An arrangement for shimming a background magnetic field of a magnetic resonance imaging apparatus having an outer vacuum chamber (OVC) bore tube (1). Rails (8, 9) are provided on the OVC bore tube and shim trays (4) are mounted between respective rails.

A coil system for a magnetic resonance tomography system includes a plurality of coils for sending and/or receiving high-frequency signals. The plurality of coils is disposed in a receiving chamber between a tomography magnet and a lining of an opening in the tomography magnet and may be cooled by a cooling apparatus. When the coil system is in an operating state, the receiving chamber is filled with a cryogenic cooling medium.

A coil for single-sided magnetic resonance imaging system is disclosed. The coil is configured to generate a magnetic field outwards away from the coil. The coil includes a first ring and a second ring having different diameters and the current flows through the coil to generate the magnetic field in a region of interest. A method of imaging via a magnetic imaging apparatus is also disclosed. The method includes providing a power source and providing a coil that includes a first ring and a second ring having different diameters. The method includes turning on the power source so as to flow a current through the coil to generate a magnetic field in a region of interest. The method also includes selectively turning on a particular set of electronic components so as to pulse the magnetic field in a narrower frequency range.

A magnetic resonance imaging antenna (114) comprising one or more coil elements (115) is disclosed. The magnetic resonance imaging antenna further comprises a radio frequency system (116) coupled to the one or more coil elements. The magnetic resonance imaging antenna further comprises a gas inlet (200) configured for receiving a pressurized gas. The magnetic resonance imaging antenna further comprises a gas outlet (202) configured for venting the pressurized gas. The magnetic resonance imaging antenna further comprises an electrical generator (117) configured for converting mechanical energy resulting from passing the pressurized gas from the gas inlet to the gas outlet into electricity while in the presence of an external magnetic field. The electrical generator is configured to power the radio frequency system using the electricity.

Apparatus for imaging during surgical procedures includes an operating room for the surgical procedure and an MRI for obtaining images periodically through the surgical procedure by moving the magnet up to the table. The magnet wire is formed of a superconducting material such as magnesium di-boride or Niobium-Titanium which is cooled by a vacuum cryocooling system to superconductivity without use of liquid helium. The magnet weighs less than 1 to 2 tonne and has a floor area in the range 15 to 35 sq feet so that it can be carried on the floor by a support system having an air cushion covering the base area of the magnet having side skirts so as to spread the weight over the entire base area. The magnet remains in the room during surgery and is powered off to turn off the magnetic field when in the second position remote from the table.

A cryogenic device for cooling an RF coil of a Magnetic Resonance Imaging scanner. The cryogenic device includes: a cryocooler providing a cold source; a solid thermal link; the solid thermal link in thermal contact with the cryocooler; a RF coil holder for holding the RF coil, the RF coil holder being in thermal contact with thermal link; a vacuum chamber enclosing the solid thermal link and the RF-coil holder; a measurement surface, facing the RF coil holder; wherein each one of the cryocooler, the solid thermal link, the RF coil holder and the measurement surface is magnetic material free.

According to one embodiment, a magnetic resonance imaging system includes a first imaging apparatus, a first cooling system, a second imaging apparatus, a second cooling system and a cooling control device. The first imaging apparatus includes a first magnet configured to generate a static magnetic field. The first cooling system is configured to cool the first magnet. The second imaging apparatus includes a second magnet configured to generate a static magnetic field. The second cooling system is configured to cool the second magnet. The cooling control device is configured to switch a cooling target of each of the first cooling system and the second cooling system.

A method of monitoring depletion of a coolant in a cooling system associated with imaging modality is disclosed. The method includes receiving set of signal values from sensing unit, wherein set of signal values correspond to parameters of cooling system, determining class associated with set of signal values using an artificial intelligence model, selecting prediction model capable of predicting depletion rate of the coolant based on class associated with set of signal values, computing depletion rate of coolant in cooling system based on set of signal values using the selected prediction model, determining number of days remaining to refill the coolant in cooling system based on the depletion rate of the coolant in cooling system, and generating warning signal on graphical user interface, warning signal indicative of number of days remaining to refill coolant in cooling system.

A pediatric magnetic resonance imaging (MRI) system is provided. The pediatric MRI system includes a radio frequency (RF) coil configured to image a portion of a patient. The pediatric MRI system also includes a cryo-cooling mechanism operatively coupled to the RF coil. The cryo-cooling mechanism is configured to maintain a temperature of the RF coil within a prescribed temperature range.

The NMR probe head comprises a base and a tube. A coil is arranged in the tube. A tuning and matching circuit is also arranged in the tube adjacent to the coil. The coil and/or the tuning and matching circuit comprise several tunable elements. Several actuators are arranged in the tube for actuating the tunable elements. The actuators are located in in a compact actuator assembly.