Patent application number | Description | Published |
20080255627 | Implantable Heart Stimulation Device and Method - The above object is achieved in accordance with the present invention by a cardiac stimulation device for stimulating a heart having a first ventricle and a second ventricle. The device includes a first ventricle sensing circuit that is configured to communicate with a first ventricle sensing electrode suited to be positioned in or at the first ventricle, to enable the first ventricle sensing circuit to sense the first ventricle. The device also includes a second ventricle pacing circuit, configured to communicate with a second ventricle pacing electrode suited to be positioned in or at the second ventricle of the heart, to enable the second ventricle pacing circuit to pace the second ventricle. The device includes a control circuit that operates with time cycles corresponding to normal heart cycles. The control circuit is configured to, within such a time cycle, to detect a cardiac event in the first ventricle with the first ventricle sensing circuit and, after a time duration that is greater than or equal to zero, to cause the second ventricle pacing circuit to deliver a pacing pulse. The control circuit is also configured to detect the aforementioned loop of events indicative of the pacemaker-mediated tachycardia by detecting one or both of (i) the regularity of one or more repetitious events related to operation of the first ventricle sensing circuit or the second ventricle pacing circuit, and (ii) a repetitive operation pattern of the heart stimulation device. The control circuit is configured to determine if the detected regularity satisfies a predetermined regularity criterion and to determine if the operation pattern satisfies a predetermined operation pattern criterion. Based on whether one or both of these criteria are satisfied, the control circuit determines whether the aforementioned loop of events, and thus the presence of pacemaker-mediated tachycardia, is likely to exist. | 10-16-2008 |
20080262365 | Detection and/or Monitoring of Diastolic Heart Failure - In an implantable medical device for detecting and/or monitoring the progression of diastolic heart failure (DHF), and a corresponding method, a parameter is measured that is indicative of left ventricular ejection fraction (LVEF), and a variable is also measured that is indicative of the workload of the patient, and a relation is determined between LVEF and the workload, and DHF is detected and/or the progression of DHF is monitored, dependent on this relation. | 10-23-2008 |
20080281373 | Implantable Heart Stimulator and Method for Operation Thereof - In an implantable heart stimulator and a method for operation thereof, stimulation pulses are delivered to a heart. The amplitude of the delivered stimulation pulses can be selectively set. For setting the amplitude, threshold searches are performed at selected time intervals. Each threshold search determines a threshold value required for achieving capture. The amplitudes of the respective stimulation pulses are set to a value that exceeds the determined threshold value by a safety margin. The safety margin is selected as a function of the selected time intervals. | 11-13-2008 |
20090018597 | System and Method for Estimating Cardiac Pressure Based on Cardiac Electrical Conduction Delays Using an Implantable Medical Device - Techniques are provided for estimating left atrial pressure (LAP) or other cardiac performance parameters based on measured conduction delays. In particular, LAP is estimated based interventricular conduction delays. Predetermined conversion factors stored within the device are used to convert the various the conduction delays into LAP values or other appropriate cardiac performance parameters. The conversion factors may be, for example, slope and baseline values derived during an initial calibration procedure performed by an external system, such as an external programmer. In some examples, the slope and baseline values may be periodically re-calibrated by the implantable device itself. Techniques are also described for adaptively adjusting pacing parameters based on estimated LAP or other cardiac performance parameters. Still further, techniques are described for estimating conduction delays based on impedance or admittance values and for tracking heart failure therefrom. | 01-15-2009 |
20090030470 | IMPLANTABLE HEART STIMULATION DEVICE WITH REMEDIAL RESPONSE TO ANODAL CAPTURE - An implantable heart stimulating device has a left ventricular coronary sinus electrode lead provided with a tip electrode, a right ventricular electrode lead provided with a ring electrode, and a pulse generator connected to the leads that applies stimulation pulses between the tip electrode and the ring electrode, with the tip electrode serving as the anode. A monitoring unit monitors for and detects anodal capture at the right ventricular ring electrode subsequent to a stimulation. If anodal capture is detected, either a threshold search is performed by varying the pulse width and/or pulse amplitude of stimulation pulses in order to identify stimulation pulse characteristics that avoid anodal capture at the ring electrode, or at least one further electrode is activated to function as an indifferent electrode together with the ring electrode, also in order to avoid anodal capture at the ring electrode. | 01-29-2009 |
