JP2006141774A - Mri apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide MRI apparatus uniformly impressing an RF magnetic field (Radio Frequency) by a plurality of RF coils. <P>SOLUTION: This MRI apparatus reconstructs an image based on magnetic resonance signals generated by impressing a static magnetic field, a gradient magnetic field and the RF magnetic field by the plurality of RF coils 802-808 to a subject, and is provided with an adjustment means 430 adjusting a ratio of powers to be supplied to the plurality of RF coils so as to uniformize the intensity of the RF magnetic field to be impressed to the subject by the plurality of RF coils. The adjustment means adjusts the ratio based on an RF magnetic field detecting signal by a common sensor 420. Alternatively, the adjustment means adjusts the ratio based on the RF magnetic field detecting signals by sensors for every plurality of RF coils. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an MRI (Magnetic Resonance Imaging) apparatus, and more particularly, to an image based on a magnetic resonance signal generated by applying a static magnetic field, a gradient magnetic field, and an RF magnetic field by a plurality of RF coils (radio frequency coils) to an object. The present invention relates to an MRI apparatus to be reconfigured.

In an MRI apparatus that performs parallel imaging or the like, reception of a magnetic resonance signal from a target is performed using a plurality of RF coils. The reception signals of the plurality of RF coils are respectively received through the plurality of receivers. The plurality of RF coils are configured not to be electromagnetically coupled to each other, and such RF coils are also called phased array coils (see, for example, Patent Document 1).
Japanese Patent Laying-Open No. 2004-097606 (page 5-7, FIG. 1-2)

  Although there are attempts to use a phased array coil as a transmission coil, since the phased array coil is used in close proximity to the object, the positional relationship with the object may be different for each individual RF coil. In such a case, even if the same RF power is supplied to each RF coil, the application of the RF magnetic field to the object by the individual RF coils is not uniform, and appropriate imaging cannot be performed.

  Thus, an object of the present invention is to realize an MRI apparatus in which application of an RF magnetic field by a plurality of RF coils is uniform.

  The present invention for solving the above problems is an MRI apparatus that reconstructs an image based on a magnetic resonance signal generated by applying a static magnetic field, a gradient magnetic field, and an RF magnetic field generated by a plurality of RF coils to a target. An MRI apparatus comprising adjusting means for adjusting a ratio of power supplied to a plurality of RF coils so that the intensity of the RF magnetic field applied to the object by each of the plurality of RF coils is equalized.

The adjustment means preferably adjusts the ratio based on an RF magnetic field detection signal from a common sensor in order to minimize the number of sensors.
The ratio is a ratio at which a signal that matches an RF magnetic field detection signal when an RF magnetic field having the same intensity is generated in each of a plurality of RF coils in a state where no target exists is obtained as an RF magnetic field detection signal by the common sensor. It is preferable in terms of optimizing the power ratio.

The adjustment means preferably adjusts the ratio based on an RF magnetic field detection signal from a sensor for each of a plurality of RF coils in terms of equalizing the RF magnetic field detection conditions.
The ratio is preferably a ratio of the reciprocal of the square of the detection signal in terms of optimizing the power ratio.

It is preferable that the adjusting means adjust the ratio based on individual impedances of a plurality of RF coils in view of using electrical characteristic values of the RF coils.
The ratio is preferably a ratio of the reciprocal of the impedance from the viewpoint of optimizing the power ratio.

  It is preferable that the plurality of RF coils surround the object in a cylindrical shape because it is easy to share the imaging center.

  According to the present invention, the MRI apparatus is an MRI apparatus that reconstructs an image based on a magnetic resonance signal generated by applying a static magnetic field, a gradient magnetic field, and an RF magnetic field generated by a plurality of RF coils to an object. Since there is an adjustment means for adjusting the ratio of the power supplied to the plurality of RF coils so that the intensity of the RF magnetic field applied to the object by each RF coil is equal, the application of the RF magnetic field by the plurality of RF coils is even. Can be.

