Abstract: The present invention provides an antibody that binds to an NTCP, capable of inhibiting infection of human hepatocytes with hepatitis B virus (HBV) particles. The present invention also provides an antibody that binds to an NTCP, capable of inhibiting infection of human hepatocytes with hepatitis B virus (HBV) particles, the antibody having a reduced effect on bile acid transport by NTCP.

Abstract: An imaging support device used in a radiography apparatus including a radiation source and a radiation image detector that detects a radiation image of a subject on the basis of radiation emitted from the radiation source and transmitted through the subject includes an optical camera that outputs an optical image by optically imaging a region including an irradiation field of the radiation applied to the subject from the radiation source, and at least one processor, in which the processor associates the optical image acquired by the optical camera with the radiation image on the basis of a timing signal transmitted from the radiation image detector side.

Abstract: An image inspection device includes a radiation image acquisition unit that acquires a radiation image obtained by imaging a subject using radiation, an imaging condition recognition unit that recognizes an imaging condition relating to an imaging direction and/or laterality of the subject reflected in the radiation image, and a marker superimposition unit that superimposes, on the radiation image, a marker indicating the imaging direction and/or laterality of the subject reflected in the radiation image by using a result of the recognition of the imaging condition recognition unit.

Abstract: An image processing apparatus includes an acquisition unit that acquires a radiographic image captured by a radiography apparatus according to an imaging order including a plurality of examination purposes from the radiography apparatus, a processing unit that performs predetermined processing for each corresponding examination purpose on the radiographic image acquired by the acquisition unit, an output unit that outputs each processing result of the processing performed for each examination purpose by the processing unit to the outside, and a control unit that performs one of a first control for outputting the processing result from the output unit at timings that are considered to be the same and a second control for sequentially outputting the processing result from the output unit in response to an end of the processing, according to settings.

Abstract: A derivation unit derives imaging conditions corresponding to virtual grid characteristics (grid ratio) received by a receiving unit on the basis of a table stored in a storage unit. The derivation unit sets the derived imaging conditions in a radiation source control unit. The radiation source control unit controls a radiation source on the basis of the set imaging conditions such that a radiographic image is captured. An execution unit of an image processing device acquires the radiographic image captured by the radiation detector through a detector control unit. The execution unit performs a virtual grid process for the acquired radiographic image on the basis of the virtual grid characteristics received by the receiving unit and the imaging conditions derived by the derivation unit to generate a radiographic image from which the influence of scattered radiation has been removed and displays the radiographic image on a display unit.

Abstract: In an image analysis device, an image analysis method, and a non-transitory computer-readable recording medium, it is determined whether a radiographic image is captured by rocking a rocking imaging grid. The image analysis device includes: a radiographic image acquisition section; a dosage data acquisition section that acquires dosage data indicating, in a time-series manner, a dosage of radiation rays exposed to a specific position in an imaging area in a specific period; and a determining section that determines whether the dosage data has a first feature indicating a dosage variation as a plurality of radiation absorbing bodies and a radiation transmitting body disposed between adjacent radiation absorbing bodies pass through a space between the specific position and a radiation source, and determines that the radiographic image corresponding to the dosage data determined to have the first feature is a rocking grid use image captured by rocking a rocking imaging grid.

Abstract: It is detected whether a grid stripe is present in a radiographic image. In a case in which the grid stripe is detected, a process of removing the grid stripe from the radiographic image is performed and the radiographic image is displayed. In a case in which the grid stripe is not detected, a process of removing a scattered component from the radiographic image is performed and a radiographic image subjected to the scattered radiation removal process and a radiographic image before the process are displayed.

Abstract: A radiographic image captured by irradiating a subject with radiation is acquired. A scattered radiation removal unit removes a scattered component from the radiographic image using at least imaging conditions. A correction information acquisition unit acquires correction information for correcting the degree of removal of the scattered component and changes the imaging conditions on the basis of the correction information. The scattered radiation removal unit performs a process of removing the scattered component from the radiographic image on the basis of the changed imaging conditions.

Abstract: The present invention is capable of reducing a load of a processing operation of a user. That is, a console acquires an original image acquired from a radiographic image capturing device. The console performs image analysis process A to generate a purpose A image and performs image analysis process B to generate a purpose B image. The console detects a processing operation performed on the purpose A image by the user and performs image processing to generate the purpose A image, and sets, as handover processing, a processing operation corresponding to a definition of predetermined handover conditions. The console reflects the handover processing in the purpose B image. Further, the console detects a processing operation performed on the purpose B image by the user and performs image processing to generate a purpose B image.

Abstract: A derivation unit acquires imaging conditions corresponding to order information received by a receiving unit based on a table stored in a storage unit and sets the imaging conditions in a radiation source control unit. The radiation source control unit controls a radiation source based on the set imaging conditions such that a radiographic image is captured. An acquisition unit acquires the actual values of the imaging conditions from the radiation source control unit. The derivation unit derives virtual grid characteristics based on the actual values of the imaging conditions. An execution unit acquires a captured radiographic image through a detector control unit. The execution unit performs a virtual grid process for the acquired radiographic image based on the virtual grid characteristics derived by the derivation unit and the acquired imaging conditions to generate a radiographic image from which the influence of scattered radiation has been removed.

Abstract: The present disclosure provides an image processing device including: a scattered radiation correction data acquisition section that acquires scattered radiation correction data as a result of radiation being irradiated onto a radiographic imaging device that images a radiographic image; a pixel region acquisition section that acquires information indicating a size of an effective pixel region of the radiographic imaging device; an exposure range acquisition section that acquires information indicating an imaging exposure range of radiation for imaging an imaging subject with the radiographic imaging device; an image data acquisition section that acquires image data as a result of imaging a radiographic image of the imaging subject; and a correction section that corrects the image data acquired by the image data acquisition section using the scattered radiation correction data, in a case in which the imaging exposure range includes an area outside of the effective pixel region.