20090036788 | SYSTEMS AND METHODS FOR DETECTION OF VT AND VF FROM REMOTE SENSING ELECTRODES - Methods and systems are provided for performing ventricular arrhythmia monitoring using at least two sensing channels that are each associated with different sensing vectors, for example by different pairs of extracardiac remote sensing electrodes. Myopotential associated with each of the sensing channels in monitored, and a ventricular arrhythmia monitoring mode is selected based thereon (e.g., based on determined myopotential levels). Ventricular arrhythmia monitoring is then performed using the selected monitoring mode. | 02-05-2009 |
20090099475 | METHOD AND IMPLANTABLE MEDICAL DEVICE FOR ASSESSING A DEGREE OF PULMONARY EDEMA OF A PATIENT - In a method and an implantable medical device for assessing a degree of pulmonary edema of a patient, at least two specific body patients of the patent are detected and at least one impedance sensing session is initiated to sense trans-thoracic impedance signals from the patient when the patient is in one of the at least two specific positions. Impedance values are obtained from the impedance signals, and a relation between respective impedance values at the at least two positions is determined. This relation is then used as a metric of pulmonary edema to assess the degree of pulmonary edema, and is provided as an output. | 04-16-2009 |
20090149908 | IMPLANTABLE HEART STIMULATING DEVICE, SYSTEM AND METHOD - In an implantable biventricular heart stimulating device, and a biventricular heart stimulating method, wherein operation takes place normally with a time VV between a pacing pulse delivered, or inhibited, by a first ventricular pacing circuit and a pacing pulse delivered, or inhibited, by a second ventricular pacing circuit, and wherein a time VV | 06-11-2009 |
20090204169 | IMPLANTABLE HEART STIMULATING DEVICE AND METHOD - In an implantable heart stimulating device and a method of the operation thereof, device has a control circuit that detects an evoked responses to delivered pacing pulses and to carry out an automatic capture routine. The control circuit is arranged to automatically temporarily disable the automatic capture routine on the basis of at least one of the following criteria:
| 08-13-2009 |
20090216291 | SYSTEM AND METHOD FOR DETECTING ELECTRIC EVENTS IN CHAMBERS OF A HEART - In a system and method for detecting electrical cardiac events, and a heart stimulator embodying such a system, cardiac events are detected in respective chambers of a heart by sensing electrical signals in at least two different chambers of the heart and forming a difference signal from the sensed signals, and using the difference signal to automatically distinguish between events originating from one of the chambers and events originating in another of the chambers. At least one of the sensed signals is sensed in a coronary vein on the left atrium or the left ventricle. | 08-27-2009 |
20090254139 | IMPLANTABLE MEDICAL DEVICE WITH OPTIMIZATION PROCEDURE - In an implantable medical device and a method for the operation thereof, acoustic energy is sensed in a subject in whom the device is implanted, and signals indicative of heart sounds of the heart of the patient are produced over predetermined periods of a cardiac cycle, during successive cardiac cycles. A signal corresponding to the second heart sound (S | 10-08-2009 |
20090281584 | IMPLANTABLE SENSOR ARRANGEMENT - An implantable medical sensor arrangement has a sensor body configured for implantation in a subject, to which at least one sensor head is connected through at least one connective wire. The sensor head(s) and at least a portion of the connective wire(s) are tightly packed and enclosed by a protective sensor shell. This sensor shell is composed of a dissolvable material that will dissolve or can be triggered to dissolve following introduction of the sensor arrangement into a subject. | 11-12-2009 |
20090287267 | System and Method for Estimating Cardiac Pressure Based on Cardiac Electrical Conduction Delays Using an Implantable Medical Device - Techniques are provided for estimating left atrial pressure (LAP) or other cardiac performance parameters based on measured conduction delays. In particular, LAP is estimated based interventricular conduction delays. Predetermined conversion factors stored within the device are used to convert the various the conduction delays into LAP values or other appropriate cardiac performance parameters. The conversion factors may be, for example, slope and baseline values derived during an initial calibration procedure performed by an external system, such as an external programmer. In some examples, the slope and baseline values may be periodically re-calibrated by the implantable device itself. Techniques are also described for adaptively adjusting pacing parameters based on estimated LAP or other cardiac performance parameters. Still further, techniques are described for estimating conduction delays based on impedance or admittance values and for tracking heart failure therefrom. | 11-19-2009 |
