A radiographic imaging system includes plural radiographic imaging devices that image a same subject. The radiographic imaging device includes: a radiation detector; a detection unit that detects whether or not application of the radiation has been started based on electrical signals indicating detection results of sensors that detect the application of the radiation and that are disposed in correspondence to the radiation detector; a determination unit that determines whether or not noise is superimposed on the electrical signals after the detection unit has detected whether or not the application of the radiation has been started; and a communication unit that is connected to another radiographic imaging device and transmits to and receives from the other connected radiographic imaging device a detection result signal indicating the detection result of the detection unit and a determination result signal indicating the determination result of the determination unit.

A medical radiology system comprises an external x-ray source (1) and a CMOS image sensor (2) that is connected via a USB link (4) by way of USB peripheral of a device (3) for digitally processing the image data of the sensor. A tracking device is placed on the USB link (4) in order to continuously read and decode the data transmitted over this link in a way that is transparent to the device and to the sensor, and to detect, in the transmitted data stream, one particular datum (XAMC=1) representing a signal indicating detection, by the sensor, that a sufficient dose of radiation has been received. On detection of this particular datum, the tracking device sends an electrical signal Stop-X to the radiation source, in order to stop the emission of the radiation. The system is especially suitable for taking dental radiology images with an intra-oral CMOS sensor.

A radiographing system includes a mobile terminal configured to store an examination time of a subject that is based on examination-related information about the subject, a radiographing apparatus configured to take a radiation image of the subject based on the examination-related information and to store an imaging time of the radiation image, and an association unit configured to associate the radiation image with the examination-related information based on the imaging time and the examination time.

A bearing configuration for the rotational mounting of a component provided for rotational movement includes a positionally fixed sleeve on which the component is rotatably mounted by one or more bearing elements or a plain-bearing. A pressure element is provided in the interior of the sleeve for readily expanding the sleeve and placing the sleeve in frictional contact with the component which is spaced apart from the sleeve by an air gap. A medical examination device having the bearing configuration is also provided.

To establish a wireless connection to a desired radio network by preventing a user from erroneously connecting to another radio network without a special operation in a radiation imaging system. In the radiation imaging system, a radiation imaging apparatus establishes a first wireless connection between the radiation imaging apparatus and a wireless master unit by using first information uniquely indicating itself as an identifier, third information corresponding to the radiation imaging apparatus wirelessly connected to a wireless master unit comprising an access point and a console connected thereto as an identifier, a radiation imaging apparatus uses fourth information according to second information uniquely indicating the wireless master unit itself notified from the wireless master unit through the first wireless connection as an identifier, and the wireless master unit uses fourth information as an identifier to establish a second wireless connection between the radiation imaging apparatus and the wireless master unit.

The invention provides a patient shuttle system and an irradiation system for particle therapy. A patient shuttle system of one embodiment of the invention includes: a patient table (110) adapted to carry a patient; a patient table drive unit (120) that moves and/or rotates the patient table; and a transfer unit (130) having a base (131) on which the patient table drive unit is placed. In a home position state of the patient shuttle system (100), the patient table and first and second arms of the patient table drive unit are configured to be folded in the height direction (Z-axis). A robot arm base connected to the second arm is fixed at a position off the center of the base in plan view, and thereby a helper space (135) where a helper may ride is secured on the base. The robot arm base is fixed in a recess (138) provided in the base.

A medical system (300) comprises a medical examination apparatus (302) and a wearable patient device (100). The medical examination apparatus (302) comprises an examination zone for a patient (304), and the wearable patient device (100) comprises a user interface operable by a hand of the patient when the patient (304) is positioned in the examination zone of the medical examination apparatus (302). The wearable patient device (100) is communicatively connected with the medical examination apparatus (302) via a wireless connection, for sending a control command corresponding to input received from the patient via the user interface of the wearable patient device (100), the control command being adapted to control a patient-controllable part or parameter (308) of the medical examination apparatus (302).

An apparatus for cone beam computed tomography can include a support structure, a scanner assembly coupled to the support structure for controlled movement in at least x, y and z orientations, the scanner assembly can include a DR detector configured to move along at least a portion of a detector path that extends at least partially around a scan volume with a distance D1 that is sufficiently long to allow the scan volume to be positioned within the detector path; a radiation source configured to move along at least a portion of a source path outside the detector path, the source path having a distance D2 greater than the distance D1, the distance D2 being sufficiently long to allow adequate radiation exposure of the scan volume for an image capture by the detector; and a first gap in the detector path.

A breast imaging apparatus includes a radiation source that irradiates a breast of a subject with radiation, a radiation detector that detects the radiation transmitted through the breast to output a radiographic image, and an ultraviolet light source that performs irradiation of ultraviolet light. The ultraviolet light source irradiates an imaging table, a face guard, a pressing plate, and the like with the ultraviolet light in a case where a turn-on command signal input from an operator through an input device is input.

Systems and methods are presented for delivering medical fluids to a patient. A data storage device (120) is either separately attached to or incorporated within the structure of a reusable fixture that may be detachably connected to a barrel (111) of a syringe (107). A filling station (110) and an power injector (108) may each include a read-write device (114, 122) that is operable to read the data storage device (120) within its field of view. When the read-write devices (114, 122) are attached to the filing station (110) and the power injector (40), respectively, and when the fixture including the data storage device (120) is attached to the syringe (107), the read-write devices (114, 122) may be operable to store data on and read data from the data storage device (120) associated with the syringe (107). After an injection procedure, the fixture may be detached from the syringe (107) and reused with a new or resterilized syringe (107).