Abstract: There is provided a method of displaying a pre-acquired three dimensional (3D) image of at least a portion of an organ of a patient, the method comprising: receiving a plurality of electrical readings, each from a different electrode mounted on a catheter inside the portion of the organ of the patient, wherein the electrodes are mounted on the catheter at known distances from each other, transforming the plurality of electrical readings to a corresponding plurality of image points using a mapping transformation that transforms each electrical reading of the catheter from inside the portion of the organ of the patient to an anatomically corresponding image point in the 3D image based on the known distances, and displaying the 3D image with a marking of at least one of the plurality of image points.

Abstract: In some embodiments, data sensed and/or operational parameters used during a catheterization procedure are used in the motion frame-rate updating and visual rendering of a simulated organ geometry. The organ geometry is rendered as a virtual material using a software environment (preferably a graphical game engine) which applies simulated optical laws to material appearance parameters affecting the virtual material's visual appearance, as part of simulating a scene comprising the simulated organ geometry, and optionally also comprising simulated views of a catheter probe used for sensing and/or treatment. Optionally, measurements of and/or effects on tissue by sensing and/or commanded probe-tissue interactions are converted into material appearance changes, allowing dynamic visual simulation of intra-body states and/or events based on optionally non-visual input data.

Abstract: A method for performing at least one ablation comprising receiving image data of a mass to be ablated; segmenting a volume of the mass to yield a plurality of sub-volumes, each of the plurality of sub-volumes corresponding to one of a plurality of ablation steps; identifying, for each of the plurality of ablation steps and based on the corresponding sub-volume, an ablation center; calculating, for each of the plurality of ablation steps, an ablation tool position and an imaging device position, the imaging device position being independent of the ablation tool position; causing both an ablation tool to be positioned based on the calculated ablation tool position and an imaging device to be positioned based on the calculated imaging device position for one ablation step of the plurality of ablation steps; and causing an ablation tool to activate based on the one ablation step.

Abstract: Methods for estimating of the effectiveness of catheter ablation procedures to form lesions, and particular lesions which together form an ablation segment of an ablation line. Lesion effectiveness parameters are received, and effectiveness, optionally the joint effectiveness, of corresponding ablations (optionally planned, current, and/or already performed) is estimated. In some embodiments, estimating is based on use by computer circuitry of an estimator constructed based on observed associations between previously analyzed lesion effectiveness parameters, and observed lesion effectiveness. Additionally or alternatively, estimators may be constructed based on analytic functions. The estimator is used by application to the received lesion effectiveness parameters.

Abstract: Disclosed herein is a method of graphically presenting an indicating marker over a 3-D model of a tissue surface during a catheterization procedure, comprising determining a region over the 3-D model, deforming the indicating marker to congruently match a shape defined by the 3-D model across the region at a plurality of positions; and rendering the 3-D model into an image including the deformed indicating marker by generating an image of the 3-D model covered by said deformed indicating marker.

Abstract: Methods for estimating of the effectiveness of catheter ablation procedures to form lesions. Lesion effectiveness parameters are received, and effectiveness of a corresponding ablation (optionally planned, current, and/or already performed) is estimated. The estimating is based on use by computer circuitry of an estimator constructed based on observed associations between previously analyzed lesion effectiveness parameters, and observed lesion effectiveness. The estimator is used by application to the received lesion effectiveness parameters.

Abstract: Multi-arm robotic systems and methods for monitoring a target are provided. The system may include a first robotic arm configured to orient a first component and a second robotic arm configured to orient a second component. The first robotic arm and the second robotic arm may be co-registered. The first robotic arm may be caused to orient the first component at a first pose. The second robotic arm may be caused to orient the second component at a second pose. At least one image may be received from the first component and the second component.

Abstract: Systems and methods for detecting motion of soft tissue are provided. An illustrative method is described to include attaching a flexible material to an object, where the flexible material includes one or more tracking markers distributed thereon and where the object includes soft tissue. The method is also disclosed to include obtaining a first image of the object that includes the one or more tracking markers in a first position, obtaining a second image of the object that includes the one or more tracking markers in a second position, and determining a motion of the soft tissue based on a comparison of the one or more tracking markers in the first position with the one or more tracking markers in the second position.

Abstract: In some embodiments, a body cavity shape of a subject is reconstructed based on intrabody measurements of at least one property of an electromagnetic field by an intrabody probe (for example, a catheter probe) moving within a plurality of electrical fields intersecting the body cavity. In some embodiments, the electrical fields are generated at least in part from electrodes positioned in close proximity, for example, within 1 cm, of the body cavity. In some embodiments, the body cavity is a chamber of a heart (for example, a left atrium or left ventricle), and the electrodes used to generate the electrical field are positioned in the coronary sinus, a large vein occupying the groove between the left atrium and left ventricle. In some embodiments, known distances between measuring electrodes are used in guiding reconstruction, potentially overcoming difficulties of reconstruction from measurements of non-linear electrical fields.

Abstract: A device comprises at least one processor and memory including instructions that when executed by the at least one processor cause the at least one processor to: generate, based on at least one image of a spine within a body, a set of possible screw poses for implanting at least one screw into the spine during a surgical procedure; evaluate each possible screw pose based on at least one consideration associated with the surgical procedure; select, based on the evaluation, at least one screw pose from the set of possible screw poses; and output an indication of the selected at least one screw pose to a user interface.