  The best mode for carrying out the invention will be described below in detail with reference to the drawings. The present invention is not limited to the best mode for carrying out the invention. FIG. 1 shows a block diagram of the MRI apparatus. This apparatus is an example of the best mode for carrying out the invention. An example of the best mode for carrying out the present invention relating to the MRI apparatus is shown by the configuration of the apparatus.

  As shown in the figure, this apparatus has a magnet system 100. The magnet system 100 includes a main magnetic field coil unit 102, a gradient coil unit 106, and an RF coil unit 108. Each of these coil portions has a substantially cylindrical shape and is arranged coaxially with each other.

  The imaging target 1 is mounted on a cradle 500 in a generally cylindrical internal space (bore) of the magnet system 100 and is carried in and out by a conveying means (not shown). For example, the head of the object 1 is accommodated in the RF coil unit 108. The RF coil unit 108 will be described later.

  The main magnetic field coil unit 102 forms a static magnetic field in the internal space of the magnet system 100. The direction of the static magnetic field is generally parallel to the direction of the body axis of the object 1. That is, a so-called horizontal magnetic field is formed. The main magnetic field coil unit 102 is configured using, for example, a superconducting coil. In addition, you may comprise using not only a superconductive coil but a normal conductive coil.

  The gradient coil section 106 generates three gradient magnetic fields for giving gradients to the static magnetic field strength in the directions of three axes perpendicular to each other, that is, the slice axis, the phase axis, and the frequency axis.

  When the coordinate axes perpendicular to each other in the static magnetic field space are x, y, and z, any of the axes can be a slice axis. In that case, one of the remaining two axes is a phase axis, and the other is a frequency axis. In addition, the slice axis, the phase axis, and the frequency axis can have arbitrary inclinations with respect to the x, y, and z axes while maintaining the perpendicularity therebetween. In this apparatus, the body width direction of the object 1 is the x direction, the body thickness direction is the y direction, and the body axis direction is the z direction.

  The gradient magnetic field in the slice axis direction is also called a slice gradient magnetic field. The gradient magnetic field in the phase axis direction is also referred to as a phase encode gradient magnetic field. The gradient magnetic field in the frequency axis direction is also referred to as a read out gradient magnetic field. The readout gradient magnetic field is synonymous with the frequency encoding gradient magnetic field. In order to make it possible to generate such a gradient magnetic field, the gradient coil unit 106 has three gradient coils (not shown). Hereinafter, the gradient magnetic field is also simply referred to as a gradient.

  The RF coil unit 108 forms an RF magnetic field for exciting spins in the body of the subject 1 in the static magnetic field space. Hereinafter, forming the RF magnetic field is also referred to as RF excitation signal transmission or RF transmission. The RF excitation signal is also referred to as an RF pulse.

  An electromagnetic wave generated by the excited spin, that is, a magnetic resonance signal is received by the RF coil unit 108. The magnetic resonance signal is a signal in the frequency domain (Fourier) space.

  If the magnetic resonance signal is encoded in two axes by the gradient in the phase axis direction and the frequency axis direction, the magnetic resonance signal is obtained as a sampling signal for the two-dimensional Fourier space, and the encoding is performed in three axes using the slice gradient. Is obtained as a signal for a three-dimensional Fourier space. Each gradient determines the sampling position of the signal in 2D or 3D Fourier space. Hereinafter, the Fourier space is also referred to as k-space.

  A gradient driving unit 130 is connected to the gradient coil unit 106. The gradient driving unit 130 gives a driving signal to the gradient coil unit 106 to generate a gradient magnetic field. The gradient drive unit 130 has three systems of drive circuits (not shown) corresponding to the three systems of gradient coils in the gradient coil unit 106.

  An RF drive unit 140 is connected to the RF coil unit 108. The RF drive unit 140 gives a drive signal to the RF coil unit 108 to transmit an RF pulse, thereby exciting the spin in the body of the subject 1.

  A data collection unit 150 is also connected to the RF coil unit 108. The data collection unit 150 collects reception signals received by the RF coil unit 108 as digital data.

  A sequence control unit 160 is connected to the gradient driving unit 130, the RF driving unit 140, and the data collecting unit 150. The sequence controller 160 controls the gradient driver 130 or the data collector 150 to collect magnetic resonance signals.

