Abstract: In the present invention, a catheter identification system for providing information about one or more attributes of a catheter connectable to an electrophysiology (EP) recording or mapping system includes a catheter, a resistor network operably connected to the catheter, the resistor network including at least one identification resistor and an identification resistor measurement circuit operably connected to the catheter and configured to send an identification signal through the at least one resistor in the resistor network to retrieve an altered identification signal from the identification resistor, where the altered identification signal provides information on an attribute of the catheter.

Abstract: In the present invention, a system and method for determining the orthogonality and applied force vector of an ablation catheter includes the steps of providing an electrophysiology system including an RF generator, a processor operably connected to the RF generator, a display operably connected to the processor and an ablation catheter operably connected to the RF generator and the processor, the catheter including an ablation electrode disposed opposite the RF generator and a number of microelectrodes disposed on and electrically isolated from the ablation electrode, the processor configured to compare data signals obtained from the microelectrodes with one another to derive a difference value for each pair of data signals, obtaining data signals from the microelectrodes, comparing the data signals from microelectrode pairs to determine difference values and generating a visual representation on the display of the orthogonality and applied force vector of the ablation electrode using the difference values.

Abstract: In the present invention, a catheter identification system for providing information about one or more attributes of a catheter connectable to an electrophysiology (EP) recording or mapping system includes a catheter, a resistor network operably connected to the catheter, the resistor network including at least one identification resistor and an identification resistor measurement circuit operably connected to the catheter and configured to send an identification signal through the at least one resistor in the resistor network to retrieve an altered identification signal from the identification resistor, where the altered identification signal provides information on an attribute of the catheter.

Abstract: In the present invention, a catheter identification system for providing information about one or more attributes of a catheter connectable to an electrophysiology (EP) recording or mapping system includes a catheter, a resistor network operably connected to the catheter, the resistor network including at least one identification resistor and an identification resistor measurement circuit operably connected to the catheter and configured to send an identification signal through the at least one resistor in the resistor network to retrieve an altered identification signal from the identification resistor, where the altered identification signal provides information on an attribute of the catheter.

Abstract: A method for analyzing noise in an electronic signal monitoring study includes selecting a study signal for analysis, removing a study subject's physiological signal from the study signal, and performing a quantitative analysis on the study signal. A fingerprint of any noise present in the study signal is then created.

Abstract: An interventional radiology system includes an imaging system for generating an image of anatomy of a patient and a catheter within the anatomy and a display system operable to display the image as a projection onto the patient, proximate and aligned with the patient anatomy. An interventional radiology method includes generating an image of anatomy of a patient and a catheter within the anatomy using an imaging system, and displaying the image as a projection onto the patient, proximate and aligned with the patient anatomy.

Abstract: In the present invention, a system and method for determining the orthogonality and applied force vector of an ablation catheter includes the steps of providing an electrophysiology system including an RF generator, a processor operably connected to the RF generator, a display operably connected to the processor and an ablation catheter operably connected to the RF generator and the processor, the catheter including an ablation electrode disposed opposite the RF generator and a number of microelectrodes disposed on and electrically isolated from the ablation electrode, the processor configured to compare data signals obtained from the microelectrodes with one another to derive a difference value for each pair of data signals, obtaining data signals from the microelectrodes, comparing the data signals from microelectrode pairs to determine difference values and generating a visual representation on the display of the orthogonality and applied force vector of the ablation electrode using the difference values.

Abstract: In the present invention, a catheter identification system for providing information about one or more attributes of a catheter connectable to an electrophysiology (EP) recording or mapping system includes a catheter, a resistor network operably connected to the catheter, the resistor network including at least one identification resistor and an identification resistor measurement circuit operably connected to the catheter and configured to send an identification signal through the at least one resistor in the resistor network to retrieve an altered identification signal from the identification resistor, where the altered identification signal provides information on an attribute of the catheter.

Abstract: A method for analyzing noise in an electronic signal monitoring study includes selecting a study signal for analysis, removing a study subject's physiological signal from the study signal, and performing a quantitative analysis on the study signal. A fingerprint of any noise present in the study signal is then created.

Abstract: A system in combination with a stimulator system and an electrophysiology recorder system in delivering a stimulator signal to a subject's heart is provided. The electrophysiology recorder system can be generally operable to acquire an electrocardiogram from the subject's heart. The system can include an electrical couple in electrical connection between the simulator system and the electrophysiology recorder. The electrical couple can be configured to communicate the stimulator signal without loading an impedance of the electrophysiology recorder system on the stimulator system.

Abstract: A system to use in combination with an ECG signal acquisition system connected to an arrangement of electrodes on a subject is provided. The system can include an antenna system in communication with the ECG signal acquisition system, a location tracking system operable to track a direction and a location of the antenna system relative to a reference, and an interface connected in communication with the ECG signal acquisition system and the location tracking system. The interface includes an output indicative of a direction of a source of the noise signal detected by the antenna system. A filter reduces an effect of the noise signal on an acquired ECG waveform data received by the ECG signal acquisition system.

