Abstract: Devices and methods for treating patients suffering from an eating disorder, such as obesity and/or pathologies resulting in obesity, by regulating sensations affecting food consumption. The devices and methods may facilitate appropriate caloric intake, thereby inducing weight loss, by simulating, stimulating, amplifying, blocking and/or modulating signals in the gastrointestinal (GI) tract and/or nerves innervating the GI tract, to manage sensations of hunger and satiety, such as controlling hunger by signaling the gastrointestinal tract and/or gastrointestinal nerves when different hunger sensations are detected.

Abstract: Apparatus, systems and methods for stimulation of a vagus nerve of a patient are disclosed. An element that can be deployed and retained inside the patient's stomach without surgery and having a power supply and electrodes is associated with the expandable element. The electrodes are capable of stimulating the vagus nerve while the expandable element remains in the stomach for an extended period of time.

Abstract: Systems and methods are disclosed to stimulate gastrointestinal tissue to treat medical conditions such as eating disorders, gastroparesis, and gastric reflux. The invention uses electrical stimulation of the nerve, where vibrational energy from a source is received by an implanted device and converted to electrical energy and the converted electrical energy is used by implanted electrodes to stimulate the pre-determined gastrointestinal tissue site. The vibrational energy is generated by a controller-transmitter, which could be implanted or located externally. The vibrational energy is received by a receiver-stimulator, which could be located in the various regions on or around the gastrointestinal tissue that needs to be stimulated. The implantable receiver-stimulator stimulates different gastrointestinal tissue to provide the desired therapeutic benefit.

Abstract: A method and apparatus for treatment of an eating disorder includes electrically, mechanically and/or pharmaceutically/chemically stimulating a of the vagus nerve of the lower esophagus, cardia, esophageal/cardia junction, cardia/fundus junction or upper stomach so as to induce afferent action potentials on the vagus nerve. The device may be noninvasively adjusted after implantation to provide increased or decreased restriction on the patient's gastrointestinal tract. Each stimulus may be administered as a series of programmed pulses of defined amplitude, duration and period, to evoke a responsive signal to the brain by the target nerve, effective for producing a temporary feeling of satiety in the person. An implantable stimulus generator may be operatively coupled to a nerve electrode, pressure device or chemical outlet to apply a defined signal to a selected nerve branch.

Abstract: An implantable gastrointestinal (GI) stimulation system includes an implantable medical device and at least one stimulus delivery device configured to be placed in one or more lymphatic vessels of a patient, such as the patient's thoracic duct and/or vessels branching from the thoracic duct. In one embodiment, the implantable medical device includes a GI stimulation circuit to deliver electrical stimulation pulses to one or more target regions adjacent to a lymphatic vessel through the stimulus delivery device. In one embodiment, to control obesity, the electrical stimulation pulses are delivered to the organs and/or nerves of the GI tract to create a sensation of satiety and/or to expedite food movement through the GI tract.

Abstract: A method of treating patients for compulsive overeating includes stimulating left and right branches of the patient's vagus nerve simultaneously with electrical pulses in a predetermined sequence of a first period in which pulses are applied continuously, alternating with a second period in which no pulses are applied. The electrical pulses are preferably applied to the vagus nerve at a supradiaphragmatic location.

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: A method for altering operation of a nerve related to a given body condition includes the steps of identifying at least one nerve root of a nerve related to the given body condition; laparoscopically implanting at least one electrode on the nerve root; and operating the electrode to electrostimulate the nerve root and alter operation of the nerve.

Abstract: Disclosed are methods and apparatus for implantation into the walls of an organ such as the stomach. Deformable or inflatable anchors with a connector between are used to pull the walls of the organ together, or to implant devices in the wall of the organ. Also disclosed are surgical instruments useful in practicing the disclosed methods.

Abstract: The present invention relates to treatment of visceral pain of gastrointestinal origin, functional bowel disorders and irritable bowel syndrome comprising electrical stimulation of the spinal cord using one or more commercially available and implantable spinal cord stimulation leads for a time period sufficient to suppress or extinguish the pain or symptoms associated with visceral pain of gastrointestinal origin, functional bowel disorders or irritable bowel syndrome.

