The invention discloses a scanning method and apparatus suitable for scanning a pipeline or process vessel in which a beam of gamma radiation from a source is emitted through the vessel to be detected by an array of detectors which are each collimated to detect radiation over a narrow angle relative to the width of the emitted radiation beam.

A radiographic imaging device includes: a radiation detector including plural pixels, each including a sensor portion and a switching element; a detection unit that detects a radiation irradiation start if an electrical signal caused by charges generated in the sensor portion satisfies a specific irradiation detection condition, and/or if an electrical signal caused by charges generated in a radiation sensor portion that is different from the sensor portion satisfies a specific irradiation detection condition; and a control unit that determines whether or not noise caused by external disturbance has occurred after the detection unit has detected the radiation irradiation start, and if the noise has occurred, that stops a current operation of the radiation detector, and causes the detection unit to perform detection.

A radiographic imaging device includes: a radiation detector including plural pixels, each including a sensor portion and a switching element; a detection unit that detects a radiation irradiation start if an electrical signal caused by charges generated in the sensor portion satisfies a specific irradiation detection condition, and/or if an electrical signal caused by charges generated in a radiation sensor portion that is different from the sensor portion satisfies a specific irradiation detection condition; and a control unit that determines whether or not noise caused by external disturbance has occurred after the detection unit has detected the radiation irradiation start, and if the noise has occurred, that stops a current operation of the radiation detector, and causes the detection unit to perform detection.

Disclosed herein are embodiments of gold nanoparticles and methods of making and using the gold nanoparticles. The disclosed gold nanoparticles have core sizes and polydispersities controlled by the methods of making the gold nanoparticles. In some embodiments, the methods of making the gold nanoparticles can concern using flow reactors and reaction conditions controlled to make gold nanoparticles having a desired core size. The gold nanoparticles disclosed herein also comprise various ligands that can be used to facilitate the use of the gold nanoparticles in a variety of applications.

A system includes one or more storage devices storing a set of instructions and at least one processor in communication with the storage device. When executing the instructions, the at least one processor is configured to cause the system to obtain a first operating state of an X-ray imaging device, and obtain a first input from a user via a terminal, the first input being associated with a second operating state of the X-ray imaging device. The at least one processor may further cause the system to determine whether the first input satisfies a switch condition. Upon a determination that the first input satisfies the switch condition, the at least one processor may further cause the system to transmit a first instruction to switch the X-ray imaging device from the first operating state to the second operating state.

An X-ray imaging system, including a target; an electron beam source configured to provide an electron beam for interaction with the target to generate X-ray radiation; electron optics configured to alternately direct the electron beam to at least a first and a second location on the target; an X-ray detector array configured to receive X-ray radiation generated at the first and second locations on the target; a sample position region for receiving a sample to be exposed to generated X-ray radiation, the sample position region being located in a region where X-ray radiation generated at the first location overlaps with X-ray radiation generated at the second location; and a processing unit coupled to the X-ray detector array, the processing unit being configured to create an image of a sample, positioned in the sample position region, based on the X-ray radiation originating from the first location and from the second location.

An X-ray imaging system, including a target; an electron beam source configured to provide an electron beam for interaction with the target to generate X-ray radiation; electron optics configured to alternately direct the electron beam to at least a first and a second location on the target; an X-ray detector array configured to receive X-ray radiation generated at the first and second locations on the target; a sample position region for receiving a sample to be exposed to generated X-ray radiation, the sample position region being located in a region where X-ray radiation generated at the first location overlaps with X-ray radiation generated at the second location; and a processing unit coupled to the X-ray detector array, the processing unit being configured to create an image of a sample, positioned in the sample position region, based on the X-ray radiation originating from the first location and from the second location.

A specimen holding and positioning apparatus operable to substantially non-movably maintain a specimen (e.g., an excised tissue specimen) in a fixed or stable orientation with respect to the apparatus during imaging operations (e.g., x-ray imaging), transport (e.g., from a surgery room to a pathologist's laboratory), and the like for use in facilitating accurate detection and diagnosis of cancers and/or other abnormalities of the specimen.

A specimen holding and positioning apparatus operable to substantially non-movably maintain a specimen (e.g., an excised tissue specimen) in a fixed or stable orientation with respect to the apparatus during imaging operations (e.g., x-ray imaging), transport (e.g., from a surgery room to a pathologist's laboratory), and the like for use in facilitating accurate detection and diagnosis of cancers and/or other abnormalities of the specimen.

A radiation imaging apparatus includes an attenuation member for reducing reflection of components arranged on a backside of the radiation imaging apparatus generated by back scattered radiation that has reflected on a structure on the backside of the radiation imaging apparatus, the attenuation member being provided on the backside of the radiation incident plane of the radiation detection unit, wherein the attenuation member is made of a material with a higher atomic number and a material with a lower atomic number than a material with a highest atomic number among materials of the component, covers an end portion of an outer shape of the component overlapping the radiation detection unit in orthogonal projection onto the second plane, and is smaller in area than the radiation detection unit.