Abstract: An image processing apparatus includes: an image acquisition unit that acquires a plurality of endoscope images obtained by imaging an observation target at different times with an endoscope; a blood vessel extraction unit that extracts blood vessels of the observation target from the plurality of endoscope images; a blood vessel information calculation unit that calculates a plurality of pieces of blood vessel information for each of the blood vessels extracted from the endoscope images; a blood vessel parameter calculation unit that calculates a blood vessel parameter, which is relevant to the blood vessel extracted from each of the endoscope images, by calculation using the blood vessel information; and a blood vessel change index calculation unit that calculates a blood vessel change index, which indicates a temporal change of the blood vessel, using the blood vessel parameter.

Abstract: An acoustic wave diagnostic apparatus includes: an image display unit that displays an acquired acoustic wave image; a measurement item designation receiving unit that receives designation of a measurement item relevant to a measurement target; a detection measurement algorithm setting unit that sets a detection measurement algorithm based on the received measurement item; a position designation receiving unit that receives designation of a position of the measurement target on an acoustic wave image displayed on the image display unit; and a measurement unit that, in a case where the designation of the position is received, detects the measurement target based on the received position and the detection measurement algorithm and performs measurement for the detected measurement target.

Abstract: An ultrasound imaging system includes a processor that is programmed to operate the system in a normal operating state and two or more lesser power states. The processor lowers the operating power state to a lesser power state upon detecting one or more operating conditions such as no tissue been imaged in a predetermined time limit or that the imaging system or transducer has not been moved in a time limit. Upon awakening from a power off state, the processor implements a lesser power state before operating at the normal operating state to avoid undue power use until the transducer is positioned to image tissue.

Abstract: A photoacoustic image evaluation apparatus includes a processor configured to acquire a first photoacoustic image generated at a first point in time and a second photoacoustic image generated at a second point in time before the first point in time, the first and second photoacoustic images being photoacoustic images generated by detecting photoacoustic waves generated inside a subject, who has been subjected to blood vessel regeneration treatment, by emission of light into the subject; acquire a blood vessel regeneration index, which indicates a state of a blood vessel by the regeneration treatment, based on a difference between a blood vessel included in the first photoacoustic image and a blood vessel included in the second photoacoustic image; and display the blood vessel regeneration index on a display.

Abstract: An image selection unit selects a B2 image signal of which an image blurring amount satisfies a first condition, from a B2 image signal at a first timing T1 or B2 image signals at the second timing T2 to an N-th timing TN. A computed image signal generation unit performs computation based on a B1 image signal at the first timing T1 and a second image signal selected in the image selection unit, thereby generating a computed image signal.

Abstract: An ultrasound diagnostic apparatus includes: an ultrasound probe; an imaging unit that transmits and receives an ultrasound beam to and from a subject using the ultrasound probe and converts a received signal output from the ultrasound probe into an image to generate an ultrasound image of the subject; a collation pattern memory that stores a plurality of collation patterns corresponding to a plurality of examination parts of the subject in advance; an information input unit that is used by a user to input examination type information indicating content of an examination for continuously examining the plurality of examination parts; a determination order decision unit that decides a determination order of the plurality of examination parts to be continuously examined, on the basis of the examination type information input to the information input unit; and a part determination unit that reads the collation patterns corresponding to the examination parts to be continuously examined from the collation pattern m

Abstract: The endoscope system includes an image acquiring unit that acquires a first image and a second image, the first image being obtained by imaging an observation target by using first illumination light, the second image being obtained by imaging the observation target by using second illumination light that is different from the first illumination light at a different timing from the first image; an alignment unit that aligns the first image and the second image; and an accuracy changing unit that changes an accuracy of the alignment in accordance with at least a structure of interest to which an attention is paid in the observation target.

Abstract: Periodic displacement occurs in body tissue due to heartbeat. A peak level D of the movement distance of the body tissue is detected (Step 21), and a heartbeat cycle T is calculated from a frequency spectrum (Steps 22 and 23). By dividing twice the peak level D by the heartbeat cycle T, the moving velocity of the body tissue in a unit heartbeat cycle is calculated (Step 24). By dividing the moving velocity by a frame rate r, an average movement distance of the body tissue between frames is calculated (Step 25). In a case where the average movement distance is smaller than a predetermined threshold value, a time interval between the frames used for the calculation of the movement distance is extended (being Step 26 NO, Step 27).

Abstract: An image processing apparatus includes: an image acquisition unit that acquires a plurality of endoscope images obtained by imaging an observation target at different times with an endoscope; a blood vessel extraction unit that extracts blood vessels of the observation target from the plurality of endoscope images; a blood vessel information calculation unit that calculates a plurality of pieces of blood vessel information for each of the blood vessels extracted from the endoscope images; a blood vessel parameter calculation unit that calculates a blood vessel parameter, which is relevant to the blood vessel extracted from each of the endoscope images, by calculation using the blood vessel information; and a blood vessel change index calculation unit that calculates a blood vessel change index, which indicates a temporal change of the blood vessel, using the blood vessel parameter.

Abstract: An ultrasound diagnostic apparatus includes: an ultrasound probe; an imaging unit that transmits and receives an ultrasound beam to and from a subject using the ultrasound probe and converts a received signal output from the ultrasound probe into an image to generate an ultrasound image of the subject, according to set imaging conditions; a part determination unit that determines an imaging part of the subject using the ultrasound image generated by the imaging unit; a determination result storage unit that stores determination results corresponding to a plurality of frames obtained by the part determination unit; and a determination result integration unit that integrates the determination results corresponding to the plurality of frames stored in the determination result storage unit and outputs an integrated determination result.

