| Patent application number | Description | Published |
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| 20080214945 | Method and System for Atrial Fibrillation Analysis, Characterization, and Mapping - A method and system for atrial fibrillation analysis, characterization, and mapping is disclosed. A finite element model (FEM) representing a physical structure of a heart is generated. Electrogram data can be sensed at various locations in the heart using an electrophysiology catheter, and the electrogram data is mapped to the elements of the FEM. Function parameters, which measure some characteristics of AF arrhythmia, are then simultaneously calculated for all of the elements of the FEM based on the electrogram data mapped to the elements of the FEM. An artificial neural network (ANN) can be used to calculate the function parameters. | 09-04-2008 |
| 20080269628 | Denoising and Artifact Rejection for Cardiac Signal in a Sensis System - A method and apparatus for denoising and rejecting artifacts from cardiac signals, having the steps of accepting a cardiac signal from a patient, subjecting the cardiac signal from the patient to a frequency band width controllable choke to separate the cardiac signal into predefined frequencies, filtering each of the predefined frequencies to remove dynamic common noise, joining each of the predefined frequencies into a cardiac signal without the dynamic common noise, and providing a feedback control to the filtering of each of the predefined frequencies. | 10-30-2008 |
| 20080281216 | Cardiac Arrhythmias Analysis of Electrophysiological Signals Based on Symbolic Dynamics - The disclosed method analyzes cardiac electrophysiological signals, including ECG and internal cardiac electrograms, based on multi-level symbolic complexity calculation and multi-dimensional mapping. The results may be used to objectively identify cardiac disorders, differentiate cardiac arrhythmias, characterize pathological severities, and predict life-threatening events. Multi-level symbolization and calculation of the electrophysiological signal is used provide better reliability and analysis resolution for identifying and characterizing cardiac disorders. Adaptive analysis of the cardiac signal complexity enables calculation efficiency and reliability with high SNR, and with low calculation volume and power consumption. One dimension (time or frequency domain) and multi-dimension symbolic analysis is used to provide more information of cardiac pathology and high risk rhythm transition to doctors. | 11-13-2008 |
| 20090024016 | Continuous Measurement and Mapping of Physiological Data - A catheter has a plurality of sensors and electrodes, wherein the sensors are arranged alternately and spaced apart from each other. A system for continuous measurement and mapping of physiological data may use such a catheter with a coupling unit for insulated coupling of the plurality of sensors with a measurement unit and a mapping unit for mapping values received from the sensors to a predefined matrix. | 01-22-2009 |
| 20090043223 | Non-Invasive Temperature Scanning and Analysis for Cardiac Ischemia Characterization - A method is disclosed for achieving improved quality of monitoring and diagnosis for heart functions. Specifically, a method is disclosed for continuous temperature measurement and thermal characterization of patient heart tissue based on non-invasive thermal mapping technology. The method includes multi-dimensional cardiac tissue temperature scanning and tissue thermal pattern analysis with high precision, which can greatly improve the efficiency and lower the medical procedure risk for identifying myocardial ischemia (MI) disorders, predicting the MI occurrence, and mapping MI characteristics and impacting MI medical treatment, such as drug delivery and long term cardiac care. A system is also disclosed for use with the method. | 02-12-2009 |
| 20090110148 | System for Processing Patient Monitoring Power and Data Signals - A device interface selectively acquires patient physiological parameter data. An acquisition processor acquires physiological data from a patient. A communication processor is coupled to an optical communication pathway for receiving a plurality of optical signals from a source. A conversion processor is electrically coupled to the acquisition processor and communication processor and converts a first optical power signal at a first frequency and received via the optical communication pathway using the communication processor, to a first electrical signal for providing power to said device 1interface. The conversion processor converts an optical control signal at a second frequency different from the first frequency and received via the optical communication pathway using the communication processor, to a second electrical signal for providing control data to the acquisition processor directing the acquisition processor to acquire at least one physiological parameter from a patient. | 04-30-2009 |
| 20090112106 | Signal Analysis of Cardiac and Other Patient Medical Signals - A system and method provide detecting and monitoring cardiac electrophysiological changes by determining differences between a reference signal representing a heartbeat signal and an analysis signal representing another heartbeat signal. A set of signal data consisting of a number of heartbeat signals is acquired as a function of time. Individual heartbeat signals within the set of acquired signals are identified, an individual signal comprising data values representing a plurality of sample points during a single heartbeat. One of the identified individual signals or a derived signal representing an average of a subset of the identified individual signals is selected as an analysis signal. A reference signal is identified. The sample points of the reference signal are aligned with the sample points of the analysis signal. A single value representative of mutual correspondence between the sample points of the reference signal and the corresponding sample points of the analysis signal is calculated. Data indicating a calculated value is communicated to a destination for viewing by a user | 04-30-2009 |
