JPH0686770A - Magnetic resonance imaging system - Google Patents

Abstract

PURPOSE:To obtain a diagnostic tomographic image being free from an image distortion by preventing a fact that a slice position of the diagnostic tomographic image is set to an area deviated from a uniform static magnetic field space. CONSTITUTION:This system device is provided with a uniform static magnetic field area display means 6 for displaying an area on a display screen of a uniform static magnetic field space on a display device 20 together with a positioning tomographic image, at the time of slice-positioning a diagnostic tomographic image on the positioning tomographic image.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention displays a positioning tomographic image which has been obtained in advance on a display device, and a magnetic slice on which a diagnostic tomographic image different from the above can be slice-positioned. The present invention relates to improvement of a resonance imaging apparatus.

[0002]

2. Description of the Related Art Generally, a magnetic resonance imaging apparatus is
Magnetic field generating means for applying a static magnetic field and a gradient magnetic field to the subject,
A transmission system for irradiating a high frequency signal in order to cause nuclear magnetic resonance in atomic nuclei constituting the biological tissue of the subject, a receiving system for detecting an echo signal emitted by the nuclear magnetic resonance, and this receiving system A signal processing system for performing a tomographic image reconstruction calculation using the echo signal detected in step 1, and a display device for displaying the tomographic image reconstructed by this signal processing system.

In such a magnetic resonance imaging apparatus, the difference in magnetic field strength from the center of the static magnetic field is a constant value (Equation 1).
A space equal to or less than 0 ppm) is defined as a uniform static magnetic field space, and a tomographic image in this uniform static magnetic field space can be regarded as having no image distortion.

Conventionally, a positioning tomographic image obtained in advance is displayed on a display device, and a slice positioning (setting) of a diagnostic tomographic image different from this is possible on the positioning tomographic image. Resonance imaging devices are widely known.

[0005]

In the conventional magnetic resonance imaging apparatus of this kind, when the slice position of the diagnostic tomographic image is positioned on the positioning tomographic image displayed on the display device, the magnetic field deviates from the center of the static magnetic field. It is not uncommon to set the slice position, but when imaging is performed with such position setting, a part or all of the obtained diagnostic tomographic image becomes an image in a region outside the uniform static magnetic field space, resulting in image distortion. There was a problem that caused.

An object of the present invention is to display a region of a uniform static magnetic field space together with a positioning tomographic image on a display device when setting a slice position of a diagnostic tomographic image so that the slice position of the diagnostic tomographic image is uniform. It is an object of the present invention to provide a magnetic resonance imaging apparatus capable of preventing a setting in a region outside the magnetic field space and obtaining a diagnostic tomographic image without image distortion.

[0007]

[Means for Solving the Problems] The above-mentioned object is to provide a magnetic field generating means for applying a static magnetic field and a gradient magnetic field to a subject, and a high frequency for causing nuclear magnetic resonance in atomic nuclei of atoms constituting the biological tissue of the subject. A transmission system for irradiating a signal, a reception system for detecting an echo signal emitted by the nuclear magnetic resonance, a signal processing system for performing a tomographic image reconstruction operation using the echo signal detected by the reception system, and this signal A display device for displaying a tomographic image reconstructed by a processing system, and a previously obtained positioning tomographic image is displayed on the display device, and a diagnostic tomographic image separate from the tomographic image for positioning is displayed on the tomographic image for positioning. In a magnetic resonance imaging apparatus capable of slice positioning of an image, when performing slice positioning of a diagnostic tomographic image on the positioning tomographic image, the positioning is performed on the display device. With the tomographic image is accomplished by providing a uniform static magnetic field region display means for displaying the region on the display screen of the homogeneous static magnetic field space.

[0008]

The uniform static magnetic field area display means displays the area on the display screen of the uniform static magnetic field space together with the positioning tomographic image on the display device when performing slice positioning of the diagnostic tomographic image on the positioning tomographic image. indicate.

As a result, the operator can perform slice positioning so as not to deviate from the displayed uniform static magnetic field region. Therefore, it is possible to obtain a diagnostic tomographic image without image distortion in which the influence of the non-uniform static magnetic field in the peripheral portion away from the center of the static magnetic field is minimized.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of a magnetic resonance imaging apparatus according to the present invention.

