According to one embodiment, an X-ray diagnosis apparatus includes an X-ray generator, an X-ray diaphragm, an X-ray detector, an image capturing unit, a blood vessel running information acquiring unit, a device position specifying unit, and a diaphragm controller. The X-ray generator emits X-rays. The X-ray diaphragm restricts a region to be irradiated with X-rays emitted from the X-ray generator. The X-ray detector detects X-rays emitted from the X-ray generator. The image capturing unit acquires an X-ray image based on a detection result obtained by the X-ray detector. The blood vessel running information acquiring unit acquires blood vessel running information. The device position specifying unit specifies the position of a device in the X-ray image. The diaphragm controller controls the X-ray diaphragm based on the blood vessel running information and the position of the device.

A portable barium test apparatus is used to perform Modified Barium Swallow Studies (MBSS) on patients in different locations, such as the home of the patient or a care facility. The apparatus includes a hand truck, a U-shaped support, a height-adjusting track, a support carriage, an X-ray generator, and an image-capturing device. The hand truck allows the medical staff to transport the apparatus to the desired location to perform the procedure. The U-shaped support maintains the X-ray generator and the image-capturing device at the desired arrangement to perform the procedure. The height-adjusting track enables the repositioning of the U-shaped support at the desired height to accommodate the patient. The support carriage connects the U-shaped support to the height-adjusting track and maintains the arrangement of the U-shaped support during the procedure. The X-ray generator and the image-capturing device enable the medical staff to perform the MBSS procedure on the patient.

Disclosed is a ceramic shielding apparatus including at least one shield made of a ceramic material and provided inside or outside an X-ray tube to shield radiation; and supports configured to support the shield. According to such a configuration, disadvantages of conventional shielding materials such as lead can be addressed, so that a shield apparatus having excellent shielding properties while being harmless to the human body can be provided.

Methods and systems are provided for adaptive scan control. In one embodiment, a method includes, upon an injection of a contrast agent, processing acquired projection data of an anatomical region of interest (ROI) of a subject to measure a contrast signal of the contrast agent, determining when each of a plurality of zones of a contrast scan are estimated to occur based on the contrast signal, updating a scan prescription for the contrast scan based on when each of the plurality of zones of the scan protocol are estimated to occur, and performing the contrast scan according to the updated scan prescription.

This application describes an internal, re-chargeable power source for a portable medical device. The power source contains a removable battery pack comprising a lithium-containing material with 5 to 7 battery cells in series, each individual cell having a current capacity ranging from about 3000 mAh to about 3700 mAh. The power source can have a total energy capacity ranging from about 65 Watt-hour to about 170 Watt-hours. Other embodiments are described.

An x-ray tube includes an electron emitter to emit an electron beam; and a multilayer anode including a first anode layer facing the electron beam and a second anode layer facing away from the electron beam. The first anode layer includes a first anode material to generate a braking radiation via the electron beam and the second anode layer includes a second anode material to generate a further x-ray radiation via the braking radiation. The further x-ray radiation is relatively more monochromatic than the braking radiation and wherein the first anode layer and the second anode layer adjoin in a planar manner.

The present invention relates to an X-ray analysis apparatus and a method of X-ray analysis. The X-ray analysis apparatus enables a user to carry out a plurality of X-ray analysis applications, for analysing a sample by measuring X-ray diffraction and/or X-ray fluorescence, using the same X-ray source. The apparatus comprises an X-ray source for irradiating the sample with X-rays, the X-ray source comprising a solid anode and a cathode for emitting an electron beam. It also comprises a focusing arrangement for focusing the electron beam onto the anode, and a controller. The controller is configured to receive X-ray analysis application information and to control the X-ray analysis apparatus to selectively operate in either a first X-ray analysis mode or a second X-ray analysis mode based on the X-ray analysis application information. In the first X-ray analysis mode the X-ray source operates at a first operating power and has an effective focal spot size that is less than 100 μm. In the second X-ray analysis mode the X-ray source operates at a second operating power that is higher than the first operating power, and the area of the effective focal spot is larger than the area of the effective focal spot in the first X-ray analysis mode.

A specimen radiography system may include a controller and a cabinet. The cabinet may include an x-ray source, an x-ray detector, and a specimen drawer disposed between the x-ray source and the x-ray detector. The specimen drawer may be automatically positionable along a vertical axis between the x-ray source and the x-ray detector.

A mobile X-ray imaging apparatus is an apparatus that enables the performance of a fluoroscopic procedure in any setting. The apparatus may include an elongated frame, a wheeled base, a U-shaped support, a height-adjusting track, a support carriage, an X-ray generator, and an image-capturing device. The elongated frame supports the U-shaped support and maintains the U-shaped support at a desired height. The wheeled base maintains the elongated frame upright and facilitates the relocation of the apparatus. The U-shaped support maintains the X-ray generator and the image-capturing device at the desired arrangement to perform the fluoroscopic procedure. The height-adjusting track enables the repositioning of the U-shaped support along the elongated frame to accommodate the patient. The support carriage connects the U-shaped support to the height-adjusting track and keeps the U-shaped support in place during the procedure. The X-ray generator and the image-capturing device enable the fluoroscopic procedure to be performed.

The present application relates to a deflection electrode assembly, an X-ray source, and an X-ray imaging system. The deflection electrode assembly includes: a first electrode plate, including a first connection portion and a plurality of first tooth portions, wherein the first electrode plate is formed as a comb shape; and a second electrode plate, including a second connection portion and a plurality of second tooth portions, wherein the second electrode plate is formed as a comb shape. The first electrode plate and the second electrode plate are not in contact with each other, and the plurality of first tooth portions and the plurality of second tooth portions are arranged at least partially in a staggered manner to form a plurality of electron beam passageways; each electron beam passageway is located between adjacent first and second tooth portions.