Abstract: A portable wearable defibrillator device, a distributed defibrillator system, and a computer-implemented method use at least one node that is connected to a wireless network and communicates with sensors, electronic mobile devices, and/or defibrillator devices to determine when a person is having a cardiac or pulmonary event or other event, identify a person who is able to assist the arresting person, and notify the assisting person and/or any other emergency contacts and/or emergency personnel. The electronic components of the wearable defibrillator are arranged in serial to minimize the size of the defibrillator. The control circuit of the wearable defibrillator is configured to provide fast charging for the capacitor, such that the defibrillator is able to be used at any time and frequently. An application for an electronic mobile device is used to interface with an assisting person and other people, e.g., emergency contacts or emergency personnel, associated with the network.

Abstract: Systems and methods for active charge-balancing for high frequency neural stimulation are disclosed.

Abstract: Methods and systems are provided for managing residual charge for multi-point pacing therapy. The method and system provide an electrode configuration that includes an atrial (A) electrode, a right ventricular (RV) electrode and multiple left ventricular (LV) electrodes. The method and system deliver pacing pulses for an MPP therapy, during a first cardiac cycle, from a pulse generator to the electrode configurations. The pacing pulses are separated by pacing pulse (PP) intervals. The method and system dynamically adjust at least one of a timing or a duration of discharge pulses for the residual charge to form a discharge sequence. The method and system activate the discharge pulses based on the discharge sequence, during the first cardiac cycle, to the multiple LV electrodes to distribute the residual charge across the PP intervals.

Abstract: An external medical device includes a battery that can support a plurality of charge-discharge cycles prior to a predetermined battery life threshold. The device also includes a battery circuit that is operative for monitoring a condition of the battery, determining a battery life status of the battery based on the monitored condition and the predetermined battery life threshold, and, responsive to the determined battery life status, causing the device to enter into a low power operating mode. The low power operating mode can include modifying device functions that are performed, or modifying the manner in which a capacitor of the device is charged, or changing the battery that charges the capacitor, or isolating the capacitor from charge drainage, or causing the device to operate from charge stored on the capacitor.

Abstract: The invention relates to a user-operated device, a method and computer program for providing acknowledgement indicators performed by a user-operated device within a communication network. The user-operated device for receiving user input to trigger in a user-perceivable reaction of the user-operated device or a system controlled by it, the user-operated comprising means for detecting an actuation pattern of the user-operated device upon actuation of a user; means for comparing the detected actuation pattern with a predetermined pattern; and means for generating an acknowledgement indicator in dependence of a comparison result of the actuation pattern with the predetermined pattern.

Abstract: A sensor system includes a sensor and a sensor electronics device. The sensor includes a plurality of electrodes. The sensor electronics device includes a connection detection device, a power source, and a delay circuit. The connection detection device determines if the sensor electronics device is connected to the sensor and transmits a connection signal. The delay circuit receives the connection signal, waits a preset hydration time, and couples the regulated voltage from the power source to an electrode in the sensor after the preset hydration time has elapsed. Alternatively, the sensor electronics device may include an electrical detection circuit and a microcontroller. The electrical detection circuit determines if the plurality of electrodes are hydrated and generates an interrupt if the electrodes are hydrated. A microcontroller receives the interrupt and transmits a signal representative of a voltage to an electrode of the plurality of electrodes.

Abstract: Systems and methods for switching modes in a multi-device medical system. In one example, a first leadless cardiac pacemaker (LCP) may be implantable at a ventricular site, and a second leadless cardiac pacemaker (LCP) may be implantable at an atrial site and configured to sensing atrial contractions. The first LCP and the second LCP may be configured to be communicatively coupled such that the first LCP and the second LCP can deliver pacing therapy to the ventricular site in a tracking mode. The first LCP and/or the second LCP may additionally be configured to deliver pacing therapy to the ventricular site in a non-tracking mode if an interval between atrial contractions sensed by the second LCP becomes shorter than a threshold duration.

Abstract: A current sense circuit for measuring a charge level of a battery is disclosure. The circuit comprising: a shunt resistor (R10) connected between a high side terminal of the battery and a load/charge terminal for connecting the battery to a load; translation circuitry arranged to produce a voltage across a pair of current sense terminals (GG_SRP, GG_SRN) in proportion to the voltage across the shunt resistor; wherein one of the current sense terminals (GG_SRP) is provided on a first current path connected at one end between the high side terminal of the battery and the shunt resistor (R10), and connected at the other end to ground, and the other of the current sense terminals (GG_SRN) is provided on a second current path connected at one end between the shunt resistor (R10) and the load/charge terminal, and connected at the other end to ground.

Abstract: An electrical stimulation device configured to perform an electrical stimulation therapy on a patient includes a stimulation circuit, at least one electrode lead comprising one or more electrodes, a communication circuit and a controller. The controller is configured to execute a stimulation program received through the communication circuit. Electrical stimulation pulses are generated by the stimulation circuit and delivered to the at least one electrode lead in response to the execution of the stimulation program.

Abstract: An apparatus is disclosed for providing efficient stimulation. As an example, a variable compliance regulator can be connected to supply a compliance voltage to a power supply rail, which compliance voltage can vary dynamically based on a stimulus waveform. A pulse generator can be configured to provide an output waveform to one or more output based on the stimulus waveform for delivery of electrical therapy.

Abstract: A neurostimulation device includes an external neurostimulator worn by a patient using a bracing element that braces a portion of the patient's body. The external neurostimulator delivers neurostimulation to modulate a cardiovascular function of the patient. In one embodiment, the external stimulator delivers neurostimulation percutaneously to a stimulation target in the patient's body using at least one percutaneous stimulation electrode having a distal end lodged on or near the stimulation target.