Abstract: An ultrasound diagnostic apparatus includes: an ultrasound probe; an imaging unit that transmits and receives an ultrasound beam to and from a subject using the ultrasound probe and converts a received signal output from the ultrasound probe into an image to generate an ultrasound image of the subject, according to set imaging conditions; a probe state determination unit that determines whether the ultrasound probe is in an aerial emission state or a contact state with the subject; and an apparatus control unit that changes the imaging conditions in a case in which the probe state determination unit determines that the ultrasound probe has been changed from the contact state with the subject to the aerial emission state and controls the imaging unit such that the ultrasound image is generated using the changed imaging conditions.

Abstract: It is possible to allow image processing on a radiation image such that the same effect of scattered radiation elimination as when imaging is actually performed using a grid is obtained. When performing processing for eliminating scattered radiation included in radiation transmitted through a subject M on a radiation image imaged by irradiating the subject M with radiation, a characteristic acquisition unit 32 acquires a virtual grid characteristic as a characteristic of a virtual grid assumed to be used to eliminate scattered radiation at the time of imaging of the radiation image. A scattered radiation elimination unit 36 performs scattered radiation elimination processing of the radiation image based on the virtual grid characteristic.

Abstract: It is possible to allow image processing on a radiation image such that the same effect of scattered radiation elimination as when imaging is actually performed using a grid is obtained. When performing processing for eliminating scattered radiation included in radiation transmitted through a subject M on a radiation image imaged by irradiating the subject M with radiation, a characteristic acquisition unit 32 acquires a virtual grid characteristic as a characteristic of a virtual grid assumed to be used to eliminate scattered radiation at the time of imaging of the radiation image. A scattered radiation elimination unit 36 performs scattered radiation elimination processing of the radiation image based on the virtual grid characteristic.

Abstract: It is possible to allow image processing on a radiation image such that the same effect of scattered radiation elimination as when imaging is actually performed using a grid is obtained. When performing processing for eliminating scattered radiation included in radiation transmitted through a subject M on a radiation image imaged by irradiating the subject M with radiation, a characteristic acquisition unit 32 acquires a virtual grid characteristic as a characteristic of a virtual grid assumed to be used to eliminate scattered radiation at the time of imaging of the radiation image. A scattered radiation elimination unit 36 performs scattered radiation elimination processing of the radiation image based on the virtual grid characteristic.

Abstract: There are provided an acoustic wave diagnostic apparatus capable of shortening the time until a color image is obtained and a control method thereof. Processing for transmitting an ultrasound pulse (43) converging on a focusing position (41) in the same direction of a subject from acoustic wave transducers to be driven, among a plurality of ultrasound transducers (20 to 32) included in an ultrasound probe, while sequentially updating the acoustic wave transducers to be driven is performed multiple times for the same ultrasound transducers (22 to 28). An acoustic wave echo signal group is obtained by receiving an ultrasound echo (44) of an observation target position (42) in the ultrasound transducers (22 to 28).

Abstract: The acoustic wave processing device includes a data processing unit which performs superimposition processing on first element data or first reception data generated by performing phasing addition on the first element data to generate processed data, an image generation unit which generates a B mode image based on the first element data and the processed data, a bloodstream image generation unit which generates a bloodstream image based on bloodstream information included in the first element data, a region setting unit which sets a bloodstream image region, a processing region setting unit which sets a region for processing in the data processing unit based on information relating to the bloodstream image region, and a display image generation unit which generates a synthesized image of the B mode image and the bloodstream image.

Abstract: It is possible to allow image processing on a radiation image such that the same effect of scattered radiation elimination as when imaging is actually performed using a grid is obtained. When performing processing for eliminating scattered radiation included in radiation transmitted through a subject M on a radiation image imaged by irradiating the subject M with radiation, a characteristic acquisition unit 32 acquires a virtual grid characteristic as a characteristic of a virtual grid assumed to be used to eliminate scattered radiation at the time of imaging of the radiation image. A scattered radiation elimination unit 36 performs scattered radiation elimination processing of the radiation image based on the virtual grid characteristic.

Abstract: A subject component removed signal is obtained from an image signal representing an image by performing, with respect to a first direction and/or a second direction that is different from the first direction, one-dimensional filtering processing using a subject component removal filter that removes a low frequency component including a subject component of the image to roughly remove the subject component. Further, frequency components corresponding to the periodic pattern in the subject component removed signal are detected with respect to both of the first direction and the second direction.

Abstract: A first frequency analysis unit performs frequency analysis on a reference radiographic image of plural radiographic images obtained by tomosynthesis imaging using a grid, and obtains a frequency characteristic of a periodic pattern caused by the grid and a frequency analysis result. A second frequency analysis unit performs, based on the frequency analysis result, limited frequency analysis on a radiographic image or images other than the reference radiographic image, and obtains a frequency characteristic of the periodic pattern about the radiographic image or images. A suppression unit performs, based on the frequency characteristic, processing for suppressing the periodic pattern in all of the radiographic images.

Abstract: The image obtaining unit obtains a radiation image from the radiation detector, the radiation field area detection unit detects a radiation field area from the radiation image. The analysis area setting unit detects a direct radiation area, a superabsorbent body area, and a high noise area as the areas where a periodic pattern is unlikely to present and sets an analysis area by excluding these areas. The frequency analysis unit performs a frequency analysis only on the analysis area and detects a frequency component of the periodic pattern arising from a grid. The filtering processing unit removes the frequency component of the periodic pattern arising from the grid from the radiation image.