The present disclosure is associated with monitoring health of a patient. An example electromagnetic-evoked acoustic device includes an electromagnetic component to emit energy toward tissue of a patient to cause the energy to be absorbed by the tissue; an ultrasound transmission component to transmit acoustic energy toward the tissue to cause a biological response from the tissue; and an ultrasound sensing component to sense the biological response from the tissue to permit a status of the tissue to be determined, wherein the biological response is sensed based on the energy absorbed by the tissue during the biological response.

Scan planes in acquisition of ultrasound images and dimensional measurements of objects represented in the images are determined by: defining a body to be examined and a predetermined orientation of the scan plane which intersects said body along which plane at least one ultrasound image is acquired; providing machine learning algorithm for verifying orientation and position of the scan plane, said algorithm trained with database of known cases which correlate image data of an image of a body previously examined and similar to said body with the position and orientation of the scan plane; reporting the scan plane does not correspond to the position and/or orientation of said predetermined scan plane; repeating the scan by changing the position and/or the orientation of the scan plane and repeating the steps as long as the position and orientation of the scan plane do not correspond to those of the predetermined scan plane.

A wireless fetal and maternal monitoring system includes a fetal sensor unit adapted to receive signals indicative of a fetal heartbeat, the sensor optionally utilizing a Doppler ultrasound sensor. A short-range transmission unit sends the signals indicative of fetal heartbeat to a gateway unit, either directly or via an auxiliary communications unit, in which case the electrical coupling between the short-range transmission unit and the auxiliary communications unit is via a wired connection. The system includes a contraction actuator actuatable upon a maternal uterine contraction, which optionally is a EMG sensor. A gateway device provides for data visualization and data securitization. The gateway device provides for remote transmission of information through a data communication network. A server adapted to receive the information from the gateway device serves to store and process the data, and an interface system to permits remote patient monitoring.

The present invention relates to a pregnancy monitoring system (10) and to a method for detecting medical condition information from a pregnant subject of interest (12). The system (10) comprises a fetal monitoring transducer (20) that detects fetal medical condition information, a first motion sensor unit (30) associated with the fetal monitoring transducer (20), the first motion sensor unit (30) comprising at least one first motion sensor (70, 72), a second motion sensor unit (32) comprising at least one second motion sensor (70, 72), and a control device (48) comprising an evaluation unit (50) that determines relative motion between the first motion sensor unit (30) and the second motion sensor unit (32), wherein the control device (48) selectively permits, in an enablement mode, processing of the detected fetal medical condition information when a level of relative motion between the first motion sensor unit (30) and the second motion sensor unit (32) indicates stable measurement conditions, and wherein the control device (48) selectively prevents, in a suppression mode, processing of the detected fetal medical condition information when the level of relative motion between the first motion sensor unit (30) and the second motion sensor unit (32) indicates unstable measurement conditions.

The present invention relates to an ultrasound diagnosis apparatus (10), in particular for analyzing a fetus (62). An ultrasound data interface (66) is configured to receive 3D (three dimensional) ultrasound data from an object (12). The ultrasound diagnosis apparatus further comprises a measurement unit (70) for measuring anatomical structures of the object based on the segmentation data and a calculation unit (72) configured to calculate at least one biometric parameter based on the 3D ultrasound data.

In one embodiment of the disclosure, a method of monitoring a fetus in utero is disclosed that includes implanting a medical device into a patient's uterus, collecting fetal data using the medical device, and transmitting, e.g., wirelessly, the fetal data from the medical device to a receiver. In another embodiment, a medical monitoring system is disclosed that includes a first device that is implantable into a patient's uterus for collecting fetal data, and a second device that is configured and dimensioned for connection with the first device such that the fetal data is wirelessly communicable from the first device to the second device.

In certain embodiments, a method for communicating with a fetus may include providing, on an electronic device, a user interface configured to facilitate wireless communication of signals between the electronic device and at least one implanted device located in proximity to the fetus; and responsive to a user selecting a communication selection element, causing the wireless communication of signals inclusive of content data between the electronic device and implanted device.

A region of interest setting unit sets a region of interest within image data for a tomographic image. The region of interest setting unit sets the region of interest to the heart of an embryo and partitions the region of interest into a plurality of blocks. A waveform generating unit generates an embryonic heartbeat waveform for each block of the plurality of blocks within the region of interest on the basis of the image data within the block. A waveform evaluating unit uses a standard waveform to evaluate the reliability of the embryonic heartbeat waveform for each block of the plurality of blocks within the region of interest.

A system and a method for assessing the ovarian reserve function of a subject. The system for assessing a subject's ovarian reserve function comprises: a data acquisition module configured to acquire data of the subject's age, anti-Müllerian hormone (AMH) level, follicle stimulating hormone (FSH) level, and antral follicle count (AFC); and an ovarian reserve function calculation module configured to calculate the above-mentioned information acquired in the data acquisition module, so as to work out the subject's probability of poor ovarian response (p). Further, the population is divided into four groups according to the interaction relationship between the predicted probability of poor ovarian response and the dose of ovulation stimulants, so as to divide the population with similar ovarian responses into one group.

A fetal head direction measuring device includes a medical ultrasonic probe for scanning and acquiring a preset ultrasonic image, an angle sensor fixed to the medical ultrasonic probe for sensing an angular change of a scanning direction of the medical ultrasonic probe, and a data processing unit for calculating a fetal head direction. A fetal head direction measuring method includes: obtaining an angle value sensed by the angle sensor at an initial position; acquiring a preset ultrasonic image and recording an angle value sensed by an angle sensor at this time; marking preset fetal head feature points and calculating a directional angle of the preset fetal head feature points in the preset ultrasonic image; and determining the fetal head direction. A fetal head orientation can be measured and calculated more conveniently and flexibly, and the user operation is simpler and more flexible.