Abstract: A computed tomography apparatus capable of confirming the positional relationship of an imaging region and a field of view in a real space at the time of determining the position of the imaging region. The computed tomography apparatus according to an embodiment comprises a couch that moves a top board on which a subject is placed. A gantry comprises an opening into which a top board is inserted. A light projection part is provided in the gantry. A setting part sets a field of view with respect to the subject. A controller causes light indicating the set field of view to be projected by controlling the light projection part.

Abstract: A respiration suppressing member includes a main body of an elastic material which is formed into a shape having a pressurizing portion for pressurizing that portion of the abdomen of a subject under imaging diagnosis by a medical modality which is located below the sternum and between the right and left ribs of the subject.

Abstract: MRI apparatus includes an RF coil device, a first radio communication unit, a second radio communication unit, an image reconstruction unit and a judging unit. The RF coil device detects an MR signal, and includes a data saving unit for storing the MR signal. The first radio communication unit wirelessly transmits the MR signal detected by the RF coil device, and the second radio communication unit receives the MR signal from the first radio communication unit. The image reconstruction unit reconstructs image data using the MR signal. The judging unit judges existence of a transmission error in radio communication between the first and second radio communication units. If the transmission error is present, the first radio communication unit wirelessly transmit the MR signal stored in the data saving unit to the second radio communication unit.

Abstract: An apparatus for determining a contour of a treatment region in a patient includes a computer processor to receive input regarding a contour of at least one organ-at-risk (OAR) adjacent to the treatment region; receive input regarding an initial contour of the treatment region; predict a radiation toxicity to the at least one OAR based on the contour of the at least one OAR, the initial contour of the treatment region, and a radiation treatment regimen; determine whether the predicted radiation toxicity exceeds a threshold; and determine a contour of the treatment region by iteratively modifying the initial contour of the treatment region, and any subsequent modified contours of the treatment region, until a stopping condition is satisfied. The stopping condition can be a preselected number of iterations or that the predicted radiation toxicity using the contour in place of the initial contour is first calculated is below said threshold.

Abstract: A medical image processing apparatus according to one embodiment includes obtaining circuitry, calculating circuitry, and transforming circuitry. The obtaining circuitry takes an expiration time phase or an inspiration time phase as a benchmark time phase and obtains a benchmark line structure, which is a line structure of a bronchus in a lung field, from a medical image at the benchmark time phase. The calculating circuitry calculates a motion amount between a component depicted in the medical image at the benchmark time phase and a component depicted in a medical image at at least one other time phase than the benchmark time phase. The transforming circuitry transforms the benchmark line structure based on the motion amount to obtain an estimated line structure, which is estimated as a line structure at the at least one other time phase.

Abstract: In an X-ray CT apparatus, an annular rotating body includes an X-ray tube and an opening portion accommodating a radiator that discharges heat from the X-ray tube and into which a bed can be inserted. A stand includes a frame disposed in a rear portion of the annular rotating body, and supports the annular rotating body to be rotatable about an axis. A cover which covers the annular rotating body and the stand includes an exhaust port. A cooling mechanism, disposed at a position away from a position of the exhaust port along a circumferential direction of the annular rotating body between an outer circumferential surface of the annular rotating body and cover, includes a fan disposed at the stand. A duct receives exhaust air from the fan at a rear position of the fan between the frame and cover, and leads from the fan to the exhaust port.

Abstract: An X-ray CT apparatus includes: intensity distribution data acquiring circuitry is configured to acquire, by performing a first scan, intensity distribution data of X-rays being radiated from an X-ray tube and having passed through a subject; scan controlling circuitry is configured to estimate an X-ray dose with which it is possible to discriminate individual X-ray photons having passed through the subject based on the intensity distribution data and to cause a second scan that is for a photon counting CT purpose to be performed by causing the estimated dose of X-rays to be radiated from the X-ray tube to the subject; a counting result acquiring circuitry is configured to acquire, by the second scan, a counting result by counting the X-ray photons being radiated from the X-ray tube and having passed through the subject; and an image reconstructing circuitry is configured to reconstruct X-ray CT image data based on the counting result.

Abstract: According to one embodiment, a structuring circuitry temporarily structures a dynamical model of analysis processing based on the time-series medical image. The identification circuitry identifies a latent variable of the dynamical model so that at least one of a prediction value of a blood vessel morphology and a prediction value of a bloodstream based on the temporarily structured dynamical model is in conformity with at least one of an observation value of the blood vessel morphology and an observation value of the bloodstream measured in advance. The analysis circuitry analyzes the dynamical model to which the identified latent variable is allocated.

Abstract: There is provided a medical image display apparatus comprising a storage unit which stores data of a plurality of different types of medical images including the same region of a subject to be examined which are generated by the same type of image generating device, and a display control unit which displays the plurality of medical images at substantially the same position on a screen while sequentially switching the medical images one by one.

Abstract: According to one embodiment, an ultrasonic diagnostic apparatus sets a desired period with reference to a predetermined time phase in each heartbeat of the object, sequentially executes ultrasonic scanning on a plurality of sub-volumes in a period including the diagnosis period to acquire sub-volume data corresponding to a plurality of time phases, controls acquisition timing of the sub-volume data from a time point elapsed from the predetermined time phase by a predetermined period of time while switching the sub-volume, generates composite sub-volume data or a full volume data constituted by a plurality of sub-volume data by performing combining processing of the sub-volume data acquired in the different diagnosis periods, detects at least one of a cyclic change of a heartbeat signal and a change in the number of sub-volume data acquired in the one diagnosis period and performs combining processing of sub-volume data based on a detection result.

