Patent application number | Description | Published |
20080269823 | Apparatus and Methods for Automatic Determination of a Fusion Pacing Pre-Excitation Interval - Automated adjustment of a pre-excitation interval (PEI) used to deliver hemodynamically efficient fusion pacing therapy. | 10-30-2008 |
20090024045 | MECHANICAL FUNCTION MARKER CHANNEL FOR CARDIAC MONITORING AND THERAPY CONTROL - The implantable medical device (IMD) system disclosed here utilizes one or more cardiac sensors that measure mechanical characteristics of the heart, such as left ventricular acceleration or right ventricular pressure. The raw sensor data is collected and processed by the IMD, which derives one or more mechanical event marker signals from features, traits, and characteristics of the sensor data waveforms. The mechanical event marker signals are wirelessly transmitted to an external monitor device for display. | 01-22-2009 |
20090248103 | APPARATUS AND METHODS OF OPTIMIZING VENTRICLE-TO-VENTRICULAR PACING DELAY INTERVALS - Provided herewith are methods and apparatus for optimizing ventricle-to-ventricle (V-V) pacing delay intervals based upon ECG-based optimization calculated as a linear function of P-wave duration sensed PR (intrinsic) interval sensed (or paced) QRS duration and heart rate. Since the relationship among these parameters is linear once the coefficients are solved (which can be any value, including null) with reference to a known optimized V-V interval such as from an echocardiographic study, an operating V-V interval value can be dynamically adjusted in an ambulatory subject. The various combinations of values can be loaded into a look up table or calculated automatically. And, since some of the parameters do not typically change much over time they can be determined acutely and fed into the equation while the other values can be measured more frequently. The parameter values can be measured by an implantable medical device such as a dual- or triple-chamber pacemaker. | 10-01-2009 |
20100016914 | APPARATUS AND METHODS FOR AUTOMATIC ADJUSTMENT OF AV INTERVAL TO ENSURE DELIVERY OF CARDIAC RESYNCHRONIZATION THERAPY - The disclosure provides methods and apparatus of left ventricular pacing including automated adjustment of a atrio-ventricular (AV) pacing delay interval and intrinsic AV nodal conduction testing. It includes—upon expiration or reset of a programmable AV Evaluation Interval (AVEI)—performing the following: temporarily increasing a paced AV interval and a sensed AV interval and testing for adequate AV conduction and measuring an intrinsic atrio-ventricular (PR) interval for a right ventricular (RV) chamber. Thus, in the event that the AV conduction test reveals a physiologically acceptable intrinsic PR interval then storing the physiologically acceptable PR interval in a memory structure (e.g., a median P-R from one or more cardiac cycles). In the event that the AV conduction test reveals an AV conduction block condition or if unacceptably long PR intervals are revealed then a pacing mode-switch to a bi-ventricular (Bi-V) pacing mode occurs and the magnitude of the AVEI is increased. | 01-21-2010 |
20100023081 | Comprehensive System for Detection of Coronary Syndrome, Cardiac Ischemia and Myocardial Infarction - Heart-monitoring systems, apparatus, and methods adapted to detect CS, CI and/or MI. In one embodiment, a system comprising at least two first-tier sensors capable of measuring and converting into signals at least two aspects related to cardiac function, at least one second-tier sensor that is also a first-tier sensor, at least one signal processor capable of transmitting a first-tier and second-tier trigger signal when coronary syndrome, cardiac ischemia or myocardial infarction has been detected, at least one communication device capable of communicating, at least one control element adapted to produce a first-tier and second-tier trigger signal when at least one first-tier sensor exceeds its threshold signal level, to exclude the signal from the first-tier sensor that exceeded its threshold and lower at least one threshold of the at least one first-tier sensor is provided. | 01-28-2010 |
20100198291 | FUSION PACING INTERVAL DETERMINATION - Delivery of fusion pacing therapy to a later depolarizing ventricle (V | 08-05-2010 |
20100198293 | PACING THERAPY ADJUSTMENT BASED ON VENTRICULO-ATRIAL DELAY - Techniques for adjusting pacing therapy based on ventriculo-atrial delay are described herein. These techniques may be used to control ventricular filling times during the delivery of pacing therapy. In some examples, a device or system delivers pre-excitation fusion pacing therapy to a ventricular chamber, determines a ventriculo-atrial delay interval for the ventricular chamber for at least one cardiac cycle, and adjusts the pacing therapy delivered by the implantable medical device to compensate for decreased ventricular filling time when the ventriculo-atrial delay interval is less than a threshold. In some examples, the device or system may adjust the pacing therapy by decreasing a pacing rate of the implantable medical device, increasing a pre-excitation interval for pacing of the ventricular chamber, and/or switching from a fusion pacing mode to a biventricular pacing mode. | 08-05-2010 |
20100317940 | Absolute calibrated tissue oxygen saturation and total hemoglobin volume fraction - A medical device for monitoring a patient condition includes a sensor capable of being advanced transvascularly to be positioned along a volume of tissue, the sensor including a first combination of a light source and a light detector to emit light into a volume of tissue and to detect light scattered by the volume of tissue and to generate a first output signal corresponding to an intensity of the detected light. A control module is coupled to the light source to control the light source to emit light at least four spaced-apart light wavelengths, and a monitoring module is coupled to the light detector to receive the output signal and compute a measure of tissue oxygenation using the light detector output signal. | 12-16-2010 |
20100317941 | ABSOLUTE CALIBRATED TISSUE OXYGEN SATURATION AND TOTAL HEMOGLOBIN VOLUME FRACTION - A medical device for monitoring a patient condition includes a first combination of a light source and a light detector to emit light into a volume of tissue, detect light scattered by the volume of tissue, and provide a first output signal corresponding to an intensity of the detected light. A control module is coupled to the light source to control the light source to emit light at least four spaced-apart light wavelengths, and a monitoring module is coupled to the light detector to receive the output signal, compute a measure of tissue oxygenation in response to the light detector output signal, and detect tissue hypoxia using the measure of tissue oxygenation. | 12-16-2010 |
