A device for monitoring bone density comprises: a first electrode unit comprising a first electrode area to be arranged within a bone; a second electrode unit comprising a second electrode area to be arranged outside the bone, wherein the first and the second electrode units are configured for being arranged such that an electrical signal between the first and the second electrode areas travels through a cortical bone portion of the bone; an injection signal generating unit configured to provide an injection signal for generating the electrical signal; and a measurement unit configured to detect a measurement signal induced by the injection signal for determining an impedance between the first and the second electrode areas as a measure of bone density.

In an ultrasound system and a control method of the ultrasound system, in a case where the number of times of an operation corresponding to first operation information as at least one piece of operation information among a plurality of pieces of operation information corresponding to a wireless connection error, which is performed by a user, has reached a predetermined number within a predetermined period, second operation information as at least one piece of the operation information among the plurality of pieces of operation information, which corresponds to an operation that is not performed by the user, is proposed to the user.

An ultrasound diagnostic system (1) includes an ultrasound probe (2), a handheld type diagnostic apparatus main body (3), and a server (4), the ultrasound probe (2) includes a position sensor (14) that detects a measurement position of the ultrasound probe (2), the diagnostic apparatus main body (3) includes an image generation unit (22) that generates an ultrasound image and a monitor (24), the server (4) detects an organ of a subject by analyzing the ultrasound image and calculates a score of the measurement position with respect to an optimum position in a case of measuring the detected organ by the ultrasound probe (2), and the score is transmitted from the server (4) to the diagnostic apparatus main body (3) and displayed on the monitor (24).

A system including: a table assembly for supporting a subject in one or more examination positions; a table support assembly for supporting the table assembly, wherein the table support assembly includes: one or more moving mechanisms controlled to move the table assembly relative to a reference point along one or more axes, and to rotate the table assembly around the one or more axes; and a probe support assembly comprising: a grip for holding a probe; and an arrangement of a plurality of arms and joints controlled to movably support the probe that is held by the grip, wherein the probe support assembly is removably arranged at a predetermined position and orientation relative to the table support assembly to permit movement of the table support assembly and the probe support assembly for reproduction of a position and orientation of the probe relative to the subject supported by the table assembly.

The present disclosure relates to a method and system for diagnosing blood vessel obstruction, such as would occur in deep vein thrombosis (DVT). More specifically, the present disclosure relates to a software tool for use with sensor hardware to allow users to perform standardised and repeatable testing of patients to assist with diagnosis of deep vein thrombosis or related conditions. The present disclosure further relates to an apparatus and method for conducting the diagnosis. The apparatus includes an imaging probe and a computing device, where the computing device is configured to assist the user in placing the imaging probe on a blood vessel and moving the imaging probe between predetermined landmarks along the blood vessel.

Navigational and/or robotic tracking systems include one or more wireless tracking device attached to an object or to a bone of a patient. The wireless tracking device may include a camera, a pair of cameras, and/or a probe, and a wireless transmitter. Surgical methods may include wirelessly obtaining reference data, the reference data based on the camera of the wireless tracking device operably attached to the bone of the patient, the reference data is associated with a plurality of markers and using the reference data in a surgical navigation system. Surgical methods may also include wirelessly obtaining positional and orientation data, and/or surface or structural data, and using the positional and orientation data, and/or surface or structural data in the surgical navigation system.

A wireless handheld ultrasound system an ultrasound front end to transmit ultrasonic waves into a subject and convert received ultrasonic echoes into digital data; an image processor coupled to the ultrasound front end to convert the digital data into an image; and a power section coupled to the ultrasound front end and the image processor. The power section may include a battery; a charging circuit to charge the battery; and a wireless power transducer coupled to the charging circuit to convert wireless power received from an external source into electrical energy for the charging circuit.

Provided herein are cranial implant devices that include at least one acoustic, optical, and/or photoacoustic lens element comprising one or more electromagnetically translucent, electromagnetically transparent, sonolucent, and/or acoustically active materials. The cranial implant devices are structured for subgaleal scalp implantation within, beneath, and/or over at least one cranial opening of a subject and typically includes a substantially anatomically-compatible shape. In addition, the cranial implant devices permit transcranial therapeutic ultrasound, transcranial diagnostic ultrasound, photoacoustic imaging, electromagnetic wave diagnostic imaging, and/or electromagnetic wave therapeutic intervention of intracranial matter of the subject via the acoustic, optical, and/or photoacoustic lens element when the cranial implant device is subgalealy implanted within, beneath, and/or over the cranial opening of the subject. Other aspects are directed to various related systems and methods of obtaining diagnostic information from, and/or administering therapy to, a subject.

A sensor network for pregnancy monitoring of a subject includes a plurality of sensor systems time-synchronized to each other, each sensor system placed on a respective region of the subject and having a sensor member configured to detect data associated with at least one of physiological parameters of the subject, and a Bluetooth low energy system-on-a-chip configured to process and transmit the detected data; and a controller adapted in wireless communication with the plurality of sensor systems and configured to receive, from the plurality of sensor systems, to process, and to display the physiological parameters.

Disclosed herein is a medical device system configured to detect one or more blood vessels within a target area. The medical device system includes an ultrasound probe configured to detect one or more blood vessels, the ultrasound probe in communication with a console. The medical device system further includes one or more blood vessel correlation tools configured to generate a local output detectable by a user. The one or more blood vessel correlation tools are coupled to the ultrasound probe and in communication with a console. The one or more blood vessel correlation tools are selected from the group consisting of a light array, one or more visible light projectors, a haptic feedback system, and an auditory device.