SPECIFIC ABSORPTION RATE MODULATED BY SPATIAL PROXIMITY TO PATIENT Russian patent published in 2019 - IPC A61B5/55 G01R33/58 

Abstract RU 2700468 C2

FIELD: medicine.

SUBSTANCE: group of inventions relates to medical equipment, specifically to means for magnetic resonance imaging. Method of operation of a magnetic resonance imaging system based on adjustment of a radio-frequency excitation field B1, applied to analyzed subject to be tomographed, comprises steps of determining at least one position parameter (d), which indicates the position of at least a portion of the analyzed subject with respect to at least one radio frequency transmitting antenna of the magnetic resonance imaging system and is carried out by using proximity detection unit, which includes at least two proximity sensors (D1, D9), determination by means of two proximity sensors (D1, D9) of at least one transverse dimension (wi) of the analyzed subject for a plurality of locations (zi) of at least part of analyzed subject, obtaining data for generating a geometric outline of the analyzed subject with respect to said at least one radio frequency transmitting antenna of the magnetic resonance imaging system from parameters (di) position and transverse dimensions (wi) defined on said plurality of locations (zi), adjustment of at least one radio-frequency power parameter of radio-frequency signal power, to be transmitted to said at least one radio frequency transmitting antenna, depending on at least one of the determined at least one position (d) position and the determined geometric size (w) of the analyzed subject. Magnetic resonance imaging system is configured to obtain magnetic resonance images of at least part of the analyzed subject and comprises a scanning unit providing a test space for accommodating at least a portion of the analyzed subject, wherein the test space has an input region for the analyzed subject to enter the examination space, and the scanning unit further has a main magnet configured to generate a static magnetic field B0 in the surveyed space, a magnetic field gradient coil system configured to generate gradient magnetic fields, superimposed on static magnetic field B0, at least one radio frequency transmitting antenna, which is configured to apply a radio-frequency excitation field B1 to nuclei of analyzed subject or nuclei inside part of investigated subject for magnetic resonance excitation, at least one radio-frequency receiving antenna which is configured to receive magnetic resonance signals from nuclei of the analyzed subject or nuclei within a portion of the analyzed subject which have been excited by applying a radio-frequency excitation field B1, control unit configured to control functions of the magnetic resonance imaging system, and proximity detection unit, including at least one proximity sensor (D), which is configured to determine at least one position parameter (d), which indicates position of at least part of analyzed subject in relation to said at least one radio-frequency transmitting antenna, wherein the control unit is configured to perform the method steps.

EFFECT: use of inventions makes it easier to monitor and verify the position of the analyzed subject.

8 cl, 5 dwg

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RU 2 700 468 C2

Authors

Harvey, Paul Royston

Dates

2019-09-17Published

2015-05-27Filed