Abstract: Systems and methods for facilitating display of cardiac information based on sensed electrical signals include a processing unit configured to receive a set of electrical signals; receive an indication of a measurement location corresponding to each electrical signal of the set of electrical signals; and generate an activation waveform corresponding to the set of electrical signals. Systems and methods disclosed herein may be configured to generate, based on the activation waveform, a representation of a cardiac electrical signal feature; and facilitate presentation, on a display device, of a cardiac map and the representation of the cardiac electrical signal feature.

Abstract: Systems and methods for facilitating processing of cardiac information based on sensed electrical signals include a processing unit configured to receive a set of electrical signals; receive an indication of a measurement location corresponding to each electrical signal of the set of electrical signals; and generate, based on at least one of an annotation waveform corresponding to each electrical signal of the set of electrical signals and a set of annotation mapping values, an annotation histogram.

Abstract: Systems and methods for processing cardiac information include a processing unit configured to receive a set of cardiac electrical signals; receive an indication of a measurement location corresponding to each of the set of electrical signals; and identify, for each electrical signal of the set of electrical signals, a deflection. The deflection includes a deviation from a signal baseline. An activation waveform corresponding to the set of electrical signals is generated based on the identified deflections.

Abstract: Systems for facilitating display of cardiac mapping information include a mapping probe configured to sense cardiac electrical signals. The systems also include a processing unit configured to receive the cardiac electrical signals; determine signal features; and determine conduction characteristics. The processing unit also is configured to generate, based on the signal features and the corresponding conduction characteristics, a cardiac map.

Abstract: A system and method for voltage-guided anatomical shell editing includes outputting, to a display device, an anatomical shell of a cardiac structure. The anatomical shell is based on signals sensed by a mapping probe, each signal including a respective sensed voltage. User input specifying a first target depth for editing is received, as is a selection of a first region of the anatomical shell. A modified anatomical shell is generated by removing a first portion of the anatomical shell including the selected first region to a first editing depth based on the first target depth and generating a new surface region on the modified anatomical shell. Based on the voltage associated with the new surface region, the edit can be maintained, undone, and/or modified.

Abstract: Methods and systems for mapping and displaying cardiac structures are disclosed. The method includes sensing cardiac electrical signals at a plurality of points and generating a cardiac map of at least a portion of one or more cardiac structures based on at least a portion of the sensed cardiac electrical signals. A surface map having a corresponding first position relative to the cardiac map is generated. The surface map includes a first surface point, where a first cardiac electrical signal feature is represented on the surface map at the first surface point if a corresponding first cardiac electrical signal is sensed at a point that is located within a threshold distance of the first surface point. The cardiac map and the surface map, at the first position, are displayed. The surface map may be repositioned to a second position.

Abstract: Embodiments for adjustable depth anatomical shell editing are disclosed. In an embodiment, a method for adjustable depth anatomical shell editing comprises: outputting, to a display device, a first anatomical shell of a cardiac structure, wherein the first anatomical shell is based on a plurality of signals sensed by a mapping probe; receiving, from a user input device, a selection of a portion of the first anatomical shell; generating a modified anatomical shell that has the selected portion removed to an approximate depth from the first anatomical shell, wherein the approximate depth is finite; and outputting, to the display device, the modified anatomical shell.