Electrophysiology system and methods
First Claim
1. An electrophysiology method comprising:
- advancing a distal portion of an ablation catheter intravascularly to a location proximate myocardial tissue within a chamber of a heart, the distal portion of the ablation catheter including;
a tissue ablation electrode configured to apply ablation energy to the myocardial tissue;
a plurality of microelectrodes circumferentially distributed about the tissue ablation electrode and electrically isolated therefrom, the plurality of microelectrodes defining a plurality of bipolar microelectrode pairs, each bipolar microelectrode pair configured to generate an output signal based on a cardiac activation signal;
acquiring the output signals from each of the bipolar microelectrode pairs;
comparing an amplitude of the output signal from each of the bipolar microelectrode pairs to the amplitudes of the output signals from the other of the plurality of bipolar microelectrode pairs; and
displaying to a clinician a visual indication of a proximity of the tissue ablation electrode to the myocardial tissue, the visual indication including;
an indication that the tissue ablation electrode is in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, a difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals exceeds a predetermined threshold; and
an indication that the tissue ablation electrode is not in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, the difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals does not exceed a predetermined threshold.
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Abstract
An electrophysiology system comprises an ablation catheter, a radiofrequency generator, and a mapping processor. The ablation catheter has a tissue ablation electrode and a plurality of microelectrodes distributed about the circumference of the tissue ablation electrode and electrically isolated therefrom. The plurality of microelectrodes define a plurality of bipolar microelectrode pairs. The mapping processor is configured to acquire output signals from the bipolar microelectrode pairs, compare the output signals, and generate an output to a display providing a visual indication of a characteristic of the microelectrodes and the tissue ablation electrode relative to myocardial tissue to be mapped and/or ablated.
471 Citations
13 Claims
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1. An electrophysiology method comprising:
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advancing a distal portion of an ablation catheter intravascularly to a location proximate myocardial tissue within a chamber of a heart, the distal portion of the ablation catheter including; a tissue ablation electrode configured to apply ablation energy to the myocardial tissue; a plurality of microelectrodes circumferentially distributed about the tissue ablation electrode and electrically isolated therefrom, the plurality of microelectrodes defining a plurality of bipolar microelectrode pairs, each bipolar microelectrode pair configured to generate an output signal based on a cardiac activation signal; acquiring the output signals from each of the bipolar microelectrode pairs; comparing an amplitude of the output signal from each of the bipolar microelectrode pairs to the amplitudes of the output signals from the other of the plurality of bipolar microelectrode pairs; and displaying to a clinician a visual indication of a proximity of the tissue ablation electrode to the myocardial tissue, the visual indication including; an indication that the tissue ablation electrode is in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, a difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals exceeds a predetermined threshold; and an indication that the tissue ablation electrode is not in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, the difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals does not exceed a predetermined threshold. - View Dependent Claims (2, 3, 4, 5, 6, 7)
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8. An electrophysiology method comprising:
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acquiring signals indicative of bioelectrical cardiac activity from bipolar pairs of microelectrodes of a plurality of microelectrodes, the plurality of microelectrodes circumferentially distributed around a tissue ablation electrode and electrically isolated therefrom, the tissue ablation electrode mounted on a catheter and configured to apply ablation energy to the myocardial tissue; comparing an amplitude of the signal from each of the bipolar microelectrode pairs to the amplitudes of the signals from the other of the plurality of bipolar microelectrode pairs; and displaying to a clinician a visual indication of a proximity of the tissue ablation electrode to the myocardial tissue, the visual indication including; an indication that the tissue ablation electrode is in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, a difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals exceeds a predetermined threshold; and an indication that the tissue ablation electrode is not in contact with the myocardial tissue if, based on the comparison between the amplitudes of the output signals, the difference between the amplitude of any one of the output signals and the amplitude of any one or more of the other output signals does not exceed a predetermined threshold. - View Dependent Claims (9, 10, 11, 12, 13)
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Specification