The present disclosure relates to a magnetic resonance apparatus having a scanner unit, a patient receiving region at least partially surrounded by the scanner unit, and a patient positioning apparatus, which has a patient table that is movable within the patient receiving region. The patient positioning apparatus may include a vertical adjusting unit for an adjustment of a vertical position of the patient table within the patient receiving region, and the vertical adjusting unit nay include at least two different vertical positions for a positioning of the patient table within the patient receiving region.

A surgical monitoring system including a machine vision sensor, an electronic controller communicatively coupled to the machine vision sensor, the electronic controller including a processor and a memory storing a computer readable instruction set, where, when the computer readable instruction set is executed by the processor, the electronic controller, detects a position of a subject with the machine vision sensor, detects a position of a person support apparatus, compares the detected position of the subject with the detected position of the person support apparatus, and determines if the detected position of the subject and the detected position of the person support apparatus indicates that the subject is not aligned with the person support apparatus.

Modules for housing electronic and electromechanical medical equipment including a system to measure and record administration of one or more IV medications or fluids for IV administration. A system and method for fusing independent measures of the physiological parameters, in some examples using a Kalman filter for each possible combination of sensor measurements.

A magnetic resonance imaging apparatus according to an embodiment includes a static magnetic field generator, a transmit/receive system, and an acquiring means. The static magnetic field generator is configured to apply a second static magnetic field in addition to a first static magnetic field serving as a reference. The transmit/receive system is configured to perform transmitting and receiving at a single frequency. The processing circuitry is configured to acquire a magnetic resonance signal by employing the transmit/receive system. The transmit/receive system is configured to perform transmitting and receiving at a resonance frequency of a hydrogen nucleus in a state in which the first static magnetic field is applied and is configured to perform transmitting and receiving at a resonance frequency of a nuclide different from the hydrogen nucleus in a state in which the second static magnetic field is applied in addition to the first static magnetic field.

A patient positioning apparatus may include a compressor, a support surface having an upper side with at least one upper opening pore and a lower side with at least two lower opening pores, and a valve having at least one first setting connecting the compressor to at least one lower opening pore of the at least two lower opening pores by a first line and a second setting connecting the compressor to the at least one upper opening pore by a second line. The compressor can create an overpressure in the first line and/or the second line, and/or create a vacuum in the first line and/or the second line.

A rotary imaging system, a plant imager, an animal imager, and an animal and plant imager, relating to the technical field of living sample imaging. The plant imager, the animal imager, and the animal and plant imager all comprise a rotary imaging system. The rotary imaging system comprises the sample table unit is used for carrying a sample; the camera unit is used for imaging the sample; the rotation unit comprises an accommodating cavity accommodating the sample table unit, and the rotation unit is used for driving the camera unit to rotate with respect to the sample table unit and controlling the camera unit to be stationary with respect to the sample table unit. By means of rotary imaging system, powerful data support is provided for the subsequent image reconstruction and image fusion, and the number of cameras required for imaging different parts of a sample is also reduced.

Systems, architectures, and methods of neurophysiological monitoring are described. In a particular example, an architecture may include a monitoring system and display system including two or more display devices. The monitoring system may manage the monitoring of some aspect of a patient's nervous system. A first display device is positioned adjacent the patient and viewable by a first user. A second display device is positioned apart from the patient and viewable by a second user and obscured from the first user. The first display device and the second display device may be used to display monitoring data collected by the monitoring system.

The invention relates to an insertable patient table for a Magnetic Resonance Imaging scanner, wherein the patient table has a length of up to ± 20 % of the length of the bore of the main magnet of the scanner and is adapted for pediatric and/or small patients, and wherein the patient table is adapted to be inserted into the bore of the main magnet without having a stand standing on the floor of an examination room. The invention further relates to a Magnetic Resonance Imaging scanner comprising an insertable patient table and a method for positioning a small and/or pediatric patient within the bore of a main magnet of a Magnetic Resonance Imaging scanner.

A system for scanning an object is provided. The system may include: a supporting table configured to support the object; a first signal conversion unit configured to receive one or more first signals associated with the object and convert the first signals into one or more second signals; and a signal receiver board configured to receive the one or more second signals. The first signal conversion unit may include a plurality of first signal receiving channels. Each first signal receiving channel may be configured to receive a first signal associated with a portion of the object. The supporting table and the signal receiver board may be configured to move relative to each other to cause the signal receiver board to receive at least one second signal corresponding to at least one first signal received by at least one target channel of the first signal receiving channels.

The present disclosure provides a mounting assembly for attaching medical equipment to a patient table. In one particular embodiment, the present disclosure provides a mounting assembly for attaching a magnetic field generator to a patient table. The mounting assembly allows for the secure attachment of the magnetic field generator to the patient table while also allowing for easy adjustment of the positioning and location of the magnetic field generator, even after the patient is on the table. In many embodiments the mounting assembly is comprised of a mounting apparatus that attaches directly to the patient table and first and second side rails that attach to the magnetic field generator and are configured to slidably attach to the mounting apparatus. In some embodiments, the mounting apparatus and side rails are constructed of a material that provides little or no interference with the magnetic field generator.