Abstract: A magnetic resonance imaging apparatus includes a first blood flow image acquisition unit and a second blood flow image acquisition unit. The first blood flow image acquisition unit acquires a first blood flow image of a breast of an object without contrast medium. The second blood flow image acquisition unit acquires a second blood flow image without contrast medium with applying a spin labeling pulse by which a region to be tagged is set based on the first blood flow image as a reference image so as to distinguish blood flowing into a desired region.

Abstract: According to a Magnetic Resonance Imaging (MRI) apparatus, each of buttons provided in a plurality of sections included in a receiving coil receives from an operator a selecting operation of selecting a section in which the button itself is provided. A control unit of a computer system moves a table on which a subject is placed such that the center of the section selected by receiving the selecting operation via the button is positioned at the center of a magnetic field.

Abstract: An apparatus for manufacturing a device comprises a processing unit configured to perform a process for manufacturing the device, a conveying unit configured to convey an article to the processing unit, and a controller configured to control the conveying unit based on a job queue. Information for controlling conveyance of an article for a job next to a job for which the processing unit is performing the process is registered in the job queue. The controller is configured to control the conveying unit so as to convey the article for the next job in advance, based on the information.

Abstract: Disclosed is a method appropriate for safely, economically and easily producing at a high yield a 4-substituted benzothioamide derivative which is useful as an intermediate in the production of a 2-(3-cyanophenyl)thiazole derivative useful as a drug for gout. Specifically disclosed is a method for producing a 4-substituted benzothioamide derivative represented by formula (A).

Abstract: A magnetic resonance imaging apparatus includes a movement unit which moves a subject placed in a static magnetic field, a collector which collects data corresponding to a magnetic resonance signal emitted from the subject, a detector which detects a position of a particular section of the subject in the static magnetic field, a reconstruction unit which reconstructs an image, based on the collected data, when the detected position falls within an allowable area, and a controller which controls the movement unit to compensate for a deviation of the detected position from a reference position.

Abstract: A magnetic resonance imaging (MRI) system includes an ECG detector for the patient object being imaged and an element for performing an MRI pulse sequence. An imaging unit defined by the pulse sequence is longer in temporal length than one heart beat represented by the ECG signal. An MR signal is acquired from the object in response to the pulse sequence and an MR image based on the acquired MR signal is produced. A plurality of divided MT pulses can be applied instead of the conventional single MT pulse. In this case, an SE-system pulse sequence having a shorter echo train spacing is used, to generate sounds by applying gradient pulses incorporated in an imaging pulse sequence so as to automatically instruct a patient to perform an intermittent breath hold during three-dimensional scanning.

Abstract: A storage unit stores a parameter list that defines a method of creating scanning conditions for a preparation scan from scanning conditions set for a main scan, with respect to each type of scanning. A scanning-condition edit/scan positioning unit receives an operation of selecting a type of a preparation scan, and when the operation of selecting the type of the preparation scan is received, the scanning-parameter limit calculating unit acquires the parameter list corresponding to the type of the preparation scan, from among the parameter lists stored by the storage unit, creates scanning conditions for the preparation scan from scanning conditions set for a main scan based on the parameter list corresponding to the type of the preparation scan. The pulse-sequence execution-data creating unit then causes execution of the preparation scan based on the created scanning conditions.

Abstract: A magnetic resonance imaging (MRI) system obtains an MR image of an object. The system detects an ECG signal and performs a pulse sequence of RF gradient magnetic fields toward the object. Imaging defined by the pulse sequence is longer in temporal length than one heartbeat. The system further acquires an MR signal from the object in response to performance of the pulse sequence and produces the MR image based on the acquired MR signal. Also possible are: a plurality of divided MT pulses instead of the conventional single MT pulse, an SE-system pulse sequence having a shorter echo train spacing, and the generation of sounds by applying gradient pulses incorporated in an imaging pulse sequence so as to automatically instruct a patient to perform an intermittent breath hold.

Abstract: A magnetic resonance diagnostic apparatus is configured in such a manner that: a high-frequency transmission coil transmits a high-frequency electromagnetic wave at a magnetic resonance frequency to an examined subject; a heating coil performs a heating process by radiating a high-frequency electromagnetic wave onto the examined subject at a frequency different from the magnetic resonance frequency; based on a magnetic resonance signal, a measuring unit measures the temperature of the examined subject changing due to the high-frequency electromagnetic wave radiated by the heating coil; and a control unit exercises control so that the measuring unit measures the temperature while the heating coil is performing the heating process, by ensuring that the transmission of the high-frequency electromagnetic wave by the high-frequency transmission coil and the radiation of the high-frequency electromagnetic wave by the heating coil are performed in parallel.

Abstract: An image processing method generates two-dimensional images, each of which are respectively in accordance with left and right breasts of a subject using three-dimensional image data of the left and right breasts. A comparison two-dimensional combined image is generated, wherein the left and right breast images are disposed symmetrically. The comparison two-dimensional combined image is displayed on a display unit.

Abstract: To execute printing on a continuous sheet by using a printing unit, a printing control apparatus includes a reversal unit, an input unit, and a printing control unit. The reversal unit reverses the continuous sheet to execute printing on a second surface of the continuous sheet after executing printing on a first surface of the continuous sheet. The input unit inputs an instruction for executing an interruption print job while executing printing by the printing unit. If instruction for executing the interruption print job is input while the printing of a two-sided print job on the continuous sheet has been currently executed, the printing control unit suspends the two-sided print job, causes the printing unit to execute the interruption print job, and resumes processing of the two-sided print job on the continuous sheet that has been held by the reversal unit after the interruption print job is completed.