20100004712 | SYSTEMS AND METHODS FOR USE BY AN IMPLANTABLE MEDICAL DEVICE FOR DETECTING HEART FAILURE BASED ON THE INDEPENDENT INFORMATION CONTENT OF IMMITANCE VECTORS - Techniques are provided for detecting heart failure or other medical conditions within a patient using an implantable medical device, such as pacemaker or implantable cardioverter/defibrillator, or external system. In one example, physiological signals, such as immittance-based signals, are sensed within the patient along a plurality of different vectors, and the amount of independent informational content among the physiological signals of the different vectors is determined. Heart failure is then detected by the implantable device based on a significant increase in the amount of independent informational content among the physiological signals. In response, therapy may be controlled, diagnostic information stored, and/or warning signals generated. In other examples, at least some of these functions are performed by an external system. | 01-07-2010 |
20100121398 | IMPLANTABLE MEDICAL DEVICE AND METHOD FOR MONITORING VALVE MOVEMENTS OF A HEART - An implantable medical device for monitoring the movements of the valve planes of the heart to determine at least one hemodynamic measure reflecting a mechanical functioning of a heart of a patient, includes an impedance measuring circuit that measures impedance between at least electrode pairs including at least one electrode placed substantially at the level of the valve plane. The measured impedances reflect valve plane movements. A hemodynamic parameter determining circuit determines at least one hemodynamic parameter based on the impedances reflecting the mechanical functioning of the heart. | 05-13-2010 |
20100121404 | IMPLANTABLE HEART STIMULATING DEVICE - Implantable heart stimulating device has at least one electrode lead provided with at least two electrodes adapted to be arranged for electrical stimulation of a heart, a pulse generating that applies stimulation pulses between the electrodes, wherein one of the electrodes is the cathode and the other is the anode, to achieve cathodal capture of heart tissue by the cathode electrode. An anodal capture detector detects anodal capture at the anode electrode. The device further has a control unit and if anodal capture is detected by the detection means, the control unit changes the pacing regimen in order to optimize the hemodynamics of the heart. | 05-13-2010 |
20100185252 | DEVICE AND METHOD OF A MEDICAL IMPLANT FOR MONITORING PROGRESSION OF HEART FAILURE IN A HUMAN HEART - In a device and method for a medical implant for monitoring progression of heart failure in a human heart, an activity sensor provides information related to the activity level of a patient and an oxygen sensor provides information related to the level of oxygen content in venous blood. A determined level of venous oxygen content at a determined activity level is obtained, and that level of venous oxygen content is compared to stored values at a corresponding activity level. The result of the comparison is used as a basis for determining a degree of heart failure. | 07-22-2010 |
20100292550 | IMPLANTABLE MEDICAL DEVICE - An analyte measuring system has an implantable medical device having a signal source arranged for generating a current signal and electrodes for applying the current signal to a surrounding tissue in a subject body. The device measures a resulting voltage signal with the electrodes and calculates an impedance signal therefrom. The system comprises a signal processor arranged for generating an estimate of a concentration of an analyte in the tissue based on a spectrum analysis of the determined impedance signal. | 11-18-2010 |
20100305640 | METHOD, DEVICE, IMPLANTABLE STIMULATOR AND DUAL CHAMBER CARDIAC THERAPY SYSTEM - In a device and method in a dual chamber pacing system operating in an atrial synchronized mode, the cardiac stimulator is connectable to a lead arrangement arranged for sensing atrial electrical and mechanical activity. Upon detection of an atrial arrhythmia based on either of sensed atrial mechanical activity, atrial electrical activity, or a combination thereof, a mode switch from an atrial synchronized ventricle stimulating mode to a non-atrial synchronized mode is triggered. | 12-02-2010 |
