Patent application number | Description | Published |
20100056897 | System For Non-Uniform Image Scanning and Acquisition - A system employs non-uniform and nonlinear patient monitoring signals in automatically adaptively varying image resolution, image scanning frequency and acquisition speed and gates and synchronizes the image scanning and acquisition of an imaging system. A system acquires medical images of patient anatomy using a trigger generator. The trigger generator generates a trigger signal comprising a non-periodic sequence of pulses in a first signal portion within individual heart beat cycles. The first signal portion is periodically repeated for multiple sequential individual heart beat cycles. An image acquisition device acquires multiple images of a patient anatomical portion in response to corresponding multiple individual pulses of the non-periodic sequence of pulses. A display processor presents acquired images on a display for review by a user. | 03-04-2010 |
20100060350 | Adaptive Filtering System for Patient Signal Monitoring - A system provides a high quality, and intuitive multi-band filter that adapts when noise frequencies or noise amplitudes change. A system for adaptively filtering patient monitoring signals, comprises a filter controller for adaptively determining the number of, and individual filter bandwidth of, multiple adaptive signal filters to be used in filtering multiple bandwidths within an encompassing signal filtering bandwidth. The filter controller does this in response to, (a) noise data indicating noise source frequencies and (b) configuration data determining medical signal or noise source characteristics, to provide programming data for programming a plurality of adaptive signal filters. The system includes multiple adaptive signal filters individually having a filtering bandwidth and filtering characteristic programmable in response to received programming data. A noise detector automatically identifies a noise component in a received patient monitoring signal and generates the noise data. | 03-11-2010 |
20100081917 | SYSTEM FOR MULTI-DIMENSIONAL ANATOMICAL FUNCTIONAL IMAGING - A cardiac functional analysis system reconstructs a 3D anatomical image volume using image frames acquired at predetermined cardiac phases over multiple cardiac cycles in response to a trigger derived from hemodynamic signals. A medical imaging system generates 3D anatomical imaging volume datasets from acquired 2D anatomical images. The system includes an image acquisition device for acquiring 2D anatomical images of a portion of patient anatomy in selectable angularly variable imaging planes in response to a synchronization signal derived from a patient blood flow related parameter. A synchronization processor provides the synchronization signal derived from the patient blood flow related parameter. An image processor processes 2D images acquired by the image acquisition device of the portion of patient anatomy in multiple different imaging planes having relative angular separation, to provide a 3D image reconstruction of the portion of patient anatomy. | 04-01-2010 |
20100097259 | SYSTEM FOR PROCESSING PATIENT MONITORING SIGNALS - A patient monitoring signal processing system adaptively varies medical signal data rate. The system uses an analog to digital converter for digitizing an analog cyclically varying input signal derived from a patient in response to a sampling clock input. The sampling clock determines frequency of analog to digital sampling of the analog input signal by the analog to digital converter. A detector detects first and second different signal portions within a cycle of the cyclically varying input signal. A control processor coupled to the analog to digital converter and the detector, provides the sampling clock and adaptively determines first and second different frequencies of the sampling clock to be used in sampling within detected corresponding first and second different signal portions of the cyclically varying input signal in response to predetermined information indicating a frequency of a signal component of the cyclically varying input signal in the first signal portion is higher than a frequency of a signal component of the cyclically varying input signal in the second signal portion. Also the first frequency is higher than the second frequency of the first and second different frequencies. | 04-22-2010 |
20100152598 | 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 a heart beat cycle of a patient heart. A detector detects multiple parameters of the electrophysiological signal comprising at least one of, (a) amplitude, (b) time duration, (c) frequency and (d) time-frequency, representative parameters. A signal analyzer calculates at least one ratio of the detected parameters from ratios including, (i) ratio of T wave amplitude to P wave amplitude, (ii) ratio of time duration of ST wave to time duration of PR wave, (iii) ratio of a frequency of a PR wave to a frequency of a RT wave and (iv) ratio of a time-frequency measure of a PR wave to a time-frequency measure of a RT wave. A comparator determines whether a calculated ratio exceeds a predetermined upper limit threshold or a predetermined lower limit threshold. An output processor generates data representing an alert message in response to the calculated ratio exceeding a predetermined threshold. | 06-17-2010 |
