A catheter ablation system includes: a catheter probe having distal end including: a temperature sensor; a plurality of irrigation holes; and an ablating electrode; a radiofrequency (RF) heating controller coupled to the catheter probe and configured to supply RF energy to the ablating electrode to control the ablating electrode to emit heat at a target power; an irrigation controller coupled to the catheter probe and configured to supply an irrigation fluid at a continuously adjustable irrigation flow rate through the catheter probe to exit through the irrigation holes; and an operating console having a processor and memory, the memory storing instructions that, when executed by the processor, cause the processor to control the irrigation controller to set the irrigation flow rate based on the target power and a target average temperature.

Temperature sensing catheters and systems that can be used during cardiac ablation procedures to measure and monitor temperatures, and the rate and spread of temperature changes in the heart. The temperature data can be used to calculate temperature gradients, which may be used to estimate if and when certain regions of heart may undergo injury due to thermal exposure. The temperature data can be used to limit or cut-off power delivery to an ablation catheter, or otherwise modify the ablation procedure, to prevent injury to certain regions of heart. In some cases, the temperature data is used to control aspects of the ablation in a feedback loop control scheme.

A catheter includes, a shaft for insertion into an organ, an expandable distal-end assembly coupled to the shaft and includes splines, at least one of the splines includes a flexible substrate, configured to conform to tissue of the organ, and a sensing electrode, configured: (a) to be coupled to the flexible substrate, and (b) when in contact with the tissue, to produce a electrically signal indicative of an electrocardiogram signal sensed in the tissue, the sensing electrode including: (i) a gold substrate, formed over the flexible substrate and configured to conduct the electrically signal, (ii) a first polymer layer, formed over a first section of the gold substrate and configured to electrically isolate between the tissue and the gold substrate, and (iii) a second polymer layer, formed over a second, different, section of the gold substrate, and configured to conduct the electrocardiogram signal between the tissue and the gold substrate.

In one exemplary mode, a catheter apparatus includes an elongated deflectable element including a distal end, a flexible puller including a distal portion, and configured to be retracted through the deflectable element, and an expandable assembly including a plurality of resilient splines, each resilient spline including at least one electrode disposed thereon, the resilient splines being disposed circumferentially around the distal portion of the puller, with first ends of the splines being coupled with the distal end of the deflectable element and second ends of the splines coupled with the distal portion of the puller, the splines being configured to bow radially outward in a relaxed form of the expandable assembly and bow further radially outward when the puller is retracted expanding the expandable assembly from the relaxed form to an expanded form.

A catheter includes: (i) a shaft for insertion into an organ of a patient, (ii) an expandable distal-end assembly, which is coupled to the shaft and includes multiple splines, (iii) at least an ablation electrode, which is configured: (a) to be coupled to a spline of the splines, and (b) when placed in contact with tissue of the organ, to apply an ablation signal to the tissue, and the ablation electrode includes a slot, and (iv) a temperature sensor, which is contained within the slot and is configured, when the ablation electrode is placed in contact with the tissue, to produce a thermal signal indicative of a temperature of the tissue.

An apparatus includes a flexible electrically-insulating substrate including an inner surface and an outer surface. The substrate is shaped to define multiple channels passing between the inner surface and the outer surface, at least some of the channels being concave channels. The apparatus further includes an outer layer of an electrically-conducting metal covering at least part of the outer surface, an inner layer of the electrically-conducting metal covering at least part of the inner surface, and respective columns of the electrically-conducting metal that fill the channels such as to connect the outer layer to the inner layer.

An intravascular ablation device, including a flexible elongate body; an expandable element positioned on the elongate body; a radiofrequency or electroporation treatment segment located distally of the expandable element; a cryogenic coolant source in fluid communication with an interior of the expandable element; and a radiofrequency or electroporation energy source in communication with the radiofrequency or electroporation treatment segment.

Transducer-based systems can be configured to display a graphical representation of a transducer-based device, the graphical representation including graphical elements corresponding to transducers of the transducer-based device, and also including between graphical elements respectively associated with a set of the transducers and respectively associated with a region of space between the transducers of the transducer-based device. Selection of graphical elements and/or between graphical elements can cause activation of the set of transducers associated with the selected elements. Selection of a plurality of graphical elements and/or between graphical elements can cause visual display of a corresponding activation path in the graphical representation. Visual characteristics of graphical elements and between graphical elements can change based on an activation-status of the corresponding transducers. Activation requests for a set of transducers can be denied if it is determined that a transducer in the set of transducers is unacceptable for activation.

A catheter for tissue ablation with one or more electrodes attached to the inner surface of the catheter body facing the lumen, and one or more electrodes attached to the outer surface. The electrodes are offset from the distal end of the catheter. The material between the inner and outer electrodes is an insulator and may be for example a dielectric with a high dielectric constant. This catheter configuration generates an electric field that bends around the tip of the catheter. The field strength near the catheter tip is relatively symmetric; therefore, tissue ablation depth is relatively insensitive to catheter orientation. Embodiments may have multiple inner or outer electrodes and may switch voltage configurations across electrodes to vary the electric field direction over time, improving ablation consistency.

An endocardial catheter comprises an outer shaft having an outer shaft lumen, an inner shaft slidably disposed within the outer shaft lumen, a spline assembly comprising a plurality of flexible splines each having a spline proximal end attached to a distal end of the outer shaft, an opposite spline distal end attached to a distal end of the inner shaft, and an electrode, wherein the plurality of splines collectively define an interior space of the spline assembly, and a foldable membrane disposed within the interior space of the spline assembly, the foldable membrane having an outer edge portion attached to one or more of the splines. The foldable membrane comprises an electrically insulative material.