Abstract: The present invention relates to an apparatus for an ultrasonic examination of a deformable object, particularly, the breast. More particularly, the present invention relates to an apparatus capable of performing an ultrasonic examination by moving an ultrasonic probe while maintaining the position and shape of a deformable object to be inspected. That is, the present invention relates to an apparatus capable of performing an effective ultrasonic by scanning an entire deformable object such as the breast at one time using a movable ultrasonic probe.

Abstract: A display and control device for medical equipment, comprising several identically configured display/control units, which are located on a base unit. The base unit is equipped with a bus, to which the display/control units and components of the medical equipment are connected. The base unit comprises connection devices, which are used to connect the display/control units to the bus. Once a display/control unit has been connected, a configuration unit transmits configuration data to the display/control unit and only then defines which function the display/control unit is to fulfill. This permits defective display/control units to be simply replaced. The construction of the display/control units is likewise simple and not susceptible to malfunctions.

Abstract: Imaging and therapy for the treatment of venous disease are integrated into the same device, such that there is a common user interface and/or display, which may be passive or interactive between image and therapy parameters.

Abstract: A method for the non-destructive inspection of a test body using ultrasound is disclosed, in which at least one ultrasonic transducer couples ultrasonic waves into the test body and ultrasonic waves reflected inside the test body are received by ultrasonic transducers and converted into ultrasonic signals, which form the basis of the non-destructive inspection.

Abstract: Elasticity variation within biological tissue is often correlated with its pathology. Variation of elasticity can be assessed by specific ultrasound acquisition sequences during which pressure is applied. The tissue motion and deformation during those sequences is correlated to the tissue stiffness. The present invention describes a hybrid method that combines a real-time monitoring mode during acquisition and a non-real-time fine analysis after acquisition. This method allows early identification and fair assessment of pathology from elastographic analysis to obtain the best possible result for elastography assessment.

Abstract: A non-invasive visual imaging system is provided, wherein the imaging system procures an image of a transducer position during diagnostic or therapeutic treatment. In addition, the system suitably provides for the transducer to capture patient information, such as acoustic, temperature, or ultrasonic images. For example, an ultrasonic image captured by the transducer can be correlated, fused or otherwise combined with the corresponding positional transducer image, such that the corresponding images represent not only the location of the transducer with respect to the patient, but also the ultrasonic image of the region of interest being scanned. Further, a system is provided wherein the information relating to the transducer position on a single patient may be used to capture similar imaging planes on the same patient, or with subsequent patients. Moreover, the imaging information can be effectively utilized as a training tool for medical practitioners.

Abstract: A semi-invasive ultrasound imaging system for imaging biological tissue includes a transesophageal probe or a transnasal, transesophageal probe connected to a two-dimensional ultrasound transducer array, a transmit beamformer, a receive beamformer, and an image generator. The two-dimensional transducer array is disposed on a distal portion of the probe's elongated body. The transmit beamformer is connected to the transducer array and is constructed to transmit several ultrasound beams over a selected pattern defined by azimuthal and elevation orientations. The receive beamformer is connected to the transducer array and is constructed to acquire ultrasound data from the echoes reflected over a selected tissue volume. The tissue volume is defined by the azimuthal and elevation orientations and a selected scan range. The receive beamformer is constructed to synthesize image data from the acquired ultrasound data.

Abstract: A curved array ultrasound transducer is described which is usable in both sector and curved linear modes. The transducer includes a central portion (40) of elements and lateral portions (44) of elements on either side of the central portion. In the sector mode the central portion of elements is operated to perform phased array scanning. In the curved linear mode both the central and lateral portions of elements are operated to perform curved linear array scanning. The transducer elements of the central portion have a finer pitch than the pitch of the transducer elements of the lateral portions. In the sector mode, the elements of the central portion are operated individually, and in the curved linear mode the transducer elements of the central portion are operated in pairs. In the sector mode, the number of transducer elements of the central portion that participate in the active aperture of the transducer may be varied according to the number of transducer elements in acoustic contact with the patient.

Abstract: An ultrasound diagnostic imaging device has an optional-direction M-mode cursor set position information selector for selecting optional-direction M-mode cursor set position information, a memory, and an optional-direction M-mode cursor image generator. The memory stores optional-direction M-mode cursor set position information, associating it with the optional-direction M-mode cursor set position information selector. The optional-direction M-mode cursor image generator generates an optional-direction M-mode cursor image, based on the optional-direction M-mode cursor set position information that has been associated with the optional-direction M-mode cursor set position information selector that was selected.

