A system for hepatic nerve denervation includes a medical device and a generator in communication with the medical device. The medical device includes an elongate body having a proximal portion and a distal portion opposite the proximal portion, and a plurality of treatment electrodes coupled to the distal portion. The distal portion is configured to be in contact with an area of target tissue. The area of target tissue is an area of tissue within the hepatic artery. The generator is configured to generate and deliver at least one pulse train of energy to the plurality of treatment electrodes to ablate the area of target tissue.

Systems and methods for the treatment of gastroesophageal reflux disease (GERD) include at least one electrically stimulating electrode coupled to a pulse generator. Individuals with GERD are treated by implanting a stimulation device within and/or proximate the patient's lower esophageal sphincter, gastric fundus, or other nearby gastrointestinal structures and applying electrical stimulation to the patient's lower esophageal sphincter and/or fundus, in accordance with certain predefined protocols. Electrical stimulation provided by the disclosed systems results in an increase in the length of the high pressure zone of the LES and/or modulation of the receptive relaxation response of the fundus to decrease gastric pressure, creating a longer barrier to the reflux of gastric contents or increasing functional lower esophageal pressure respectively, thereby treating GERD.

The object of the present invention is the method to assess the pelvic floor muscle injury, comprising the steps of applying the measuring probe into the anus, generation of electric current signals of constant amplitude, using a current generator, and applying the signals into the pelvic floor muscles by means of application electrodes (EA1) and (EA2), detection of electric voltage signals from the pelvic floor muscles by means of a plurality of measuring electrodes (EP1), EP2 . . . EPn, analysis of electric current and voltage signals for amplitude values and phase dependencies of their waveform, wherein the electric current signals and the electric voltage signals from the pelvic bottom muscles constitute signals variable in time, of the frequencies ranging from 2 kHz to 200 kHz. The object of the invention is also an electrode based measuring probe and apparatus implementing the method of assessment pelvic floor muscles injury.

The object of the present invention is the method to assess the pelvic floor muscle injury, comprising the steps of applying the measuring probe into the anus, generation of electric current signals of constant amplitude, using a current generator, and applying the signals into the pelvic floor muscles by means of application electrodes (EA1) and (EA2), detection of electric voltage signals from the pelvic floor muscles by means of a plurality of measuring electrodes (EP1), EP2 . . . EPn, analysis of electric current and voltage signals for amplitude values and phase dependencies of their waveform, wherein the electric current signals and the electric voltage signals from the pelvic bottom muscles constitute signals variable in time, of the frequencies ranging from 2 kHz to 200 kHz. The object of the invention is also an electrode based measuring probe and apparatus implementing the method of assessment pelvic floor muscles injury.

A non-invasive colon motility monitoring system comprises an electrobioimpedance unit, an electromyography unit, and a computing device. The electrobioimpedance unit measures an impedance of a body of a subject and communicates an impedance signal that varies according to the measured impedance. The electromyography unit measures an electric voltage of the body of the subject and communicates a voltage signal that varies according to the measured voltage. The computing device includes a processing element programmed to receive the impedance signal and determine impedance data from the impedance signal, receive the voltage signal and determine voltage data from the voltage signal, compute impedance derivative data from the impedance data, compute a correlation between any two of the impedance data, the voltage data, and the impedance derivative data, determine when a bowel event is about to occur based on the correlation, and provide an indication of the bowel event.

A non-invasive colon motility monitoring system comprises an electrobioimpedance unit, an electromyography unit, and a computing device. The electrobioimpedance unit measures an impedance of a body of a subject and communicates an impedance signal that varies according to the measured impedance. The electromyography unit measures an electric voltage of the body of the subject and communicates a voltage signal that varies according to the measured voltage. The computing device includes a processing element programmed to receive the impedance signal and determine impedance data from the impedance signal, receive the voltage signal and determine voltage data from the voltage signal, compute impedance derivative data from the impedance data, compute a correlation between any two of the impedance data, the voltage data, and the impedance derivative data, determine when a bowel event is about to occur based on the correlation, and provide an indication of the bowel event.

Articles and systems configured for treating GI motility disorders are generally provided. In some embodiments, an article comprising one or more electrodes (with both sensing and stimulating capabilities) may be configured to stimulate one or more tissues in the GI tract, electrically and/or chemically, to modulate peristalsis and/or allow neuromodulation. In some embodiments, a system comprises a controller that allows for close-loop operation of the article, e.g., such that the article may stimulate (e.g., via a feedback loop) the one or more organs in the GI tract upon receiving sensed parameters in the GI tract. In some embodiments, an implantation tool comprising a sensor may allow for submucosal or intramuscular implantation of an article. The implantation tool and the article may be useful for, for example, as a general platform for delivery of treating GI motility disorders and/or neuromodulation of the GI tract.

A system and method which performs translumbosacral neuromodulation therapy in a subject by outputting pulses of magnetic energy onto the lumbar and sacral nerves of the subject is described. The system includes a control unit, an anorectal probe, at least one skin electrode, a first magnetic coil, a second magnetic coil, and a neurophysiological recorder. The control unit manages the system components. The anorectal probe and the skin electrode detect muscle activity when a nerve from the back of the subject is stimulated. The first magnetic coil outputs singular pulses of magnetic energy to localize a plurality of optimal stimulation sites. The second magnetic coil outputs repetitive pulses of magnetic energy to each of the plurality of optimal stimulation sites in order to treat medical problems. The neurophysiological recorder displays motor-evoked potential (MEP) data that is detected by the anorectal probe and the skin electrode through electromyographic sensors.

A system and method which performs translumbosacral neuromodulation therapy in a subject by outputting pulses of magnetic energy onto the lumbar and sacral nerves of the subject is described. The system includes a control unit, an anorectal probe, at least one skin electrode, a first magnetic coil, a second magnetic coil, and a neurophysiological recorder. The control unit manages the system components. The anorectal probe and the skin electrode detect muscle activity when a nerve from the back of the subject is stimulated. The first magnetic coil outputs singular pulses of magnetic energy to localize a plurality of optimal stimulation sites. The second magnetic coil outputs repetitive pulses of magnetic energy to each of the plurality of optimal stimulation sites in order to treat medical problems. The neurophysiological recorder displays motor-evoked potential (MEP) data that is detected by the anorectal probe and the skin electrode through electromyographic sensors.

The present disclosure provides a microfluidic device and system for measuring a composite electropharyngeogram (EPG) signal from a pool of multiple nematodes, wherein the composite EPG signal is measured from the pool of nematodes present in a single recording channel connected to two or more integrated electrodes. The microfluidic device includes an inlet port and outlet port directly connected to a single recording channel and two or more electrodes directly connected to the recording channel. The recording channel is configured to hold 10 to 10,000 nematodes.