The present invention relates to an implantable sensor configured to be implanted within the body of the subject and being configured to measure impedance within a body tissue of the subject resulting from an electrical current flowing through the body tissue, wherein the body tissue is sub-dermal or subcutaneous tissue of the subject. One pair of injection electrodes is configured for injection of electrical current into the body tissue and one pair of sensing electrodes is configured to detect the resulting voltage. A detector is operatively connected to the sensing electrodes and is configured to receive the voltage detected by the sensing electrodes, wherein the detector is configured to measure the impedance of the body tissue based on the voltage detected by the pair of sensing electrodes. A microcontroller is operatively connected to the detector and is configured to receive impedance signals from the detector and to provide control signals to the current signal output circuit and a powering and communication circuit including a coil configured to be powered by an electromagnetic field produced by an external coil.

The present invention relates to a health monitoring system comprising an implantable sensor configured to measure impedance within a body tissue of the subject resulting from an electrical current flowing through said body tissue, wherein the body tissue is sub-dermal or subcutaneous tissue of said subject, the sensor including a powering and communication circuit having a coil configured to be powered by an electromagnetic field and to communicate with external devices. Further, the system comprises a reader module including a coil configured to produce the electromagnetic field for powering the powering and communication circuit and for communicating with the powering and communication circuit, a computing device comprising a display device, a processing device and at least one storage device, the computing device being configured to communicate with other devices via at least one wireless network and a monitoring engine for determining or monitoring at least one physiological parameter based on measured impedance, wherein the reader module and the computing device and the monitoring engine are configured to communicate with each other.

A vaginal ring sensor device adapted to be placed within the vaginal vault of a user, the device including a ring body, at least one through hole that passes through the ring body, and at least one biosensor structured and arranged to sense and/or measure a parameter of vaginal fluid as such fluid passes through the at least one through hole.

An in vivo optical biopsy applicator of the vaginal wall for treatment planning, monitoring, and imaging guided therapy is described herein. The applicator may include an imaging probe operatively coupled to a laser ablation device. The applicator allows for non-invasive optical tissue monitoring in order to define pre- and post menopausal parameters, pre- and post-treatment microscopic changes, and offers an objective scientific tool in order to compare currently available medical, non-medicated, and energy-based treatment protocols.

A vaginal ring sensor device adapted to be placed within the vaginal vault of a user, the device including a ring body, at least one through hole that passes through the ring body, and at least one biosensor structured and arranged to sense and/or measure a parameter of vaginal fluid as such fluid passes through the at least one through hole.

A method of assessing Fallopian tubal patency includes introducing a distension medium into a patient's uterus, introducing a contrasting medium into the uterus, and observing the contrasting medium, for example, via a hysteroscope, to determine whether the contrasting medium flows into one or both Fallopian tubes. A device for assessing Fallopian tubal patency includes a chamber for receiving contrast media, a flow path through the chamber for delivering distension media to a patient's uterus, and a flow controller for regulating the flow of distension media to the patient's uterus. The flow path is configured to permit flow of contrast media from the chamber into the flow path.

Exemplary embodiments of the present disclosure are directed towards an electronic module positioned in a multifunctional disposable hygiene apparatus of a user, wherein the electronic module comprises of: a plurality of sensors enabled to sense a plurality of parameters of a discharge and read a pressure generated due to a seating pattern of the user; and an embedded dipstick configured to conduct a test of a plurality of blood parameters from the discharge; a network device of a user comprising an application and in communication with the multifunctional disposable hygiene apparatus, wherein the application is configured to receive a data comprising data comprising the plurality of parameters of a discharge and pressure generated due to the seating pattern of the user and the plurality of blood parameters from the discharge from the electronic module; a remote data centre in communication with the user's network device configured to store and process the data received from the user's network device and transmitting notifications to the user's network device in response to processing the data; and a medical service provider's network device in communication with the user's data centre and the user's network device configured to allow the medical service provider to view the data of the user.

Methods of enhancing reproductive capacity in a female subject are provided. Aspects of the methods include inducing infertility in the subject in a manner effective to cause the subject to mount a compensatory response and thereby enhance reproductive capacity in the subject. Systems and kits useful in practicing the methods of the present disclosure are also provided.

The methods and apparatuses (including systems and device) described herein may be used to accurately and comfortably monitor and track body temperature using a wearable device that can be positioned inside a patient's ear for measuring the patient's temperature, sleeping quality, or other vital signs. These systems and methods may also include a base station and a remote analytics unit (e.g., software, hardware or firmware, including application software that may run on a hand-held or wearable electronics device). The inter-aural device (earplug device) may record and pre-process information that may then be adaptively passed on the remote analytics unit for further processing. The earplug device may engage the remote analytics unit with to download and process the temperature measurement data from the device, to electrically charge the device and also to communicate wirelessly with a smart phone or different types of mobile devices.

One embodiment of the present invention provides an apparatus for analyzing a liquid comprising a plurality of different substances. The apparatus includes an absorber that comprises one or more layers of absorbent material for absorbing the liquid and one or more sensors embedded within the one or more layers of absorbent material. The sensors are configured to provide information associated with the different substances included in the absorbed liquid, and a location of a respective sensor is determined based on a corresponding substance detected by the sensor and a diffusion property of the substance.