Abstract: The present invention relates to an ultrasound imaging system in which the scan head either includes a beamformer circuit that performs far field subarray beamforming or includes a sparse array selecting circuit that actuates selected elements. When used with second stage beamforming system, three dimensional ultrasound images can be generated.

Abstract: An ultrasonic enhanced-contrast imager and method includes an ultrasonic probe for transmitting and receiving an ultrasonic wave to and from an organism, a transmitting section for transmitting an ultrasonic signal to the ultrasonic probe, a receiving section for processing a response signal ultrasonic wave received by the ultrasonic probe, a filter for extracting a specific frequency component from the processed response signal, and a setting control section for setting a pass frequency band of the filter on the basis of a frequency band of the response signal from a contrast medium injected to the organism. A control section controls the operation of the filter in the set pass band, and the setting control section sets the center frequency of the pass band of the filter to be greater than f0 and less than 2f0, where f0 is the average frequency of the ultrasonic signal transmitted to the ultrasonic probe.

Abstract: Methods and systems are provided for automatic optimization for ultrasound medical imaging. In one approach, velocity values are unwrapped to avoid aliasing artifacts. Multi-dimensional phase unwrapping is applied to the velocity data. The unwrapped velocity information is used to optimize one or both of the velocity scale (e.g., pulse repetition frequency) and the imaging frequency. For optimizing the scale setting, the distribution of unwrapped velocities from a systolic time period of the heart cycle are used to identify the pulse repetition frequency. For optimizing the imaging frequency, a correlation as a function of depth shows the penetration depth for a given imaging frequency. In a dependent or independent approach, one or more thresholds for velocity or energy in flow imaging are adaptively selected as a function of an amount of clutter. Velocity or other energy information in addition to the clutter information may be used for selecting the thresholds.

Abstract: An ultrasonographic apparatus in which the S/N ratio of a compound image is improved operates by combining a plurality of reception beam signals from probes arranged at different positions relative to a sample, converting the combined ultrasonic beam into a luminance signal, and displaying the luminance signal.

Abstract: A digital medical diagnostic system according to the present invention enables ophthalmologists to view patient and other images remotely to diagnose various conditions. The system includes at least one modality, one or more viewing stations, and an image server. The modality generates patient images associated with examinations, while the image server retrieves and processes information from the modalities. The image server may accommodate modalities utilizing different interfaces and/or formats. The viewing stations enable remote access to the images via a network (e.g., Internet), where the image server provides the interface for a user in the form of screens or web pages for security and viewing of information. The system enables an ophthalmologist or other medical personnel to view and/or manipulate one or more images to enhance diagnosis of patient examinations.

Abstract: There are disclosed embodiments for an ultrasound system for providing a color M mode image and a brightness M mode image. The ultrasound system comprises: an ultrasound data acquisition unit configured to perform a first operation for providing a first piece of ultrasound data for a color M mode image and a second operation for providing a second piece of ultrasound data for a brightness M mode image; a control unit configured to control the ultrasound data acquisition unit to perform the first operation by an average number of times and the second operation one or more times in a selective pattern within a predetermined sweep period to respectively accumulate the first pieces of ultrasound data and the second pieces of ultrasound data provided from the ultrasound data acquisition unit; and an image processor configured to form the color M mode image based on the accumulated first pieces of ultrasound data and to form the brightness M mode image based on the accumulated second pieces of ultrasound data.

Abstract: A system and method for functional ultrasound imaging are provided. The method includes obtaining ultrasound image data acquired from a multi-plane imaging scan of an imaged object. The ultrasound image data defines a plurality of image planes. The method also includes determining functional image information for the imaged object from two-dimensional tracking information based on the plurality of image planes and generating functional ultrasound image data for the imaged object using the functional image information.

Abstract: A method for performing ultrasound imaging and elasticity measurement, the method includes scanning an object to obtain a B-mode ultrasound image, selecting an A-mode signal from the B-mode ultrasound image, transmitting a high frame rate ultrasound signal, by a selected group of ultrasound transducers, at the selected A-mode signal location, forming a transient M-mode image based on the high frame rate ultrasound signal, enhancing propagation trace of shear wave based on the transient M-mode image, calculating elasticity of the object based on the propagation trace and displaying result, and displaying, simultaneously, the B-mode ultrasound image and the transient M-mode measurement result.