Abstract: A method of estimating a spatial relationship between at least a part of a patient esophagus and a heart chamber, including: measuring at least one electric parameter at one or more positions within the heart chamber to obtain measured values; and estimating the spatial relationship based on the measured values.

Abstract: In some embodiments, a body cavity shape of a subject is reconstructed based on intrabody measurements of voltages by an intrabody probe (for example, a catheter probe) moving within a plurality of differently-oriented electromagnetic fields crossing the body cavity. In some embodiments, the method uses distances between electrodes as a spatially calibrated ruler. Positions of measurements made with the intrabody probe in different positions are optionally related by using spatial coherence of the measured electromagnetic fields as a constraint. Optionally, reconstruction is performed without using a detailed reference (image or simulation) describing the body cavity shape. Optionally, reconstruction uses further information to refine and/or constrain the reconstruction; for example: images, simulations, additional electromagnetic fields, and/or measurements characteristic of body cavity landmarks. Optionally, reconstruction accounts for time-dependent cavity shape changes, for example, phasic changes (e.g.

Abstract: A device comprises at least one processor and a memory comprising instructions that when executed by the at least one processor cause the at least one processor to: generate a first signal that causes a vibration device to vibrate, the vibration device being in force-transmitting contact with a first anatomical element; receive, from a sensor, a second signal based on sensed vibration in a second anatomical element proximate the first anatomical element; and determine, based on the second signal, an amount of mechanical coupling between the second anatomical element and the first anatomical element.

Abstract: Systems and methods for tracking a pose of a target and/or tracking the target is provided. A first robotic arm may be configured to orient a first imaging device and a second robotic arm may be configured to orient a second imaging device. The first robotic arm and the second robotic arm may operate in a shared or common coordinate space. A first image may be received from the first imaging device and a second image may be received from the second imaging device. The first image and the second image may depict at least one target. A pose of the at least one target may be determined in the coordinate space based on the first image, a corresponding first pose, the second image, and a corresponding second pose.

Abstract: An in-situ fusion system includes at least one robotic arm; a bioprinter; a polymerization tool; at least one processor; and a memory storing instructions for execution by the at least one processor. The instructions, when executed, cause the at least one processor to: control the at least one robotic arm to prepare at least two bone surfaces to support cellular growth; cause the bioprinter to print, from a scaffold material, a scaffold between the at least two bone surfaces; and cause the polymerization tool to induce the scaffold material to polymerize.

Abstract: In some embodiments, data sensed and/or operational parameters used during a catheterization procedure are used in the motion frame-rate updating and visual rendering of a simulated organ geometry. In some embodiments, measurements of and/or effects on tissue by sensed and/or commanded probe-tissue interactions are converted into adjustments to the simulated organ geometry, allowing dynamic visual simulation of intra-body states and/or events based on optionally partial and/or non-visual input data. Adjustments to geometry are optionally to 3-D positions of simulated data and/or to simulated surface properties affecting geometrical appearances (e.g., normal mapping). Optionally, the organ geometry is rendered as a virtual material using a software environment (preferably a graphical game engine) which applies simulated optical laws to material appearance parameters affecting the virtual material's visual appearance.

Abstract: There is provided a method of displaying a pre-acquired three dimensional (3D) image of at least a portion of an organ of a patient, the method comprising: receiving a plurality of electrical readings, each from a different electrode mounted on a catheter inside the portion of the organ of the patient, wherein the electrodes are mounted on the catheter at known distances from each other, transforming the plurality of electrical readings to a corresponding plurality of image points using a mapping transformation that transforms each electrical reading of the catheter from inside the portion of the organ of the patient to an anatomically corresponding image point in the 3D image based on the known distances, and displaying the 3D image with a marking of at least one of the plurality of image points.

Abstract: A system for tracking the position of a surgical tool manipulated by a surgical robotic system, to determine that the tool is correctly positioned and orientated. Miniature 3-D tracking cameras are mounted on the end effector of the robotic system, one viewing markers on the surgical tool, and the other markers attached to the anatomy part being operated on. The initial spatial position and orientation of the surgical tool on the surface of the anatomy part is measured, and the progress of the surgical tool into the anatomic body part is tracked using one of the miniature cameras. The cameras or sensors are close to the surgical region of interest, and all the mechanical and sensor elements necessary for the system operation are mounted within the realm of the robot. The system thus avoids interruption of communication between a remotely positioned navigation camera and the robot or patient.

Abstract: A method of generating a virtual MRI image includes receiving an initial MRI image of a patient in a first position, the initial MRI image depicting at least a portion of an anatomy of the patient; receiving a plurality of images of the patient in a second position, each of the plurality of images depicting at least a plurality of bony elements within the portion of the patient's anatomy; receiving soft tissue information corresponding to at least a plurality of soft tissue elements within the portion of the patient's anatomy; segmenting the initial MRI image to identify a depiction of each of the plurality of bony elements and each of the plurality of soft tissue elements within the initial MRI image; and generating a virtual MRI image based on the MRI image, the plurality of images, and the soft tissue information.