20100185084 | Non-invasive Cardiac Characteristic Determination System - A system uses non-invasive laser, ultrasound or electro-magnetic monitoring, to derive CO/SV, CO/SV deviation, and related cardiac function parameters. The non-invasive system determines cardiac stroke volume and includes an input processor for receiving determined values provided using a measurement processor. The determined values comprise, a blood vessel internal diameter and rate of flow of blood through the blood vessel in a heart cycle. A computation processor calculates a vessel stroke volume comprising volume of blood transferred through the blood vessel in a heart cycle using the measured blood vessel internal diameter and the rate of flow of blood. The computation processor determines cardiac stroke volume by determining a factor for use in adjusting the vessel stroke volume to provide a cardiac stroke volume and adjusting the vessel stroke volume using the determined factor to provide the cardiac stroke volume. An output processor provides data representing the determined cardiac stroke volume to a destination. | 07-22-2010 |
20100204585 | System for Heart Performance Characterization and Abnormality Detection - A system for heart performance characterization receives an electrical signal indicating heart electrical activity of a patient over a heart beat cycle. The electrical signal is acquired at a particular anatomical location. A gating signal generator generates a gating signal for use in identifying a particular portion of the heart beat cycle. An acquisition device, responsive to the gating signal, derives first and second voltage potentials from the received electrical signal. The first voltage potential comprises a voltage potential derived over a time period comprising a heart beat cycle and the second voltage potential comprises a voltage potential derived over a time period comprising a particular portion of the heart beat cycle. A computation processor derives a dynamic impedance representative value by adjusting a baseline impedance value by a ratio of the first and second voltage potentials. The dynamic impedance represents an average impedance at the particular anatomical location over a time period comprising the particular portion of the heart beat cycle. | 08-12-2010 |
20100210945 | System for Cardiac Ultrasound Image Acquisition - An ultrasound image acquisition device initiates acquisition of anatomical images of a portion of patient anatomy in response to a heart rate related synchronization signal. The ultrasound image acquisition device includes multiple ultrasound transducers for generating sound waves. The ultrasound transducers are arranged in different transducer groups oriented to enable acquisition of different ultrasound imaging information used in generating a single composite ultrasound image. A synchronization processor derives the heart rate related synchronization signal from a patient cardiac function blood flow related parameter. The synchronization signal enables adaptive activation of a particular group of the different transducer groups for acquisition of ultrasound imaging information used in generating the single composite ultrasound image. A display processor presents the single composite ultrasound image, acquired by the ultrasound image acquisition device, to a user on a reproduction device. | 08-19-2010 |
20100280396 | System for Cardiac Pathology Detection and Characterization - A system for heart performance characterization and abnormality detection includes an interface for receiving an electrical signal comprising a pressure indicative waveform indicating a heart blood pressure of a patient over a heart beat cycle. A timing detector determines multiple different time periods in at least one heart cycle from the pressure indicative waveform. A patient monitor monitors the multiple different time periods and in response to detection of a variation in at least one of the multiple different time periods exceeding a predetermined threshold or range, generates an alert message associated with the variation. | 11-04-2010 |
20100312125 | System for Cardiac Pathology Detection and Characterization - A system for heart performance characterization and abnormality detection includes an interface for receiving digitized electrical signals representing blood pressure waveforms over one or more heart beat cycles. The digitized electrical signals comprise, a first digital data sequence representing normal blood pressure of a patient, a second digital data sequence representing random blood pressure of a normal patient and a third digital data sequence representing a potentially abnormal blood pressure of a patient. A complexity processor calculates first, second and third complexity indices for the corresponding first, second and third digital data sequences respectively. A correlation processor uses the calculated first, second and third complexity indices to calculate one or more measures indicating deviation of the potentially abnormal blood pressure of the patient from a normal value. | 12-09-2010 |
20110015532 | Denoising and Artifact Rejection For Cardiac Signal in a Sensis System - A system denoises and rejects artifacts from cardiac signals, by accepting a cardiac signal from a patient, processing the cardiac signal from the patient using 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 feedback control of the filtering of each of the predefined frequencies. | 01-20-2011 |