20100324432 | METHOD AND DEVICE TO DETECT EATING, TO CONTROL ARTIFICIAL GASTRIC STIMULATION - In a method and device for detecting the intake of food in a subject at least one parameter related to the blood flow and/or perfusion of a blood vessel and/or an organ in the digestive system of a patient is monitored by a sensor attached to, or in, a blood vessel or organ of the digestive system. The value of each monitored parameter is analyzed and may be used to control the activity of a gastric stimulator. | 12-23-2010 |
20110046691 | IMPLANTABLE HEART STIMULATOR DETERMINING LEFT VENTRICULAR SYSTOLIC PRESSURE - An implantable heart stimulator has an impedance measurement a cardiogenic impedance waveform using an impedance configuration arranged to measure myocardial contractility of the heart. The heart stimulator further has a calculating unit that calculates an estimate value being related to at least two impedance values of the waveform, or of an average waveform of several consecutive waveforms, during a predetermined time period of the waveform, or average waveform, the calculated estimate value being an estimate of the left ventricular (LV) systolic pressure. | 02-24-2011 |
20110112419 | IMPLANTABLE MEDICAL DEVICE AND METHOD FOR CLASSIFYING ARRHYTHMIA EVENTS - In an implantable medical device such as an implantable cardiac defibrillator, and a method for classifying arrhythmia events, IEGM signals are analyzed to detect an arrhythmia event and a respiratory pattern of the patient is sensed. At least one respiratory parameter reflecting characteristics of the respiratory pattern of the patient is determined based on the sensed respiratory pattern and a respiratory measure corresponding to a change of a rate of change of the at least one respiratory parameter is calculated. The detected arrhythmia event is classified based on the respiratory measure and the IEGM signals, wherein arrhythmia events that satisfy at least a first criterion is classified as an arrhythmia event requiring therapy. | 05-12-2011 |
20110245701 | ARRHYTHMIA CLASSIFICATION - An implantable medical device, is designed to collect a signal representative of the electric activity of the heart and determine a cardiogenic impedance signal for at least a portion of the heart. An R-wave detector of the IMD detects the timing of an R-wave during a cardiac cycle based on the signal representative of the electric activity. A minimum detector detects the timing of a cardiogenic impedance minimum in the cardiogenic impedance signal and within a systolic time window of the cardiac cycle. A detected arrhythmia is then classified by the IMD based on the timing of the R-wave detected by the R-wave detector and the timing of the cardiogenic impedance minimum detected by the minimum detector. | 10-06-2011 |
20120157861 | DEVICES AND METHOD FOR DETERMINING AND MONITORING A CARDIAC STATUS OF A PATIENT BY USING PLVDT OR PLVST PARAMETERS - The present invention relates to an improved medical device and method for accurately and reliably determining a cardiac status of a patient. An implantable medical device, IMD, comprises a sensor arrangement adapted to sense signals related to mechanical activity of the heart and an activity level sensor arrangement adapted to sense an activity level of the patient. Further, the IMD calculates a percentage of left ventricular diastolic time (PLVDT) for a cardiac cycle corresponding to a relation between a diastolic time interval and a cardiac cycle time interval using the determined systolic and diastolic time intervals or a percentage of left ventricular systolic time (PLVST) for a cardiac cycle corresponding to a relation between a systolic interval time interval and a cardiac cycle time interval. A cardiac status is determined based on the calculated PLVDT (or PLVST) and on an activity level of the patient. | 06-21-2012 |
20120184866 | IMPLANTABLE MEDICAL DEVICE AND METHOD FOR MULTISITE MEASUREMENT OF INTRACARDIAC IMPEDANCE - The present invention generally relates to an implantable medical device and method for detecting and monitoring cardiac status of a patient using simultaneous multisite measurements of the intracardiac impedance and in particular to ischemia detection using the simultaneous multisite measurements. The device comprises an impedance measuring unit being connectable to a plurality of electrode configurations including a current generating device adapted to generate a current and apply the current between two electrodes of a current injecting electrode configuration of the electrode configurations and a voltage sensing device including a plurality of voltage sensing circuits arranged in parallel. Each voltage sensing circuit being connectable to a specific voltage sensing electrode configuration of the electrode configurations and being arranged to sense a voltage over the voltage sensing electrode configuration resulting from the applied current, wherein the voltage sensing circuits are capable of sensing the resulting voltages simultaneously. The device further comprises an impedance calculating module adapted to calculate a plurality of impedance values, each impedance value being based on the applied current and a resulting voltage. | 07-19-2012 |
