Abstract: The present embodiments relate generally to systems and methods for controlling visualization of ultrasound image data. The systems can be configured to display a live ultrasound image feed on a touchscreen and receive input via the touchscreen to adjust imaging parameters of the live ultrasound image feed, with the input having continuous contact with the touchscreen. During the continuous contact with the touchscreen, a transitional view of the live ultrasound image feed can be displayed, with the transitional view being continuously updated to indicate previews of the live ultrasound image feed with the imaging parameters adjusted. The continuous updating can be performed in accordance with characteristics of the contact with the touchscreen and while the transitional view continues the display of the live ultrasound image feed.

Abstract: In a method and apparatus for identifying an organ structure of an examined object in magnetic resonance image data, magnetic resonance measurement data for the organ structure of the examined object are acquired by operation of a magnetic resonance scanner using a magnetic resonance sequence that specifies a sampling scheme of k-space. Magnetic resonance image data are reconstructed from the magnetic resonance measurement data. The organ structure is identified in the magnetic resonance image data. The sampling scheme of k-space is selected so as to support the subsequent identification of the organ structure in the magnetic resonance image data reconstructed from the magnetic resonance measurement data.

Abstract: A method includes acquiring an anatomical image of at least part of a head of a specific patient, the anatomical image capturing at least a selected location in the head. A personalized gripper, which is shaped based on the anatomical image to personally fit an organ of the specific patient at the selected location, and which includes a first position sensor of a position-tracking system, is fitted. The anatomical image is registered with a coordinate system of the position-tracking system, by identifying the selected location in the anatomical image and measuring a first position of the first position sensor using the position-tracking system. A medical device that includes a second position sensor of the position-tracking system, is navigated in the head of the specific patient by displaying a second position of the medical device in the head on the registered anatomical image.

Abstract: According to one embodiment, an ultrasound diagnostic apparatus comprises processing circuitry. The processing circuitry sets one of wavelengths of a plurality of light sources as a reference wavelength, normalize an intensity of light having a wavelength other than the reference wavelength, which is detected by a pair of each light irradiation unit and each optical detector, with an intensity of light having the reference wavelength, calculate a first value for each pair by nonlinear enhancement correction of a normalized light intensity, calculate a second value for the each pair by nonlinear reduction correction of an intensity of light having the reference wavelength detected by the each pair, and calculate an evaluation value based on a value obtained by multiplication of the first value and the second value for the each pair.

Abstract: A method for dual-contrast unenhanced magnetic resonance angiography includes iteratively acquiring flow-dependent slices and flow-independent slices in a region. Each iteration of the acquisition process comprises identifying a flow-dependent slice location within the region and identifying a flow-independent slice location upstream from the flow-dependent slice location according to blood flow in the region. Each iteration further includes applying a first radio frequency (RF) saturation pulse to the region such that MR signals from veins in the region are substantially suppressed, and applying a second RF saturation pulse to the flow-dependent slice location such that MR signals from background muscle and arterial blood in the region are substantially suppressed. A flow independent slice is acquired at the flow-independent slice location after the second RF saturation pulse is applied and before unsaturated arterial blood has maximally flowed into the region.

Abstract: The system includes a stand surrounding a working area, a signal detector receiving a signal generated by the wire, and a positioning module disposed on the stand. The positioning module is configured to drive the signal detector moving forward and backward on a two-dimensional plane in the working area. The system also includes a computer system electrically connected to the signal detector and the positioning module. The compute system receives the signal from the signal detector, generates position information according to the signal, and transmits the position information to the positioning module, such that the positioning module moves the signal detector to a position corresponding to a position of the wire in the blood vessel according to the position information.

Abstract: For estimating attenuation in ultrasound imaging, displacements at different locations along an acoustic radiation force impulse (ARFI) beam are used measured. The on-axis displacements and displacements from a phantom using a same ARFI focus as a reference are used to cancel out focusing effects. A single ARFI beam may be used to estimate the attenuation for a location.