The Cardiac Tissue Engineered Model (TEEM) invention provides a robust in vitro model for cardiotoxicity evaluation using three-dimensional (3D) human heart microtissues to quantify dose-dependent changes in electromechanical activity, resulting in a comprehensive cardiotoxicity and arrhythmia risk assessment of test compounds. The invention also provides a predictive in vitro screening platform for pro-arrhythmic toxicity testing using human three-dimensional cardiac microtissues. The invention enables the screening of environmental and pharmaceutical compounds, chemicals, and toxicants to establish safe human exposure levels.

Systems, apparatus, and methods for ablation therapy are described herein, with a processor for confirming pacing capture or detecting ectopic beats. An apparatus includes a processor for receiving cardiac signal data captured by a set of electrodes, extracting a sliding window of the cardiac signal data, identifying a peak frequency over a subrange of frequencies associated with the extracted sliding window, detecting ectopic activity based at least on a measure of the peak frequency over the subrange of frequencies, in response to detecting ectopic activity, sending an indication of ectopic activity to a signal generator configured to generate pulsed waveforms for cardiac ablation such that the signal generator is deactivated or switched off from generating the pulsed waveforms. An apparatus can further include a processor for confirming pacing capture of the set of pacing pulses based on cardiac signal data.

Devices, systems, and methods for pacing tissue are disclosed herein. In some embodiments, the devices, systems, and methods position a tip section of a catheter adjacent tissue within an anatomical structure. The tip section is attached to a distal end portion of a catheter shaft, has a maximum radial dimension that is larger than a maximum radial dimension of the catheter shaft, and includes a plurality of electrodes spatially distributed about the tip section. The devices, systems, and methods further select one or more groupings of individual ones of the plurality of electrodes and deliver stimulating energy to or through the adjacent tissue via the selected groupings of electrodes. The stimulating energy is sufficient to activate nerve tissue proximate the tip section but is insufficient to ablate the adjacent tissue. In this manner, devices, systems, and methods disclosed herein can be used to locate nerve tissue proximate the tip section.

Computer implemented methods and systems are provided for automatically determining capture thresholds for an implantable medical device equipped for cardiac stimulus pacing using a multi-pole left ventricular (LV) lead. The methods and systems measures a base capture threshold for a base pacing vector utilizing stimulation pulses varied over at least a portion of an outer test range. The base pacing vector is defined by a first LV electrode provided on the LV lead and a second electrode located remote from an LV chamber. The methods and systems designate a secondary pacing vector that includes the first LV electrode and a neighbor LV electrode provided on the LV lead. The methods and systems further define an inner test range having secondary limits based on the base capture threshold, wherein at least one of the limits for the inner test range differs from a corresponding limit for the outer test range. The methods and systems measure a secondary capture threshold associated with the secondary pacing vector utilizing stimulation pulses varied over at least a portion of the inner test range.

A system and method are provided. The system includes a HIS electrode configured to be located proximate to a HIS bundle. A pulse generator is coupled to the HIS electrode and is configured to deliver HIS bundle pacing (HBP), a right atrial (RA) electrode is located in a right atrium, a sensing circuitry coupled to the RA electrode and defines an RA sensing channel that does not utilize the HIS electrode. The system includes a memory including program instructions. The system includes a processor is configured to collect cardiac activity (CA) signals over the RA sensing channel utilizing the RA electrode. The CA signals include a far field (FF) component associated with a ventricular event (VE). The processor analyzes the FF component to identify first and second FF component (FFC) characteristics of interest (COI) of the ventricular event and utilizes the first FFC COI to apply a first capture class (CC) discriminator to distinguish between first and second capture classes. The first capture class includes first and second capture types. The processor utilizes the second FFC COI to apply a second CC discriminator to distinguish between at least one of i) the first and second capture types within the first capture class, or ii) third and fourth capture classes and manages HIS bundle pacing based on distinctions by the first and second CC discriminators.

An analysis device for supporting the implantation of a system for stimulating the human heart or animal heart, comprising a processor and a memory unit. The memory unit includes a computer-readable program, which prompts the processor to carry out the following steps when the program is being executed on the processor: a) receiving an electrocardiogram of a human heart or an animal heart into which a system for stimulating this heart is being implanted; b) automatically identifying signals of the electrocardiogram caused by a His bundle stimulation, a signal being identified which appears between an atrial signal and a ventricular signal; c) marking the previously identified signals in the received electrocardiogram; and d) outputting the electrocardiogram thus marked on an output device. The analysis device comprises a detection unit having a sensitivity of at least 0.25 mV.

A system for stimulating phrenic nerves to provide smooth breathing patterns is provided. More specifically, by identifying contraction threshold voltages for muscles associated with each of the left and right portions of a patient's diaphragm, a phrenic nerve pacing signal customized for each phrenic nerve may be provided to a patient. More specifically, a voltage of a pacing voltage provided to a first phrenic nerve may be less than the contraction threshold while a voltage of a pacing voltage provided to a second phrenic nerve may be greater than the contraction threshold.

An implantable medical device system delivers a pacing pulse to a patient's heart and starts a first pacing interval corresponding to a pacing rate in response to the delivered pacing pulse. The system charges a holding capacitor to a pacing voltage amplitude during the first pacing interval. The system detects an increased intrinsic heart rate that is at least a threshold rate faster than the current pacing rate from a cardiac electrical signal received by a sensing circuit of the implantable medical device. The system starts a second pacing interval in response to an intrinsic cardiac event sensed from the cardiac electrical signal and withholds charging of the holding capacitor for at least a portion of the second pacing interval in response to detecting the increased intrinsic heart rate.

A pacing lead for temporary atraumatic placement via transvascular access on an endocardial surface of a heart chamber of an animal body. The pacing lead body has a curled shaft at the distal end region of the pacing lead body having a plurality of electrode sites. Each of the electrode sites is individually connected via an electrode conduction wire to a switch box, which receives generator signals from a pulse generator and directs the electrode generator signal to specific electrode sites. A push-pull element is connected to the lead body distal end. A tension-compression member connects to the push-pull element and provides tension and compression to the push-pull element.

In at least one example, a medical device is provided. The medical device includes at least one therapy electrode, at least one acoustic sensor, and at least one processor coupled with the at least one therapy electrode and the at least one acoustic sensor. The at least one processor is configured to deliver at least one pacing pulse via the at least one therapy electrode and to analyze processed acoustic data to determine whether the at least one pacing pulse resulted in capture.