Abstract: In an ultrasound diagnosis apparatus, a plurality of sub arrays are defined on a 2D array transducer. A plurality of groups are defined for each sub array. Each group is basically composed of a plurality of transducer elements which are connected in parallel with each other. A sub array shape is variably defined for a plurality of sub arrays in accordance with the beam direction and the depth of a focal point. Further, a grouping pattern is variably defined for each sub array. The acoustic distances between the respective transducer elements and the focal point is made as equal as possible for a plurality of transducer elements forming each group, whereby a preferable beam profile can be obtained.

Abstract: In one embodiment of the invention, there is an ultrasound processing system that communicates images over a single asynchronous serial channel according to a scheme that does not require an isochronous serial channel and that switches among ultrasound imaging modes robustly. For example, the system is configured to packetize ultrasound image data of at least one ultrasound imaging mode into a stream of data frames and to convey the stream of data frames via the asynchronous channel. Each data frame includes indication of the ultrasound imaging mode and includes ultrasound-imaging-mode-specific imaging parameters. Other embodiments exist.

Abstract: Based on medical image data acquired in each time phase included in a one-cycle interval, first tracking part tracks the position of a first region of interest set in a first time phase in each time phase and tracks the position of a second region of interest set in a second time phase in each time phase. Based on position information of the first region of interest and the second region of interest in each time phase, position correction part obtains position information of a region of interest in each time phase so that it passes through the position of the first region of interest in the first time phase and the position of the second region of interest in the second time phase. Motion-information calculator obtains motion information of a tissue based on the obtained position information.

Abstract: A means to which at least two ROIs are input, a calculating means that calculates strain values of tissue with respect to the at least two ROIs by applying a pressure onto an object, and a display means that displays the strain values of the at least two ROIs so as to be compared with each other are comprised.

Abstract: Blood-flow image display equipment for displaying a CFM image that is not affected by a motion of a tissue in an object area during capturing of images or is affected in a reduced manner.

Abstract: An ultrasound-imaging system and method is provided that permits an operator to acquire an image of a volume-of-interest in a time critical fashion, that is capable of referencing the volume rendering to a standard two-dimensional imaging mode, and permits the operator to selectively choose a number of display-mode parameters that result in an operator directed view of the volume-of-interest. The ultrasound-imaging system comprises an input device configured to receive a plurality of imaging parameters and a controller in communication with the input device. The ultrasound-imaging system generates an operator-directed transmit-beam scan sequence in response to the imaging parameters and transmits a spatially modified transmit-beam scan sequence over a portion of the volume-scan range of the ultrasound-imaging system. Moreover, the ultrasound-imaging system provides the flexibility for an operator to direct a plurality of operator-configurable multi-dimensional views.

Abstract: An ultrasonic diagnosis apparatus and method wherein both imaging of a contrast effect and imaging of a tissue appearance before and after inflow of a contrast medium can be realized on condition that low-power transmission and a high frame rate are maintained. The ultrasonic diagnostic apparatus includes a transmission/reception unit for transmitting subject ultrasonic waves with a band substantially centered at a fundamental frequency and generating a received signal based on an ultrasonic echo from the subject, a harmonic unit for extracting a signal of a harmonic component of the fundamental frequency included in the received signal and extracting a signal of the fundamental component with the band substantially centered the fundamental frequency included in the received signal, and a display unit for generating a display image based on the extracted harmonic and fundamental components.

Abstract: A method of three-dimensional (3D) ultrasound imaging comprises acquiring ultrasound data representative of an imaging volume as a function of time, from which can be obtained a plurality of two-dimensional images, and acquiring data from a stationary ultrasound beam concurrently with the acquiring of the ultrasound data representative of the imaging volume. The stationary ultrasound beam data is analyzed to derive a parameter from the stationary ultrasound beam data. The method further includes rearranging a plurality of 2D ultrasound images obtained from the acquired ultrasound data for 3D processing as a function of the derived parameter. In one embodiment, acquiring data from the stationary ultrasound beam comprises one or more of an M-mode acquisition, a Doppler mode acquisition, or an acquisition tailored to a specific ultrasound imaging application.

Abstract: An ultrasound medical imaging system and non-ultrasound medical imaging system are combined and communicate via a suitable docking port, which is supported by the non-ultrasound medical imaging system and configured to receive the ultrasound medical imaging system. The systems can communicate directly, indirectly, and/or wirelessly. Each can also be configured for cross-imaging in the other modality, displaying medical imagery from the other modality on respective and/or combined displays, and/or control by a user interface of the other and/or a common user interface. Registry between patient imagery is possible, and improved workflow is provided.