  The sequence control unit 160 is configured using, for example, a computer. The sequence control unit 160 has a memory. The memory stores a program for the sequence control unit 160 and various data. The function of the sequence control unit 160 is realized by the computer executing a program stored in the memory.

  The output side of the data collection unit 150 is connected to the data processing unit 170. Data collected by the data collection unit 150 is input to the data processing unit 170. The data processing unit 170 is configured using, for example, a computer. The data processing unit 170 has a memory. The memory stores a program for the data processing unit 170 and various data.

  The data processing unit 170 is connected to the sequence control unit 160. The data processing unit 170 is above the sequence control unit 160 and controls it. The function of this apparatus is realized by the data processing unit 170 executing a program stored in the memory.

  The data processing unit 170 stores the data collected by the data collection unit 150 in a memory. A data space is formed in the memory. This data space corresponds to k-space. The data processing unit 170 reconstructs an image by performing inverse Fourier transform on k-space data.

  A display unit 180 and an operation unit 190 are connected to the data processing unit 170. The display unit 180 is configured by a graphic display or the like. The operation unit 190 includes a keyboard having a pointing device.

  The display unit 180 displays the reconstructed image and various information output from the data processing unit 170. The operation unit 190 is operated by the user and inputs various commands and information to the data processing unit 170. A user can operate the apparatus interactively through the display unit 180 and the operation unit 190.

  FIG. 2 is a perspective view showing the main part of the RF coil unit 108. As shown in the figure, the RF coil unit 108 has a plurality of coils 802-808. Each of the coils 802 to 808 is a rectangular coil and is disposed so as to form a cylinder as a whole. By arranging in this way, it becomes easy to share the imaging center. The axial direction of the cylinder coincides with the body axis direction. Coils 802 to 808 are an example of a plurality of RF coils in the present invention.

  Here, an example in which the number of coils is four is shown, but other appropriate plural numbers may be used. Each of the coils 802 to 808 forms a closed loop. Each loop is a conductor loop having a capacitor in series. However, the illustration of the capacitor is omitted.

  Coils 802-808 are configured not to be electromagnetically coupled to each other. That is, the coils 802-808 are phased array coils. The phased array coil is realized by providing a neutralization circuit in each loop.

  A state in which the object 1 is accommodated in the RF coil unit 108 is shown in FIG. The figure is a view seen in the body axis direction. The object 1 has a generally elliptical outline, but generally does not have strict body axis symmetry. Furthermore, the body axis does not always coincide with the central axis of the RF coil unit 108. Therefore, the positional relationship between the object 1 and the coils 802 to 808 is different for each coil.

  For this reason, even if all the RF power supplied to the coils 802 to 808 is the same, the RF magnetic field actually applied to the object 1 will be different for each coil due to differences in load conditions and the like. Regardless of the difference in the individual positional relationship between the object 1 and the coils 802 to 808, a means for equalizing the RF magnetic field actually applied to the object 1 is provided. This will be described below.

  FIG. 4 shows an example of main components of the RF coil unit 108, the RF drive unit 140, the data collection unit 150, and the sequence control unit 160. As shown in the figure, the RF driving unit 140 includes power amplifiers 402 to 408 at the output stage. The power amplifiers 402 to 408 are variable gain amplifiers. The power amplifiers 402-408 amplify the power of the input RF pulses and supply them to the coils 802-808 of the RF coil unit 108 through the transmission / reception switchers 412-418, respectively.

  The reception signals of the coils 802 to 808 are respectively input to pre-amplifiers 502 to 508 in the input stage of the data collection unit 150 through the transmission / reception switchers 412 to 418.

  A sensor 420 is provided in the vicinity of the RF coil unit 108 to detect the intensity of the RF magnetic field generated by the RF coil unit 108. The sensor 420 is an example of a common sensor in the present invention. Since a common sensor is used, the number of sensors can be minimized. As the sensor 420, for example, a search coil or the like is used. A detection signal of the sensor 420 is input to the adjustment unit 430.

