Abstract: An apparatus, including a flexible insertion tube having a distal end for insertion into a body cavity, and first and second conduits configured to deliver first and second fluids, respectively, to the distal end. The distal end includes a first balloon coupled to the first conduit so that the first fluid inflates the first balloon and is delivered, via one or more spray ports in the first balloon, to tissue in the body cavity, a second balloon contained within the first balloon and coupled to the second conduit so that the second fluid inflates the second balloon, and multiple splines including a flexible, resilient material and extending along a longitudinal axis of the distal end, and configured to constrain the second balloon so that inflation of the second balloon creates lobes that form, along the longitudinal axis between the lobes, channels that direct the first fluid to the spray ports.

Abstract: A method for electrophysiological assessment, including acquiring electrical signals from locations of a region of ablated tissue in a heart chamber, and deriving from the signals respective annotations, which are indicative of times within a heart cycle at which a conduction wave traversed the locations. The method includes identifying a first location, at a first distance from the region, where the electrical signals include a double-potential signal, having first and second annotations at different times within the heart cycle, and identifying, in proximity to the first location, a second location, at a second distance from the region, greater than the first distance, where the electrical signals have a third annotation. The method further includes selecting one of the first and second annotations that is closest to the third annotation as a valid annotation for the first location, and displaying the valid annotation on an electroanatomical map of the heart.

Abstract: An electrical apparatus includes a spiral electrode and an interface circuit. The spiral electrode is disposed on a distal end of a probe for insertion into a body of a patient. The interface circuit is configured to (a) transfer a radiofrequency (RF) ablation signal to the electrode for ablating tissue in the body, (b) output a voltage that develops across the electrode in response to an external magnetic field, for measuring a position of the distal end in the body, and (c) transfer electrical current through the electrode for measuring a resistivity that is indicative of tissue temperature in a vicinity of the electrode.

Abstract: In one embodiment, an irrigated medical system includes a medical tool, an irrigation line configured to fluidically connect an irrigation reservoir storing irrigation fluid to the medical tool, and provide at least some of the irrigation fluid to the medical tool, a force sensor configured to be coupled with the irrigation reservoir, and provide a signal responsively to a force exerted by the irrigation reservoir on the force sensor over time as irrigation fluid in the irrigation reservoir is depleted, and a controller configured to find an irrigation rate of the irrigation fluid flowing in the irrigation line responsively to the signal.

Abstract: A system includes a jig and a processor. The jig includes a pressure wave damping element under test, and a sensor that is coupled with an aspiration line of a phacoemulsification system distally to the pressure wave damping element, the sensor configured to measure a pressure wave traveling distally in the aspiration line. The processor is coupled with the jig, the processor configured to analyze and display readings of the sensor, so as to allow a user to assess pressure wave damping performance of the pressure wave damping element.

Abstract: An irreversible electroporation (IRE) method includes receiving a total number of IRE pulses to be applied by one or more electrodes of a catheter placed in proximity to a tissue in an organ. An IRE protocol is defined by defining a partitioning of the total number of the IRE pulses into multiple pulse trains separated by pauses, the partitioning defined so as to reduce a total duration of the IRE protocol while meeting a safety criterion. The IRE protocol is applied to the tissue using the electrodes.

Abstract: A sinuplasty tool, consisting of a handle, and a rigid tube, containing a rigid tube lumen, having a rigid tube distal end and a rigid tube proximal end connected to the handle. The tool also has a resilient tube, containing a resilient tube lumen, having a resilient tube distal end and a resilient tube proximal end fixed to the rigid tube distal end so that the lumens align. The resilient tube has a multiplicity of separated openings partially encircling the resilient tube so as to form ribs in the resilient tube and permitting the resilient tube to bend. The resilient tube distal end may be inserted into a sinus of a living subject. The tool also has a wire, traversing the aligned lumens, connected to the resilient tube distal end and coupled to the handle, so that applying tension to the wire causes the resilient tube to bend.

Abstract: A method for applying bipolar ablation pulses, the method includes positioning multiple electrodes of a catheter in contact with tissue of an organ. The tissue is ablated using the multiple electrodes in accordance with a predefined pattern including a periodic set of time slots. Each of the time slots defines (i) an electrode-pair (EP), (ii) a waveform of one or more bipolar ablation pulses (BAPs) applied to the tissue by the EP, and (iii) a duration of the time slot. The time slots are applied sequentially, and the pattern further includes at least one time slot that is empty.

Abstract: A system (11) includes a medical probe (36) for insertion into a cavity of an organ, which includes a position and direction sensor (60) and a camera (45), both operating in a sensor coordinate system (62). The system further includes a processor (44) configured to: receive, from an imaging system (21) operating in an image coordinate system (28), a three-dimensional image of the cavity including open space and tissue; receive, from the medical probe, signals indicating positions and respective directions of the medical probe inside the cavity; receive, from the camera, respective visualized locations inside the cavity; register the image coordinate system with the sensor coordinate system so as to identify one or more voxels in the image at the visualized locations, and when the identified voxels have density values in the received image that do not correspond to the open space, to update the density values of the identified voxels to correspond to the open space.