20120290031 | MEDICAL IMPLANTABLE LEAD - The invention relates to a medical implantable lead for monitoring and/or controlling an organ inside a human or animal body. The lead comprises a conducting arrangement having a first conducting coil of at least one electrically conducting wire for connecting a first electrode electrically to a connector to receive and/or transmit electric signals from and to the tissue, respectively. The lead is tapered in a distal portion and has a smaller cross sectional dimension at the distal portion than at the rest of the lead. The first conducting coil is terminated at a termination point on a distance from the distal end. The conducting arrangement has a first end conductor in the form of a non-coiled electric conductor or an eccentrically positioned small diameter coil which connects the first electrode electrically with the coil. | 11-15-2012 |
20120310296 | DETERMINATION OF CARDIAC RESYNCHRONIZATION THERAPY SETTINGS - CRT settings for an implantable medical device are determined by applying pacing pulses to heart chambers of a scheme of different combinations of interchamber delays. A respective width parameter value representing an R or P wave width is determined for each such delay combination based on an ECG representing signal and the width parameter values are employed to estimate a parametric model defining the width parameter as a function of interchamber delays. Candidate interchamber delays that minimize the width parameter are determined from the parametric model and employed to determine optimal CRT settings. The technique provides an efficient way of finding optimal CRT settings when multiple pacing sites are available in a heart chamber. | 12-06-2012 |
20130023779 | Method and System for Ischemia Detection - Disclosed herein are systems and methods for automatically determining ST windows for ischemia detection. In one example, an R-wave is identified in a signal derived from an IEGM and the derivative signal data following the identified R-wave is analyzed so as to find portions of the derivative signal comprising samples having lower values than a predetermined threshold. Further, a portion of the derivative signal including samples having lower values than the threshold is determined to correspond to a ST window for that cardiac cycle if that portion fulfills predetermined requirements. A reference ST window based on a number of determined ST windows is determined. Using the reference ST window, ischemia can be detected by comparing IEGM data in the reference ST window with current IEGM data from a segment of the IEGM signal corresponding to the reference ST window. | 01-24-2013 |
20130060118 | IMPLANTABLE MEDICAL DEVICE AND METHOD COMPRISING MEANS FOR DETECTING AND CLASSIFYING AN ARRHYTHMIA - An implantable medical device ( | 03-07-2013 |
20130325359 | HEMODYNAMIC STATUS ASSESSMENT - A patient-specific hemodyanmic status model is determined from impedance data collected during periods of normal and abnormal hemodynamic status by deriving parameter values of a set of multiple impedance-derivable parameters from impedance signals collected during periods of normal hemodynamic status and in connection with periods of abnormal hemodynamic status. The parameter values are employed to estimate coefficients of a linear parametric status model. These coefficients can then be used together with parameter values determined from impedance signals determined during status assessment periods in order to determine a current hemdoynamic status of the patient. | 12-05-2013 |
20140012359 | MEDICAL IMPLANTABLE LEAD - The invention relates to a medical implantable lead for monitoring and/or controlling an organ inside a human or animal body. The lead comprises a first electrode ( | 01-09-2014 |
20150025397 | SYSTEM AND METHOD FOR ESTIMATING CARDIAC PRESSURE BASED ON CARDIAC ELECTRICAL CONDUCTION DELAYS USING AN IMPLANTABLE MEDICAL DEVICE - Techniques are provided for estimating left atrial pressure (LAP) or other cardiac performance parameters based on measured conduction delays. In particular, LAP is estimated based interventricular conduction delays. Predetermined conversion factors stored within the device are used to convert the various the conduction delays into LAP values or other appropriate cardiac performance parameters. The conversion factors may be, for example, slope and baseline values derived during an initial calibration procedure performed by an external system, such as an external programmer. In some examples, the slope and baseline values may be periodically re-calibrated by the implantable device itself. Techniques are also described for adaptively adjusting pacing parameters based on estimated LAP or other cardiac performance parameters. Still further, techniques are described for estimating conduction delays based on impedance or admittance values and for tracking heart failure therefrom. | 01-22-2015 |