Abstract: Cardiac electrical activity includes intrinsic signals as well as paced or stimulated signals. Waveforms of cardiac electrical activity may be detected by a variety of systems, including surface ECG systems and various implantable cardiac devices including implantable cardiac stimulation devices. Intrinsic cardiac signals and various cardiac conditions influence these waveforms in ways that can be identified using various detection criteria, and from which cardiac markers may be generated. Musical notations are linked to these cardiac markers as appropriate, and are sounded as a function of time to generate musical sound which is indicative of the patient's cardiac function.

Abstract: An exemplary method includes selecting multiple electrodes located in a patient; acquiring position information during one or more cardiac cycles for the multiple electrodes where the acquiring includes using each of the electrodes for measuring one or more electrical potentials in an electrical localization field established in the patient; calculating one or more vector metrics based on the acquired position information for one or more vectors, each vector defined by two of the multiple electrodes; and analyzing the one or more vector metrics to assess cardiac performance during the one or more cardiac cycles. Various other methods, devices, systems, etc., are also disclosed.

Abstract: When a medical procedure is performed on a patient in whom an implantable medical device is implanted, the medical procedure may have undesired effects on the medical device, such as triggering a response that initiates therapy by the device that is unnecessary and potentially dangerous to the patient. Systems and methods may facilitate performing of such medical procedures on such patients by temporarily reprogramming the medical device, monitoring for one or more detectable characteristics associated with the medical procedure to be performed, and restoring normal programming of the device based on detection and/or lack of detection of the detectable characteristic(s).

Abstract: A system and method for using an implantable cardiac stimulation device to monitor a patient for the progress of an existing condition and/or early detection of an emerging condition based, at least in part, on measuring and evaluating the timing characteristics of the patient's atrial activity. The atrial timing characteristics are used as indicators or predictors of conditions of interest, such as heart failure (HF) and atrial fibrillation (AF). In certain implementations, the system can determine discriminating indicators of a predominant underlying cause of a condition, such as between vagal and non-vagal AF, as an indicator of a suggested therapy. The system can store data corresponding to the observed atrial timing for trending analysis as well as transmit data for offline analysis, such as via an external device.

Abstract: Methods, systems and devices are provided for monitoring respiratory disorders based on monitored factors of a photoplethysmography (PPG) signal that is representative of peripheral blood volume. The monitored factors can be respiratory effort as well as respiratory rate and/or blood oxygen saturation level. The systems and devices may or may not be implanted in a patient.

Abstract: A system with an implantable cardiac stimulation device having an implantable stimulation generator, at least one implantable lead adapted for connection to the implantable stimulation generator and further adapted for at least one of sensing physiologic activity and delivery of therapy, memory, and a controller in communication with the memory and with the at least one implantable lead and stimulation generator. The controller is configured to automatically evaluate a patient's physiologic status and selectively induce delivery of therapeutic stimulation under variable timing parameters. The system also has a measurement system adapted to measure at least one of strain and velocity of myocardial tissue and is adapted to evaluate strain and/or velocity measures and adjust the variable timing parameters of the implantable stimulation device to increase mechanical synchrony of the myocardial tissue.

Abstract: Implantable stimulation devices can provide intracardiac electrograms (EGMs) and impedance measurements to detect changes in electrical, mechanical, and electromechanical activation of the heart. Many patients with congestive heart failure have conventional intracardiac devices implanted that are not capable of resynchronization therapy and these patients could benefit from resynchronization, but are not candidates based on current criteria. These patient populations can be identified through analyses of intracardiac electrogram data that is available through implantable stimulation devices comprising at least one lead for providing electrical stimulation to the heart of a patient, at least one sensor that detects electrical signals indicative of the depolarization of the heart of the patient, and a controller that is adapted to be implanted within the patient.

Abstract: Systems and methods are provided for obtaining measures of blood oxygen saturation using an implantable device implanted within a patient and a non-implanted device external to the patient, while limiting the amount of processing that need be performed by the implantable device. Other embodiments limit the amount of processing that is performed within the implantable device by monitoring changes and blood oxygen saturation without determining actual measures of blood oxygen saturation.

Abstract: Implantable systems that can monitor myocardial electrical stability, and methods for use therewith, are provided. Also provided are novel pacing sequences that are used in such monitoring. Such pacing sequences are designed to reveal alternans at low to moderate heart rates.

Abstract: An exemplary controller includes an input for receiving information related to a signal of supraventricular origin, control logic to determine a control signal and an output to deliver the control signal to thereby actively filter the signal of supraventricular origin in the His bundle. Other exemplary methods, devices, systems, etc., are also disclosed.

Abstract: Methods and devices are provided for reducing motion artifacts when measuring blood oxygen saturation. A portion of the light having the first wavelength, a portion of light having the second wavelength and a portion of the light having the third wavelength are received. A first signal is produced based on the received portion of light having the first wavelength. Similarly, a second signal is produced based on the received portion of light having the second wavelength, and a third signal is produced based on the received portion of light having the third wavelength. A difference between the second signal and the first signal is determined, wherein the difference signal is first plethysmography signal. Similarly, a difference is determined between the third signal and the first signal to produce a second plethysmography signal. Blood oxygen saturation is then estimated using the first and second plethysmography signals.