  The adjustment unit 430 individually adjusts the gains of the power amplifiers 402 to 408 based on the input signal. The individual gains of the power amplifiers 402-408 are adjusted so that the strengths of the RF magnetic fields applied to the object 1 by the coils 802-808 are all the same. The adjustment unit 430 is an example of an adjustment unit in the present invention.

  The gain adjustment will be described. In the gain adjustment, first, the RF power of the same magnetic field strength is generated by sequentially supplying the same RF power to the coils 802 to 808 in a state where the object 1 is not accommodated in the RF coil section 108, and is obtained each time. Each detection value of the sensor 420 is stored. Thus, an RF magnetic field strength detection value at the position of the sensor 420 when the same RF magnetic field is generated in each of the coils 802 to 808 is obtained for each coil.

  Next, in a state where the object 1 is accommodated in the RF coil unit 108, one of the coils 802 to 808, for example, the coil 802, is supplied with the same RF power as above to generate an RF magnetic field. A detection value of the sensor 420 is obtained.

  Even if the same RF power is supplied due to a change in the load condition and the like accompanying accommodation of the object 1, the RF magnetic field generated by the coil 802 is not always the same as in the previous no-load state. When the magnetic field strength is different, a detection value different from the previous detection value is obtained.

  In such a case, the adjustment unit 430 changes the RF power supplied to the coil 802 by adjusting the gain of the power amplifier 402 so that the detected value of the magnetic field strength matches the previous detected value. Since the coincidence of the detected values indicates the coincidence of the magnetic field strengths, at this time, the output power of the power amplifier 402 is RF power that causes the coil 802 to generate an RF magnetic field having the same intensity as when there is no load. As a result, the gain of the power amplifier 402 for supplying the coil 802 with RF power for generating an RF magnetic field having the same strength as that at the time of no load is determined.

  The same gain adjustment is performed for each of the other power amplifiers 404-408, and the gains of the power amplifiers 404-408 for generating the RF magnetic fields having the same intensity as those in the no-load state in the coils 804-808 are determined.

  The gain ratio of the power amplifiers 402-408 thus determined is that of the power amplifiers 402-408 for generating the RF magnetic fields of the same intensity in the coils 802-808 under the current load conditions and the like. Represents the ratio of output power.

  Therefore, at the time of RF excitation for imaging, the output power of the power amplifiers 402-408 is maintained while maintaining this ratio, so that all the RF magnetic field strengths applied from the coils 802-808 to the object 1 can be made equal. . Note that the absolute value of the output power of the power amplifier 402-408, that is, the absolute value of the RF magnetic field intensity is appropriately controlled according to the desired degree of spin excitation.

  FIG. 5 shows another example of main configurations of the RF coil unit 108, the RF drive unit 140, the data collection unit 150, and the sequence control unit 160. In the figure, the same parts as those shown in FIG.

  In the figure, RF magnetic field sensors 422-428 are provided for the coils 802-808. Sensors 422-428 are provided in the vicinity of the corresponding coils, respectively. Sensors 422 to 428 are an example of a sensor for each of a plurality of RF coils in the present invention. By providing a sensor for each of the plurality of RF coils, the RF magnetic field detection conditions can be made equal.

  The adjustment unit 430 individually adjusts the gains of the power amplifiers 402-408 based on the input signals from the sensors 422-428. The individual gains of the power amplifiers 402-408 are adjusted so that the strengths of the RF magnetic fields applied to the object 1 by the coils 802-808 are all the same. The adjustment unit 430 is an example of an adjustment unit in the present invention.

  The gain adjustment will be described. Gain adjustment is performed in a state where the object is accommodated in the RF coil unit 108. That is, in a state where the object 1 is accommodated in the RF coil unit 108, the same RF power is sequentially supplied to the coils 802 to 808 to generate RF magnetic fields, and the detection values of the sensors 422 to 428 obtained respectively are respectively obtained. Ask. Thereby, an RF magnetic field strength detection value when the same RF power is supplied to the coils 802 to 808 is obtained for each coil.

