Abstract: The present disclosure provides various methods and systems for performing magnetic resonance studies. In accordance with many embodiments, image or other information of interest is derived from super radiant pulses.

Abstract: A method for correcting image artifacts during the acquisition of magnetic resonance imaging data includes the following steps. At least one part of the linear, location-dependent and spatially constant interference fields arising at the measurement location is determined in a time interval between an excitation point in time and a MR data acquisition point in time.

Abstract: A device and a process for performing high temporal- and spatial-resolution MR imaging of the anatomy of a patient during intensity modulated radiation therapy (IMRT) to directly measure and control the highly conformal ionizing radiation dose delivered to the patient for the treatment of diseases caused by proliferative tissue disorders. This invention combines the technologies of open MRI, multileaf-collimator or compensating filter-based IMRT delivery, and cobalt teletherapy into a single co-registered and gantry mounted system.

Abstract: A magnetic resonance method for imaging blood volume in parenchyma via magnetic transfer (MT) includes: determining a MT effect of parenchyma; determining a MT effect of tissue; and quantifying the parenchymal blood volume using the difference between the MT effect of parenchyma and the MT effect of tissue. In one embodiment, the parenchymal blood volume is quantified through the following: MTRpar=MTRtissue(1?BV/Vpar), where MTRpar is the magnetization transfer ratio of parenchyma, MTRtissue is the magnetization transfer ratio of tissue, BV is the blood volume, and Vpar is a total parenchymal water volume.

Abstract: The present invention relates to a method and apparatus for non-invasive monitoring of brain density variations. At least two ultrasonic pulses having different frequencies are provided into the brain for transmission therethrough. The reflected ultrasonic pulses are then sensed and the sensed signal data are then processed for determining at least two phase differences between the phases of the at least two reflected ultrasonic pulses and the phases of the at least two provided ultrasonic pulses. A phase of at least a beat frequency is determined in dependence upon the at least two phase differences. Data indicative of a brain density variation are determined based on the at least two phase differences and the at least a beat frequency.

Abstract: A method for retrospectively correcting data prior to image reconstruction using an imaging system, wherein the method includes acquiring a first sinogram of a first slice of an object at a first axial field of view and a second sinogram of the first slice of the object at a second axial field of view different than the first axial field of view, determining at least one boundary of the object in the first sinogram and the second sinogram at the first slice, measuring a shift between the first sinogram and the second sinogram using the determined boundaries, and generating a corrected image using the measured shift.

Abstract: The invention has a structure, in an acoustic lens for an ultrasonic probe comprising leg portions which are connected by a planar shape, and a lens portion which is provided on the leg portions and has curvature in the lengthwise direction, wherein the leg portions are made from an attenuation prevention material having the less ultrasonic propagation loss than for the lens portion. Moreover, the leg portions of the acoustic lens are formed with opposite end sides thereof in a bent L-shape. Furthermore, an ultrasonic probe is constructed by adhering onto a piezoelectric element group where a plurality of piezoelectric elements are arranged side by side, an acoustic lens provided with curvature in the lengthwise direction.