20110029034 | ALGORITHM TO MODULATE ATRIAL-VENTRICULAR DELAY AND RATE RESPONSE BASED ON AUTONOMIC FUNCTION - An implantable medical device and associated method provide atrial pacing and measure an atrial ventricular (AV) delay. An autonomic function index is computed using the AV delay. The autonomic function index may be compiled in a medical report. In some embodiments, the autonomic function index is used to adjust atrial pacing control parameters. | 02-03-2011 |
20110190841 | APPARATUS AND METHODS OF OPTIMIZING ATRIOVENTRICULAR PACING DELAY INTERVALS - Provided herewith are methods and apparatus for optimizing an atrioventricular (AV) pacing delay interval based upon ECG-based optimization is calculated as a linear function of P-wave duration, sensed PR (intrinsic) interval, sensed or paced QRS duration and heart rate. Since the relationship among these parameters is linear, once the coefficients are solved (which can be any value, including null) with reference to a known optimized AV interval (AVopt) such as from an echocardiographic study, an AVopt value can be dynamically adjusted in an ambulatory subject. The various combinations of values can be loaded into a look up table or calculated automatically. And, since some of the parameters do not typically change much over time they can be determined acutely and fed into the equation while the other values can be measured frequently. The parameter values can be measured by an implantable medical device such as a dual- or triple-chamber pacemaker. | 08-04-2011 |
20120296387 | PHRENIC NERVE STIMULATION DETECTION USING HEART SOUNDS - A method of delivering phrenic nerve stimulation in a medical device system that includes detecting an activation event, delivering phrenic nerve stimulation therapy in response to the detected activation event, sensing a heart sound signal, in response to the delivered phrenic nerve stimulation therapy, monitoring a portion of the sensed heart sound signal, the portion defined by a predetermined window ocurring after the delivered phrenic nerve stimulation therapy, and determining whether the delivered phrenic nerve stimulation therapy was successful in response to the monitoring. | 11-22-2012 |
20120296388 | PHRENIC NERVE STIMULATION DETECTION USING HEART SOUNDS - A method and system of detecting phrenic nerve stimulation in a patient that includes detecting an activation event, obtaining a heart sound signal of a patient from an implanted heart sound sensor, determining that an electrical stimulation has been applied to the patient, in response to detecting the activation event, monitoring a portion of the heart sound signal, the portion defined by a predetermined window after the application of the electrical stimulation, and determining whether phrenic nerve stimulation occurred based on the portion of the heart sound signal. | 11-22-2012 |
20130013017 | APPARATUS AND METHODS FOR AUTOMATIC ADJUSTMENT OF AV INTERVAL TO ENSURE DELIVERY OF CARDIAC RESYNCHRONIZATION THERAPY - Methods and apparatus of left ventricular pacing including automated adjustment of a atrio-ventricular (AV) pacing delay interval and intrinsic AV nodal conduction testing. Thus, in the event that the AV conduction test reveals a physiologically acceptable intrinsic PR interval then storing the physiologically acceptable PR interval in a memory structure (e.g., a median P-R from one or more cardiac cycles) and delivering fusion pacing using a decremented value of the intrinsic PR interval. | 01-10-2013 |
20130030484 | SYSTEM AND METHOD FOR PACING PARAMETER OPTIMIZATION USING HEART SOUNDS - A medical device system and associated method predict a patient response to a cardiac therapy. The system includes for delivering cardiac pacing pulses to a patient's heart coupled to a cardiac sensing module and a cardiac pacing module for generating cardiac pacing pulses and controlling delivery of the pacing pulses at multiple pace parameter settings. An acoustical sensor obtains heart sound signals. A processor is enabled to receive the heart sound signals, derive a plurality of heart sound signal parameters from the heart sound signals, and determine a trend of each of the plurality of heart sound signal parameters with respect to the plurality of pace parameter settings. An external display is configured to present the trend of at least one heart sound parameter with respect to the plurality of pace parameter settings. | 01-31-2013 |
20130197599 | ADAPTIVE CARDIAC RESYNCHRONIZATION THERAPY - Cardiac resynchronization therapy (CRT) delivered to a heart of a patient may be adjusted based on detection of a surrogate indication of the intrinsic atrioventricular conduction of the heart. In some examples, the surrogate indication is determined to be a sense event of the first depolarizing ventricle of the heart within a predetermined period of time following the delivery of a fusion pacing stimulus to the later depolarizing ventricle. In some examples, the CRT is switched from a fusion pacing configuration to a biventricular pacing configuration if the surrogate indication is not detected, and the CRT is maintained in a fusion pacing configuration if the surrogate indication is detected. | 08-01-2013 |
20130268017 | HEART-SOUNDS BASED ADAPTIVE CARDIAC RESYNCHRONIZATION THERAPY TIMING PARAMETER OPTIMIZATION SYSTEM - A medical device and associated method for controlling a cardiac pacing therapy sense a first cardiac signal including events corresponding to cardiac electrical events and a second cardiac signal including events corresponding to cardiac hemodynamic events. A processor is enabled to measure a cardiac conduction time interval using the first cardiac signal and control a signal generator to deliver a pacing therapy. A pacing control parameter is adjusted to a plurality of settings during the pacing therapy delivery. A hemodynamic parameter value is measured from the second cardiac signal during application of each of the control parameter settings. The processor identifies an optimal setting from the plurality of settings and solves for a patient-specific equation defining the pacing control parameter as a function of the cardiac conduction time interval. | 10-10-2013 |