  Because the positional relationship between the object 1 and the coils 802-808 differs for each coil, the RF magnetic fields generated by the coils 802-808 are not necessarily the same even when the same RF power is supplied. When the magnetic field strengths are different, different detection values are obtained by the sensors 422 to 428, respectively.

  The adjustment unit 430 adjusts the gain ratio of the power amplifiers 402-408 so as to be the ratio of the reciprocal of the square of the detection values of the sensors 422-428. The gain ratio of the power amplifiers 402-408 thus determined is that of the power amplifiers 402-408 for generating the RF magnetic fields of the same intensity in the coils 802-808 under the current load conditions and the like. This is the ratio of output power.

  Therefore, RF excitation at the time of imaging is performed while maintaining the ratio of the output power of the power amplifiers 402-408 at this ratio, so that all the RF magnetic field strengths applied to the object 1 from the coils 802-808 are equalized. Can do. The absolute value of the output power of the power amplifier 402-408 is appropriately controlled according to the desired degree of spin excitation.

  FIG. 6 shows another example of the main configuration of the RF coil unit 108, the RF drive unit 140, the data collection unit 150, and the sequence control unit 160. In the figure, the same parts as those shown in FIG.

  In the figure, the impedance of the coils 802 to 808 is measured by the impedance measuring unit 440. As the impedance measuring unit 44, for example, a reflected wave type impedance measuring device or the like is used.

  The adjustment unit 430 individually adjusts the gains of the power amplifiers 402-408 based on the impedance of each of the coils 802-808 input from the impedance measurement unit 440. The individual gains of the power amplifiers 402-408 are adjusted so that the strengths of the RF magnetic fields applied to the object 1 by the coils 802-808 are all the same. The adjustment unit 430 is an example of an adjustment unit in the present invention.

  The gain adjustment will be described. Gain adjustment is performed in a state where the object is accommodated in the RF coil unit 108. That is, the impedances of the coils 802 to 808 are measured in a state where the object 1 is accommodated in the RF coil unit 108.

  Since the positional relationship between the target 1 and the coils 802-808 differs from coil to coil, the impedances of the coils 802-808 are not always the same. If the impedances are different, different values are measured for coils 802-808.

  The adjustment unit 430 adjusts the gain ratio of the power amplifiers 402-408 so as to be the ratio of the reciprocal of the impedance of the coils 802-808. Since the ratio is adjusted based on the individual impedances of the plurality of RF coils, the adjustment using the electrical characteristic values of the RF coils can be performed.

  The gain ratio of the power amplifiers 402-408 thus determined is that of the power amplifiers 402-408 for generating the RF magnetic fields of the same intensity in the coils 802-808 under the current load conditions and the like. This is the ratio of output power.

  Therefore, at the time of RF excitation for imaging, the output power of the power amplifiers 402-408 is maintained while maintaining this ratio, so that all the RF magnetic field strengths applied from the coils 802-808 to the object 1 can be made equal. . Note that the absolute value of the output power of the power amplifier 402-408, that is, the absolute value of the RF magnetic field intensity is appropriately controlled according to the desired degree of spin excitation.

  FIG. 7 shows an example of a pulse sequence for photographing. This pulse sequence is a pulse sequence by EPI (echo planer imaging). The pulse sequence proceeds from left to right. The same applies hereinafter.

  In the figure, (1) shows an RF signal sequence. (2) to (4) are all gradient magnetic field sequences, (2) is a slice gradient, (3) is a frequency encoding gradient, and (4) is a phase encoding gradient. The static magnetic field is always applied with a constant magnetic field strength.

  First, spin excitation is performed with a 90 ° pulse. 180 ° excitation by a 180 ° pulse is performed after a predetermined time of 90 ° excitation. Both are selective excitations under the slice gradient Gslice.

  Next, a phase encode gradient Gphase and a frequency encode gradient Gfreq are applied in a predetermined sequence, and a plurality of echoes are sequentially read out. Multiple echoes have different phase encodings. The echo is represented by the center signal. The same applies hereinafter.

