In one aspect, wireless gastrointestinal stimulations are described herein. In some embodiments, a system described herein comprises at least one transmitter and at least one stimulation device. The transmitter can include a signal generator operable to generate an electromagnetic signal, a first antenna operable to broadcast the electromagnetic signal, and an energy source. The at least one stimulation device is operable to deliver a pattern of electrical pulses to a gastrointestinal tissue comprising a muscle, and the stimulation device includes a circuit board having a circumference, at least one second antenna wrapped around the circumference of the circuit board, the at least one second antenna being configured to receive the electromagnetic signal and to generate an electrical current from the electromagnetic signal, and at least one electrode operable to deliver the electrical current to the muscle.

The present disclosure provides systems and methods for disrupting neuronal oscillations. A neurostimulation system includes a stimulation lead comprising at least one contact, and an implantable pulse generator (IPG) communicatively coupled to the stimulation lead and configured to cause stimulation to be applied to a patient using no more than two contacts of the stimulation lead by causing a first burst of stimulation to be delivered, and causing a second burst of stimulation to be delivered within a neuronal refractory period that follows the first burst of stimulation.

Systems and methods are provided for reducing stimulation interference between two stimulation modules positioned on a user's body, which may be used in stimulation systems without a central treatment controller. Systems and methods are also provided for stimulation treatment using multiple independent stimulators wirelessly managed by a remote management device.

This document discusses, among other things, systems and methods for managing pain of a subject. A system may include a motion sensor configured to sense at least one functional signal indicative a physical state of the subject. The at least one functional signal may include at least one motor activity signal or at least one sleep state signal. A pain analyzer circuit may extract, from the functional signal, signal metrics indicative of subject motor control or kinetics, and generate a pain score using the signal metrics. The pain score may be output to a user or a process. The system may additionally include an electrostimulator to generate and deliver a closed-loop pain therapy according to the pain score.

Methods and apparatuses for use in medical procedures are disclosed. Some implementations may include a medical procedure guide that can overlay portions of anatomy of a patient. The guide may include alignment markings to facilitate proper placement, procedure markings to facilitate determination of a position at which to commence a medical procedure, and/or imaging markers incorporated within the guide to facilitate commencement or completion of the medical procedure in conjunction with imaging.

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.

Systems and methods for ambulatory detection of medical events such as cardiac arrhythmia are described herein. An embodiment of an arrhythmia detection system may include a detection criterion circuit that determines a patient-specific detection criterion using a baseline cardiac characteristic when the patient is free of cardiac arrhythmias. The detection criterion circuit generates a patient-specific threshold of a signal metric by adjusting a population-based threshold of the signal metric, where the manner and the amount of adjustment is based on information about patient baseline cardiac characteristic. The arrhythmia detection system detects an arrhythmia episode using a physiologic signal sensed from the patient and the patient-specific arrhythmia detection threshold.

A system and methods of maintaining communication with a medical device for exchange of information, instructions, and programs, in a highly reliable manner. Apparatus and methods for accomplishing this task include: 1) The inclusion of a locating device in the system, in close proximity to an implanted device, but which does not drain the implanted device battery. The locating device may be implanted or external to the body. 2) The use of motion detection and global positioning system devices to locate elements within a communicating system for the medical device; 3) The assessment of received signal quality by elements of the system; 4) The use of a notification system for a device user who is moving out of range of communications; and 5) Documenting the absolute and functional integrity of instructions received by the medical device.

Methods for automatically programming a signal generator in a patient therapy system and associated systems are disclosed. A representative method comprises retrieving data including therapy program parameters, level of efficacy, and medication use corresponding to a plurality of time periods; identifying from the data a target time period having a corresponding level of efficacy; determining from the data if medication was used during the target time period; determining from the data if medication was used during a prior time period immediately before the target time period; calculating a lead position confidence factor; and programming the signal generator to repeat therapy with the therapy program parameters corresponding to the target time period if the confidence factor is greater than a threshold value and medication was used during the prior time period and not during the target time period.

System and methods are provided for determining a stimulation threshold for closed loop spinal cord stimulation (SCS). The system and methods provide a lead coupled to an implantable pulse generator (IPG). The system and methods deliver SCS pulses from the IPG to the lead electrodes in accordance with an SCS therapy and determine an evoked compound action potential (ECAP) amplitude based on an ECAP waveform resulting from the SCS therapy. The system and methods increase the SCS therapy by increasing at least one of an amplitude, a duration, and number of the SCS pulses associated with the SCS therapy. The system and methods also include iteratively repeat the delivering, determining and increasing operations until the ECAP amplitude exhibits a downward trend divergence. The system and methods define a stimulation threshold based on the ECAP amplitude at the trend divergence.