The magnetic resonance imaging apparatus obtains a tomographic image of a subject by utilizing a nuclear magnetic resonance (NMR) phenomenon. As shown in FIG. 1, a static magnetic field generating magnetic circuit 2 and a gradient magnetic field generating system 3 are provided. 1, a transmission system 4, a reception system 5, a signal processing system 6, a sequencer 7, and a CPU (central processing unit) 8.

The static magnetic field generating magnetic circuit 2 generates a uniform static magnetic field around the subject 1 in the body axis direction or in the direction orthogonal to the body axis, and spreads a certain spread around the subject 1. A magnetic field generating means of permanent magnet type, normal conducting type or superconducting type is arranged in the space provided.

The gradient magnetic field generation system 3 includes gradient magnetic field coil groups 9a to 9c (9c is not shown) wound in three axial directions of X, Y and Z, and gradients for driving the gradient magnetic field coil groups 9a to 9c. The magnetic field power supply 10 and each of the gradient magnetic field coil groups 9a to 9 according to an instruction from the sequencer 7 described later.
By driving the gradient magnetic field power source 10 of c, X, Y,
The gradient magnetic fields Gs, Gp, and Gf in the Z triaxial directions are applied to the subject 1. The slice plane for the subject 1 can be set by the method of applying the gradient magnetic field.

The transmission system 4 irradiates a high-frequency signal in order to cause nuclear magnetic resonance in the atomic nuclei of the atoms constituting the biological tissue of the subject 1 by the high-frequency magnetic field pulse sent from the sequencer 7 described later. The oscillator 11, the modulator 12, the high frequency amplifier 13, and the high frequency coil 14a on the transmission side.
The high frequency pulse output from the high frequency oscillator 11 is amplitude-modulated by the modulator 12 according to the instruction of the sequencer 7, and the amplitude-modulated high-frequency pulse is amplified by the high-frequency amplifier 13 and then close to the subject 1. Electromagnetic waves are radiated to the subject 1 by being supplied to the arranged high frequency coil 14a.

The receiving system 5 detects an echo signal (NMR signal) emitted by nuclear magnetic resonance of atomic nuclei of the living tissue of the subject 1, and includes a high frequency coil 14b on the receiving side, an amplifier 15 and a quadrature phase detector. 16 and an A / D converter 17, the electromagnetic wave (NMR signal) of the response of the subject 1 due to the electromagnetic wave emitted from the high-frequency coil 14a on the transmission side is placed in the high-frequency coil 14 close to the subject 1.
detected by b, input to the A / D converter 17 through the amplifier 15 and the quadrature detector 16, converted into a digital amount, and further sampled by the quadrature detector 16 at the timing according to the instruction from the sequencer 7. Two series of collected data are provided, and the signals thereof are sent to the signal processing system 6.

The signal processing system 6 comprises a CPU 8, a data recording device such as a magnetic disk device 18 and a magnetic tape device 19, and a display device 20 such as a CRT device. The CPU 8 performs Fourier transform, correction coefficient calculation,
Processing such as tomographic image reconstruction is performed, and a signal intensity distribution of an arbitrary cross section or a distribution obtained by performing appropriate calculation on a plurality of signals is imaged and displayed as a tomographic image on the display device 20.

The sequencer 7 is a control means for repeatedly applying a high frequency magnetic field pulse for causing nuclear magnetic resonance to the atomic nuclei of the atoms constituting the biological tissue of the subject 1 in a predetermined pulse sequence, and is controlled by the CPU 8. Various commands necessary for collecting tomographic image data of the subject 1 are sent to the transmission system 4, the gradient magnetic field generation system 3 and the reception system 5.

FIG. 2 is a perspective view of a gantry 27 using a permanent magnet which forms the magnetic field generating means of the static magnetic field generating magnetic circuit 2, and FIG. 3 is a partially cut side view of FIG.

As shown in both figures, the gantry 27 (permanent magnet type static magnetic field generating means) comprises disk-shaped permanent magnets 21a and 21b arranged so as to face each other. In this case, the permanent magnets 21a and 21b are fixed to approximately the central portions of the flat yokes 22a and 22b, respectively.

These yokes 22a, 22b are opposed and held at positions separated by a constant distance by four columnar yokes 23 in order to form a uniform static magnetic field space 28 between them. Here, the four columnar yokes 23 face and hold them at positions where the permanent magnets 21a and 21b of the yokes 22a and 22b are not fixed, that is, at four corners of the yokes 22a and 22b. There is.

