Abstract: Systems and methods are provided for modulating the autonomic nervous system by the electrical stimulation of the neuro-muscular system of a patient, and include an implantable electrical system for gastrointestinal stimulation which incorporates a heart rate sensor to indicate the neurovegetative patient condition, to initiate and terminate stimulation at specific locations, and an algorithm to automatically control electrical stimulation frequency, interval, amplitude, or a combination of such parameters for adaptive treatment of obesity, anorexia, other eating disorders, diseases related with the so called “metabolic syndrome” (e.g., impaired glucose tolerance and diabetes type 2, GERD, systemic hypertension, early arterovascular degeneration, early senility, and the like), and disorders related to a pathologic imbalance of the autonomic nervous system.

Abstract: An implantable lead device and method for implanting the lead, wherein the lead device electrically stimulates tissue within a patient's body and more particularly the lead device stimulates gastrointestinal tissue. The implantable lead may be inserted through the tissue with minimal expansion of the penetration tunnel and attached to the tissue being stimulated with minimal efforts or apparatus. The implantable lead has flexible properties thus minimizing the potential for electrode erosion, maximizing tissue compliance, and minimizing the mechanical stress concentration that may result in fatigue failure in the lead.

Abstract: Apparatus and method for stimulating neuromuscular tissue in the stomach. The neuromuscular stimulator stimulates the neuromuscular tissue by applying current-controlled electrical pulses. A voltage sensor detects the voltage across the neuromuscular tissue to determine if the voltage meets a predetermined voltage threshold. A control circuit adjusts the current-controlled pulse if the voltage is found to meet the voltage threshold, such that the voltage does not exceed the voltage threshold. A voltage-controlled pulse may also be applied to the tissue. A current sensor would then detect whether the current on the neuromuscular tissue meets a predetermined current threshold, and a control circuit adjusts the voltage-controlled pulse such that the current does not exceed the current threshold. A real time clock may be provided which supplies data corresponding to the time of day during the treatment period.

Abstract: An improved medical implant device is provided which has a plurality of micro-electrodes. The use of a plurality of micro-electrodes allows a clinically effective electrical stimulation pathway to be selected once the implant is positioned within or adjacent to the tissue to be treated even if the implant is not optimally placed or located. Thus, in cases where the implant is not optimally placed, it is not necessary to remove the implant and then reposition it within or adjacent to the tissue to be treated, thereby reducing stress to the patient caused by additional surgery. Moreover, using the micro-electrodes of this invention, directional electrostimulation can be provided to the tissue to be treated. Implant devices with a plurality of micro-electrodes are provided which are especially adapted for use in reducing the frequency and/or severity of neurological tremors.

Abstract: The anti-gastroesophageal reflux valvular prosthesis has a body presenting a seat of substantially semicircular shape engageable with the gastric wall of the stomach connected to the body through connectors and inflatable for the variation of this volume to accentuate the angle of His (cardiac incisure) and to improve the natural valvular anti-reflux system.

Abstract: Apparatus and method for stimulating neuromuscular tissue in the stomach. The neuromuscular stimulator stimulates the neuromuscular tissue by applying current-controlled electrical pulses. A voltage sensor detects the voltage across the neuromuscular tissue to determine if the voltage meets a predetermined voltage threshold. A control circuit adjusts the current-controlled pulse if the voltage is found to meet the voltage threshold, such that the voltage does not exceed the voltage threshold. A voltage-controlled pulse may also be applied to the tissue. A current sensor would then detect whether the current on the neuromuscular tissue meets a predetermined current threshold, and a control circuit adjusts the voltage controlled pulse such that the current does not exceed the current threshold. A real time clock may be provided which supplies data corresponding to the time of day during the treatment period.

Abstract: The device (1) for controlling the extent of intra-abdominal fat in the monitoring of an individual's slimming, comprises one electrical signal generator (2) connected to at least one first pole (3), associable to the stomach surface, and a second pole (4), associable to the abdominal wall. The poles (3,4) are connected to detection means (6) and means (7) for processing said electrical signals, adapted to provide a signal indicating the extent of intra-abdominal fat. The control procedure of the entity of the intra-abdominal fat in the monitoring of an individual's slimming, consists in detecting the impedance of the abdominal fat tissues, and hence, in calculating the extent of intra-abdominal fat is obtained.