Abstract: A Signal-to-Noise (SN) ratio maintained scanning-condition recalculating unit re-sets a value of a scanning parameter other than an SN ratio included in scanning conditions when the size of a Field Of View (FOV) to be set for a scan is changed, so as to make the SN ratio of an image to be taken under after-change scanning conditions equal to or larger than the SN ratio of an image assumed to be taken under before-change scanning conditions. A scanning-condition edit/scan positioning unit then sets scanning conditions based on the value of the scanning parameter recalculated by the scanning-condition recalculating unit.

Abstract: A flip-angle calculating unit calculates a flip angle of a fat-suppression pulse by inputting scanning parameters read from a scanning-parameter storage unit based on scanning conditions set by a scan-condition setting unit and a desired fat-suppression level, into a predetermined computing program. A control unit suppresses fat signals to a desired level by performing irradiation of a fat-suppression pulse having the calculated flip angle and application of a spoiler gradient magnetic field onto a scan target portion of a subject by controlling a gradient magnetic-field generating unit and a transmitting-receiving unit, and further performs irradiation of an RF pulse and application of a gradient magnetic field in accordance with a predetermined pulse sequence, thereby detecting water signals and suppressed fat signals as MR signals. An image-data creating unit creates image data by reconstructing the MR signals.

Abstract: A medical image diagnostic apparatus has an imaging unit that images volume data of a region-of-interest of an object, an extracting unit that extracts a characteristic point from the volume data; and, a generating unit that generates an observation sectional image from the volume data using the characteristic point and correlation parameters.

Abstract: A magnetic resonance imaging apparatus according to an embodiment includes a data gathering unit and an image generating unit, the data gathering unit gathers magnetic resonance data in a non-contrast manner by applying a first readout gradient pulse having a zero-order moment of 0 and a second readout gradient pulse having a zero-order moment of 0 and a first-order moment of a value different from a value of a first-order moment of the first readout gradient pulse to a region of interest including a fluid in motion, and the image generating unit periodically arranges first magnetic resonance data read out with the first readout gradient pulse and second magnetic resonance data read out with the second readout gradient pulse in at least one of a phase encoding direction and a slice encoding direction in a k-space to generate k-space data and reconstructs the k-space data to generate an image in which a fluid image and a static part image surrounding the fluid are spatially separated from each other.

Abstract: A display device includes: a display element for showing information as a screen image; and an ornamental member disposed on a display surface of the display element and having a shape corresponding to the screen image. The ornamental member includes a light transparent element and a light nontransparent element. The screen image includes a designed image on a position of the display surface corresponding to the light transparent element. The display element outputs a screen image light from the display surface. The screen image light corresponding to the designed image passes through the light transparent element so that the screen image light is outputted from the ornamental member to the display side.

Abstract: A storage unit stores a parameter list that defines a method of creating scanning conditions for a preparation scan from scanning conditions set for a main scan, with respect to each type of scanning. A scanning-condition edit/scan positioning unit receives an operation of selecting a type of a preparation scan, and when the operation of selecting the type of the preparation scan is received, the scanning-parameter limit calculating unit acquires the parameter list corresponding to the type of the preparation scan, from among the parameter lists stored by the storage unit, creates scanning conditions for the preparation scan from scanning conditions set for a main scan based on the parameter list corresponding to the type of the preparation scan. The pulse-sequence execution-data creating unit then causes execution of the preparation scan based on the created scanning conditions.

Abstract: According to one embodiment, a magnetic resonance imaging apparatus includes an electrocardio information acquisition unit and an image data generation unit. The electrocardio information acquisition unit acquires a magnetic resonance signal for estimating an electrocardiogram signal of an object in sync with a biomedical signal other than an electrocardiogram signal. The biomedical signal is acquired from the object and shows a cardiac beat. The electrocardio information acquisition unit further determines a time difference between a position of a reference wave of the electrocardiogram signal and a synchronous position of the biomedical signal. The position of the reference wave is estimated from the acquired magnetic resonance signal.

Abstract: A magnetic resonance imaging apparatus includes a first blood flow image acquisition unit and a second blood flow image acquisition unit. The first blood flow image acquisition unit acquires a first blood flow image of a breast of an object without contrast medium. The second blood flow image acquisition unit acquires a second blood flow image without contrast medium with applying a spin labeling pulse by which a region to be tagged is set based on the first blood flow image as a reference image so as to distinguish blood flowing into a desired region.

Abstract: An ECG-prep scan is used to set an optimum time phase in both systole and diastole of the heart. At each of the different time phases, an imaging scan is started to acquire a plurality of sets of echo data. An artery/vein visually separated blood flow image is produced from the echo data. The imaging scan uses a half-Fourier technique, for example. This provides high-quality blood flow images with shorter scan time, without injecting a contrast medium. Additionally, with a readout gradient pulse applied substantially parallel with a direction of slowly flowing blood, a scan is performed in synchronism with an optimally determined cardiac time phase. The readout gradient pulse has a dephasing pulse for enhancing differences in a flow void effect depending on blood flow velocities. This enables slow-speed flows, such as blood flows in the inferior limb, to be depicted without fail.