20110028856 | System for Heart Performance Characterization and Abnormality Detection - A system improves analysis, diagnosis and characterization of cardiac function signals (including surface ECG signals and intra-cardiac electrograms) based on cardiac electrophysiological activity momentum computation, characterization and mapping. The system calculates an electrophysiological signal momentum of different portions of cardiac signals including a timing, location and severity of cardiac pathology and improves reliability of diagnosis, detection, mapping to an identified medical condition, and characterization. The system improves identification of cardiac disorders, differentiation of cardiac arrhythmias, characterization of pathological severity, prediction of life-threatening events and supports evaluation of drug administration effects. | 02-03-2011 |
20110054335 | System for Cardiac Pathology Detection and Characterization - A system improves characterization and diagnosis of cardiac electrophysiological activities by analyzing and characterizing cardiac function signals (including surface ECG signals and intra-cardiac electrograms) based on cardiac electrophysiological energy mode and pattern identification and mapping. The system accurately determines a time stamp, location and severity of cardiac pathology and clinical events by calculating a cardiac signal energy mode and energy variation and distribution. The system identifies cardiac disorders, differentiates cardiac arrhythmias, characterizes pathological severity, predicts life-threatening events, and supports evaluation of administration of drugs. | 03-03-2011 |
20110087121 | System for Continuous cardiac pathology detection and characterization - A system determines fractal values, a nonlinear fractal ratio and fractal data patterns in a heart and maps determined fractal values to medical conditions. A system for heart performance characterization and abnormality detection includes an interface for receiving sampled data representing an electrical signal indicating electrical activity of a patient heart over at least one heart beat cycle. A signal processor calculates, a first signal characteristic value comprising a first fractal dimension value derived from the sampled data over at least a portion of a heart beat cycle, a second signal characteristic value representing a computed derivative of the first fractal dimension value and a ratio of the first and second signal characteristic values. A comparator compares the calculated ratio with a threshold value to provide a comparison indicator. A patient monitor, in response to the comparison indicator indicating the calculated signal characteristic value exceeds the threshold value, generates an alert message associated with the threshold. | 04-14-2011 |
20110118590 | System For Continuous Cardiac Imaging And Mapping - A system improves precision and reliability of intra-cardiac catheter position tracking and monitoring. An interventional system for internal anatomical examination includes a catheterization device for internal anatomical insertion. The catheterization device includes, at least one magnetic field sensor for generating an electrical signal in response to rotational movement of the at least one sensor about an axis through the catheterization device within a magnetic field applied externally to patient anatomy and a signal interface for buffering the electrical signal for further processing. A signal processor processes the buffered electrical signal to derive a signal indicative of angle of rotation of the catheterization device relative to a reference. The angle of rotation is about an axis through the catheterization device. A reproduction device presents a user with data indicating the angle of rotation of the catheterization device. | 05-19-2011 |
20110166618 | System for Cardiac Arrhythmia Detection - A system for heart performance characterization and abnormality detection includes an interface for receiving sampled data representing an electrical signal indicating electrical activity of a patient heart over multiple heart beat cycles and for receiving a pace signal indicating occurrence of a heart pace pulse applied to the heart. A signal processor uses the received sampled data and pace signal in calculating, a first signal characteristic value comprising a time interval between occurrence of the pace pulse and a cardiac cycle characteristic and a second signal characteristic comprising an average of the time intervals determined over a multiple heart cycles. A comparator compares at least one of the first and second characteristic values with a threshold value to provide a comparison indicator. A patient monitor generates an alert message associated with the threshold in response to the comparison indicator indicating a calculated signal characteristic value exceeds the threshold value. | 07-07-2011 |
20110190643 | System for Cardiac Status Determination - A system improves detection and diagnosis of blood pressure based cardiac function and tissue activities by analyzing and characterizing cardiac blood pressure signals (including non-invasive and invasive blood pressure, discrete values and continuous waveforms) using pressure signal variation and variability calculation and evaluation. The system combines blood pressure analysis with multi clinical related factors and parameters to detect and quantify cardiac health status and arrhythmia severity. The system determines an accurate time, location and severity of cardiac pathology and events by calculating blood pressure variability and statistical variation. The accurately and reliably identifies cardiac disorders, differentiates cardiac arrhythmias, characterizes pathological severity, predicts the life-threatening events, and supports evaluation of drug delivery effects. | 08-04-2011 |