| 20090112110 | System for Cardiac Medical Condition Detection and Characterization - A system and method provides monitoring for atrial fibrillation. A data acquisition processor acquires a cardiac signal data stream from a patient and a wave detector detects an R-wave in a cardiac signal of the data stream. A T-wave in the cardiac signal occurring after the detected R-wave and a Q-wave in a subsequent cardiac signal of the data stream is also detected by the wave detector. A filter provides signal gating and extraction of data representing a Region of Interest (ROI) time window from the detected T-wave to the Q-wave. An integration processor detects characteristics of a P wave signal occurring within the ROI time window. At least one of the detected P wave characteristics is compared to characteristics derived from data representing at least one P wave signal and generating an output signal in response to the comparison for use in determining if the patient is in atrial fibrillation. | 04-30-2009 |
| 20090112199 | EP SIGNAL MAPPING-BASED OPTICAL ABLATION FOR PATIENT MONITORING AND MEDICAL APPLICATIONS - A system and method are disclosed for utilizing a single integrated EP/ablation catheter to treat cardiac arrhythmias. The disclosed catheter combines the EP signal monitoring of a traditional EP diagnostic catheter, and optical energy for the ablation therapy, which is expected to provide a more efficient, accurate and reliable method of cardiac ablation than current RF techniques since it is based on real-time EP signal mapping, with precise pathological tissue localization, cardiac arrhythmia severity characterization and delivers predictable energy doses with continuous safety monitoring of the intracardiac signals. | 04-30-2009 |
| 20090131762 | Medical Device Synchronization System for use in Cardiac & Other Patient Monitoring - A system provides synchronization between different medical signal (e.g., EKG and ICEG signal) acquisition and processing devices. A system synchronizes multiple different patient medical parameter processing devices, using a master clock generator. The master clock generator is adaptively programmable to provide synchronization clocks having frequencies compatible with multiple different medical devices for acquiring patient medical parameter data and for synchronization of processing of medical parameter data concurrently acquired from a single particular patient. The master clock generator is programmed by dividing a clock signal to provide a desired clock frequency in response to received frequency selection command data. An output interface provides synchronization clocks to the multiple different medical devices for acquiring patient medical parameter data and providing synchronized output patient medical parameter data from the different medical devices for presentation to a user in synchronized format on a display. An input interface receives the command data for determining clock division and generating the desired clock frequency. | 05-21-2009 |
| 20090137997 | Interventional system providing tissue ablation cooling - An interventional system integrates a laser optical cooling unit into a medical catheter device for treating coronary artery disease (CAD) to safely steer and control cardiac tissue temperature and thermal patterns to prevent cardiac disease, tissue damage and myocardial ischemia or infarction, for example. An interventional system provides tissue ablation and cooling using a catheterization device. The catheterization device for internal anatomical insertion includes, a laser light emitting node for optical cooling of anatomical tissue, an ablation node for use in surgical removal of anatomical tissue and a temperature sensor. The temperature sensor senses temperature of anatomical tissue for use in regulating heating and cooling of tissue resulting from use of the ablation node and the laser light emitting node. | 05-28-2009 |
| 20090157337 | System for determining electrical status of patient attached leads - A system determines electrical status of patient attached leads in medical patient monitoring. The system includes a repository of data indicating multiple predetermined impedance value ranges and corresponding associated lead status information of at least one electrical lead attached to a patient for conducting electrical signals for use in patient monitoring. An impedance measurement processor automatically successively determines whether an impedance value of a particular patient attached lead of multiple electrical leads attached to a patient is within a particular impedance value range of multiple predetermined impedance value ranges. An output processor automatically communicates data comprising a message identifying an electrical status of a particular lead of the multiple electrical leads by deriving status information from the repository in response to a determination the impedance value of the particular patient attached lead is within the particular impedance value range. | 06-18-2009 |
