An intragastric device including (1) a first wire mesh structure having a pre-deployment shape, a post-deployment shape greater than the pre-deployment state, and one or more openings on an upper portion of the first wire mesh structure that are configured to permit food to enter the device, (2) a second wire mesh structure having a pre-deployment shape a post-deployment shape greater than the pre-deployment state, and one or more openings on a lower portion of the second wire mesh structure that are configured to permit food to exit the device. A sleeve may be coupled to the lower portion of the wire mesh structure. An anti-migration collar may interconnect the wire mesh structure and the sleeve. In use, food enters the upper portion of the first wire mesh structure, passes through both wire mesh structures, and then exits the lower portion of the second wire mesh structure.

An apparatus for treating obesity of a patient having a stomach with a food cavity. The apparatus comprising a volume filling device adapted to be at least substantially invaginated by a stomach wall portion of the patient with the outer surface of the volume filling device resting against the stomach wall, such that the volume of the food cavity is reduced in size by a volume substantially exceeding the volume of the volume filling device. The apparatus further comprises at least one adjustable stretching device adapted to be at least substantially invaginated by a stomach wall portion of the patient with the outer surface of the stretching device resting against the stomach wall and adapted to stretch a portion of stomach wall, and a fluid connection device interconnecting the volume filling device and the stretching device.

Devices and systems to fit around a tissue or organ and methods of using the same. In at least one embodiment of an implantable device of the present disclosure, the implantable device comprises a first engaging component comprising a first rigid inner plate at least partially surrounded by a first flexible coating, a second engaging component comprising a second rigid inner plate at least partially surrounded by a coating selected from the group consisting of the first flexible coating and the second flexible coating, a first c-ring and a second c-ring coupled to the engaging components, and a cover flap coupled to either the first engaging component or the second engaging component and capable of either further coupling to the second engaging component when initially coupled to the first engaging component or further coupling to the first engaging component when initially coupled to the second engaging component.

Methods and systems for regulating nerve activity and/or treating conditions associated with disorder of blood glucose are disclosed. A method of downregulating activity by applying a high frequency alternating current electrical signal to a nerve in a subject is disclosed. A method of upregulating activity by applying a low frequency stimulation signal to a nerve in a subject is disclosed. A method of regulating nerve activity by applying a high frequency signal to a first nerve/organ and applying a low frequency stimulation signal to a second nerve/organ is disclosed. The application of the high frequency signal and the low frequency stimulation signal to separate nerves or nerve branches/fibers can be independent, simultaneous, concurrent, or in a coordinated fashion in therapy programs. Various signal parameters including the waveform, frequency, amplitude, active/inactive phases are described.

An operable implant adapted to be implanted in the body of a patient, the operable implant comprising an operation device and a body engaging portion, wherein the operation device comprises a first unit comprising a receiving unit for receiving wireless energy and a first gear system adapted to receive mechanical work having a first force and first velocity, and output mechanical work having a different second force and a different second velocity. The operation device further comprises a second unit comprising an electrical motor adapted to transform electrical energy to the mechanical work, and a distance element adapted to separate the first and second units such that the receiving unit, when receiving wireless energy, is not substantially affected by the second unit.

The present invention is directed toward an intragastric device used to treat obesity that includes a wire mesh structure capable of changing from a compressed pre-deployment shape to an expanded post-deployment shape with a greatly increased volume. The post-deployment shape contains a light weight at the top and a heavier weight at the bottom to ensure proper positioning within the stomach. In the post-deployment shape, the device contains larger spaces in the upper portion and smaller spaces in the lower portion to sequester food and delay gastric emptying. Alternatively, the device can be enveloped by a membrane containing larger holes at the top and smaller holes at the bottom to sequester food and delay gastric emptying. The device has a dynamic weight where the weight of the device in the pre-feeding stage is less than the weight of the device in feeding or post-feeding stage.

A surgical anchor device for being anchored on the mucous membrane of the inner wall of the intestine, the device having a temporary anchor element presenting anchoring that can be modified in a controlled manner and having a first substantially cylindrical multiply-perforated wall presenting properties of radial elasticity whereby the first wall presents an outer diameter that can be varied in controlled manner, wherein a portion of the inner surface of the first wall is lined with an independent leakproof inner sheath having only its longitudinal ends fastened to the anchor element to define a suction chamber between the inner sheath and the first wall, the temporary anchor element being coupled to a flexible or semi-rigid tube extending outside the anchor element, an open end of the injection-suction tube opening out into the suction chamber enabling air to be injected into or sucked out from the suction chamber.

“An artificial stomach for replacing the normal stomach of a patient comprises a food reservoir adapted to collect food, an inlet connected to a first opening of the food reservoir and further being adapted to upstream connect to the patient's gastrointestinal tract, and an outlet connected to a second opening of the food reservoir and further being adapted to downstream connect to the patient's gastrointestinal tract”.

An volume filling device for treatment of obesity is placed outside the stomach wall of the patient to reduce the inner volume of the stomach, thereby affecting the patient's appetite. By providing the volume filling device outside the stomach wall, contact with stomach acids is avoided, thereby increasing the life of the device.

An intragastric device including (1) a first wire mesh structure having a pre-deployment shape, a post-deployment shape greater than the pre-deployment state, and one or more openings on an upper portion of the first wire mesh structure that are configured to permit food to enter the device, (2) a second wire mesh structure having a pre-deployment shape a post-deployment shape greater than the pre-deployment state, and one or more openings on a lower portion of the second wire mesh structure that are configured to permit food to exit the device. A sleeve may be coupled to the lower portion of the wire mesh structure. An anti-migration collar may interconnect the wire mesh structure and the sleeve. In use, food enters the upper portion of the first wire mesh structure, passes through both wire mesh structures, and then exits the lower portion of the second wire mesh structure.