20110201900 | System for Monitoring and Visualizing a Patient Treatment Process - A patient treatment monitoring system includes an interface for receiving multiple different types of patient medical information including data derived from a patient monitoring device and a patient medical imaging device. A data processor processes the received multiple different types of patient medical information to be suitable for presentation in a display image. A display processor initiates generation of data representing a single composite display image including an image element representing multiple sequentially performed individual stages of a treatment process. The individual stages are associated with corresponding different sets of the received multiple different types of patient medical information. The single composite display image includes multiple image areas for displaying one of the corresponding different sets of the received multiple different types of patient medical information, in response to user selection of a particular stage of the individual stages using the image element. | 08-18-2011 |
20110201951 | System for cardiac arrhythmia detection and characterization - A system for heart performance characterization and abnormality detection includes an interface that receives a signal representing electrical activity of a patient heart occurring during individual heart cycles of multiple sequential heart cycles. A signal processor decomposes the received signal into multiple signals comprising a heart cycle signal primary wave and one or more heart cycle signal wavelets occurring at corresponding successively higher frequencies. The signal processor determines multiple amplitude representative values of the heart cycle signal primary wave and the one or more heart cycle signal wavelets. A comparator compares the multiple amplitude representative values with corresponding multiple predetermined threshold values to provide comparison indicators. A patient monitor in response to the comparison indicators indicating at least one of the amplitude representative values exceeds a respective predetermined threshold value, generates an alert message associated with the respective predetermined threshold. | 08-18-2011 |
20110245669 | System for Cardiac Condition Detection and Characterization - A system monitors and characterizes internal elasticity of a blood vessel to detect abnormality. A catheter system for heart performance characterization and abnormality detection, comprises an ultrasound device for emitting ultrasound wave signals within patient anatomy and acquiring corresponding ultrasound echo signals. A signal processor processes the ultrasound echo signals to, determine a signal indicating displacement of a tissue wall over at least one heart cycle and identify a displacement value in the displacement signal. The displacement value indicates a tissue wall displacement occurring at a point within a heart cycle. A comparator compares the tissue wall displacement value with a threshold value to provide a comparison indicator. A patient monitor, in response to the comparison indicator indicating the tissue wall displacement value exceeds the threshold value, generates an alert message associated with the threshold. | 10-06-2011 |
20110282227 | System for Cardiac Medical Condition Detection - A system for heart performance characterization and abnormality detection processes a heart electrical activity signal in determining multiple first signal characteristic values over multiple heart cycles. A first signal characteristic value substantially comprises a time interval between a peak of a P wave to a peak of a succeeding R wave representing a repolarization time interval in an individual heart cycle and the signal processor uses a peak detector and time detector for identifying the peaks and detecting a time difference between the identified peaks. A comparator compares at least one of the multiple first signal characteristic values or a value derived from the multiple first signal characteristic values with a threshold value to provide a comparison indicator. A patient monitor in response to the comparison indicator indicating a calculated signal characteristic value exceeds the threshold value, generates an alert message associated with the threshold. | 11-17-2011 |
20120016251 | System for Respiration Data Processing and Characterization - A system for respiration or cardiac condition characterization and abnormality detection includes an interface that receives data representing a signal indicating concentration of carbon dioxide in patient gases over multiple signal cycles. A signal processor uses the received data in determining multiple amplitude related characteristic values. A comparator compares at least one of the amplitude related characteristic values or a value derived from the amplitude related characteristic values, with a threshold value to provide a comparison indicator. A patient monitor in response to the comparison indicator indicating an amplitude related characteristic value or a value derived from the amplitude related characteristic values, exceeds the threshold value, generates an alert message associated with the threshold. | 01-19-2012 |
