A device (10) is provided for ultrasound-based reflection and transmission tomography. The device (10) comprises: a transducer holder (14) configured to hold a plurality of ultrasonic transducers around an imaging volume (30) to be filled with an ultrasonic coupling medium, the transducer holder (14) having an opening for inserting, into the imaging volume (30), at least one part of a body to be imaged, wherein the transducer holder (14) is configured to move, during imaging of the at least one part of the body to be imaged, with respect to the body to be imaged; a support member (11) configured to support, during imaging, the body to be imaged, the support member (11) having a support-member-opening allowing access to the transducer holder (14) by the at least one part of the body to be imaged; a diaphragm (12) having a diaphragm-opening (13), the diaphragm (12) being arranged across the support-member-opening such that a center of the diaphragm-opening (13) is placed substantially at a predetermined position, wherein the diaphragm (12) comprises a material that has a higher transmissivity of ultrasound than a material of the support member (11); an outlet (15) for the ultrasonic coupling medium to flow out of the imaging volume (30) when the at least one part of the body to be imaged is inserted into the imaging volume (30) filled with the ultrasonic coupling medium and/or during imaging; and an elastic membrane (16) comprising a fluidtight material connecting the transducer holder (14) and the outlet (15) in order to guide the ultrasonic coupling medium flowing out of the imaging volume (30) towards the outlet (15).

A system and method for capturing ultrasound signals from a hemispheric imaging region (e.g., by a stationary array of transducer elements arranged in the shape of a faceted hemisphere) and estimating scattering measurements that would be made by a virtual array in the opposite hemisphere (e.g., by a network of processors that receive and process the transmitted ultrasound signals in parallel) by forming an initial estimate of a medium variation for each of a plurality of subvolumes in the scattering object to form an estimated object, calculating residual scattering by using a difference between a scattering response calculated for the estimated object and measured ultrasound signals received from the scattering object, forming an initial three-dimensional image of the scattering object, and extrapolating a difference between the scattering response calculated for the estimated object and the measured ultrasound signals received from the scattering object.

The medical imaging apparatus of the present invention includes a bath tank for accommodating a test subject, the test subject being at least a portion of a body of a human subject; a measurement device movable in a predetermined direction, the measurement device including ab group of elements to emit a radiation wave into the bath tank and receive a scattered radiation wave; and a control unit for measuring by the measurement device when at least one of a location of the test subject within a plane orthogonal to the predetermined direction, a location of the test subject in the predetermined direction, and continuity of data measured by the measurement device satisfies a predetermined condition. Because of this configuration, the medical imaging apparatus is able to acquire data covering the entire measurement target site.

A photoacoustic tomography system includes a first ring-shaped mirror having a central axis therethrough and configured to converge light inwardly towards the central axis and a subject, and an adjustment mechanism configured to move the first ring-shaped mirror along the central axis to a plurality of different positions. Each position of the plurality of different positions allows the first ring-shaped mirror to illuminate a respective ring of light around a respective portion of the subject, and an acoustic signal detector is movable along the central axis such that acoustic signals can be detected from the respective portion of the subject when illuminated by the first ring-shaped mirror while at each respective position of the plurality of different positions.

A method for characterizing tissue of a patient, including receiving acoustic data derived from the interaction between the tissue and the acoustic waves irradiating the tissue; generating a morphology rendering of the tissue from the acoustic data, in which the rendering represents at least one biomechanical property of the tissue; determining a prognostic parameter for a region of interest in the rendering, in which the prognostic parameter incorporates the biomechanical property; and analyzing the prognostic parameter to characterize the region of interest. In some embodiment, the method further includes introducing a contrast agent into the tissue; generating a set of enhanced morphology renderings of the tissue after introducing the contrast agent; determining an enhanced prognostic parameter from the enhanced morphology renderings; and analyzing the enhanced prognostic parameter.

An ultrasonic imaging system including an array transducer that includes a plurality of elements each performing at least one of emission or reception of ultrasonic waves, at least some of the plurality of elements being disposed so as to face each other. The ultrasonic imaging system performs malfunction inspection including specifying one emitting element among emitting elements that emit ultrasonic waves and a group of receiving elements that are at least some of the plurality of elements and that receive transmitted waves emitted from the emitting element and transmitted through an imaging region; collecting measurement data of the transmitted waves via the group of receiving elements while switching the emitting element; calculating transfer characteristic values from the measurement data; and detecting a malfunctioning element among the plurality of elements on the basis of the transfer characteristic values.

A method of analyzing an image of a volume of tissue to determine a risk of developing breast cancer using a volume averaged sound speed within the volume. A method of determining a response to a treatment plan by determining a volume and a volume averaged sound speed of a region of interest within a volume of breast tissue and generating a combined metric from the volume and the volume averaged sound speed over the plurality of instances of time. A method of analyzing an image of a volume of tissue of a breast by applying a spatial filter to at least one ultrasound tomography image at the computing system and generating a stiffness map from the at least one ultrasound tomography image.

An object of the invention is to provide an ultrasonic CT device in which a reflected signal or the like from an object disposed close to transducers is received, and a reception signal thereof can be received by a receiver while transceivers whose number is smaller than the number of the transducers are used. The ultrasonic CT device includes: a transducer array in which a plurality of transducers are arranged; transceivers whose number is smaller than the number of the transducers; and a transmission transducer selector and a reception transducer selector disposed for each of the transceivers. While a transmitter included in the transceiver is selectively connected to any of the transducers in the transducer array by the transmission transducer selector, a receiver included in the transceiver is selectively connected to any of the transducers in the transducer array by the reception transducer selector.

A method for postural independent location of targets in diagnostic images acquired by multimodal acquisitions, compensating for deformation of soft tissues due to changing posture, includes generating a transition of a digital image of the inside of a target region from a first to a second position by correlating the position of markers placed on the external surface of the target region in a digital image of the inside of the target region and in a digital representation of the external surface of the target region acquired by optically scanning the external surface; and at a later time registering the diagnostic image of the inside of the target region, transitioned into the second position, with a diagnostic image of the same target region acquired with the target region in the second position by matching a second representation of the external surface of the target region in the second position without markers with the diagnostic image of the inside of the target region transitioned into the second position.

An acoustic wave apparatus is used, the apparatus comprising: a supporting member supporting an examinee and having insertion opening; a subject holding member holding the subject; a transducer array including transducers and being distant from the subject holding member; a load acquiring unit acquiring a load value applied between the supporting member and the subject holding member based on an amount of deformation of the subject holding member; a memory unit storing a first load reference value determined based on the amount of deformation of the subject holding member and an area applied with the load when the subject holding member and the transducer array come into contact with each other; a comparing and determining; and an interlock controlling unit.