Abstract: An implantable medical device, such as a pacemaker or implantable cardioverter defibrillator (ICD), is configured to automatically detect ingestion of medications to verify that prescribed medications are taken in a timely manner and at the correct dosage. Briefly, individual pills are provided with miniature radio frequency identification (RFID) devices capable of transmitting RFID tag signals, which identify the medication contained within the pill and its dosage. The implanted device is equipped with an RFID transceiver for receiving tag signals from a pill as it is being ingested. The implanted system decodes the tag to identify the medication and its dosage, then accesses an onboard database to verify that the medication being ingested was in fact prescribed to the patient and to verify that the correct dosage was taken. Warning signals are generated if the wrong medication or the wrong dosage was taken. Therapy may also be automatically adjusted.

Abstract: Techniques are provided for use by implantable medical devices for controlling ventricular pacing. In one example, optimal atrio-ventricular and interventricular pacing delay values are determined for pacing the heart of the patient based, in part, on a measured inter-atrial conduction delay. Atrio-ventricular conduction delays are then measured within the patient. The atrio-ventricular pacing delays are compared with the measured atrio-ventricular conduction delays. If the atrio-ventricular pacing delays are less than the measured atrio-ventricular conduction delays, biventricular pacing is delivered using the atrio-ventricular pacing delay and the interventricular pacing delay.

Abstract: An implantable medical device and methods of manufacture are provided for implantation in a body. The device includes a device housing having an interior cavity and electronic circuitry located in the interior cavity of the device housing. The electronic circuitry detects a physiologic condition of the body and delivers a therapy to the body. The device further includes a feed-through assembly having a feed-through housing that is joined to the device housing. The feed-through assembly includes conductors held in the feed-through housing and electronically connected to the electronic circuitry. A back-fill member is joined to the feed-through housing. The back-fill member has an opening there through communicating with the interior cavity of the device housing. A sealing element is hermetically secured in the opening through the back-fill member. The sealing element and back-fill member are formed of different first and second materials, respectively.

Abstract: An implant tool for use with an endocardial or other implantable lead having an extendable/retractable active fixation tip includes a housing, a shaft rotatably supported by the housing, and a shaft rotation mechanism for rotating the shaft through a predetermined angular travel. The shaft includes a lead attachment portion for selectively coupling a lead to the shaft such that the lead is rotatable with the shaft. The implant tool may include a control tab slidably supported by the housing, wherein longitudinal movement of the control tab actuates the shaft rotation mechanism. The shaft rotation mechanism may include a gear train, an electric motor, a double acting spring mechanism, or a retractable tape wound around the shaft. The gear train includes an input member coupled to the control tab and an output gear coupled to the shaft. The input member meshes with an input gear supported by the housing.

Abstract: Techniques are provided for selecting and configuring inductors for use in radio-frequency (RF) inductive filters within pacing/sensing leads of pacemakers or implantable cardioverter-defibrillators. The filters are employed to reduce heating due to induced currents caused by magnetic resonance imaging (MRI) procedures or other sources of strong RF fields. In particular, techniques are provided for determining optimal inductance values by taking into account parasitic resistances and parasitic capacitances of the inductors. Tolerances of the inductive devices are also taken into account.

Abstract: An implantable medical device and methods of manufacture are provided for implantation in a body. The device includes a device housing having an interior cavity and electronic circuitry located in the interior cavity of the device housing. The electronic circuitry detects a physiologic condition of the body and delivers a therapy to the body. The device further includes a feed-through assembly having a feed-through housing that is joined to the device housing. The feed-through assembly includes conductors held in the feed-through housing and electronically connected to the electronic circuitry. A back-fill member is joined to the feed-through housing. The back-fill member has an opening there through communicating with the interior cavity of the device housing. A sealing element is hermetically secured in the opening through the back-fill member. The sealing element and back-fill member are formed of different first and second materials, respectively.

Abstract: An implantable cardiac stimulation device is equipped with a hardware elastic buffer. In an exemplary device, the hardware elastic buffer comprises SRAM and a SRAM controller. The device optionally includes averaging, concatenating, filling and/or other features.

Abstract: Provided herein are implantable systems, and methods for use therewith, for estimating a level of noise in a signal produced by an implantable sensor that is sensitive to motion induced noise. Sample data is obtained that is representative of a window of a signal produced by the implantable sensor that is sensitive to motion induced noise. Such sample data includes a plurality of samples each having a magnitude (e.g., amplitude). Each of at least some of the samples is assigned to one of a plurality of bins based on the magnitude of the sample, wherein each bin corresponds to a different range of magnitudes. The plurality of bins includes at least a low bin defining a lowest magnitude range and a high bin defining a highest magnitude range. A level of motion induced noise in the sensor signal is estimated based on a distribution of the samples to the bins.

Abstract: An implantable cardiac device minimizes apnea burden. In one implementation, the device administers a series of cardiac pacing trials using a different value for a pacing parameter in each trial and then measures an apnea burden corresponding to each trial in order to determine a value which reduces apnea burden when used for ongoing cardiac pacing. In one implementation the implantable cardiac device performs series of trials in cycles, during which a first series of trials determines a value for a first pacing parameter for reducing apnea burden while other pacing parameters are held constant. Subsequent series of trials subject the other pacing parameters, in turn, to their own series of pacing trials while holding the non-subjected pacing parameters constant. Through multiple cycles, the device optimizes each parameter in turn based on continually improving values for the other pacing parameters.