A tubing assembly for use with an electronic catheter guidance systems is provided and includes a catheter and a stimulation electrode assembly, and an electrical connection for delivering a stimulation waveform to the stimulation electrode assembly. The catheter extends in a longitudinal direction and has a proximal end and a distal end that define a lumen therebetween. Further, the catheter is configured for placement within a patient's digestive tract. The stimulation electrode assembly is configured to deliver an electrical stimulation to tissue. A catheter guidance system and method for accurately placing a catheter in the digestive tract are also provided.

The present specification discloses devices and methodologies for the treatment of transient lower esophageal sphincter relaxations (tLESRs). Individuals with tLESRs may be treated by implanting a stimulation device within the patient's lower esophageal sphincter and applying electrical stimulation to the patient's lower esophageal sphincter, in accordance with certain predefined protocols. The presently disclosed devices have a simplified design because they do not require sensing systems capable of sensing when a person is engaged in a wet swallow and have improved energy storage requirements.

A medical device, a method for preparation thereof, and use thereof are provided. The medical device comprises a thermoplastic elastomer that is composed of soft segments and hard segments. The method for preparing a medical device comprising a thermoplastic elastomer, comprises forming the thermoplastic elastomer into tubing or other shapes via extrusion, molding, or coating, assembling the tubing or other shapes with other parts including: cables, coils, coated cables, or coated coils, and bonding the tubing, cables, or coils with other components including: other tubing components, cables, coils, sleeves, electrical pulse generator, defibrillation shock generator, electrodes, sensors, or drug release components. The medical device is used for correcting cardiac rhythm, defibrillating, assisting hearts, sensing, stimulating neurological systems, gastrointestinal system, or skeletomuscular tissues or organs.

A process of treatment of internal organ oedema is using an electric current delivering electrode system comprising electrodes to be positioned at two places on the outer surface of the internal organ and/or in a liquid carrying vessel of the internal organ and delivering electric current to induce electro-osmosis between the electrodes. An electrode assembly system for this treatment by electro-osmosis includes, in addition to the two electrodes, a control unit adapted to control the current flow between the two electrodes.

A system for performing a diagnostic or therapeutic procedure within a subject includes a device having a distal portion configured for insertion within a lumen or duct of the subject, the device including an elongate body having a longitudinal axis, the elongate body comprising a polymeric material and having a proximal end and a distal end, one or more electrically-conductive tracings carried on a first surface of the elongate body and configured to carry a signal, and one or more conductors embedded within the polymeric material and configured to carry a signal.

A wireless implantable neuromuscular stimulator includes an antenna for producing an induced current in response to being disposed in an electromagnetic field. The antenna includes a substrate having an upper surface and a lower surface. An upper coil including a plurality of coil turns is disposed on the upper surface of the substrate. A lower coil including a plurality of coil turns is disposed on the lower surface of the substrate. The upper and lower coils are electrically connected to each other in parallel. The parallel connection can be facilitated by a plurality of connectors that extend through the substrate and electrically connect the upper coil to the lower coil. In one example configuration, connectors connect each coil turn of the upper coil to a corresponding turn of the lower coil.

A system is provided herein for stimulating an anatomical element of a patient. For example, the system may include a device (e.g., an implantable pulse generator) and an electrode device electrically coupled to the device. In some examples, the device may be configured to generate a current that is to be applied to the anatomical element via the electrode device to stimulate the anatomical element as part of a therapy aimed at achieving or supporting glycemic control in the patient. Additionally, the current may be applied to the anatomical element based on a machine learning algorithm that uses inputs gathered for determining one or more characteristics for the current. Accordingly, the machine learning algorithm may be configured to determine the one or more characteristics for the current specific to the patient (e.g., to provide personalized therapy settings for the patient).

Systems and methods for mechanically blocking a nerve are provided. The system may comprise a blocking device configured to selectively compress the nerve. The system may also comprise a feedback mechanism configured to measure a response correlating to whether the nerve is blocked. When the blocking device compresses the nerve, a response from the feedback mechanism is received that correlates to the nerve being blocked or unblocked after a period of time.

System and methods for stimulating or blocking a nerve are provided. The system may include an implantable pulse generator configured to generate a current and an electrode device in communication with the implantable pulse generator and configured to surround the nerve. The electrode device may include a housing comprising an inner surface, a first edge, and a second edge opposite the first edge; at least one electrode disposed on the inner surface and configured to apply the current to the nerve; and at least one closure configured to couple the first edge to the second edge to form a seal.

A system is provided herein for stimulating an anatomical element of a patient. For example, a device may be configured to generate a current, and an electrode device coupled to the device may be configured to apply the current to the anatomical element. Additionally, the system may include a user interface in communication with the implantable pulse generator, the electrode device, or both. In some examples, the user interface may include a first element that is configured to display information associated with the patient. Additionally, the user interface may include a second element that is configured to receive inputs for programming parameters of the current. The user interface may also include a third element that is configured to display diagnostic information associated with applying the current to the anatomical element.