A method includes, receiving multiple signals from multiple respective electrodes arranged along an inner circumference of a blood vessel that has been ablated. Based on the multiple signals, one or more quality measures of the ablated blood vessel are produced. A graphical presentation indicative of the one or more quality measures, is displayed to a user in a two-dimensional (2D) polar coordinate system.

Systems and methods for electroporation are provided. An electroporation system includes a catheter including a plurality of electrodes, and a pulse generator coupled to the catheter, the pulse generator configured to generate a waveform to be delivered using at least one of the plurality of electrodes. The waveform includes a first pulse having a first polarity, a first pulse amplitude, and a first pulse width, and a second pulse having a second polarity, a second pulse amplitude, and a second pulse width, wherein the first and second pulses are separated by an interpulse delay, and wherein at least one of i) the first pulse amplitude is different than the second pulse amplitude and ii) the first pulse width is different than the second pulse width.

Pulmonary vein isolation catheters and associated devices, systems, and methods are disclosed herein. In some embodiments, a pulmonary vein isolation catheter includes a tip section having an expandable portion and a deployment member. The expandable portion includes a plurality of mesh electrode panels that are electrically insulated from one another. The expandable portion is mechanically coupled to (i) the deployment member at a distalmost portion of the tip section and (ii) a distal end portion of a catheter shaft. The expandable portion is expandable and compressible via proximal and distal movement, respectively, of the deployment member. In some embodiments, the expandable portion in a deployed state is pear- or onion-shaped and includes a nose portion and/or an active body portion. The nose portion can be insulated and/or configured to fit within a pulmonary vein and position the active body portion against tissue about the ostium of the pulmonary vein.

Bipolar belt ablation systems and methods for treating patient tissue involve the use of an ablation an ablation apparatus with a plurality of ablation elements carried by a flexible tube structure, a radiofrequency generator capable of delivering a plurality of differing radio frequency power signals to the ablation elements of the ablation device, wires transmitting the radiofrequency power signals from the radiofrequency generator to the ablation elements, and a control mechanism to enable temperature-based power control to each of the powered ablation elements.

Systems and methods for forming a lesion on an endocardial tissue of a patients heart involve placing an ablation assembly inside of the heart and adjacent to the endocardial tissue, and placing a guiding assembly outside of the heart. An ablation assembly includes an ablation element and a first attraction element, and a guiding assembly includes a second attraction element. First and second attraction elements can be attracted via magnetism. Techniques involve forming an ablation on the cardiac tissue of a patient's heart with an ablation element of the ablation assembly. Optionally, techniques may include moving the second attraction element of the guiding assembly relative to the patient's heart, so as to effect a corresponding movement of the ablation element of the ablation assembly.

Described embodiments include apparatus that includes a signal generator and an electric circuit. The signal generator is configured to supply a signal having both a first dominant frequency and a second dominant frequency. The electric circuit, which includes a reactive component, is configured to generate, upon the signal being supplied to the electric circuit, a magnetic field having both the first dominant frequency and the second dominant frequency, by virtue of the reactive component simultaneously resonating at both the first dominant frequency and the second dominant frequency. Other embodiments are also described.

An apparatus for cooling tissue or a fluid for an elongate medical device comprising an elongate shaft extending along a longitudinal axis and comprising a shaft proximal end and a shaft distal end; a support structure located at the shaft distal end, where the support structure is expandable from a contracted state to an expanded state, and a plurality of thermoelectric elements, wherein the thermoelectric elements are located on the support structure. A medical device comprising a first catheter end shape, a second catheter end shape located distally with respect to the first catheter end shape, a support structure that extends between the first and the second catheter end shape, and a plurality of thermoelectric elements. A system for cooling a tissue or a fluid for an elongate medical device, comprising a plurality of thermoelectric elements, a thermocouple, an electronic control unit (ECU).

Aspects of the present disclosure are directed to flexible high-density mapping catheters with a high-density array of mapping electrodes. These mapping catheters may be used to detect electrophysiological characteristics of tissue in contact with the electrodes, and may be used to diagnose cardiac conditions, such as cardiac arrhythmias for example.

A method for ablating a patient, consisting of ascertaining a CHA.sub.2DS.sub.2-VASc score for the patient and inserting a probe into the patient, so as to contact a pulmonary vein of the patient. The method further includes applying energy via the probe so as to ablate the pulmonary vein until pulmonary vein isolation (PVI) is achieved. When PVI is achieved and the CHA.sub.2DS.sub.2-VASc score is less than a preset value, ablation of the pulmonary vein is ceased. When PVI is achieved and the CHA.sub.2DS.sub.2-VASc score is greater than or equal to the preset value, energy is applied to perform a further ablation.

A medical system includes a catheter configured to be inserted into a body part of a living subject, and including a distal end comprising an electrode, and a processor configured to compute position coordinates of the electrode, and find a measure of proximity of the electrode to tissue of the body part responsively to the position coordinates of the electrode and position coordinates of a wall of an anatomical map of the body part.