Abstract: An interactive graphical user interface (GUI) for displaying frequency, amplitude and direction information provided by an intelligence system is provided comprising: a plot of RF versus amplitude, and a graph of frequency versus direction. The intelligence system has a front end to generate digital data based on received radio frequency (RF) signals, a post processing stage to process the digital data, and a direction finding stage to prevent the post-processing stage from processing portions of the digital data that correspond to RF signals arriving from a direction other than a predetermined direction. The GUI is updated continuously in near real time. Methods of operating the GUI are also provided.

Abstract: An ultrasound system and a method of controlling the ultrasound system are provided. The ultrasound system may receive, from a user, a selection command for a first mode among a plurality of display modes, set a target region based on region setting information that is input from the user, when the first mode is a wide mode, and extract an ultrasound image in the target region when an image extraction command is input from the user.

Abstract: Certain embodiments of the present invention include methods, systems, and computer readable media for real-time structure suppression in ultrasonically scanned volumes. A method includes receiving a plurality of datasets, each of said plurality of datasets representative of an ultrasonically scanned volume. The method further includes automatically applying in real-time a suppression filter to said plurality of datasets to form a plurality of filtered datasets, wherein at least two of said plurality of filtered datasets are sequenceable to form a data stream.

Abstract: Unipolar, bipolar or sinusoidal transmitters may leave the transmitter in any of various states at the end of one pulse. Undesired acoustic energy may be generated to change states prior to beginning another transmit sequence or pulse. For example, phase inversion for tissue harmonic imaging is performed where two sequential pulses are transmitted with different phases. The first waveform starts at a low state and ends at the low state of a unipolar transmitter. The next waveform starts at the high state. Transmit apodization or spectrum control techniques may require a pattern of waveform starting states different than a current state. Acoustic disruption due to a change of state of the transmitter between transmissions for imaging is minimized.

Abstract: An ultrasonic diagnosis system includes an ultrasonic probe, which has an array of plural ultrasonic transducer elements, for transmitting an ultrasonic wave to an object, and for receiving an echo signal thereof to output a detection signal. A testing unit sets a testing mode, and operates in test operation of the plural ultrasonic transducer elements while the testing mode is set, so as to acquire a testing detection signal. There is a display panel. A display control unit controls the display panel to display information of the testing detection signal obtained for each of the ultrasonic transducer elements. Furthermore, the testing unit, when in a first inspection, drives the ultrasonic transducer elements together to obtain the testing detection signal, and when in a second inspection, drives the ultrasonic transducer elements by at least one element to obtain the testing detection signal.

Abstract: In a medical image diagnosis apparatus which forms a scanogram image of a subject and forms tomographic images under imaging conditions set by using the scanogram image, an imaging condition setting frame 33 independent of the scanogram image 31 is provided on a monitor 14. Desired imaging for which imaging conditions are to be set is designated by inputting a numeric value presenting an ordinal number for imaging in a numeric value input box 40 in the imaging condition setting frame 33. A pointer is set to a frame 41, a mark 42 or a dotted line 43 and dragged, thus enabling imaging conditions indicating the number of instances of imaging and image reconstruction and image reconstruction positions for the designated imaging. Settings in the imaging condition setting frame 33 are reflected in a frame 32A and lines 32B on the scanogram image 31 indicating the number of instances of imaging and image reconstruction and image reconstruction positions.

Abstract: Using compression, tissue elasticity data from two or more different fields of view is acquired. Since different amounts of compression may be used for the different fields of view, the dynamic range of the elasticity data is updated. A panoramic elasticity image is generated from the updated elasticity data of multiple fields of view. A panoramic elasticity image represents the combined fields of view for the elasticity data.

Abstract: Disclosed herein is a method for obtaining a composite interference-free ultrasound image when non-imaging ultrasound waves would otherwise interfere with ultrasound imaging. A conventional ultrasound imaging system is used to collect frames of ultrasound image data in the presence of non-imaging ultrasound waves, such as high-intensity focused ultrasound (HIFU). The frames are directed to a processor that analyzes the frames to identify portions of the frame that are interference-free. Interference-free portions of a plurality of different ultrasound image frames are combined to generate a single composite interference-free ultrasound image that is displayed to a user. In this approach, a frequency of the non-imaging ultrasound waves is offset relative to a frequency of the ultrasound imaging waves, such that the interference introduced by the non-imaging ultrasound waves appears in a different portion of the frames.