Abstract: A system to use in combination with an ECG signal acquisition system is provided. The ECG signal acquisition system can be operable to connect to an arrangement of electrodes on a subject. The system can include a circuit board and a plurality of subcircuits mounted on the circuit board. The plurality of subcircuits can be arranged on the circuit board having an electrical impedance that correlate to an electrical impedance of the arrangement of electrodes on the skin surface of the subject. The system can further include an output connector connected in electrical communication to receive signals communicated from the plurality of subcircuits for communication to the ECG acquisition system.

Abstract: A system in combination with a stimulator system and an electrophysiology recorder system in delivering a stimulator signal to a subject's heart is provided. The electrophysiology recorder system can be generally operable to acquire an electrocardiogram from the subject's heart. The system can include an electrical couple in electrical connection between the simulator system and the electrophysiology recorder. The electrical couple can be configured to communicate the stimulator signal without loading an impedance of the electrophysiology recorder system on the stimulator system.

Abstract: A system to use in combination with an ECG signal acquisition system is provided. The ECG signal acquisition system can be operable to connect to an arrangement of electrodes on a subject. The system can include a circuit board and a plurality of subcircuits mounted on the circuit board. The plurality of subcircuits can be arranged on the circuit board having an electrical impedance that correlate to an electrical impedance of the arrangement of electrodes on the skin surface of the subject. The system can further include an output connector connected in electrical communication to receive signals communicated from the plurality of subcircuits for communication to the ECG acquisition system.

Abstract: A system to use in combination with an ECG signal acquisition system connected to an arrangement of electrodes on a subject is provided. The system can include an antenna system in communication with the ECG signal acquisition system, a location tracking system operable to track a direction and a location of the antenna system relative to a reference, and an interface connected in communication with the ECG signal acquisition system and the location tracking system. The interface includes an output indicative of a direction of a source of the noise signal detected by the antenna system. A filter reduces an effect of the noise signal on an acquired ECG waveform data received by the ECG signal acquisition system.

Abstract: An electrical-mechanical system may be used in electrophysiology and hemodynamic studies. The system may include a mounting arrangement couplable to a support surface for supporting a patient. At least one catheter input module may be electrically and mechanically coupled to the mounting arrangement, the catheter input module being connectable to catheters for use in the patient. A central processing device may be attached to the support surface and placed in communication with the mounting arrangement.

Abstract: An electrical-mechanical system may be used in electrophysiology and hemodynamic studies. The system may include a mounting arrangement couplable to a support surface for supporting a, patient. At least one catheter input module may be electrically and mechanically coupled to the mounting arrangement, the catheter input module being connectable to catheters for use in the patient. A central processing device may be attached to the support surface and placed in communication with the mounting arrangement.

Abstract: A system and device for obtaining and reviewing patient data and ultrasound images from a patient such that the patient data and ultrasound images can be viewed simultaneously. The ultrasound images are obtained by an ultrasound system in real-time during a procedure carried out on the patient. The physiology workstation receives patient data as well as the ultrasound images and stores both the patient data and the ultrasound images within the physiological recording system. The ultrasound images and patient data are also communicated to a central data storage device where the ultrasound images and patient data are stored and can be accessed by a remotely located reviewing station. A display contained on the physiology workstation allows both the ultrasound images and the patient data to be viewed at the physiology workstation.

Abstract: A method and apparatus for determining A, C, and V waves in an atrial pressure waveform. The method includes the acts of establishing a time reference based on R waves in an ECG. A first interval in the an atrial pressure waveform between a first point offset ahead of a first R wave and a second point offset behind the first R wave is determined. The highest peak within the first interval is then identified. This peak is the A wave. Once the A wave is identified, a second R wave in the ECG, ahead of the first R wave, is identified. A second interval in the atrial pressure waveform that extends from the second point to a third point is established. The third point is positioned at a distance ahead of the second point equal to a percentage of the interval from the second point to a location behind the second R wave. The highest peak in the second interval is the V wave. After identifying the V wave, a third interval in the atrial pressure waveform is established.

Abstract: A method and system for identifying components of a waveform. The system includes an ECG acquisition module, a pressure waveform acquisition module to acquire a pressure waveform, and an analysis module coupled to the ECG acquisition module and the pressure waveform acquisition module. A monitor or similar display device is coupled to the analysis module. The analysis module is operable to determine three peaks in the pressure waveform corresponding to “a”, “c”, and “v” waves. Those “a”, “c”, or “v” waves that are identified by the analysis module are displayed on a monitor or similar device such that they are distinguished from each other and the remainder of the displayed waveform. The method involves displaying a waveform; identifying a number of peaks in a number of intervals of the waveform, and modifying the displayed waveform such that the identified peaks are distinguished from each other and the rest of the pressure waveform.