Systems for patient support, imaging, or transport include a modality with a support surface configured to support a patient thereon, a converter associated with the modality, the converter being configured to receive relatively low-volume high-pressure air from a source of the relatively low-volume high-pressure air and to convert the relatively low-volume high-pressure air into relatively high-volume low-pressure air, and an air flow device configured to receive the relatively high-volume low-pressure air from the converter and provide an air flow function to the modality using the relatively high-volume low-pressure air.

Systems and methods are provided for a patient support device for an x-ray device for use during an examination of a patient including a patient couch and at least one support (6) bearing the patient couch. The patient couch includes a first, x-ray-transparent material disposed in an at least partially flexible covering made from a second x-ray-transparent material. The first material includes a solid, dimensionally stable state and a deformable state, in particular at least partially liquid and/or gaseous state, that are linked by reversible phase transitions. The patient support device further includes at least one induction device for inducing at least one of the phase transitions of the first material between the states by applying and/or removing energy.

A method and positioning system for determining a region to be examined in a subject on a movable support of a medical imaging system. The method includes: a) manually specifying the region by positioning a predetermined marker object in relation to the subject; b) acquiring the position of the marker object by an acquisition apparatus; c) projecting or displaying a feedback marking by a projection apparatus at the acquired position on the subject, wherein the position of the marker object and the acquired position are adjustable; d) calculating a scan position of the movable support on the basis of the acquired position by means of a computer unit, wherein in the scan position, the region to be examined is arranged in an acquisition region of the imaging system; and e) automatically moving the movable support into the scan position with a motor.

A breast support platform for an x-ray imaging system includes a housing having a compression plate and a front wall, and a heating system disposed at least partially within the housing. The heating system is configured to heat at least a portion of the compression plate, at least a portion of the front wall, or at least a portion of the compression plate and the front wall. In an example, the heating system includes a transparent conducting film coupled to an inner surface of the housing. In another example, the heating system includes a blower disposed at least partially within the housing, and the blower is configured to channel hot air across an inner surface of the housing.

In a medical system including a medical imaging device and a robotic bed, the table may be movable between a first position where a maximum dimension of the robot arm not hidden under the table is less than one fourth of a longitudinal dimension of the table when the table is viewed from vertically above, and a second position where a maximum dimension of the robot arm not hidden under the table is one fourth of a longitudinal dimension of the table or more when the table is viewed from vertically above. The second position may be an imaging position or an imaging preparation position where an image is taken by the medical imaging device. The first position may be surgery position where a shortest distance between the robotic bed and a location of the medical imaging device is at least a predetermined distance.

The present application relates to a heatable system suitable for use in a patient contacting plate used in medical imaging. The system comprises a heatable laminated structure with a plurality of layers each of which is transparent to imaging radiation and allows for thermal transfer. A heater layer, located between two of the plurality of layers, comprises an electrically resistive material and is transparent to imaging radiation. The laminated structure further includes a conductive path suitable for use in coupling a voltage source to the electrically resistive material in the heatable laminated structure, whereby the laminated structure is heated when current is passing through the conductive path. Also disclosed is a compression plate system and an imaging medical device comprising the heatable system. Methods of making the heatable system and of using it in medical imaging are also disclosed.

A breast support platform for an x-ray imaging system includes a housing having a compression plate and a front wall, and a heating system disposed at least partially within the housing. The heating system is configured to heat at least a portion of the compression plate, at least a portion of the front wall, or at least a portion of the compression plate and the front wall. In an example, the heating system includes a transparent conducting film coupled to an inner surface of the housing. In another example, the heating system includes a blower disposed at least partially within the housing, and the blower is configured to channel hot air across an inner surface of the housing.

A breast support platform for an x-ray imaging system includes a housing having a compression plate and a front wall, and a heating system disposed at least partially within the housing. The heating system is configured to heat at least a portion of the compression plate, at least a portion of the front wall, or at least a portion of the compression plate and the front wall. In an example, the heating system includes a transparent conducting film coupled to an inner surface of the housing. In another example, the heating system includes a blower disposed at least partially within the housing, and the blower is configured to channel hot air across an inner surface of the housing.

A support apparatus configured to support a person is provided. The support apparatus includes a top surface including one or more predetermined areas, one or more conduits located inside the support apparatus which are located proximate to the one or more predetermined areas, and an air supply configured to provide air to the one or more conduits for delivering to the one or more predetermined areas. The air supply includes a temperature sensor configured to measure a temperature of the air provided by the air supply, a cooling element, and a controller communicatively coupled to the temperature sensor and the cooling element. The controller determines whether the measured temperature of the air is higher than a predetermined temperature, and controls the cooling element to cool the air to the predetermined temperature if it is determined that the temperature of the air is higher than the predetermined temperature.

A magnetic measuring apparatus includes an inclination gantry including a mount surface and an inclined surface that is inclined with respect to the mount surface, a cryostat disposed on the inclined surface, a cryocooling system connected to the cryostat, a sensor tube connected to the cryostat and including a curved surface that does not curve in a predetermined direction and curves in a direction orthogonal to the predetermined direction such that a center of the curved surface protrudes with respect to side edges of the curved surface, and a magnetic sensor that measures biomagnetism and is housed in the sensor tube such that a sensor surface of the magnetic sensor faces the curved surface. The sensor surface is inclined with respect to the mount surface in a direction that is the same as a direction in which the inclined surface is inclined.