Abstract: Improved assemblies, systems, and methods provide an implantable pulse generator for prosthetic or therapeutic stimulation of muscles, nerves, or central nervous system tissue, or any combination. The implantable pulse generator is sized and configured to be implanted subcutaneous a tissue region. The implantable pulse generator includes an electrically conductive case of a laser welded titanium material. Control circuitry is located within the case, the control circuitry including a rechargeable power source, a receive coil for receiving an RF magnetic field to recharge the power source, and a microcontroller for control of the implantable pulse generator. Improved assemblies, systems, and methods also provide a stimulation system for prosthetic or therapeutic stimulation of muscles, nerves, or central nervous system tissue, or any combination.

Abstract: A method of promoting the healing of a lesion in a smooth muscle, comprising selecting a smooth muscle portion having a lesion and applying a non-excitatory electrical field to the portion, which field reduces the mechanical activity of the portion.

Abstract: A method for the treatment of eating and gastrointestinal disorders through transcutaneous electrical nerve stimulation of the sympathetic celiac ganglia and nerve pathways innervating the stomach.

Abstract: A method and system for providing electrical pulses for neuromodulating sacral nerves of a patient utilizing an implantable stimulator. The implantable stimulator comprising a pulse generator module and a stimulus receiver module for coupling with an external stimulator. Control circuitry ensures selective operation of one pulse generator module. The external stimulator comprises a telemetry module for remotely activating (or de-activating) programs over the internet, to arrive at the optimal program for each patient. Once the optimal “dose” is titrated using the external stimulator, the implanted pulse generator can then be programmed to such parameters. The external stimulator in conjunction with the implanted stimulus receiver can override the implanted pulse generator, to provide extra dose of therapy or to conserve the implanted battery. The external stimulator is also networked to other computers.

Abstract: In general, an implantable medical device is disclosed for generating and applying an electric stimulation signal to a portion of a patient's gastrointestinal tract to induce symptoms of gastroparesis in the patient without substantially reducing normal stomach motility. The induced symptoms of gastroparesis may reduce a patient's desire to consume large portions of food and thus provide an effective treatment for obesity.

Abstract: A method of using a small implantable stimulator(s) with at least two electrodes small enough to have the electrodes located adjacent to the vagus nerve. The small stimulator provides a means of stimulating the vagus nerve when desired, and may be implanted via a minimal surgical procedure.

Abstract: At least one of a plurality of disorders of a patient characterized at least in part by vagal activity innervating at least one of a plurality of organs of the patient is treated by a method that includes positioning a neurostimulator carrier around a body organ of the patient where the organ is innervated by at least a vagal trunk. An electrode is disposed on the carrier and positioned at the vagal trunk. An electrical signal is applied to the electrode to modulate vagal activity by an amount selected to treat the disorder. The signal may be a blocking or a stimulation signal.

Abstract: Alpha rhythm brain waves are related to mental and physical relaxation and healing. Based on the studies of bionics, this invention relates to inducing oscillatory alpha rhythm to the human body, and relates to the means of the alpha rhythm machine applied to human body. Research of the alpha rhythm of human brain wave patterns and EEG has indicated special recorded data of alpha rhythm brain waveform which is the bearing of the proper biological information of relaxing and healing. The apparatus was developed and built to construct and release the simulated human brain alpha rhythm signals which are at the frequencies ranging 8 Hz–14 Hz and at the amplitudes altered in high or low. Both the frequencies and the amplitudes are changing at a non-stationary random order in the duration of the event, respectively.

Abstract: A muscle stimulation device has a control unit (1) that determines frequency and/or intensity of electrical impulses in dependence upon the degree of stomach filling. The impulses function to stimulate lower esophageal sphincter (11) by means of stimulating electrodes (5a, 5b, 5c) disposed radially around the sphincter (11). A computer program, executable by means of a microprocessor (10), is installed in the control unit, the program designed such that a higher stomach filling degree causes a stronger stimulation of the sphincter (11) or its substitute. The sphincter reacts to the stimulation by exerting a corresponding pressure onto a lower esophagus area (12). An increased risk of gastric reflux as a consequence of the patient's substantial food ingestion is countered by an increased stimulation of the sphincter, which in turn causes an elevated closing pressure at the lower esophagus (12).