Abstract: In an image analysis device, an image analysis method, and a non-transitory computer-readable recording medium, it is determined whether a radiographic image is captured by rocking a rocking imaging grid. The image analysis device includes: a radiographic image acquisition section; a dosage data acquisition section that acquires dosage data indicating, in a time-series manner, a dosage of radiation rays exposed to a specific position in an imaging area in a specific period; and a determining section that determines whether the dosage data has a first feature indicating a dosage variation as a plurality of radiation absorbing bodies and a radiation transmitting body disposed between adjacent radiation absorbing bodies pass through a space between the specific position and a radiation source, and determines that the radiographic image corresponding to the dosage data determined to have the first feature is a rocking grid use image captured by rocking a rocking imaging grid.

Abstract: The present invention is capable of reducing a load of a processing operation of a user. Namely, a console first acquires an original image of a radiographic image acquired from a radiographic image capturing device, in order to perform common processing operations. The console detects common processing operations performed on an original image by the user and stores processing content of the common processing operations and the original image in association with each other. In a case in which processing transitions to individual processing (purpose A) for generating a purpose A image, the console performs image analysis process A on the acquired original image and reflects the common processing to generate an image for purpose A. Further, the console detects individual processing operations performed on the image for purpose A by the user, and performs image processing corresponding to the individual processing operations to generate a purpose A image.

Abstract: In an image analysis device, an image analysis method, and a non-transitory computer-readable recording medium, it is determined whether a radiographic image is captured by rocking a rocking imaging grid. The image analysis device includes: a radiographic image acquisition section; a dosage data acquisition section that acquires dosage data indicating, in a time-series manner, a dosage of radiation rays exposed to a specific position in an imaging area in a specific period; and a determining section that determines whether the dosage data has a first feature indicating a dosage variation as a plurality of radiation absorbing bodies and a radiation transmitting body disposed between adjacent radiation absorbing bodies pass through a space between the specific position and a radiation source, and determines that the radiographic image corresponding to the dosage data determined to have the first feature is a rocking grid use image captured by rocking a rocking imaging grid.

Abstract: In a radiation image processing apparatus, method, and program, performing image processing based on scattered radiation, such as scattered radiation elimination processing, accurately by taking into account the influence of scattered radiation from an area adjacent to a processing target area. For this purpose, performing image processing on a radiation image captured by applying radiation to a subject based on scattered radiation generated by the subject. In this case, a processing target area which is the processing target in the radiation image is added with another area different from the processing target area in the radiation image. Then, the image processing based on scattered radiation is performed on the processing target area using the another area and the processing target area.

Abstract: An image obtaining unit obtains a subject image, a body thickness distribution modifying unit receives input of a virtual model having an estimated body thickness distribution and modifies the estimated body thickness distribution of the virtual model to output the modified estimated body thickness distribution, and a body thickness distribution determining unit determines the outputted estimated body thickness distribution to be used as the body thickness distribution of the subject.

Abstract: A derivation unit acquires imaging conditions corresponding to order information received by a receiving unit based on a table stored in a storage unit and sets the imaging conditions in a radiation source control unit. The radiation source control unit controls a radiation source based on the set imaging conditions such that a radiographic image is captured. An acquisition unit acquires the actual values of the imaging conditions from the radiation source control unit. The derivation unit derives virtual grid characteristics based on the actual values of the imaging conditions. An execution unit acquires a captured radiographic image through a detector control unit. The execution unit performs a virtual grid process for the acquired radiographic image based on the virtual grid characteristics derived by the derivation unit and the acquired imaging conditions to generate a radiographic image from which the influence of scattered radiation has been removed.

Abstract: A derivation unit derives imaging conditions corresponding to virtual grid characteristics (grid ratio) received by a receiving unit on the basis of a table stored in a storage unit. The derivation unit sets the derived imaging conditions in a radiation source control unit. The radiation source control unit controls a radiation source on the basis of the set imaging conditions such that a radiographic image is captured. An execution unit of an image processing device acquires the radiographic image captured by the radiation detector through a detector control unit. The execution unit performs a virtual grid process for the acquired radiographic image on the basis of the virtual grid characteristics received by the receiving unit and the imaging conditions derived by the derivation unit to generate a radiographic image from which the influence of scattered radiation has been removed and displays the radiographic image on a display unit.

Abstract: The present disclosure provides an image processing device including: a scattered radiation correction data acquisition section that acquires scattered radiation correction data as a result of radiation being irradiated onto a radiographic imaging device that images a radiographic image; a pixel region acquisition section that acquires information indicating a size of an effective pixel region of the radiographic imaging device; an exposure range acquisition section that acquires information indicating an imaging exposure range of radiation for imaging an imaging subject with the radiographic imaging device; an image data acquisition section that acquires image data as a result of imaging a radiographic image of the imaging subject; and a correction section that corrects the image data acquired by the image data acquisition section using the scattered radiation correction data, in a case in which the imaging exposure range includes an area outside of the effective pixel region.

Abstract: A radiographic image captured by irradiating a subject with radiation is acquired. A scattered radiation removal unit removes a scattered component from the radiographic image using at least imaging conditions. A correction information acquisition unit acquires correction information for correcting the degree of removal of the scattered component and changes the imaging conditions on the basis of the correction information. The scattered radiation removal unit performs a process of removing the scattered component from the radiographic image on the basis of the changed imaging conditions.