Abstract: A method includes receiving an electrophysiological (EP) map of a cardiac chamber, the EP map including data points comprising respective locations and EP values. The EP map is projected onto a sphere divided into a grid of unit areas. For at least some of the unit areas, a most likely data point is estimated that is representative of an EP activation in the unit area. The representative data points is inverse mapped onto the EP map. An updated EP map with the inverse mapped representative data points is presented to a user.

Abstract: A medical apparatus includes a probe configured for insertion into a body of a patient and including three or more electrodes arrayed along a distal portion of the probe and configured to contact tissue within the body. An electrical signal generator is configured to apply between a selected pair of the electrodes signals having an amplitude sufficient to ablate the tissue contacted by the pair of the electrodes. A controller is configured to measure an electrical current flowing through at least one of the electrodes not included in the selected pair while applying the signals, and to issue a notification indicating that the tissue was inadequately ablated if the measured electrical current exceeds a preset threshold.

Abstract: A medical system includes a catheter including an insertion tube having a distal end, an elongated resilient distal section fixed to the distal end of the insertion tube, the distal section having an outer surface, and a plurality of electrode structures, each electrode structure being disposed on, and bulging above the outer surface of the distal section, each electrode structure including a respective primary electrode and at least one respective secondary electrode extending around the outer surface, and respective electrically insulating material disposed around the outer surface and between the respective primary electrode and the at least one respective secondary electrode, the respective primary electrode bulging further above the outer surface than the at least one respective secondary electrode and the electrically insulating material.

Abstract: A disposable dual-action reciprocating pump part includes a piston and a cylinder, and multiple silicone O-rings. The piston is configured to move bi-directionally inside the cylinder. The multiple silicone O-rings are configured to seal the piston against the cylinder.

Abstract: A method for medical diagnosis, consisting of receiving electrophysiological data including first intracardiac electrogram (IEGM) signals acquired by a first pair of electrodes having a first intracardiac electrode. The data includes second IEGM signals acquired by a second pair of electrodes having a second intracardiac electrode in proximity to the first intracardiac electrode. The first and second IEGM signals are input to a first convolutional layer of a neural network and a second convolutional layer parallel to the first convolutional layer in the neural network to generate respective first and second interim results. The first and second interim results are input into one or more common layers of the neural network. The method includes receiving from an output layer of the neural network, responsively to inputting the first and second interim results, an indication of a local activation time at a location of the first and second intracardiac electrodes.

Abstract: A system includes: (a) a switching unit including: (i) first sockets, which are configured to connect between the switching unit and channels of one or more catheters, (ii) second sockets, which are configured to connect, via the switching unit, between the first sockets and a console, and (iii) a switch, which is configured, based on a control signal, to route signals conducted in the channels, between the first and second sockets, and (b) circuitry, which is configured, based on information received from the one or more catheters, to produce the control signal for routing of the signals.

Abstract: In accordance with one embodiment, an automated probe system includes a probe configured to be reversibly inserted into a live body part, a robotic arm attached to the probe and configured to manipulate the probe, a first sensor configured to track movement of the probe during an insertion and a reinsertion of the probe in the live body part, a second sensor configured to track movement of the live body part, and a controller configured to calculate an insertion path of the probe in the live body part based on the tracked movement of the probe during the insertion, and calculate a reinsertion path of the probe based on the calculated insertion path while compensating for the tracked movement of the live body part, and send control commands to the robotic arm to reinsert the probe in the live body part according to the calculated reinsertion path.

Abstract: A trocar for insertion into an organ of a patient includes a cannula, an obturator body, and two or more interchangeable obturator heads. The cannula has a longitudinal axis. The obturator body is configured to be inserted into the cannula. The two or more interchangeable obturator heads are each configured to be detachably fitted at a distal end of the obturator body.

Abstract: A medical apparatus includes a registration tool, which includes a position sensor, A position-tracking system is configured to acquire position coordinates of the sensor in a first frame of reference defined by the position-tracking system. A processing unit is configured to receive 3D image data with respect to the body of the patient in a second frame of reference, to generate a 2D image of the surface of the patient based on the 3D image data, to render the 2D image to a display screen, and to superimpose onto the 2D image icons indicating locations of respective landmarks. The processing unit receives the position coordinates acquired by the position-tracking system while the registration tool contacts the locations on the patient corresponding to the icons on the display, and registers the first and second frames of reference by comparing the position coordinates to the three-dimensional image data.

Abstract: A catheter is disclosed comprising: a connector including a plurality of first contacts and one or more second contacts; a shaft including a plurality of electrodes, each electrode being coupled to a different one of the plurality of first contacts; a memory coupled to at least one of the second contacts, wherein the memory is configured to: store a pinout map identifying an order in which the plurality of electrodes is coupled to the plurality of first contacts; and provide the pinout map to an external device via one or more of the second contacts after the connector is coupled to the external device.

Abstract: A medical probe includes a shaft, a camera, a hollow cutting tool, and an inflatable balloon. The shaft is configured for insertion through a cut in a body of a patient, whereas the shaft includes a working vacuum channel running therethrough. The camera is fitted at a distal end of the shaft and is configured to provide images of a target tissue site in the body. The hollow cutting tool is for insertion over a guidewire in the working vacuum channel of the shaft, whereas the hollow cutting tool is configured to pierce the target tissue site under guidance of images taken by the camera. The inflatable balloon is configured to stabilize the distal end of the shaft, whereas the inflatable balloon is located proximally to the camera so as not to obstruct the images of the target tissue site.