A data file system includes one or more files about a patient wearing a wearable cardiac defibrillator (WCD) system that has been assigned to them. The one or more files contain at least one patient identifier of the patient, compliance data about a history of the patient's wearing the WCD system, and possibly other data. The data file system can be accessed through a communication network when the patient uses a communication device. When so accessed, some of the contents can be viewed on a screen of the device, for example in the form of a website. In embodiments, the health care provider and friends and family can view such data and even enter inputs, which may create a situation that motivates the patient to comply better.

The present invention provides a micropackaged device comprising: a substrate for securing a device with a corrosion barrier affixed to the substrate, wherein the corrosion barrier comprises a first thin-film layer, a metal film coating the thin-film layer and a second thin-film layer to provide a sandwich layer; and optionally at least one feedthrough disposed in the substrate to permit at least one input and or at least one output line into the micropackaged device, wherein the micropackaged device is encapsulated by the corrosion barrier. Methods of producing the micropackaged device are also disclosed.

The disclosed invention varies the width of the energy pulses with constant frequency and constant amplitude to regulate the amount of energy transferred from an energy transmitting device placed outside a patient to an energy receiver inside the patient. The pulse width is achieved with a modulation technique, PWMT, to control the amount of energy transferred from the external energy transmitting coil in the system to the implanted receiver. The PWMT is used to digitally vary the amount of power from the power amplifier that drives the transmitting coil. Compared to previous analog systems a PWM system is a great deal more efficient and can easily be controlled from a digital domain system such as a microprocessor.

A medical device system and associated method determine an implantable medical device state prior to implantation. An impedance monitoring module monitors for a change in impedance between a pair of electrodes coupled to the impedance monitoring circuit. The system includes an enclosure for carrying the implantable medical device. The enclosure has a surface having an electrical impedance. A control module is configured to detect one of a first pre-implant state and a second pre-implant state of the implantable medical device in response to the impedance monitoring module detecting a change in impedance between the electrodes and adjust operation of the implantable medical device in response to detecting the impedance change.

The present subject matter includes an implantable medical device with a capture feature at or near the proximal end. In some cases, the capture feature includes a hold that is configured to facilitate a releasable connection with a delivery device that is used to deliver the implantable medical device to a target implant site.

The present disclosure relates generally to pacing of cardiac tissue, and more particularly to adjusting delivery of His bundle or bundle branch pacing in a cardiac pacing system to achieve synchronized ventricular activation. Bundle pacing may be delivered in response to determining whether the QRS parameter or activation interval is greater than a threshold. A set of AV delays may be generated, and an optimal AV delay may be selected from the stored set of AV delays. His-bundle or bundle-branch pacing may be selectively delivered based on RV or LV activation time. Pacing may also be adjusted based on dyssynchrony detected or the type of bundle branch block pattern detected.

The disclosure describes an enhancement to lead monitoring techniques, which uses a sensing integrity counter (SIC). The techniques of this disclosure may enhance lead monitoring techniques by detecting possible sensing issues based on a significant increase in periodic, e.g., daily, SIC counts relative to previous periods. Some issues with sensing cardiac signals via implantable cardiac leads can result in an implantable medical device (IMD) measuring very short intervals between what appears to be sensed heart beats. Examples of issues include insulation breach, conductor fracture, or poor electrical connection, which may cause noise that appears to be an R-wave. The IMD may detect the noise, along with actual R-waves, and determine that there are relatively short (e.g., less than a threshold) intervals between the “R-waves.” A significant increase in the number or frequency of very short intervals between R-waves may indicate the date/time of a significant sensing issue.

An introducing device for locating a tissue region and deploying an electrode is shown and described. The introducing device may include an outer sheath. An inner sheath may be disposed within the outer sheath. The inner sheath may be configured to engage an implantable electrode. In an example, the inner sheath may comprise a stimulation probe having an uninsulated portion at or near a distal end of the delivery sheath. The outer sheath may be coupled to a power source or stimulation signal generating circuitry at a proximal end. A clinician may control application of the stimulation signal to a tissue region via the outer sheath.

A neurostimulation system having an external or an implantable pulse generator programmed to innervate a specific nerve or group of nerves in a patient through an electrode as a mode of treatment, having a patient remote that wirelessly communicates with the pulse generator to increase stimulation, decrease stimulation, and provide indications to a patient regarding the status of the neurostimulation system. The patient remote can allow for adjustment of stimulation power within a clinically effective range and for turning on and turning off the pulse generator. The patient remote and neurostimulation system can also store a stimulation level when the pulse generator is turned off and automatically restore the pulse generator to the stored stimulation level when the pulse generator is turned on.

An implantable medical lead for sacral modulation therapy is disclosed. The implantable medical lead includes a lead body having a distal portion. An electrode is electrically coupled to the lead body and configured to generate a stimulation field or to sense electrical fields. A fixation mechanism is coupled to the distal portion. The fixation mechanism is configured to anchor the implantable medical lead against an interior wall of a blood vessel. The electrode can effect the stimulation field from within the vessel to stimulate a selected sacral nerve or sense electrical signals such as muscle or nerve responses. Guided implantation of the medical lead or other medical leads through the body to a nerve of interest for neurostimulation via remote sensor is also disclosed.