Abstract: A multi-purpose, functional electrical stimulation (FES) system 10 includes an implantable stimulator unit 12 for stimulating a plurality of different sites in a patient's body 14. A transmitter 20 is arranged externally of the patient's body 14 for supplying signals transcutaneously to the stimulator unit 12. A controller 16 is in communication with the transmitter 20. At least one implantable switching node 26 has an input terminal 30 in electrical communication with the stimulator unit 12 and a plurality of output terminals to each of which one of a further switching node 26 and a stimulating element 24 is connected. The switching node 26 including addressing circuitry 44 for switching at least one output terminal into electrical connection with the input terminal 30 of the switching node 26 in response to a control signal received from the controller 16 via the stimulator unit 12.

Abstract: The device and method for placement of an instrument, specifically electrodes, in the GI tract allows for placement of electrodes for gastric electrical stimulation into the gastric wall using endoscopic techniques. The device has one or more electrodes disposed on an elongated body having a pointed first end and a bolster disposed on a second end. When placed within the GI tract, the first end of the device extends through the gastric and abdominal walls, extending outside of the patient's body with the bolster in contact against the inner lining of the gastric wall to retain the device. Exposed electrodes contact the gastric smooth muscle. Insulated wires in electrical connection with-the electrodes run the length of the device body. Once the device is placed, the first end of the device body is removed to expose the wires, allowing electrical connection to an external electrical signal generator to provide electrical stimulus.

Abstract: A device, system and method for diagnosing and treating gastric disorders is provided. A functional device resides within the patient's stomach and is secured to the stomach wall by an attachment device. The functional device may be a sensor for sensing various parameters of the stomach or stomach environment, or may be a therapeutic delivery device. The functional device in one embodiment provides a device, system and method for gastric electrical stimulation where stimulating electrodes are secured to the wall of the stomach by the attachment device or otherwise. A preferred device includes: at least one stimulating electrode in electrical contact with the stomach wall; an electronics unit containing the electronic circuitry of the device; and an attachment mechanism for attaching the device to the stomach wall. The functional devices may be programmed to respond to sensed information or signals.

Abstract: A device, system and method for diagnosing and treating gastric disorders is provided. A functional device resides within the patient's stomach and is secured to the stomach wall by an attachment device. The functional device may be a sensor for sensing various parameters of the stomach or stomach environment, or may be a therapeutic delivery device. The functional device in one embodiment provides a device, system and method for gastric electrical stimulation where stimulating electrodes are secured to the wall of the stomach by the attachment device or otherwise. A preferred device includes: at least one stimulating electrode in electrical contact with the stomach wall; an electronics unit containing the electronic circuitry of the device; and an attachment mechanism for attaching the device to the stomach wall. The functional devices may be programmed to respond to sensed information or signals.

Abstract: A gastroelectric stimulator comprises a neurostimulator for producing a stimulation signal, at least one electrical lead, and at least two electrical contacts. The electrical lead has a proximal end and a distal end, the proximal end being connected to the neurostimulator and the distal end positionable in a lead position within the patient's abdomen. The electrodes are carried near the electrical lead distal end. The electrodes are electrically connected through the electrical lead to the neurostimulator to receive the stimulation signal and convey this signal to an electrode position within the patient's digestive system. The stimulation signal is adapted to influence pancreatic secretions.

Abstract: A device, system and method for diagnosing and treating gastric disorders is provided. A functional device resides within the patient's stomach and is secured to the stomach wall by an attachment device. The functional device may be a sensor for sensing various parameters of the stomach or stomach environment, or may be a therapeutic delivery device. The functional device in one embodiment provides a device, system and method for gastric electrical stimulation where stimulating electrodes are secured to the wall of the stomach by the attachment device or otherwise. A preferred device includes: at least one stimulating electrode in electrical contact with the stomach wall; an electronics unit containing the electronic circuitry of the device; and an attachment mechanism for attaching the device to the stomach wall. The functional devices may be programmed to respond to sensed information or signals.