20120057674 | System for image scanning and acquisition with low-dose radiation - A medical imaging system adaptively acquires anatomical images using a shape adaptive collimator including multiple different portions of X-ray absorbent material automatically adjustable to alter the dimensions of a spatial cross section of an X-ray beam of radiation into a non-rectangular shape, in response to a control signal. The synchronization processor provides a heart rate related synchronization signal derived from a patient cardiac function related parameter. The synchronization signal enables adaptive variation in timing of image acquisition within an individual heart cycle and between successive heart cycles of each individual image frame of multiple sequential image frames. The X-ray image acquisition device uses the shape adaptive collimator for acquiring anatomical images of the region of interest with reduced patient X-ray exposure in response to the synchronization signal. A display processor presents resultant images. | 03-08-2012 |
20120059269 | Worksheet System for Determining Measured Patient Values for Use in Clinical Assessment and Calculations - A system determines measured patient values for use in clinical calculations using an electronic form including, a first area including data fields for presenting values of the parameters associated with a first part of a cardiac catheterization study of a patient and a second area including data fields for presenting values of the parameters associated with a different second part of a cardiac catheterization study of the patient. A user interface enables a user to copy at least one of the parameters comprising a measured value from the first area to the second area as a substitute value eliminating a need for a re-measurement of the value. A calculation processor automatically calculates a cardiac flow value for incorporation in the second area in response to the measured value being copied into the second area. | 03-08-2012 |
20120123285 | System for Cardiac Condition Characterization Using Electrophysiological Signal Data - A system for heart performance characterization and abnormality detection includes an interface for receiving signal data representing an electrical signal indicating electrical activity of a patient heart over multiple heart beat cycles. A signal processor uses the received signal data in calculating at least one of, (a) a first signal characteristic value substantially comprising a ratio of a time interval from S wave to T wave, to a time interval from Q wave to S wave and (b) a second signal characteristic value substantially comprising a ratio of a T wave base voltage from a peak of a T wave to a zero base reference voltage, to an R wave base voltage from a peak of an R wave to a zero base reference voltage. A comparator compares at least one of the first and second characteristic values with a threshold value to provide a comparison indicator. A patient monitor in response to the comparison indicator indicating a calculated signal characteristic value exceeds the threshold value, generates an alert message associated with the threshold. | 05-17-2012 |
20120136264 | System for Ventricular Function Abnormality Detection and Characterization - A system for heart performance characterization and abnormality detection includes an interface for receiving signal data representing an electrical signal indicating electrical activity of a patient heart over multiple heart beat cycles. A filter extracts first signal component data in a first selected bandwidth and first heart cycle portion of the received signal data and second signal component data in a different second selected bandwidth and second heart cycle portion of the received signal data. A signal processor uses the received signal data in calculating a ratio of a first value derived from the first signal component data to a second value derived from the second signal component data. A patient monitor in response to the calculated ratio or value derived from the calculated ratio, generates an alert message associated with the threshold. | 05-31-2012 |
20120150003 | System Non-invasive Cardiac Output Determination - A system determines cardiac output and stroke volume by using non-invasive oximetric signals, such as SPO2 data and waveform, to determine blood flow quantitatively. A non-invasive system determines cardiac output or stroke volume. The system includes an input processor for receiving signal data representing oxygen content of blood of a patient at a particular anatomical location. A computation processor uses the received signal data in calculating a heart stroke volume of the patient comprising volume of blood transferred through the blood vessel in a heart cycle, in response to, a blood volume derived in response to oxygen content of patient blood and at least one factor representing reduction in blood flow volume from a patient heart to the particular anatomical location. An output processor provides data representing the calculated heart stroke volume to a destination device. | 06-14-2012 |