Abstract: An ultrasonic imaging apparatus, including an ultrasonic probe including an ultrasonic vibration element configured to transmit and receive an ultrasonic wave in a scanning direction in an object in which a contrast media has been injected; a transmission unit configured to apply successive drive pulses to the probe so as to transmit respective ultrasonic signals in respective rate sections; a reception unit configured to receive reflected ultrasonic signals, including first reflected ultrasonic signals produced by a first drive pulse in a first rate section and reflected back to the probe in the first rate section and in a second rate section subsequent to the first rate section; an operation unit configured to perform an operation including at least one of addition and subtraction of at least two of the first ultrasonic signals received during different rate sections; and a signal processor configured to produce image data based on the result of the operation performed by the operation unit.

Abstract: Multiple scanning modes are provided. In a survey mode, imaging is provided without synthetic elevation aperture processing. For greater detailed imaging, imaging is responsive to synthetic elevation aperture processes with different elevation focusing and scanning.

Abstract: The present invention relates to a method for assisting with percutaneous interventions, wherein 2D x-ray images of an object region are recorded before the intervention using a C-arm x-ray system or a robot-based x-ray system at different projection angles and 3D x-ray image data of the object region is reconstructed from the 2D x-ray recordings. One or more 2D or 3D ultrasound images are recorded before and/or during the intervention using an external ultrasound system and registered with the 3D image data. The 2D or 3D ultrasound images are then overlaid with the 3D image data record or a target region segmented therefrom or displayed next to one another in the same perspective. The method allows a puncture or biopsy to be monitored with a low level of radiation.

Abstract: A method and apparatus for lesion or organ definition for the purpose of radiation treatment planning localization and treatment position verification. The apparatus uses a combination of an ultrasound imaging system and a diagnostic imaging system to acquire localization ultrasound images referenced in the coordinate space of the diagnostic imaging system through the use of a position sensing system. The method compares the location of the lesion in the localization ultrasound images with the position of the lesion in ultrasound images taken while the patient lies on the treatment table of a therapy treatment unit, suggests corrective measures to place the lesion in its intended treatment position and executes the correction upon confirmation from qualified personnel.

Abstract: A diagnostic imaging apparatus includes an image generation device for generating a plurality of images of a subject for display in a display device, the plurality of images including a first image generated for display at a first display magnification and other images generated for display at other display magnification different from the first display magnification, and a marking setting device which sets a first marking to indicate a region of interest on the first image and other markings on the other images, the other markings being displayed, based on the other display magnification, in a position corresponding to the position of the first marking set on the first image.

Abstract: An ultrasound system is provided that includes a display processor that accesses data volumes stored in an image buffer successively to control generation of at least one of 2D and 3D renderings based on display parameters. The display processor obtains from the image buffer a first data volume defined based on first scan parameter values, while a probe acquires ultrasound information for a second data volume that is entered into the image buffer. The second data volume is defined based on second scan parameter values. A navigation view presents in real time the renderings generated by the display processor with their corresponding 31) orientation. A navigator is provided that controls the display of the navigation view in real time such that, as the user adjusts a display parameter value to change a view plane, images presented in the navigation view are updated to reflect the view plane.

Abstract: An ultrasonic imaging device for transmitting/receiving ultrasonic pulses to/from a living body in which microbubbles for contrast are introduced and forming a contrast image of the inside of the living body by using the microbubble for contrast, wherein transmitting/receiving operations are performed N times (N=an integer of three or greater) by using transmission pulse waves having a common envelope signal while varying carrier waves in phase by 360°/N from one wave to another under the same transmission/reception wave focus condition, and by summing N pieces of time-series reception echo signals obtained by the N times of transmitting/receiving operations to obtain a summed signal, thereby forming the contrast image.

Abstract: The present invention is directed to a system and method in which a portable medical device supports simultaneous imaging and monitoring applications. This portable device includes an external controller for receiving a PDA/MDA via a communication bus. An ultrasound scan head also is preferably attached to the external controller via an interconnect. In operation, real-time video feed of the patient may be acquired using the device and then displayed on the PDA/MDA. Using the ultrasound scan head in conjunction with the external controller, images may be acquired and displayed on the PDA/MDA, and vital sign monitoring of a single patient or multiple patients may be performed. Video feed, images and/or monitoring information may be transferred to a remote expert for review and analysis on the remote expert's communication device.