Abstract: A method and device for endocrine and exocrine gland control. The method comprises selecting neuro-electrical coded signals from a storage area that are representative of body organ function. The selected neuro-electrical coded signals are then transmitted to a treatment member, which is in direct contact with the body, and which then broadcasts the neuro-electrical coded signals to a specific endocrine and exocrine gland nerve or gland to modulate the gland functioning. A control module is provided for transmission to the treatment member. The control module contains the neuro-electrical coded signals which are selected and transmitted to the treatment member, and computer storage can be provided for greater storage capacity and manipulation of the neuro-electrical coded signals.

Abstract: A fixation device for holding stimulating electrodes in electrical contact with the wall of a portion of the gastrointestinal tract is provided. In one embodiment, the fixation device includes an expandable member that fixes the electrodes in electrical contact with the gastrointestinal tract wall. Also provided is an implantable device and method for controlling the opening and/or closing of the pylorus. In particular a device and method is provided for stimulating the duodenum to control the closing/and or opening of the pylorus. Finally, a method is provided for treating obesity by controlling the pylorus to retain food in the stomach for a desired period of time, among other things to provide a feeling of satiety and/or to reduce hunger. One aspect includes controlling the pylorus's contraction by electrical stimulation of the duodenum.

Abstract: An implantable stimulator(s), small enough to be located near or adjacent to an autonomic nerve(s) innervating urinary and/or gastrointestinal structures, uses a power source/storage device, such as a rechargeable battery. Periodic recharging of such a power source/storage device is accomplished, for example, by inductive coupling with an external appliance. The small stimulator provides a means of stimulating a nerve(s) or other tissue when desired, without the need for external appliances during the stimulation session. When necessary, external appliances are used for the transmission of data to and/or from the stimulator(s) and for the transmission of power, if necessary. In a preferred embodiment, the system is capable of open- and closed-loop operation. In closed-loop operation, at least one implant includes at least one sensor, and the sensed condition is used to adjust stimulation parameters.

Abstract: Methods and systems for treating patients suffering from eating disorders, e.g. obesity, through the dispensation of a drug by an implantable infusion pump (IIP) delivering drug into the cerebral spinal fluid (CSF) at a site of the intrathecal space in amounts and at times effective to suppress the patient's appetite through interaction of the drug transported through the CSF with receptors in the brain. Delivery of a programmed drug dosage is preferably by one of time-out of programmed time(s) of day, a command received from the patient, or a trigger signal developed from a sensed GI tract signal accompanying peristalsis.

Abstract: A microstimulator or neural prosthesis is powered and operative in response to an externally applied RF signal which includes a power component and control component. A slow rise time storage circuit stores RF power during a charging period and a fast rise time triggering circuit responsive to a fast rise time input triggers the device for producing output pulses following a selected delay time. The duration of the delay controls the current level of the output pulses.

Abstract: A non-invasive percutaneously acting apparatus for relieving constipation or diarrhea and appropriately stimulating peristaltic movement in the human gastro-intestinal (GI) tract. The apparatus includes an annular or toroidal shaped hollow housing having a working surface on one side thereof. A multi-point electrode generally coextensive with the working surface includes a plurality of point electrodes each separately mounted in and preferably biasingly moveably extend outwardly from the working surface. A d.c. pulse generator selectively and sequentially connectable to the point electrodes whereby, when the working surface is positioned against or in close proximity to the skin over the GI tract, the point electrodes deliver electrical pulses percutaneously and sequentially moving from one point electrode to the next adjacent point electrode repeatedly around the working surface.

Abstract: A device, system and method for diagnosing and treating gastric disorders is provided. A functional device resides within the patient's stomach and is secured to the stomach wall by an attachment device. The functional device may be a sensor for sensing various parameters of the stomach or stomach environment, or may be a therapeutic delivery device. The functional device in one embodiment provides a device, system and method for gastric electrical stimulation where stimulating electrodes are secured to the wall of the stomach by the attachment device or otherwise. A preferred device includes: at least one stimulating electrode in electrical contact with the stomach wall; an electronics unit containing the electronic circuitry of the device; and an attachment mechanism for attaching the device to the stomach wall. The functional devices may be programmed to respond to sensed information or signals.