20120179382 | System for Ventricular Arrhythmia Detection and Characterization - A system for heart performance characterization and abnormality detection detects peaks and at least one of, a valley and a baseline comprising a substantially zero voltage level, of received signal data representing oxygen content of blood in a patient vessel over multiple heart beat cycles. The signal processor determines signal parameters including at least one of, (a) a signal amplitude magnitude between a maximum peak and minimum valley, of the received signal data, (b) a signal amplitude magnitude between a maximum peak and a baseline, of the received signal data and (c) a signal amplitude magnitude between a second highest maximum peak and minimum valley, of the received signal data. The system compares a determined signal parameter or value derived from the determined signal parameter, with a threshold value and generates an alert message associated with the threshold, in response to the comparison. | 07-12-2012 |
20120197094 | 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 interface. 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. | 08-02-2012 |
20120232417 | Signal Analysis System for Heart Condition Determination - A system for heart performance characterization and abnormality detection includes an interface for receiving sampled data representing an electrical signal indicating electrical activity of a patient heart over multiple heart beat cycles. A signal processor automatically, decomposes the received sampled data to multiple different subcomponent signals in the time domain. The signal processor associates individual decomposed subcomponents with corresponding different cardiac rotors and determined characteristics of the subcomponents indicating relative significance of the rotors in a cardiac atrial condition. A reproduction device provides data indicating the subcomponent characteristics indicating relative significance of the rotors in a cardiac atrial condition. | 09-13-2012 |
20120257698 | System for Adaptive Sampled Medical Signal Interpolative Reconstruction for Use in Patient Monitoring - A patient medical signal processing system adaptively reconstructs a medical signal sampled using a varying sampling rate. The system includes an input processor and a signal processor. The input processor receives first data and second data. The first data represents a first portion of a medical signal derived by sampling at a first sampling rate and the second data represents a second portion of the medical signal derived by sampling at a second sampling rate. The first and the second sampling rates are different and comprise a master clock rate or an integer division of the master clock rate. A signal processor provides a reconstructed sampled medical signal by, interpolating the second data to provide third data at the first sampling rate and combining the first data and the third data to provide the reconstructed sampled medical signal. | 10-11-2012 |
20120296225 | System for Cardiac Condition Detection Responsive to Blood Pressure Analysis - A system provides cardiac arrhythmia detection and performs blood pressure analysis of multiple catheter channels of blood pressure signals to characterize heart hemodynamic activity. A system for heart performance characterization and abnormality detection includes a repository, data processor and output processor. The repository of data comprises, first distribution data representing a probability distribution of a first patient parameter over a first time period and acquired on a first occasion and second distribution data representing a probability distribution of the first patient parameter over a second time period and acquired on a second occasion subsequent to the first occasion. The data processor calculates an overlap indicator indicating degree of overlap of the first distribution data and the second distribution data in a predetermined interval of the distributions. The output processor provides the calculated overlap indicator to a destination device. | 11-22-2012 |
20120302903 | System for Cardiac Impairment Detection Based on Signal Regularity - A system for heart performance characterization and abnormality detection comprises an input processor and a signal processor. The input processor receives first sampled data representing a first signal portion of a heart activity related signal and second sampled data representing a second signal portion of a heart activity related signal. The signal processor determines distribution data associated with degree of similarity between the first and second signal portions by determining a difference between (a) values derived by applying a first function to mean adjusted sampled values of the first signal portion and (b) values derived by applying a second function to mean adjusted sampled values of the second signal portion. In response to the determined distribution data, the signal processor initiates generation of a message associated with the degree of similarity between the first and second signal portions. | 11-29-2012 |
20120330557 | System for Cardiac Condition Analysis Based on Cardiac Operation Patterns - A system for heart performance monitoring stores image data representing a sequence of medical images of a surface of a patient heart acquired over multiple contraction and reperfusion cycles. An image data processor automatically processes the image data to determine, change in displacement of selected points of a region of interest of the heart surface over individual cycles of the multiple contraction and reperfusion cycles, maximum and minimum peak displacement points and associated relative times of occurrence of the maximum and minimum peak displacement points and individual parameters related to change in displacement of corresponding individual points of the selected points. A display image shows a grid of individual parameters and an individual grid cell employs a visual attribute to visually indicate degree of change in an associated individual parameter occurring over the multiple contraction and reperfusion cycles. | 12-27-2012 |