Abstract: An external defibrillator having a battery; a capacitor electrically communicable with the battery; at least two electrodes electrically communicable with the capacitor and with the skin of a patient; a controller configured to charge the capacitor from the battery and to discharge the capacitor through the electrodes; and a support supporting the battery, capacitor, electrodes and controller in a deployment configuration, the defibrillator having a maximum weight per unit area in the deployment configuration of 0.1 lb/in2 and/or a maximum thickness of 1 inch. The support may be a waterproof housing.

Abstract: With a method and apparatus for detecting cardiac arrhythmias during overdrive pacing, a maximum paced rate and a reduced paced rate for a heart are determined, the maximum paced rate being higher than the reduced paced rate. The heart is paced at the maximum paced rate. After the heart is paced at the maximum paced rate for a predetermined amount of time, the heart is paced at the reduced paced rate.

Abstract: Catheters and methods for obtaining monophasic action potential (“MAP”) electrograms include a flexible catheter body defining a longitudinal axis, and a distal assembly affixed to the catheter body distal end defining a distal tip. The distal assembly has at least three MAP recording electrodes, and at least one reference electrode for determining reference potential. The recording electrodes are each positioned a radial distance from the longitudinal axis in at least three different radial directions, defining a recording geometry substantially having radial symmetry. The reference electrode is a longitudinal distance from the recording geometry. Optional features include a steerable catheter shaft, one or more radio-frequency ablation electrodes, and a dedicated pacing electrode. Different possible embodiments include a dome housing having the recording electrodes in a fixed spatial arrangement, and a distal loop assembly having an array of electrodes on at least three flexible loop elements.

Abstract: Embodiments of the invention include an implantable medical device having a digital signal processing circuit associated with an implantable medical device function. The digital signal processing circuit can be selectively implementable according to the clinical need of a patient. Embodiments of the invention also include methods of making and using such implantable medical devices.

Abstract: A neurostimulation device includes an external neurostimulator worn by a patient using a bracing element that braces a portion of the patient's body. The external neurostimulator delivers neurostimulation to modulate a cardiovascular function of the patient. In one embodiment, the external stimulator delivers neurostimulation percutaneously to a stimulation target in the patient's body using at least one percutaneous stimulation electrode having a distal end lodged on or near the stimulation target.

Abstract: A method and apparatus are provided for detecting cardiac arrhythmias during overdrive pacing. A maximum paced rate and a reduced paced rate for a heart are determined, the maximum paced rate being higher than the reduced paced rate. The heart is paced at the maximum paced rate. After the heart is paced at the maximum paced rate for a predetermined amount of time, the heart is paced at the reduced paced rate.

Abstract: Exemplary methods for affecting conduction and/or operation of the AV node and/or AV bundle. Various exemplary methods include delivery of one or more stimulation pulses to affect conduction and/or operation of an AV node and/or AV bundle. Such delivery optionally stimulates nerves and/or tissue. Nerve stimulation optionally includes parasympathetic nerve stimulation to decrease conduction of the AV node and/or AV bundle. Tissue stimulation optionally causes tissue to enter a refractory period. Various exemplary methods include delivering one or more stimulation pulses during postinspiration. Other exemplary methods and/or devices are also disclosed.

Abstract: An implantable cardioverter/defibrillator (ICD) includes an Anti-Tachycardia Pacing Before Charge (ATP-BC) mode according to which one or more high-voltage capacitors for storing defibrillation energy are charged in preparation of delivering a defibrillation shock only if a ventricular tachycardia (VT) sustains after an ATP delivery. Fast ATP delivery and effect verification methods are applied to avoid significant delay in delivering the defibrillation shock when found necessary to terminate the VT. A switch is provided such that a user decides whether to activate the ATP-BC mode or to deliver the defibrillation shock without delivering the ATP.

Abstract: A high voltage converter circuit for an implantable cardiac device. The circuit includes a plurality of transistors that are connected in parallel to a battery and the primary winding of a transformer. A switching element is connected to the circuit so as to periodically connect and disconnect the capacitors to the primary winding of the transformer to thereby induce the capacitors to be charged and periodically discharged across the transformer into charging capacitors. A circuit also preferably includes a disconnect circuit that will disconnect the capacitors from the battery during periods of non-use to inhibit unwanted dissipation of the battery's energy.

Abstract: The output stage of a tissue stimulating apparatus, for example a cochlear implant prosthesis, operating at a low supply voltage (35) incorporates a multiplier circuit (54, 62, 63, 64) for ensuring that voltage compliance is maintained in the event that high intensity stimulations are required. The multiplier circuit makes use of compliance monitoring so that multiplication is only used as required. Also described is a method for operating a tissue stimulating apparatus incorporating a multiplier circuit.

Abstract: The present invention provides for a patient-worn energy delivery apparatus for imparting electrical therapy to the body of a patient responsive to an occurrence of a treatable condition. The apparatus includes a voltage converter for converting electrical energy from an initial voltage to a final voltage at a plurality of charging rates, and a defibrillator electrically coupled between the converter and the patient and having an energy reservoir for receiving the electrical energy. The defibrillator produces preshaped electrical pulses such as defibrillation pulses and cardioversion pulses. The apparatus additionally includes an energy delivery controller electrically coupled to the patient and the converter and the defibrillator. The controller causes the converter to provide the electrical energy to the defibrillator at a specific charging rate in response to an energy level in the reservoir.

Abstract: A pacemaker has a pulse source for delivering heart stimulation pulses to at least one heart stimulation electrode which includes a source for charging a charge storage element with a prescribed amount of charge for each heart stimulus. The charge storage element is then caused to discharge a predetermined amount of charge through the stimulation electrode to form a heart stimulation pulse.