  Such a pulse sequence is repeated a predetermined number of times with a repetition time TR, and a plurality of echoes are read out each time. That is, a multi-shot scan is performed. The echo phase encoding is changed at each repetition, and the entire k-space is sampled by a predetermined number of repetitions. A 2D image is reconstructed by performing a two-dimensional inverse Fourier transform on this data.

  The pulse sequence is not limited to EPI, but may be another appropriate pulse sequence. As a pulse sequence other than EPI, for example, there is a pulse sequence by a 3D gradient echo (3D gradient echo) method.

  FIG. 8 shows the pulse sequence. In the figure, (1) shows the pulse sequence of the RF signal. (2)-(4) each show a pulse sequence of a gradient magnetic field. (2) is the slice gradient and the phase encode gradient in the slice direction, (3) is the frequency encode gradient, and (4) is the phase encode gradient. The static magnetic field is always applied with a constant magnetic field strength.

  First, spin excitation by an α ° pulse is performed. α ° excitation is selective excitation under a slice gradient Gslice. After the α ° excitation, the phase encode gradient Gslice, the frequency encode gradient Gfreq, and the phase encode gradient Gphase in the slice direction are applied in a predetermined sequence, and the echo is read out.

  Such a pulse sequence is repeated a predetermined number of times with a repetition time TR, and an echo is read out each time. The echo phase encoding is changed at each repetition, and the entire k-space is sampled by a predetermined number of repetitions. A 3D image is reconstructed by performing a three-dimensional inverse Fourier transform on this data.

It is a block diagram of an example of the best mode for carrying out the present invention. It is a figure which shows the principal part of a receiving coil part. It is a figure which shows the relationship between a receiving coil part and object. FIG. 2 is a diagram illustrating the configuration of an RF coil unit, an RF drive unit, a data collection unit, and a sequence control unit. FIG. 2 is a diagram illustrating the configuration of an RF coil unit, an RF drive unit, a data collection unit, and a sequence control unit. FIG. 2 is a diagram illustrating the configuration of an RF coil unit, an RF drive unit, a data collection unit, and a sequence control unit. It is a figure which shows an example of the pulse sequence for magnetic resonance imaging. It is a figure which shows an example of the pulse sequence for magnetic resonance imaging.

Explanation of symbols

1 Target 100 Magnet system 102 Main magnetic field coil unit 106 Gradient coil unit 108 RF coil unit 110 Reception coil unit 130 Gradient drive unit 140 RF drive unit 150 Data collection unit 160 Sequence control unit 170 Data processing unit 180 Display unit 190 Operation unit 500 Cradle 802-808 Coil 402-408 Power amplifier 412-418 Transmission / reception switcher 420-428 Sensor 430 Adjustment unit 440 Signal measurement unit 450 Impedance measurement unit

Claims (8)

An MRI apparatus for reconstructing an image based on a magnetic resonance signal generated by applying a static magnetic field, a gradient magnetic field, and an RF magnetic field generated by a plurality of RF coils to an object,
Adjusting means for adjusting the ratio of the power supplied to the plurality of RF coils so that the intensity of the RF magnetic field applied to the object by the plurality of RF coils is equal;
An MRI apparatus characterized by comprising: The adjusting means adjusts the ratio based on an RF magnetic field detection signal from a common sensor.
The MRI apparatus according to claim 1. The ratio is a ratio at which a signal that matches an RF magnetic field detection signal when an RF magnetic field having the same intensity is generated in each of a plurality of RF coils in a state where no target exists is obtained as an RF magnetic field detection signal by the common sensor. Is,
The MRI apparatus according to claim 2, wherein: The adjusting means adjusts the ratio based on an RF magnetic field detection signal from a sensor for each of a plurality of RF coils.
The MRI apparatus according to claim 1. The ratio is a ratio of the reciprocal of the square of the detection signal.
The MRI apparatus according to claim 4. The adjusting means adjusts the ratio based on individual impedances of a plurality of RF coils;
The MRI apparatus according to claim 1. The ratio is a ratio of the reciprocal of the impedance.
The MRI apparatus according to claim 8. The plurality of RF coils surround the object in a cylindrical shape,
The MRI apparatus according to any one of claims 1 to 7, wherein the MRI apparatus is characterized in that:

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