An ultrasound diaphragmography device includes a plurality of piezoelectric ultrasound transducers arranged in at least two linear arrays for placement on a patient's chest along a cranio-caudal axis of the patient. The ultrasound transducers generate and transmit ultrasound waves that penetrate the patient's anatomy and receive returned ultrasound waves. Circuitry in communication with the ultrasound transducers receive the returned ultrasound waves and analyzes the returned ultrasound waves to determine the quality of the patient's lung function in real-time and compare the movement of the left and right hemidiaphragms.

An apparatus for estimating bio-information is provided. The apparatus for estimating bio-information by using an ultrasonic signal according to an embodiment of the present disclosure includes: an ultrasonic sensor configured to acquire an ultrasonic signal from an object; and a processor configured to detect peaks from the acquired ultrasonic signal, and to determine false detection of a peak, among the detected peaks, by using at least one of amplitudes of the detected peaks or a left waveform shape and a right waveform shape of the peak.

A guidance system for guiding insertion of a needle into a body of a patient utilizes ultrasound imaging or other suitable imaging technology. The guidance system can include an imaging device including a probe for producing an image of the internal body portion target, such as a blood vessel. The imaging device can be configured to provide at least one indication of status via sensory feedback based on a determined position of the needle, for example via a plurality of light-emitting diodes located on the device. One or more sensors can be included with the probe that can sense a magnetic field associated with the needle. The system may include a processor that can receive magnetic field data sensed by the at-least-one sensor to determine the position of the needle. The system can also include a display that depicts the determined position of the needle.

A method and system is for assisting a user in positioning an ultrasound probe relative to a subject's body. In use, the user moves the probe through a series of positions, and ultrasound image data is captured for each position, the data at each position corresponding to a particular imaging view of the anatomical region being imaged. An assessment procedure (16) is operable to process ultrasound data for different imaging views, and to determine for the data for each view a rating, representative of the suitability of the data for that view for observing one or more anatomical features or deriving one or more clinical parameters from the data. Guidance feedback is generated (18) for the user for assisting the user in positioning the probe, wherein the guidance feedback is based on a history (26) of image view quality over time over the course of the imaging procedure. For example, a trend in image view quality over time may be determined and output to a user, from which the user can quickly tell whether they are moving toward (in the case of increasing quality) or away from (decreasing quality) an optimum imaging position.

A mixed reality (MR) visualization system includes an MR device comprising a holographic display configured to display a holographic image to an operator, a hand-held ultrasound imaging device configured to obtain a real-time ultrasound image of a subject's anatomy, and a computing device communicatively coupled to the MR device and the hand-held ultrasound imaging device. The computing device includes a non-volatile memory and a processor. The computing device is configured to receive the real-time ultrasound image, determine a real-time 3D position and orientation of the hand-held ultrasound imaging device, generate a modified real-time ultrasound image by modifying the real-time ultrasound image to correspond to the real-time 3D position and orientation of the hand-held ultrasound imaging device, and transmit the modified real-time ultrasound image to the MR device for display as the holographic image positioned at a predetermined location relative to the hand-held ultrasound imaging device.

An ultrasonic device is provided for use on a biological tissue, and includes a base assembly on which a vibrator is mounted, and an ultrasonic probe. The base assembly includes an annular base having at least two pairs of abutment protrusions for abutting against the biological tissue, and an installation base coaxially disposed on and rotatable relative to the annular base between two test positions. The installation base has a through hold in which the ultrasonic probe is inserted.

A system (10) is for performing ECG measurements and comprises a probe (12) with an integrated one or more ECG electrodes (22) and an ultrasound sensing means (18), such as a transducer arrangement. The probe thus provides a mobile ECG electrode which can be sequentially moved between a set of different locations on the body for acquiring ECG measurements from different angles relative to the heart (i.e. different ‘leads’). Positioning of the probe in each required location is guided by a position guidance function which uses ultrasound data acquired by the ultrasound sensing means to locate the probe (with reference to an ultrasound body atlas (28) or map), and uses a stored set of reference body locations to guide a user with guidance information as to how to move the probe to arrive at a next target electrode location. In examples, the user may be guided through a sequence of electrode locations, with ECG data acquired at each one, thereby sequentially building up a set of standard ECG lead measurements.

A system for robot-assisted ultrasound scanning comprises a multi axis robot with an end effector, a transducer holding element for connecting an ultrasound transducer to the end effector, a user input arrangement having at least three separate proportional inputs representing desired ultrasound transducer displacement along X, Y and Z axes of an orthogonal coordinate system defining the ultrasound transducer motion, and a controller which is connected to the user input arrangement and which controls the end effector based on input. The controller acquires a 3D model of a surface to be scanned and is arranged to continuously update the orthogonal coordinate system defining the ultrasound transducer motion as the ultrasound transducer moves, the X, Y and Z axes are arranged as described. In this way, the operator can easily move the transducer along the surface of the area to be scanned.

An imaging device positioning system for monitoring an anatomical region (10). The imaging device positioning system employs an imaging device (20) for generating an image (21) of an anatomical region (10). The imaging device positioning system further employs a imaging device controller (30) for controlling a positioning of the imaging device (20) relative to the anatomical region (10). During a generation by the imaging device (20) of the image (21) of the anatomical region (10), the imaging device controller (30) adapts the control of the positioning of the imaging device (20) relative to the anatomical region (10) to a physiological condition of the anatomical region (10) extracted from the image (21) of the anatomical region (10).

Arrangements described herein relate to systems, apparatuses, and methods for a disposable kit containing medical items configured for a medical device including a head cradle to support a head of a subject, the disposable kit includes a container that encloses a head cradle pad configured to be affixed to the head cradle, at least one fiducial marker configured to be disposed on a location at the head of the subject, and at least one enclosure configured to cover a portion of the medical device.