A computer-implemented method for pelvic floor feedback. The method includes capturing a strength of action potentials via wireless sensors, the wireless sensors positioned proximate to a pelvic floor of a user. The method also includes transmitting the strength of the action potentials to a mobile device. The method also includes recording the strength of the action potentials on the mobile device.

A computer-implemented method for pelvic floor feedback. The method includes capturing a strength of action potentials via wireless sensors, the wireless sensors positioned proximate to a pelvic floor of a user. The method also includes transmitting the strength of the action potentials to a mobile device. The method also includes recording the strength of the action potentials on the mobile device.

A system and method for optimizing a patient's Kegel exercises is provided. The system includes a user interface device and a vaginal device. The vaginal device includes an intra-vaginal probe having an accelerometer that is configured to generate a signal in response to movement of the probe. The user interface device is connected to the vaginal device and analyzes signals from the accelerometer to provide physiological feedback information to the patient. The vaginal device may be connected to the user interface device via wireless communications such as Bluetooth or by wire. The user interface device may be a smart device or a computer that transmits information to central web-based data server accessible by the patient or authorized healthcare providers or third-party payers.

A system and method for optimizing a patient's Kegel exercises is provided. The system includes a user interface device and a vaginal device. The vaginal device includes an intra-vaginal probe having an accelerometer that is configured to generate a signal in response to movement of the probe. The user interface device is connected to the vaginal device and analyzes signals from the accelerometer to provide physiological feedback information to the patient. The vaginal device may be connected to the user interface device via wireless communications such as Bluetooth or by wire. The user interface device may be a smart device or a computer that transmits information to central web-based data server accessible by the patient or authorized healthcare providers or third-party payers.

Described herein are radio frequency (RF) transceivers that act as a relay device to provide communication between a sensor of a medical device (e.g., a medical device implanted within the body) and a peripheral device, such as a smartphone. The medical device may be an intraurethral, intrarectal, or intravaginal device. The sensor of the medical device may be a microelectromechanical (MEM) sensor, such as an accelerometer.

Described herein are radio frequency (RF) transceivers that act as a relay device to provide communication between a sensor of a medical device (e.g., a medical device implanted within the body) and a peripheral device, such as a smartphone. The medical device may be an intraurethral, intrarectal, or intravaginal device. The sensor of the medical device may be a microelectromechanical (MEM) sensor, such as an accelerometer.

A Kegel muscle exercising apparatus includes various exercise programs that adaptively change depending on a user's exercise performance. This apparatus includes an insertable device for inserting into the body of a user, computer program code that contains exercise programs that specify operation of a stimulation mechanism by a controller, a stimulation mechanism that directs a user to contract her Kegel muscles according to an exercise program, a sensor that measures Kegel muscle contraction activity, and a controller that receives feedback from the sensor. This feedback comprises the results of an exercise program, and depending on the results, the apparatus can determine a different exercise program appropriate for the user. Following the different exercise programs allows a user to improve her Kegel muscle strength.

A Kegel muscle exercising apparatus includes various exercise programs that adaptively change depending on a user's exercise performance. This apparatus includes an insertable device for inserting into the body of a user, computer program code that contains exercise programs that specify operation of a stimulation mechanism by a controller, a stimulation mechanism that directs a user to contract her Kegel muscles according to an exercise program, a sensor that measures Kegel muscle contraction activity, and a controller that receives feedback from the sensor. This feedback comprises the results of an exercise program, and depending on the results, the apparatus can determine a different exercise program appropriate for the user. Following the different exercise programs allows a user to improve her Kegel muscle strength.

An apparatus for testing and exercising pelvic floor musculature, the apparatus comprising an elongate housing adapted for a pelvic floor aperture. The housing accommodates an oscillator and an accelerometer connected to a signal processor configured for communicating signals representative of values read from the accelerometer. A result is calculated from an applied oscillation and a response measured, and used for characterizing the musculature. In one embodiment the frequency resulting in the greatest response from the musculature is measured, and this frequency is applied during exercise.

An apparatus for testing and exercising pelvic floor musculature, the apparatus comprising an elongate housing adapted for a pelvic floor aperture. The housing accommodates an oscillator and an accelerometer connected to a signal processor configured for communicating signals representative of values read from the accelerometer. A result is calculated from an applied oscillation and a response measured, and used for characterizing the musculature. In one embodiment the frequency resulting in the greatest response from the musculature is measured, and this frequency is applied during exercise.