The present invention discloses a biomechanically compatible implant, wherein arbitrary selectable discrete locations of the the implant are defined to exhibit biomechanical characteristics in accordance with biomechanical characteristics at arbitrary selectable discrete locations of a bodily tissue where the respective arbitrary selectable discrete locations of the implant are configured to be attached. The implant may be configured to repair prolapse in an embodiment. In another embodiment, the implant may be configured to repair urinary incontinence. The present invention further discloses a device for generating a biomechanical characteristics pattern of the bodily tissue and the implant. The present invention further discloses a system for designing and fabricating the biomechanically compatible implant.

The invention provides an implantable system for managing urinary incontinence. The system includes a sling with an elongate body member having a proximal portion, a distal portion and an intermediate portion. The intermediate portion is configured to be positioned underneath urethra of a subject for providing an adequate support to prevent leakage of urine during a stress event. The system may include a pressure sensor communicatively coupled with the elongated body member and configured to be positioned in an abdominal cavity and adapted to sense an increase in intra-abdominal pressure. The pressure sensor generates a first signal that is indicative of a change in the intra-abdominal pressure upon occurrence of the pressure event. The system includes a processing circuit to process the signal sensed by the pressure sensor. The processing circuit is configured to generate a second signal causing an adjustment of tensioning force in the elongate body member thereby changing magnitude of a supportive force to the urethra.

The disclosure relates generally to an extended use systems and devices for management of bladder function for people with urinary dysfunction. The system includes a catheter which can include a sensor that can determine bladder condition and a valve that can control fluid flow. The catheter can be placed inside the bladder using devices that facilitate insertion and extraction. The placement of the catheter can be done by a trained individual such as a patient, as well as a clinician, a nurse, or a caretaker. Once placed inside the bladder, the catheter can be fully-internal, meaning no portion of the catheter is visible from outside of the patient's body.

Everting balloon systems and methods for using the same are disclosed herein. The systems can be configured to access and dilate body lumen and cavities. For example, the systems can be used to dilate the cervix and access the uterine cavity. The systems can also be used to occlude the cervix. The systems can also be used to occlude the urethra.

An implant delivery system can be configured to deliver an inflatable implant into a bladder via a urethra. The delivery system can comprise an elongate tubular body, an inflation tube and an implant decoupler. The tubular body can comprise a central lumen configured to hold an inflatable implant in an initial un-inflated state for delivery of the implant into the bladder. A method of use can include passing a distal tip of the elongate tubular body into the bladder. The implant can be inflated and released into the bladder.

An inflated implant, such as an attenuation device, previously implanted in a urinary bladder can later be removed according to a number of different methods. Preferably, removal is accomplished transurethrally. In one embodiment, removal is accomplished by reducing the inflated implant from an enlarged profile to a reduced profile so that it may be withdrawn transurethrally by a removal system. The removal system can be configured differently depending upon whether reduction from the enlarged profile to the reduced profile is accomplished by deflation, compression, and/or other ways.

Everting balloon systems and methods for using the same are disclosed herein. The systems can be configured to access and dilate body lumen and cavities. For example, the systems can be used to dilate the cervix and access the uterine cavity. The systems can also be used to occlude the cervix. The systems can also be used to occlude the urethra.

Method and system for treating a patient using a compressible, pressure-attenuating device. According to one embodiment, the system is used to treat urinary tract disorders and can include one or more of an access device, a delivery device, a pressure-attenuating device, and a removal device. The access device may be used to create a passageway to an anatomical structure, such as the patient's bladder. The delivery device may be inserted through the passageway created by the access device and may be used to deliver the pressure-attenuating device to the anatomical structure. The removal device may be inserted through the passageway created by the access device and may be used to view the bladder and/or to capture, to deflate and to remove the pressure-attenuating device.

Method and system for treating a patient using a compressible, pressure-attenuating device. According to one embodiment, the system is used to treat urinary tract disorders and comprises an access device, a delivery device, a pressure-attenuating device, and a removal device. The access device can be used to create a passageway to an anatomical structure, such as the patient's bladder. The delivery device can be inserted through the passageway created by the access device and can be used to deliver the pressure-attenuating device to the anatomical structure. The removal device can be inserted through the passageway created by the access device and can be used to view the bladder and/or to capture, to deflate and to remove the pressure-attenuating device.

The present invention discloses a biomechanically compatible implant, wherein arbitrary selectable discrete locations of the implant are defined to exhibit biomechanical characteristics in accordance with biomechanical characteristics at arbitrary selectable discrete locations of a bodily tissue where the respective arbitrary selectable discrete locations of the implant are configured to be attached. The implant may be configured to repair prolapse in an embodiment. In another embodiment, the implant may be configured to repair urinary incontinence. The present invention further discloses a device for generating a biomechanical characteristics pattern of the bodily tissue and the implant. The present invention further discloses a system for designing and fabricating the biomechanically compatible implant.