An imaging apparatus includes a patient table with a gurney and a base. The gurney can slide between two extreme positions, an electrically supplied motoreducer controlled by a control unit causing the table to slide and having a lock/unlock system of the sliding that is mechanical, independent from the electrical supply, and manually controlled by a grabbing organ actuated by a human operator. The patient table may be provided together with a gantry having a housing transparent to light for at least part of its extension, and a control unit of the radiographic apparatus. The housing or a part thereof is associated with a source of light, and the control unit, when the apparatus is electrically supplied, and/or other status conditions are determined by a status sensor, causes the light source to be illuminated and the housing to light up in its translucent parts signalling the status condition.

An X-ray fluoroscopic imaging apparatus includes a table, an imaging system including an X-ray source and a detector, and an operation panel unit including a plurality of operation input units. The plurality of operation input units include an emergency stop unit and a stop state release unit. The emergency stop unit and the stop state release unit are provided separately from each other at different positions.

Provided is a mobile radiation generation apparatus which reliably prevents the unsteady motion of a carriage unit with a simple structure and facilitates the fine adjustment of the position of a radiation emitting unit. Each of a front wheel and a rear wheel of a carriage unit is a caster that swivels about a swivel axis extending in a vertical direction. A support that vertically stands on the carriage unit supports a base end of an arm unit having a free end to which an X-ray emitting unit is attached. The arm unit rotates about a rotation axis parallel to the swivel axis with respect to the carriage unit. The carriage unit includes a front pedal that is provided closer to the front wheel than the support and is used to lock both the rotation and swivel of the caster at the same time.

Provided is a mobile radiation generation apparatus which reliably prevents the unsteady motion of a carriage unit with a simple structure and facilitates the positioning of an operation panel even in a case in which a wheel of the carriage unit is a caster. Each of a front wheel and a rear wheel of a carriage unit is a caster that swivels about a swivel axis extending in a vertical direction. An operation panel is provided in a main body unit mounted on the carriage unit. The operation panel rotates about an axis that extends in the Z-axis direction with respect to the carriage unit. The carriage unit includes a front pedal that is provided closer to the front wheel than a support and locks both the rotation and swivel of the caster at the same time.

Provided is a mammography device including: a C-arm including an irradiation unit configured to emit radioactive rays to a subject, and a detection unit on which the subject is disposed; a compression paddle coupled to the C-arm and configured to compress the subject; a carrying unit configured to move the compression paddle upward or downward; a drive unit configured to transmit power to the carrying unit; a belt support unit coupled to an upper portion of a main body of the C-arm and configured to support one side of a belt that operates in conjunction with an operation of the carrying unit; and a fall prevention unit coupled to one side of the belt support unit and configured to restrict an operation of the belt support unit when a rotation angle of the C-arm is a predetermined angle or more.

An N-M tomography system comprising: a carrier for the subject of an examination procedure; a plurality of detector heads; a carrier for the detector heads; and a detector positioning arrangement operable to position the detector heads during performance of a scan without interference or collision between adjacent detector heads to establish a variable bore size and configuration for the examination. Additionally, collimated detectors providing variable spatial resolution for SPECT imaging and which can also be used for PET imaging, whereby one set of detectors can be selectably used for either modality, or for both simultaneously.

This holding mechanism (3) for an X-ray imaging apparatus includes a switching means (36) that switches between a state of permitting movement of a moving body (4) including an X-ray tube (1) or an X-ray detector (2) and a state of prohibiting the movement, a force direction detection means (38) that detects a direction of a force applied to a moving mechanism (31), and a permission direction determination means (7) that determines a direction in which the movement is permitted by the switching means among a plurality of directions based on a detected direction of the force.

A new and improved anatomical imaging system which includes a new and improved movement system, wherein the movement system comprises an omnidirectional powered drive unit and wherein the movement system can substantially eliminate lateral walk (or drift) over the complete stroke of a scan, even when the floor includes substantial irregularities, whereby to improve the accuracy of the scan results and avoid unintentional engagement of the anatomical imaging system with the bed or gurney which is supporting the patient. The present invention also comprises the provision and use of Liddiard wheels.

A method for controlling the movement of an X-ray source via a suspension device includes obtaining, during a movement of the suspension device along the rail, a first speed of the suspension device at the first reference point. The first reference point may correspond to a first target position. The method may also include determining whether the first speed of the suspension device at the first reference point is less than a threshold speed. In response to a result of the determination that the first speed of the suspension device at the first reference point is less than the threshold speed, the method may further include actuating a control device to move the suspension device to the first target position.

A collision monitoring apparatus can include a camera to acquire a video image of surroundings of at least one target protection component on the C-arm X-ray machine system; an image processor to determine a scene of the surroundings of the at least one target protection component according to the video image; and a controller to control a C-arm X-ray machine system to stop moving or slow down when it is determined that a possible collision exists according to the scene of the surroundings of the at least one target protection component. Advantageously the apparatus effectively prevents patients, operators, patient examination beds and other obstacles from suffering a serious collision with the C-arm itself.