Abstract: A sensor based gastric stimulator system and method for gastric stimulation of a patient employing an implantable gastric stimulator, which includes an information processor, an electrical stimulator circuit, and telemetry circuitry. The implantable stimulator senses intrinsic, gastric electrical activity (slow waves and/or peristaltic waves) and delivers electrical stimulation to intentionally disrupt or disorganize that activity. The stimulation is triggered by (tracks) normal gastric electrical activity and can be delivered with a spatial offset to anticipate the propagating gastric electrical activity or may be delayed temporally to anticipate the next propagating slow or peristaltic wave. The stimulator may be programmed to disrupt/disorganize all or a percentage of the intrinsic, normal gastric electrical activity. The programmer (via radio frequency data link) may non-invasively program stimulation parameters and intervals.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the neuromuscular tissue. The pulse generator is provided with a switching matrix, and may stimulate the tissue in a time-varying manner by selecting pairs of electrodes and altering the polarities thereof while stimulating the tissue. In addition, a real-time clock allowing a trigger for on and off modes, the time clock could also allow for a trigger to change parameters. Such parameters that could be changed are pulse width, amplitude, duty cycle (amount of time of pulse and time between pulses, or series of pulses), frequency, polarity, choice of unipolar versus bi-polar, and electrode on-off. The electrical stimulation utilizes a plurality of electrodes connected to at least one organ in the gastrointestinal tract of a patient along a peristaltic flow path with each of the electrodes being connected at a different location along the peristaltic flow path.

Abstract: An improved process using electrostimulation for treating obesity, especially morbid obesity, is provided. The improved method of this invention provides electrostimulation on or along the small intestines, preferably on or along the duodenum and/or jejunum, which provides improved control of obesity. In one embodiment, the process employs stimulation of the lesser curvature at a rate of about 2 to about 30 pulses/minute with each pulse lasting about 0.1 to about 4 seconds such that there is a pause of about 3 to about 30 seconds between the pulses. More preferably, the pulse rate is about 12 to about 14 pulses/minute with each pulse lasting about 0.1 to about 0.5 seconds with a pause of about 4.5 to about 5 seconds between pulses. Preferably, the pulse amplitude is about 0.5 to about 15 milliamps. More preferable, each pulse consists of a train of micro-bursts with a frequency of about 5 to about 100 Hz.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the neuromuscular tissue. The pulse generator is provided with a switching matrix, and may stimulate the tissue in a time-varying manner by selecting pairs of electrodes and altering the polarities thereof while stimulating the tissue. In addition, a real-time clock allowing a trigger for on and off modes, the time clock could also allow for a trigger to change parameters. Such parameters that could be changed are pulse width, amplitude, duty cycle (amount of time of pulse and time between pulses, or series of pulses), frequency, polarity, choice of unipolar versus bi-polar, and electrode on-off. The electrical stimulation utilizes a plurality of electrodes connected to at least one organ in the gastrointestinal tract of a patient along a peristaltic flow path with each of the electrodes being connected at a different location along the peristaltic flow path.

Abstract: A process for treating obesity and/or related motor disorders by providing electrostimulation to one or more anatomical sphincters along the length of the gastrointestinal tract is provided. The present process provides improved control of obesity and other syndromes related to motor disorders of the stomach and/or gastrointestinal tract. Preferably, the present method is used in combination with electrostimulation of the stomach (preferably along the lesser curvature), and even more preferably in combination with electrostimulation of the lower or distal end of the lesser curvature (i.e., towards the pylorus) of the stomach. The process comprises artificially altering, using sequential electrical pulses for preset periods of time, the natural gastric motility of the patient to slow food transit through the digestive system.

Abstract: An improved process using electrostimulation for treating obesity, especially morbid obesity, and other syndromes related to motor disorders of the stomach is provided. The improved method of this invention provides electrostimulation on the lesser curvature of the stomach, preferably on the lower or distal end of the lesser curvature, which provides improved control of obesity and other syndromes related to motor disorders of the stomach. In one embodiment, the process employs stimulation of the lesser curvature at a rate of about 2 to about 14 pulses/minute with each pulse lasting about 0.5 to about 4 seconds such that there is a pause of about 3 to about 30 between the pulses. Preferably, the pulse rate is about 12 pulses/minute with each pulse lasting about 2 seconds with a pause of about 3 seconds between pulses. Preferably, the pulse amplitude is about 0.5 to about 15 milliamps. More preferable, each pulse consists of a train of micro-bursts with a frequency of about 5 to about 100 sec−1.