20130072806 | System for Cardiac Arrhythmia Detection and Characterization - A system for heart performance characterization and abnormality detection comprises an input processor and at least one signal processor. The input processor receives, sampled data representing a patient blood pressure signal and a concurrently acquired electrocardiogram (ECG) signal representing heart electrical activity of the patient. The at least one signal processor, synchronizes the patient blood pressure signal and the heart electrical activity signal, identifies at least two points of a heart electrical activity signal cycle, integrates signal data values representing the amplitude of the patient blood pressure signal of a segment between the identified two points to derive an integral value over time duration of the segment representing an area under the blood pressure signal waveform between the identified two points and in response to the derived integral value, initiates generation of a message associated with a medical condition of the patient. | 03-21-2013 |
20130116681 | System for Automatic Medical Ablation Control - A system provides heart ablation unit control. The system includes an input processor for acquiring electrophysiological signal data from multiple tissue locations of a heart and data indicating tissue thickness at the multiple tissue locations. A signal processor processes the acquired electrophysiological signal data to identify location of particular tissue sites of the multiple tissue locations exhibiting electrical abnormality in the acquired electrophysiological signal data and determines an area of abnormal tissue associated with individual sites of the particular sites. An ablation controller automatically determines ablation pulse characteristics for use in ablating cardiac tissue at an individual site of the particular tissue sites in response to the acquired data indicating the thickness of tissue and determined area of abnormality of the individual site. | 05-09-2013 |
20130158422 | System for Cardiac Arrhythmia Detection and Characterization - A system for analyzing cardiac electrophysiological signals includes an acquisition processor for acquiring signal data representing heart electrical activity over multiple heart cycles. An individual heart cycle comprises a signal portion between successive sequential R waves. A time interval detector uses a signal peak detector for detecting multiple successive time intervals including individual time intervals comprising a time interval between a first peak occurring in a first heart cycle and a second peak occurring in at least one of, (a) a successive sequential second heart cycle and (b) a third heart cycle successive and sequential to the second heart cycle. A data processor processes the multiple detected successive time intervals by, determining at least one interval parameter of, a mean, variance and standard deviation of the time intervals and generating an alert message in response to the interval parameter. | 06-20-2013 |
20130190637 | System for Monitoring and Diagnosis of Cardiac Electrogram Signals Using Multi-Dimensional Analysis - An analyzer automatically analyzes both, a common portion of multiple successive heart cycles of electrophysiological signal data synchronized with respect to a P wave and a common portion of multiple successive heart cycles of the signal data synchronized with respect to an R wave, to identify changes occurring in amplitude value and time duration of the common portion of the multiple successive heart cycles of the signal data. A display processor initiates generation of at least one display image showing the common portion of the multiple successive heart cycles synchronized in time, adjacent and mutually vertically displaced to facilitate visual comparison and highlighting an identified change by a visual attribute. | 07-25-2013 |
20130218038 | System for Non-invasive Cardiac Output Determination - A method determines cardiac output or stroke volume by receiving signal data representing multiple parameters of a patient concurrently acquired over a particular time period and comprising at least one of, (a) a parameter derived from an ECG waveform of the patient, (b) a parameter derived from a blood pressure signal of the patient, (c) a parameter derived from signal data representing oxygen content of blood of the patient and (d) a parameter derived from a patient cardiac impedance value. A selected parameter of the multiple concurrently acquired parameters is used in calculating a heart stroke volume of the patient comprising volume of blood transferred through the blood vessel in a heart cycle, in response to, a combination of a weighted summation of values of the selected parameter over the particular time period. Data representing the calculated heart stroke volume is provided to a destination device. | 08-22-2013 |
