A system for monitoring a fetus in a pregnant woman, and/or the maternal health risk for pregnancies complicated by such as pre-eclampsia and hypertensive disorders is configured to be worn by the pregnant woman, preferably so as to allow monitoring during daily life, e.g. in the form of an adhesive patch. The unit has a sound sensor, e.g. a microphone or accelerometer, to be positioned on the skin of the abdominal area so as to detect a vascular sound from umbilical arteries of the fetus or from the uterine arteries of the pregnant woman. The sound sensor is functionally connected to a processing unit which executes a processing algorithm on the captured vascular sound and extracts a signal parameter accordingly. The processing unit then communicates the signal parameter, e.g. using an audio signal, a visual display or by means of a wired or a wireless data signal.

A method of fetal ultrasound monitoring includes detecting contact of a first ultrasound transducer to a mother's abdomen based on input from a contact sensor in the first ultrasound transducer. A first transducer ID is received from the first ultrasound transducer, and then the first transducer ID is correlated with a first transducer label. A first heart rate is measured based on output of an ultrasound device in the first ultrasound transducer, and a heart rate indicator is displayed accordingly. A position of the first ultrasound transducer is identified in a two-dimensional plane, and the first transducer label is displayed on an abdomen image based on the first position.

A system for monitoring the fetal size of an expectant mother comprises an acoustic sensor for positioning over the belly of the expectant mother, the acoustic sensor configured to receive an acoustic signal generated by the fetal heartbeat and to generate a sensor output signal. A fetal size is determined from a sensor output signal strength. This system is based on the realization that certain acoustic signals generated by the fetal heart beat are strongly correlated with the fetus size.

A wearable sensor apparatus comprises a motion sensor configured to sense two or three dimensional movement and orientation of the sensor and a vibration sensor configured to sense acoustic vibrations. The apparatus includes means for attaching the motion sensor and the vibration sensor to a body. The sensor apparatus enables long term monitoring of mechanomyographic muscle activity in combination with body motion for a number of applications.

The balloon includes a pouch formed of a sealed wall delimiting an internal space, and a valve for filling the internal space with a fluid, capable of being occluded after filling the internal space. The pouch delimits a fluid-draining orifice opening into the internal space. The balloon further includes an occluding ball that occludes the draining orifice. The occluding ball can be spherical or polyhedral, and be capable of releasing the draining orifice under the effect of a magnetic field, so as to enable the at least partial drainage of the fluid contained in the internal space. The occluding ball is movable along at least two distinct axes in relation to the pouch.

An oximetry device for determining mammalian fetus oxygen levels, the oximetry device constituted of: a sensor module comprising multiple light sources of different wavelengths and at least one optical sensor; a processing unit in communication with the sensor module, the processing unit comprising a processor, and a memory, the processor in communication with an output device, the memory comprising electronically readable instructions to cause the processor to: energize the multiple light sources; determine a time varying amplitude of an output of the at least one optical sensor; asses a quality of a location of the sensor module responsive to the determined time varying amplitude; provide to the output device an indication of the assessment of quality of the location; extract features from the determined time varying amplitude; and output an indication of the mammalian fetus oxygen level responsive to the extracted features from the determined time varying amplitude.

Described is a device for determining gestational age and methods for determining gestational age at birth by measuring parameters associated with photobiological properties of the skin such as reflectance or reflectivity by measuring diffused or scattered portions of the light beam incident on the skin, as well as the erythema index, along with clinical parameters of the newborn such as gender, the use of phototherapy, birth weight and time spent in incubator. The ability to obtain a realistic estimate of the age of the conceptus quickly, non-invasively and at low cost makes it possible to provide care suited to the needs of the newborn, to assess the chances of survival and to affect the short- and long-term prognosis of the newborn. The correct determination of gestational age at birth also influences clinical follow-up protocols in infancy and vital statistics.

A modular stethoscope system has multiple ear pieces and chest pieces. The modular stethoscope system allows multiple peoples' heartbeat and breathing sounds to be shared. The apparatus can have multiple heart modules that are placed on users' chests that can each receive circulatory and/or respiratory audio signals from the users. The heart modules can be coupled to each other and/or coupled to multiple audio output devices so that some or all of the users can hear the combined heartbeats. The heart modules' inputs and outputs can be shared through direct physical links and/or converted into electrical or wireless signals that can be received by other electrical audio output devices so that multiple users can listen to multiple heartbeat outputs.

A system for monitoring a fetus in a pregnant woman, and/or the maternal health risk for pregnancies complicated by such as pre-eclampsia and hypertensive disorders is configured to be worn by the pregnant woman, preferably so as to allow monitoring during daily life, e.g. in the form of an adhesive patch. The unit has a sound sensor, e.g. a microphone or accelerometer, to be positioned on the skin of the abdominal area so as to detect a vascular sound from umbilical arteries of the fetus or from the uterine arteries of the pregnant woman. The sound sensor is functionally connected to a processing unit which executes a processing algorithm on the captured vascular sound and extracts a signal parameter accordingly. The processing unit then communicates the signal parameter, e.g. using an audio signal, a visual display or by means of a wired or a wireless data signal.

Systems and methods for monitoring uterus contraction activity and progress of labor. The system of the subject invention can comprises (1) a plurality of sensors; (2) an amplifying/filtering means; (3) a computing means; and (4) a graphical user interface. Accurate clinical data, which can be extracted and provided to the user in real-time using the system of the invention, include without limitation, progress of labor, prediction and monitoring of preterm labor, and intrauterine pressure prediction. In a preferred embodiment, the system of the invention includes an intelligence means, such as a neural network system, to analyze and interpret clinical data for use in clinical diagnosis as well as delivery strategy.