Abstract: The present invention provides an apparatus and process which can stimulate a state of complete continence of the neosphincter in the preparation of continent neostomies. More specifically, the present invention provides an apparatus and process for the stimulation of a state of complete continence of the neosphincter in the preparation of continent neostomies, comprising an electrocatheter with an electrode inserted above the neostomy near, and in electrical contact with, transplanted muscle tissue (i.e., a strip of antral gastric musculature) which has been transplanted to the distal segment of the intestine or other organ where an ostomy has been created. The apparatus and process can restore the organic continence in a subject who has undergone therapeutic alteration of an indispensable segment of the visceral anatomy (i.e., the anus or the urinary bladder), thereby significantly improving quality of life.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the surface of the neuromuscular tissue. A pair of electrodes are supported by an electrode attachment member having a distal surface configured for attachment to the surface of the neuromuscular tissue. The electrodes are supported adjacent the distal surface to provide an interface between the electrodes and the surface of the neuromuscular tissue. The electrode attachment member may be flexible to pass through a laparoscopic surgical access opening in a compacted form and then returned to an uncompacted form for attachment to the surface of the neuromuscular tissue by the use of staples or sutures.

Abstract: An improved medical implant device is provided which has a plurality of micro-electrodes. The use of a plurality of micro-electrodes allows a clinically effective electrical stimulation pathway to be selected once the implant is positioned within or adjacent to the tissue to be treated even if the implant is not optimally placed or located. Thus, in cases where the implant is not optimally placed, it is not necessary to remove the implant and then reposition it within or adjacent to the tissue to be treated, thereby reducing stress to the patient caused by additional surgery. Moreover, using the micro-electrodes of this invention, directional electrostimulation can be provided to the tissue to be treated. Implant devices with a plurality of micro-electrodes are provided which are especially adapted for use in reducing the frequency and/or severity of neurological tremors.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the neuromuscular tissue. Four electrodes are supported by an electrode assembly for attachment to the neuromuscular tissue. The electrodes are oriented substantially equidistantly with respect to the tissue and provide an electrical interface with the neuromuscular tissue. The pulse generator is provided with a switching matrix, and may stimulate the tissue in a time-varying manner by selecting pairs of electrodes and altering the polarities thereof while stimulating the tissue.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the neuromuscular tissue. Four electrodes are supported by an electrode assembly for attachment to the neuromuscular tissue. The electrodes are oriented substantially equidistantly with respect to the tissue and provide an electrical interface with the neuromuscular tissue. The pulse generator is provided with a switching matrix, and may stimulate the tissue in a time-varying manner by selecting pairs of electrodes and altering the polarities thereof while stimulating the tissue.

Abstract: Apparatus for stimulating neuromuscular tissue of the gastrointestinal tract and methods for installing the apparatus to the neuromuscular tissue. The pulse generator is provided with a switching matrix, and may stimulate the tissue in a time-varying manner by selecting pairs of electrodes and altering the polarities thereof while stimulating the tissue. In addition, a real-time clock allowing a trigger for on and off modes, the time clock could also allow for a trigger to change parameters. Such parameters that could be changed are pulse width, amplitude, duty cycle (amount of time of pulse and time between pulses, or series of pulses), frequency, polarity, choice of unipolar versus bi-polar, and electrode on-off. The electrical stimulation utilizes a plurality of electrodes connected to at least one organ in the gastrointestinal tract of a patient along a peristaltic flow path with each of the electrodes being connected at a different location along the peristaltic flow path.

Abstract: This invention relates to an implant device which is designed and adapted use in laparoscopic surgery. This implant device is especially adapted for electrostimulation and/or electrical monitoring of endo-abdominal tissue or viscera. The implant device has an elongated body having on, or near, its distal end a flexible attachment member which can be folded back on to the elongated body and attached to the elongated body thereby forming a closed loop around the tissue of interest. By “looping” around or through the tissue of interest, the attachment member and the elongated body are securely attached to the tissue and will resisted displacement even in cases where the tissue is subject to vigorous, periodic peristaltic movement within the body (e.g., digestive organs).