Abstract: An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a fixation mechanism at or near the front end of the conduit. In various embodiments, the fixation mechanism can anchor the implantable device to the tissue using a movement of a push wire. Optionally, the fixation mechanism can also allow the implantable device to be released from the tissue using another movement of the push wire, to allow for re-positioning or removal of the implantable device.

Abstract: An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a fixation mechanism at or near the front end of the conduit. In various embodiments, the fixation mechanism can anchor the implantable device to the tissue using a movement of a push wire. Optionally, the fixation mechanism can also allow the implantable device to be released from the tissue using another movement of the push wire, to allow for re-positioning or removal of the implantable device.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a helix coupled to the front end of the conduit. The helix functions as a fixation mechanism to anchor the implantable device to the tissue. The implantable device can be inserted into tissue using a sheath and can be rotated with the sheath by partially inflating the adjustable membrane element placed in a front end portion of the sheath, and the helix can be turned into the tissue by rotating the sheath.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a fixation mechanism at or near the front end of the conduit. In various embodiments, the fixation mechanism can anchor the implantable device to the tissue using a movement of a push wire. Optionally, the fixation mechanism can also allow the implantable device to be released from the tissue using another movement of the push wire, to allow for re-positioning or removal of the implantable device.

Abstract: An implantable device includes a conduit, an adjustable membrane element coupled to the conduit near the front end of the conduit for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence, and a fixation mechanism at or near the front end of the conduit. In various embodiments, the fixation mechanism can anchor the implantable device to the tissue using a movement of a push wire. Optionally, the fixation mechanism can also allow the implantable device to be released from the tissue using another movement of the push wire, to allow for re-positioning or removal of the implantable device.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: One or more sensors are incorporated onto one or more of an implantable device and a surgical tool used for placement and/or adjustment of the implantable device. The implantable device includes an adjustable membrane element for controllable coaptation of a body lumen, such as coaptation of a urethra as treatment for urinary incontinence. In various embodiments, the one or more sensors can be configured to detect information indicative of at least one of a shape of the adjustable membrane element, a position of the adjustable membrane element relative to the body lumen, or a shape of the body lumen.

Abstract: The present application relates to method and apparatus for reducing migration and rotation of implantable devices including an expandable element and an elongate portion.

Abstract: The present subject matter provides a trocar and sheath assembly for placement of implantable devices adjacent a body lumen, and a method of using the trocar and sheath assembly for implanting an implantable device at a target site for controllable coaptation of a patient's urethra.

Abstract: The present subject matter provides a trocar and sheath assembly for placement of implantable devices adjacent a body lumen, and a method of using the trocar and sheath assembly for implanting an implantable device at a target site for controllable coaptation of a patient's urethra.

Abstract: The present subject matter provides a trocar and sheath assembly for placement of implantable devices adjacent a body lumen, and a method of using the trocar and sheath assembly for implanting an implantable device at a target site for controllable coaptation of a patient's urethra.

Abstract: The present application relates to method and apparatus for reducing migration and rotation of implantable devices including an expandable element and an elongate portion.

Abstract: The present application relates to method and apparatus for reducing migration and rotation of implantable devices including an expandable element and an elongate portion.

Abstract: The present subject matter provides method and apparatus for placement of implantable devices adjacent a body lumen. A method of implanting an implantable device at a target site for controllable coaptation of a patient's urethra using an ultrasonic probe inserted into a rectum of the patient comprises inserting a Foley catheter into the urethra, expanding a Foley balloon in the bladder neck, inserting the ultrasonic probe into the rectum of the patient, using the ultrasonic probe to image the urethra and Foley balloon at the bladder neck, placing a small puncture in the perineum, passing a delivery device to the target site under ultra sonic guidance, injecting echogenic fluid at the target site adjacent the urethra, delivering the implantable device to the target site, and adjusting the implantable device to improve coaptation of the urethra.

Abstract: The present subject matter provides method and apparatus for placement of implantable devices adjacent a body lumen. A method of implanting an implantable device at a target site for controllable coaptation of a patient's urethra using an ultrasonic probe inserted into a rectum of the patient comprises inserting a Foley catheter into the urethra, expanding a Foley balloon in the bladder neck, inserting the ultrasonic probe into the rectum of the patient, using the ultrasonic probe to image the urethra and Foley balloon at the bladder neck, placing a small puncture in the perineum, passing a delivery device to the target site under ultra sonic guidance, injecting echogenic fluid at the target site adjacent the urethra, delivering the implantable device to the target site, and adjusting the implantable device to improve coaptation of the urethra.