Provided is an object information acquiring apparatus, having: an ultrasound transmitting element; a plurality of transducers each detecting a first acoustic wave generated by light, which is radiated into an object, and outputting a first electric signal, and detecting a second acoustic wave generated by an ultrasound wave, which is transmitted from the ultrasound transmitting element and which is scattered inside the object, and outputting a second electric signal; a support supporting the plurality of transducers so that directivity axes of the transducers are concentrated; and a processor acquiring property information on the object based on the first electric signal and the second electric signal respectively.

A sensor has a sensor element (5) with two opposite sides (11, 9) and an interconnect (7) with first and second terminal segments (13B, 13F) interconnected by an intermediate segment (42). The first terminal segment (13F) is positioned against a first side (11) of the sensor element and comprises a first contact terminal (50). The second terminal segment (13B) is positioned against the second side (9) of the two opposite sides of the sensor element and comprises a second contact terminal (52) on a surface facing the second side (11). There are third and fourth, external, contact terminals (54, 56). The interconnect provided electrical connections between the first and fourth contact terminals (50, 56) and between the second and third contact terminals (52, 54).

A system for acquiring ultrasound images of internal organs of a human body, comprises a scanner and at least a minimum number of components in, or associated therewith consisting of: i) an ultrasound probe head; ii) the at least one IMU, which comprises a three-axis accelerometer and a three-axis gyroscope; iii) electronic components for wired or wireless communication with remote terminals, and iv) a power source, wherein the 3-axis gyroscopes and 3-axis accelerometers of the IMU are calibrated by the manufacturer for offset, scale-factor, cross-axis sensitivity and initial orientation; and MEMS IMUs are calibrated by the user.

An ultrasound endoscope includes: an ultrasound transducer; a balloon groove in which a balloon band is fitted; a contact portion that constitutes a bottom surface of the balloon groove; a first wall portion that constitutes a proximal end side of the balloon groove and in which a first distance that is a distance from a center of a cross section orthogonal to an extension direction of the insertion portion to an outer circumference of the first wall portion is larger than a second distance that is a distance from the center of the cross section to the bottom surface; and a second wall portion that constitutes a distal end side of the balloon groove, in which a distance from the center of the cross section to an outer circumference of the second wall portion is larger than the second distance, and that includes a notch portion.

An ultrasound probe and an ultrasound system are disclosed. In some embodiments, the ultrasound probe includes a probe body having a user interface with controls and a mode selector. In some embodiments, when the mode selector is in a first setting, the controls are configured to control a probe transducer, and when the mode selector is in a second setting, the controls are configured to control the ultrasound machine via a probe transceiver.

An ultrasound system including: a scanner module including a housing including a first fastener element, an ultrasound transducer, a rotational actuator, and an electronics module; and a positioner module including a second fastener element; operable between a first mode, wherein the first and second fastener elements cooperatively couple the scanner module to the positioner module, and a second mode, wherein the scanner module and positioner modules are separate. An ultrasound system including: a housing including a handle region and a membrane; an ultrasound transducer; a reservoir; a rotational actuator; and an electronics module.

An imaging system comprises an ultrasounds probe (102) including a housing (108) with a probe orientation marker (116) disposed on the housing. The imaging system further comprises a display (132). The imaging system further comprises a console (104), electrically interfaced with the probe and the display, that includes a controller (128). The controller is configured to visually present an ultrasound image, in electronic format and via the display, with an image orientation marker visually displayed superimposed over the image and selectively located with respect to the displayed image based on the location of the probe orientation marker on the housing.

In various embodiments, a probe structure is provided. In some embodiments, the probe structure includes a probe body. In some embodiments, the probe structure further includes a plurality of fingers adapted to extend outwards from the probe body. In some embodiments, the probe structure further includes a spring including a plurality of coils adapted to wrap around the probe body and compressed between a compression plane and probe body. In some embodiments, the end coil of the plurality of coils is configured to encircle the plurality of fingers. In some embodiments, the compression plane is a grip held by a human operator. In some embodiments, the compression plane is a robotic end effector that positions itself over any topography.

A device is provided for automatically assessing functional hemodynamic properties of a patient is provided, the device comprising: a housing; an ultrasound unit coupled to the housing and adapted for adducing ultrasonic waves into the patient at a vessel; a detector adapted to sense signals obtained as a result of adducing ultrasonic waves into the patient at the vessel and to record the ; and a processor adapted for receiving the recorded signals as data and transforming the data for output at an interface. Other devices, systems, methods, and/or computer-readable media may be provided in relation to assessing functional hemodynamics of a patient.

The present invention relates to ultrasound imaging, and in particular to a device for imaging bodily tissue under load. The device has a platform (10), for at least partially supporting a part of the body (2), at least one ultrasound device (20) for imaging of the part of the body (2) in contact with the platform (10), and means (32) for measuring the pressure exerted on the platform (10).