Abstract: According to one embodiment, a medical image diagnostic apparatus includes a storage memory, processing circuitry, and a display. The storage memory stores data of a plurality of FFR distribution maps constituting a time series regarding a coronary artery, and data of a plurality of morphological images corresponding to the time series. The processing circuitry converts the plurality of FFR distribution maps into a plurality of corresponding color maps, respectively. The display displays a plurality of superposed images obtained by superposing the plurality of color maps and the plurality of morphological images respectively corresponding in phase to the plurality of color maps. The display restricts display targets for the plurality of color maps based on the plurality of FFR distribution maps or the plurality of morphological images.

Abstract: According to one embodiment, an automatic analyzing apparatus includes a reagent depository, a reagent storage unit and a probe. The reagent depository stores a first reagent vessel. The reagent storage unit is provided separately from the reagent depository and in which a second reagent vessel is placeable. The probe suctions a reagent contained in the first reagent vessel at a first position which is located above the reagent depository, suctions a reagent contained in the second reagent vessel at a second position which is located above the reagent storage unit, and discharges the reagent suctioned from the first reagent vessel or the second reagent vessel into a reaction vessel at a third position.

Abstract: According to one embodiment, a medical image diagnosis apparatus includes a gantry, a first frame, a second frame, a support base, and control circuitry. The first frame supports a table top. The table top is movable in a longitudinal direction of the table top. The second frame supports the first frame. The first frame is movable in the longitudinal direction. The support base is equipped with an X link that supports the second frame. The second frame is movable in a direction vertical to a floor surface. The control circuitry moves the first frame in the longitudinal direction based on operation information of a drive shaft of the support base to correct a change in position of the first frame in the longitudinal direction in accordance with movement of the second frame in the vertical direction.

Abstract: Devices and methods are provided for shutting down a magnet system. The device includes a portable housing, a communication unit, and a switch on the portable housing. The portable housing encloses a field shutdown initiation circuitry. The communication unit is disposed at least partially in the portable housing and the communication unit is configured to establish communication between the field shutdown initiation circuitry and the magnet system. The switch is configured to turn on the field shutdown initiation circuitry to initiate a magnet field shutdown in the magnet system.

Abstract: An X-ray computer-tomography (CT) apparatus includes an X-ray detector, a reading unit, and a read control unit. The X-ray detector has a first region and a second region at least a part of which is aligned with the first region along a channel direction, the first region in which a plurality of first detection devices that detect X-rays are arranged, the second region in which a plurality of second detection devices having a width smaller in a slice direction than that of the first detection device are arranged. The reading unit reads a signal of the X-rays detected. The read control unit adjusts timing of reading signals from the first detection device and the second detection device according to difference between the size of the first and the second detection device in such a manner that time difference in the reading signals in the slice direction decreases.

Abstract: According to one embodiment, a medical image processing apparatus includes a storage circuit and processing circuitry. The storage circuit stores correction data for emergency and/or correction data for normal time. The processing circuitry outputs a command to perform imaging of a patient and acquire radiographic data, and determines whether imaging time of the patient is in a first period during which temperature of an X-ray detector is stable or in a second period during which the temperature is not stable, before the imaging of the patient. In addition, the processing circuitry corrects the radiographic data by using the correction data for emergency when the imaging time is in the second period, and corrects the radiographic data by using the correction data for normal time when the imaging time is in the first period.

Abstract: According to one embodiment, an X-ray CT apparatus includes a rotating body configured to house an X-ray tube which irradiates X-rays on an object; at least one weight configured to be housed in the rotating body and to adjust balance of the rotating body; a sensor configured to detect fluctuation amount in a front-back direction approximately orthogonal to a rotating surface of the rotating body; processing circuitry configured to determine moving amount of the weight based on the fluctuation amount in a front-back direction detected by the sensor; and at least one weight moving mechanism configured to be housed in the rotating body and to move a position of the weight based on the moving amount determined by the determination unit.

Abstract: According to one embodiment, an image interpretation report creating apparatus that creates an image interpretation report including a finding and is associated with a key image, includes a key image selecting unit, a position detecting unit, a first local structure information generating unit, and a display. A key image selecting unit selects a sub-image as the key image from among a plurality of sub-images comprising a medical image. A position detecting unit detects a position of a characteristic local structure in a human body from the medical image. A first local structure information generating unit identifies a local structure in the key image or in a vicinity of the key image and generates information on the identified local structure as first local structure information. A display displays the first local structure information as a candidate to be entered in an entry field for the finding.

Abstract: A medical image processing apparatus according to an embodiment includes processing circuitry. The processing circuitry obtains a plurality of medical image groups in which respective motions of a part inside a subject have been photographed in time series and executes certain processing on the acquired medical image groups. The processing circuitry analyzes the motions in the respective medical image groups. The processing circuitry generates a medical image in which the motions in the respective medical image groups substantially match with each other based on the analyzed motions.

Abstract: According to one embodiment, an X-ray CT apparatus includes a gantry, a table on which an object is placed, a bed, and processing circuitry. The gantry is equipped with an X-ray source and an X-ray detector. The bed includes a moving mechanism which is configured to move the table in a horizontal direction and in a vertical direction. The processing circuitry performs a main scan and a prescan. The prescan is performed prior to the main scan. The processing circuitry calculates displacement of the table in the vertical direction and also calculates an angle of the table from the horizontal direction using data acquired in the prescan, and controls a position of the table and an angle of the gantry based on the displacement of the table and the angle of the table.