Abstract: A pancreatic controller (102), comprising: a glucose sensor (118), for sensing a level of glucose or insulin in a body serum; at least one electrode (110, 112), for electrifying an insulin producing cell or group of cells; a power source (104) for electrifying said electrode with a pulse that does not initiate an action potential in said cell and has an effect of increasing insulin secretion; and a controller (106) which receives the sensed level and controls said power source to electrify said electrode to have a desired effect on said level.

Abstract: Apparatus is provided for treating a condition such as obesity. The apparatus includes a set of one or more electrodes, which are adapted to be applied to one or more respective sites in a vicinity of a body of a stomach of a patient. A control unit is adapted to drive the electrode set to apply to the body of the stomach a signal, configured such that application thereof increases a level of contraction of muscle tissue of the body of the stomach, and decreases a cross-sectional area of a portion of the body of the stomach for a substantially continuous period greater than about 3 seconds.

Abstract: A method and system for selective inhibition of somatic nerve fibers in a mixed nerve containing both somatic and autonomic nerve fibers where the method finds use in treatment of chronic pain, spastic muscles and for sensory and motor control of a bladder. The methods and systems utilize alternate phase rectangular electrical pulses. An electrical pulse generator is coupled to a nerve. An alternate phase high frequency, low amplitude pulse is first applied to selectively inhibit somatic nerves when present in a mixed nerve. An alternate phase low frequency, high amplitude phase pulse subsequently supplied to stimulate the autonomic nerve fibers and in the case of the sacral root will permit a controlled voiding of the bladder and bowel.

Abstract: Active fixation, gastrointestinal leads adapted to be implanted within the body at a site of the GI tract to conduct electrical stimulation from an implantable or external gastrointestinal stimulator to the site and to conduct electrical signals of the GI tract from the site to the implantable or external gastrointestinal stimulator are disclosed. Disclosed active fixation mechanisms include one or more of hooks, and helixes extending from stops, e.g. plates, of an electrode head and functioning as stimulation/sense electrodes in unipolar and bipolar configurations or simply as fixation mechanisms. The active fixation mechanisms are coated to reduce inflammation and polarization effects.

Abstract: A device for, and method of restoring kidney function, the method including the steps of: (a) providing a device including: (i) a conducting coil, and (ii) a signal generator, operatively connected to a power supply, for providing a plurality of electrical impulses to the coil; (b) disposing the conducting coil proximate to a kidney of a patient, and (c) delivering the electrical impulses conducting to the conducting coil, so as to produce an electromagnetic field, the electromagnetic field acting so as to stimulate the kidney and at least partially restore kidney function.

Abstract: Apparatus and method for independently delivering a plurality of therapy programs in an implantable medical device. A therapy controller configures the device to generate independent pulse trains associated with a plurality of therapy programs and dynamically configures the electrodes to deliver the independent pulse trains to the patient. Once configured, the implantable medical device delivers the plurality of therapy programs to the patient wherein the therapy programs may overlap in time.

Abstract: An intestine dysfunction treatment apparatus comprises an electric stimulation device (56) implanted in a patient, who suffers from intestine dysfunction. The stimulation device comprises electric conductors adapted to directly engage with a muscle that directly or indirectly affects the transportation of the content of the patient's intestines, for example the anal sphincter (58) or a portion of the muscle that contracts the bowels, to electrically stimulate the muscle to increase the tonus thereof. A control device (62) is provided for controlling a source of energy (64), which may or may not be implanted, to release electric energy for use in connection with the power of the stimulation device. The apparatus can be used for treating patients suffering from anal incontinence or constipation.

Abstract: Systems and methods selectively stimulate components of the pudendal nerve away from the sacral root to evoke desired physiologic responses in persons who lack the ability to otherwise produce these responses—e.g., maintain continence and/or produce micturition, and/or provide male/female sexuality responses, and/or provide bowel responses. The systems and methods use a multiple electrode array, or individual electrodes, placed on, in, or near the pudendal nerve. The electrode array, or individual electrodes, in association with a pulse generator, provide selective stimulation of individual fascicles within the pudendal nerve, to achieve different physiologic responses.

