Abstract: A method and apparatus for quantifying and displaying ultrasound signals in an ultrasonic system are provided. A first signal value for each of at least one spatial location in a region of interest is acquired at a first time, and the signal values are summed to obtain a first surface integral value. A second signal value for each of said at least one spatial location in said region of interest is acquired at a second time, and the second signal values are summed to obtain a second surface integral value. The first surface integral value is summed with the second surface integral value to obtain a time based integral. The time based integral is displayed. Other quantities based on any of various ultrasound parameters, such as Doppler energy, Doppler velocity and B-mode intensity, are calculated and displayed as quantities or as waveforms as a function of time. Furthermore, various comparisons of quantities and waveforms are provided. Image plane data or other ultrasound data are used in the calculations.

Abstract: The present invention provides for methods and devices for monitoring cardiovascular performance. The invention also includes methods of measuring capillary related interstitial fluid, as well as cardiac and vascular function. Specific devices, particularly probes, are provided for such methods.

Abstract: An arrangement for measuring the blood flow from a multitude of individual flow measuring units (11, 11′) arranged next to one another. The multitude of individual flow measuring units arranged next to one another permit a quick placing on of the measuring arrangement. Independently of the exact location on the human body on which the measuring arrangement is placed, always one artery, in particular the carotid artery lies neighbouring at least one of the flow measuring units.

Abstract: A method and system for obtaining ultrasound data with a sparse array of transducer elements is provided. About one wavelength of a highest operating frequency separates the center of each transducer element from any adjacent transducer element. While this spacing may generate grating lobes, the beamformer of the ultrasound system is configured to filter and isolate information at a harmonic of a fundamental transmit frequency. The resultant two-way beam pattern is less effected by the grating lobes. The image generated as a function of the harmonic information has few artifacts created as a function of the sparse spacing of the transducer elements. Given a set number of beamformer transmit channels, the sparse spacing may allow for a larger aperture width with few artifacts as a result of sparse element spacing. The larger aperture width generates a narrower beam in the azimuthal dimension of a one-dimensional transducer. By generating a narrower beam, better azimuthal resolution may be obtained.

Abstract: An ultrasound contrast medium which substantially consist of microbubbles is injected into a patient and contrast echo imaging is performed by a diagnostic ultrasound apparatus. In the apparatus, an ultrasound pulse signal is transmitted toward the patient's diagnostic region on the basis of a changeable transmitted sound pressure, an echoed component of the transmitted ultrasound pulse signal is received to produce a corresponding reception signal, a tomographic image using the reception signal is produced, and the transmitted sound pressure is optimized so as to maximize a value of the reception signal. The transmitted sound pressure is a representative of the transmission power condition. For example, the transmitted sound pressure optimized is displayed. The transmitted sound pressure is, by way of example, optimized based on the reception signal corresponding to the echoed component emanating from an overall region of interest in a cross section scanned by the ultrasound pulse signal.

Abstract: An ultrasound imaging system having an adaptive spatial filter the filter coefficients of which, for particular image parameter sample, are determined by counting the number of neighboring image parameter samples having zero or near-zero values. If the number of zero or near-zero values in a data window is greater than a predetermined threshold, the data in the window is passed, not filtered. This filter has two advantages over other spatial filters. First, image parameter data samples having only zero or near-zero neighboring values (i.e., isolated "point noise") are not smeared. Second, boundaries such as the edge of color in a vessel (where the surrounding area is black, i.e., the color image parameter values are zero or near zero) are not smoothed as much as in conventional filters, preserving the sharpness of the edge.

Abstract: A three-dimensional image of flowing fluid or moving tissue using velocity or power Doppler data is displayed by using an ultrasound scanner that collects velocity or power data in a cine memory to form a volume of pixel data. Average or median pixel values are projected on an image plane by casting rays through the data volume. As the ray passes through each scan plane, a data value is assigned to the ray at that point. At each scan plane, the assigned pixel data value is tested to see if it exceeds a noise threshold. For a given ray, pixel data values above the detection threshold are accumulated until a pixel data value falls below the detection threshold. A minimum number of pixel data values exceeding the threshold are required for each ray before the average of the accumulated values is processed and/or the median value is selected. When all pixels along a given ray have been tested, the projection is complete and the average or median projection is then displayed.