.

The present invention is a minimally invasive articulating configured to be advanced through tortuous anatomy, particularly within a lung, and subsequently deliver at least two separately deployable ablation devices to a target site located at a bifurcated section of the lung (i.e., at a bronchial airway bifurcation). The pair of ablation devices are separately steerable towards respective first and second pathways extending from the bifurcation, such that each of the ablation devices can be positioned on either side of a target tissue proximate the bifurcation. The first and second ablation devices include expandable distal tips configured to transition to a deployed configuration, in which each expands in diameter and is configured to apply a degree of compression and/or RF energy emission to target lung tissue (i.e., diseased tissue, such as cancer or emphysema-related damaged tissue) for subsequent ablation thereof.

A method for controlling a balloon pressure of an inflatable balloon of an intravascular catheter system includes the steps of (i) sending sensor output to a controller, the sensor output being based at least partially on the balloon pressure, and (ii) maintaining the balloon pressure within a predetermined pressure range based at least partially upon the sensor output received by the controller. The step of maintaining includes one of (a) adjusting a flow rate of a cryogenic fluid through the inflatable balloon while moving the inflatable balloon from a first treatment site to a second treatment site, and (b) adjusting the flow rate of the cryogenic fluid that is selectively delivered from the fluid source to the inflatable balloon through an adjunct fluid injection line that is in fluid communication with a fluid exhaust line.

A system for treatment target tissue comprises an ablation device and an energy delivery unit. The ablation device comprises an elongate tube with an expandable treatment element. The system delivers a thermal dose of energy to treat the target tissue. Methods of treating target tissue are also provided.

Systems, devices, and methods for removing and/or treating obstructions in the vascular channels, such as blood clots, are provided. The systems may include a capture sock device including a shaft defining a lumen; and a mouth coupled to the shaft. The mouth includes a distal end portion defining a distal opening and is sized and configured to move between a collapsed configuration and an expanded configuration within a body channel. The mouth is formed of a mesh having porosity large enough to allow blood flow to pass through it but small enough to prevent an obstruction or a fragment of the obstruction from escaping from the mouth back into the body channel. In some embodiments, the mesh is folded to create at least two mesh layers at least at the distal opening to create a smooth atraumatic edge. In some embodiments, the system further includes a trap and/or retriever assembly.