20130245478 | Adaptive Cardiac Data Patient Filter System - A system for adaptively processing patient monitoring signals comprises an input processor for acquiring a signal having amplitude representing electrical activity of a patient heart over time. A signal processor identifies different portions of the signal associated with different phases of cardiac activity by, inverting the signal to provide an inverted signal, aligning the signal and the inverted signal in amplitude during a cardiac rest portion and identifying one or more of the different portions in response to an intersection point of the signal and the inverted signal. Multiple adaptive signal filters are used to filter multiple bandwidths of corresponding different portions of the signal. | 09-19-2013 |
20130274623 | System for Cardiac Condition Detection Using Heart Waveform Area Associated Analysis - A system for heart performance characterization uses an interface to receive waveform signal data representing electrical activity of a patient heart over at least one heart beat cycle. The signal processor uses a signal peak and amplitude detector for, identifying a first signal portion of a first heart cycle of the signal data, identifying multiple different amplitude levels within the first signal portion, determining a first area under the waveform in the first signal portion corresponding to at least one particular amplitude level and deriving a parameter in response to the determined first area. The output processor generates an alert message if at least one of, (a) the derived parameter and (b) a difference between the derived parameter and a corresponding derived parameter for a different heart cycle for the same patient, exceeds a predetermined threshold value. | 10-17-2013 |
20130317336 | Adaptive ECG Trigger Signal Jitter detection for Imaging - A system provides an image acquisition trigger signal compensated for signal processing time delay. An interface receives waveform signal data representing electrical activity of a patient heart over at least one heart beat cycle. A detector detects a particular point associated with a particular signal portion within successive heart beat cycles of the signal data. A first time variation detector provides a first timing adjustment signal in response to detected change in time of occurrence of the detected particular point. A second time variation detector provides a second timing adjustment signal in response to comparison of relative timing of the trigger signal and the detected particular point. An output processor generates the trigger signal in response to the detected particular point and the first timing adjustment signal and the second timing adjustment signal. | 11-28-2013 |
20130345573 | Adaptive Control of Monitoring Devices - Disclosed herein is a framework for facilitating adaptive control of monitoring devices. In accordance with one aspect, a position detector detects a chest elevation level and provides chest elevation level data. A processor uses the chest elevation level data to determine a heart elevation level with respect to a reference level. A comparator compares the determined heart elevation level with an elevation level of a monitoring device with respect to the reference level. In response to the comparison, a movement system adjusts the elevation level of the monitoring device. | 12-26-2013 |
20140180037 | Biological Tissue Function Analysis - Disclosed herein is a framework for facilitating biological tissue function analysis. In accordance with one aspect, saturation of hemoglobin with oxygen (SPO2) signal data is synchronized with respiration signal data. One or more waveform parameters may be generated based on the synchronized SPO2 signal data and the respiration signal data. One or more respiration-SPO2 parameters may then be determined based on the one or more waveform parameters and used to characterize the biological tissue function. | 06-26-2014 |
20140200461 | CARDIAC ANALYSIS BASED ON VESSEL CHARACTERISTICS - A system and method includes reception of a first image of a blood vessel, reception of a second image of the blood vessel, determination of a first size of a region of the blood vessel based on the first image, determination of a second size of the region of the blood vessel based on the second image, and calculation of a parameter of the blood vessel based on the first size and the second size. | 07-17-2014 |
20140276156 | PATIENT SIGNAL ANALYSIS AND CHARACTERIZATION - Disclosed herein is a framework for facilitating patient signal analysis. In accordance with one aspect, at least one region of interest within a cycle of a waveform of patient signal data is identified. The identified region of interest may be segmented into portions using amplitude percentage categories. A sequential morphological data series may be generated by compiling time intervals of the segmented portions. One or more sequential signal parameters may be calculated based on the sequential morphological data series. A report may then be generated based at least in part on the one or more sequential signal parameters. | 09-18-2014 |
20140364753 | PATIENT SIGNAL ANALYSIS AND CHARACTERIZATION BASED ON LATE POTENTIALS - Disclosed herein is a framework for facilitating patient signal analysis. In accordance with one aspect, patient signal data including at least one identified cycle is segmented into at least two regions of interest, including a late potential region of interest. The late potential region of interest may be an RS, RT, S-full or T-full signal portion. At least one patient signal parameter is determined based at least in part on the segmented regions of interest. A pathology or event may be detected based on the determined patient signal parameter. | 12-11-2014 |