Abstract: The present invention relates to an ultrasound system. The ultrasound system includes: an image processing unit for forming at least one 3-dimensional ultrasound image based on ultrasound echoes reflected from a target object; an input unit for receiving a setup instruction; and a control unit for outputting a first control signal for setting at least one predefined sample volume on the 3-dimensional ultrasound image in response to the setup instruction. The image processing unit is further configured to form at least one spectral Doppler image corresponding to the sample volume in response to the first control signal.

Abstract: Devices, systems and methods for measuring and detecting properties of a variety of particles or cells in suspension. Properties, such as, for example, velocity of particles, concentration and/or size may be measured according to the methods of the invention. Acoustic energy may be introduced to a focal zone and narrow band interrogating signals may be used. The acoustic energy may cause movement or streaming of the fluid or suspension. The acoustic streaming may allow a Doppler effect measurement without any other source of velocity.

Abstract: The preferred embodiments described herein provide a method and system for facilitating selection of stored medical images. In one preferred embodiment, a plurality of medical images are stored, and, for each medical image, the settings of at least one acquisition time control used to create the image are also stored. During image review, a user selects a set of acquisition time control settings, and a set of medical images is automatically selected from the stored images based on the selected set of acquisition time control settings. Other preferred embodiments are provided, and each of the preferred embodiments described herein can be used alone or in combination with one another.

Abstract: An ultrasound diagnostic apparatus of the invention includes: a plurality of transducer groups provided to a distal end portion of a probe, for scanning in planes that are orthogonal to each other; display portion including a display screen capable of simultaneously displaying a plurality of ultrasound images obtained by the scanning by the respective transducer groups; and image synthesis portion for displaying, on the display screen, selected one of a plurality of aspects of display wherein the positional relation of the plurality of transducer groups on the probe and the positional relation of the plurality of ultrasound images on the display screen are the same. The ultrasound diagnostic apparatus can thus provide simultaneous display of a plurality of ultrasound images and good operability.

Abstract: Plural strain gauges which are folded lines defined by gauge end points and gauge middle points are set up every time phase using motion vector information of a tissue and a strain gauge image in which the strain gauges are overlapped at a corresponding position of an ultrasonic image at each time phase is generated and displayed. A rotation angle from a reference time phase is calculated, rotational difference information between the gauge end points is generated and displayed in a predetermined form for the respective gauge end points (and the gauge middle points if necessary).

Abstract: An ultrasonic diagnostic apparatus includes an ultrasonic transmission/reception unit and an image generating unit. The ultrasonic transmission/reception unit transmits a first ultrasonic pulse having a maximum amplitude in a positive pressure, a second ultrasonic pulse having a maximum amplitude in a negative pressure and a third ultrasonic pulse derived by compounding the first ultrasonic pulse with the second ultrasonic pulse into an object in which a contrast medium is injected and obtains first, second and third reception echoes corresponding to the first, second and third ultrasonic pulses respectively. The image generating unit generates a compounded signal which is a nonlinear component from the contrast medium by a linear calculation of the first, second and third reception echoes and generates image data of the object by using the compounded signal.

Abstract: The present invention relates to an ultrasound system, which includes: a transmit/receive unit for transmitting ultrasound signals toward a target object having reflectors along scan lines and receiving ultrasound echo signals reflected from the target object to form receive signals based on the ultrasound echo signals; a signal processing unit for forming image signals based on the receive signals, the image signals being indicative of locations and velocities of the reflectors in the target object; and an image processing unit for forming a 3-dimensional image 3-dimensionally indicating the velocities of the reflectors based on the image signals.

Abstract: A tomographic image and a tissue characteristic image that are in conformity with each other in terms of time-phase and positional relationships can be displayed superimposedly, thereby providing an excellent ultrasonic diagnostic apparatus that enables an easy and detailed observation of a relationship between a structure and a characteristic of a subject tissue. During an operation of ultrasonic wave transmission/reception (in a live mode), a control part (100) allows a tomographic image to be renewed continuously, displayed on a monitor (107), and stored in a tomographic image memory (110), while allowing an elastic modulus image as a tissue characteristic image to be renewed per heartbeat, displayed on the monitor, and stored in an elastic-modulus-image memory (111) as a tissue characteristic image memory.