Abstract: A method and apparatus for electrical stimulation of the lower esophageal sphincter (LES) is provided. Electrode sets are placed in the esophagus in an arrangement that induce contractions of the LES by electrical stimulation of the surrounding tissue and nerves. The electrical stimulus is applied by a pulse generator for periods of varying duration and varying frequency so as to produce the desired contractions. The treatment may be short-term or may continue throughout the life of the patient in order to achieve the desired therapeutic effect. The stimulating electrode sets can be used either alone or in conjunction with electrodes that sense esophageal peristalsis. The electrode sets can be placed endoscopically, surgically or radiologically.

Abstract: Many patients suffer from diseases and surgical damage that result in failure of the stomach and intestinal tract to contract and relax normally in order to transfer contents distally. Electrical stimulation applied to one or more sites on the surface of the gastrointestinal viscera can treat this problem by triggering or altering muscle contractility. The present invention provides such stimulation by implanting leadless microstimulators in or on the walls of the viscera that can be programmed or controlled from a source outside the body.

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 gastroelectric stimulator comprises a neurostimulator for producing a stimulation signal, at least one electrical lead, and at least two electrical contacts. The electrical lead has a proximal end and a distal end, the proximal end being connected to the neurostimulator and the distal end positionable in a lead position within the patient's abdomen. The electrodes are carried near the electrical lead distal end. The electrodes are electrically connected through the electrical lead to the neurostimulator to receive the stimulation signal and convey this signal to an electrode position within the patient's digestive system. The stimulation signal is adapted to influence pancreatic secretions.

Abstract: A method to control an overactive bladder and to estimate bladder volume using an implanted sensor having at least one nerve electrode to sense electrical signals. The method includes detecting events from nerve signals, generating electrical pulses for stimulating nerves, and stimulating the nerves to inhibit detrusor contraction. Bladder volume may also be estimated based on the amplitude of the detected nerve signals and/or the time between two detected nerve signals from consecutive detrusor contractions.

Abstract: Systems and methods for introducing one or more stimulating drugs and/or applying electrical stimulation to the pancreas and/or nerve fibers innervating the pancreas to treat or prevent diabetes and/or to modulate pancreatic endocrine secretions uses at least one system control unit (SCU) producing electrical pulses delivered via electrodes and/or producing drug infusion pulses, wherein the stimulating drug(s) are delivered via one or more pumps and infusion outlets.

Abstract: A method of glucose level control comprising, providing at least one electrode adapted to apply an electric field to a pancreas; and applying an electric field to the pancreas using said at least one electrode such that blood glucose levels are significantly reduced and blood insulin levels are not significantly increased compared to a regular insulin response in a same person.

Abstract: A device, system and method for diagnosing and treating gastric disorders is provided. A functional device resides within the patient?s stomach and is secured to the stomach wall by an attachment device. The functional device may be a sensor for sensing various parameters of the stomach or stomach environment, or may be a therapeutic delivery device. The functional device in one embodiment provides a device, system and method for gastric electrical stimulation where stimulating electrodes are secured to the wall of the stomach by the attachment device or otherwise. A preferred device includes: at least one stimulating electrode in electrical contact with the stomach wall; an electronics unit containing the electronic circuitry of the device; and an attachment mechanism for attaching the device to the stomach wall. The functional devices may be programmed to respond to sensed information or signals.

Abstract: The present invention is directed to a method of regulating gastrointestinal action in a subject using a stimulatory electrode and a sensor to provide retrograde feedback control of electrical stimulation to the GI tract. The invention is further directed to a method for reducing weight in a subject, again using a stimulatory electrode and a sensor to provide retrograde feedback control of electrical stimulation to the stomach. The invention is further directed to a method of providing electrical field stimulation to a gastrointestinal organ, as well as a method of providing an electrical potential gradient in a gastrointestinal organ. Further provided is a method of stimulating the vagus nerve of a subject. Additionally provided is a method of placing a device in the gastrointestinal tract or wall of a subject from the exterior of the subject, using a needle to insert the device.