An artificial urinary sphincter (AUS) system includes a cuff, a pump, and a single tube that provides the system with an inflatable storage compartment. The single tube is connected between the cuff and the pump and includes a first lumen communicating between the cuff and the pump and a separate second lumen communicating between the cuff and the pump. The cuff is inflatable with a cuff volume of liquid that is sized to selectively close the urethra for treatment of urinary incontinence. The pump is operable to move the cuff volume of liquid out of the cuff to provide the cuff with a deflated state that allows the urethra to open and pass urine. The second lumen has a storage compartment sized to retain the cuff volume of liquid.

Described are methods and devices useful for supporting posterior vaginal tissue for various purposes such as treating or preventing vaginal prolapse or enterocele, especially in a patient not having a uterus, the devices including implants designed to contact the vaginal cuff and connect to sacral anatomy such as the sacrum or the uterosacral ligaments.

A medical device is provided including an artificial contractile structure which may be used to assist the functioning of a hollow organ. The medical device includes an artificial contractile structure including at least one contractile element configured to contract an organ, in such way that the contractile element is in a resting or in an activated position, at least one actuator configured to activate the contractile structure, and at least one source of energy to power the actuator. The medical device includes a corrosion reducing system configured to reduce corrosion of the medical device.

A control assembly for implantation in a patient comprises a first unit adapted for subcutaneous implantation at a first side of a body tissue of said patient, a second unit adapted for implantation in a body cavity of said patient at a second side of said body tissue, wherein at least one of the first and the second unit is adapted to control an implanted powered medical device, and an interconnecting device adapted for mechanical interconnection of the first and second units to keep the assembly in place by the body tissue, the interconnecting device having a cross-sectional area which is smaller than the cross-sectional area of the first unit and the second unit in a plane parallel to the extension of the body tissue.

An apparatus for treating a urinary retention of a patient by discharging urine from a mammal urinary bladder through a mammal urethra. The apparatus comprises an expandable member adapted to be implanted inside the urinary bladder of the patient, a control device adapted to control the volume of the expandable member for emptying the mammal urinary bladder, and an implantable restriction devices adapted to close each ureter of a patient when discharging urine from the urinary bladder.

The present invention relates to the application of medical devices that manage urinary incontinence. The inter-bladder/urethra implanted device allows for passive urine leakage above a threshold bladder pressure and subject-controlled opening and closing of a valve to allow urine passage, below the threshold bladder pressure. The valve is preferably a deformable sac which seals against the interior of the urethra when closed. The valve can be opened by withdrawing slightly from the urethra surface. Passive urine leakage to prevent over-pressure can be facilitated by including external channels on the valve sac. In another embodiment, the valve sac has a central passage which expands and contracts for opening and closing, respectively.

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.

A method is used for preparing a product for use in repairing a lesion or defect at a tissue site in a human or animal patient body. The method includes obtaining tissue from a donor human or animal body and freezing the obtained tissue. The method further includes pulverizing the frozen tissue and suspending the pulverized tissue in a fluid. The method further includes homogenizing the tissue suspension and precipitating tissue particles from the homogenized tissue suspension. The method further includes re-suspending the precipitated tissue particles and lyophilizing the tissue re-suspension to provide the product to be used in repairing the lesion or defect.

Devices and methods for treatment of bodily lumens and sphincters are disclosed. Some embodiments include methods and devices for inducing an inflammatory response and development of fibrosis, collagen, and/or scar tissue. In some embodiments, scaffolds may be composed of a matrix of filaments. Application of the methods and devices disclosed herein to treat Gastroesophageal Reflux Disease (GERD) and other sphincter disorders are discussed. Biodegradable scaffolds configured to induce an inflammatory response are also disclosed.

Pelvic implant having a frame with two arms and a sheet are disclosed. The sheet may be held under tension in the assembled implant. The implant may be planar (flat) or may be non-planar. The implant may be contoured laterally. A curved non-planar implant may be convex or concave in a rostro-caudal direction. The implants may (optionally) include two additional arms and a second sheet for supporting a urethra and/or a bladder neck. Methods for constructing and assembling the implants are disclosed. A method ultrasonically welding the frame of the implant without thermally damaging the sheet is disclosed. Methods of implantation of the implants are disclosed.