| 20090177046 | Patient Monitoring and Treatment Medical Signal Interface System - A medical signal interface device bidirectionally conveys signals between a patient and patient monitoring devices. The device comprises a bidirectional electrical signal interface that receives and buffers patient parameter monitoring signals received from a patient via patient attached leads and outputs treatment related signals used in applying invasive or non-invasive treatment to a patient. A bidirectional electrical signal processor operates in response to commands received from a control processor and is coupled to the electrical signal interface, for processing received patient parameter monitoring signals using filtering and amplification to provide processed patient monitoring signals for output to at least one patient monitoring device. The bidirectional electrical signal processor processes the treatment related signals for output by buffering the treatment related signals for output to a patient. A control processor provides data representing the commands in response to at least one of, (a) predetermined configuration data and (b) deriving data representing the commands from data entered by a user via a displayed user interface image. | 07-09-2009 |
| 20090198300 | System for Characterizing Patient Tissue Impedance for Monitoring and Treatment - A system provides early prediction of heart tissue malfunction and electrophysiological pathology by determining anatomical tissue impedance characteristics for use in medical patient monitoring and treatment decision making. At least one repository of data indicates multiple predetermined expected impedance value ranges for corresponding multiple impedance measurements taken at multiple particular different sites of at least one anatomical organ. An impedance measurement processor automatically determines whether multiple measured impedance values taken at multiple particular different sites of an anatomical organ using an invasive catheter are within corresponding multiple predetermined expected impedance value ranges derived from the at least one repository. An output processor automatically communicates data comprising at least one message to a destination. The at least one message includes data indicating whether the multiple measured impedance values taken at the multiple particular different sites of the anatomical organ are within the corresponding multiple predetermined expected impedance value ranges. | 08-06-2009 |
| 20090259266 | System for Heart monitoring, Characterization and Abnormality Detection - A system analyzes and characterizes cardiac electrophysiological signals by determining instantaneous signal entropy for identifying and characterizing cardiac disorders, differentiating cardiac arrhythmias, determining pathological severity and predicting life-threatening events. A system for heart monitoring, characterization and abnormality detection, includes an acquisition device for acquiring an electrophysiological signal representing a heart beat cycle of a patient heart. A signal processor derives an entropy representative value of the acquired electrophysiological signal within a time period comprising at least a portion of a heart beat cycle of the acquired electrophysiological signal and provides an entropy value as a function of the entropy representative value and the time period. A comparator generates data representing a message for communication to a destination device in response to the entropy value exceeding a predetermined threshold. | 10-15-2009 |
| 20090281441 | System for Heart Performance Characterization and Abnormality Detection - A system for heart performance characterization and abnormality detection includes an acquisition device for acquiring an electrophysiological signal representing heart beat cycles of a patient heart. A detector detects one or more parameters of the electrophysiological signal of parameter type comprising at least one of, (a) amplitude, (b) time duration, (c) peak frequency and (d) frequency bandwidth, of multiple different portions of a single heart beat cycle of the heart beat cycles selected in response to first predetermined data. The multiple different portions of the single heart beat cycle being selected from, a P wave portion, a QRS complex portion, an ST segment portion and a T wave portion in response to second predetermined data. A signal analyzer calculates a ratio of detected parameters of a single parameter type of the multiple different portions of the single heart beat cycle. An output processor generates data representing an alert message in response to a calculated ratio exceeding a predetermined threshold. | 11-12-2009 |
| 20090312648 | Adaptive Medical Image Acquisition System - A medical imaging system adaptively acquires anatomical images. The system includes a synchronization processor for providing a heart rate related synchronization signal derived from a patient cardiac function blood flow related parameter. The synchronization signal enables adaptive variation in timing of acquisition within successive heart cycles of each individual image frame of multiple sequential image frames. An image acquisition device initiates acquisition of anatomical images of a portion of patient anatomy in response to the synchronization signal. A display processor presents images, acquired by the acquisition device and synchronized with the synchronization signal, to a user on a reproduction device. The image acquisition device adaptively selects image pixel resolution of individual image frames of the multiple sequential image frames in response to data identifying a heart cycle segment so that successively acquired image frames have different image pixel resolution within a single heart cycle. | 12-17-2009 |