Magnetic pole pieces 25a and 25b for generating a uniform static magnetic field space 28 are arranged on the surfaces facing the permanent magnets 21a and 21b, respectively. The magnetic pole pieces 25a and 25b have a disk shape, and an annular protrusion 24 is provided on the periphery thereof.

In each of the magnetic pole pieces 25a and 25b, the gradient magnetic field coil groups 9a and 9b are arranged in the area surrounded by the annular projection 24. The gradient magnetic field coil groups 9a and 9b are provided in the uniform static magnetic field space 28.
It is driven in order to select the position where the echo signal is taken out from the subject 1 placed on.

Further, under the gradient magnetic field coil group 9a (in FIG. 3,
A compensation coil group 26a is provided in the upper magnetic pole piece 25a, and a magnetic pole piece 2 is provided below the gradient magnetic field coil group 9b (lower side in FIG. 3).
A compensation coil group 26b is arranged in 5b.

In such a configuration, the static magnetic field generating magnetic circuit 2 and the gradient magnetic field generating system 3 give a static magnetic field and a gradient magnetic field to the subject 1, while the transmitting system 4 irradiates a high frequency signal, and the subject 1 The emitted echo signal is detected by the reception system 5, the tomographic image reconstruction calculation is performed by the signal processing system 6 using the detected echo signal, and the reconstructed tomographic image is displayed on the display device 20. At this time, it is possible to display a positioning tomographic image obtained in advance on the display device 20 and perform slice positioning (setting) of a diagnostic tomographic image different from this on the positioning tomographic image.

Although the above is not particularly different from that of the conventional apparatus, in the present invention, in addition to this, when performing slice positioning of a diagnostic tomographic image on the positioning tomographic image, the display device 20 is used for the positioning. Uniform static magnetic field region display means for displaying a region on the display screen of the uniform static magnetic field space together with the tomographic image is provided. In the example of FIG. 1, the uniform static magnetic field area display means is provided in the ROM 3 in the signal processing system 6.
1, RAM 32, keyboard 33 and trackball 3
4 is added and is integrated with the signal processing system 6. Here, the ROM 31 stores a program for displaying the uniform static magnetic field region, invariant parameters used in the execution, and the like. Further, the RAM 32 temporarily stores various parameters and the tomographic image 41 for positioning. The keyboard 33 and the trackball 34 input various parameters and commands. The CPU 8 executes various calculations and programs necessary for displaying the uniform static magnetic field region.

ROM 31, RAM 32, keyboard 33
If the trackball 34 and the like are already provided for other purposes, they may be shared. Also here
Since the case where the uniform static magnetic field space is spherical is taken as an example, the region on the display screen of the uniform static magnetic field space is displayed in a circle.

That is, FIG. 4 shows a substantially static uniform magnetic field space 28 (FIG. 4A shows a plan view thereof and is represented by a circle) and a positioning tomographic image 41 (FIG. 4B). ) .The substance of the tomographic image is omitted here.)
The relationship between the area display on the display screen of the uniform static magnetic field space 28 displayed on the display device 20 together with the positioning tomographic image 41, here, the circular display 42 is shown. In FIG. 4, 43 indicates the center of the static magnetic field, which is AA ′.
A line 44 indicates the slice position of the positioning tomographic image 41 (positioning tomographic image capturing position). Further, r0 is the radius of the uniform static magnetic field space 28, d is the distance from the static magnetic field center 43 to the slice position 44, r1 is the radius of the circular display 42, and the radius r
1 is calculated by the following equation (1).

R1 = (r0 ² −d ² ) ^1/2 (1) The shape of the uniform static magnetic field space 28 is not actually spherical, but here, it is assumed that this is represented by a spherical shape. There is.

As shown in FIG. 4B, the positioning tomographic image 41 and the circular display 42 showing the region on the display screen of the uniform static magnetic field space 28 are shown on the display device 20, so that the positioning tomographic image 41 is obtained. When the slice position (imaging position) of the tomographic image for diagnosis is set using the circular display 4
If this is performed while visually observing 2, the slice position of the diagnostic tomographic image will not be set in a region outside the uniform static magnetic field space 28, and a diagnostic tomographic image without image distortion can be obtained.

In practice, when setting the slice position of the diagnostic tomographic image, the display device 20 further displays a slice setting cursor 54 representing the slice position center 51, the slice effective visual field 52, the slice thickness 53, etc. It is possible to simplify slice position setting without distortion. In the example shown in FIG. 4B, the slice setting cursor 5
Seen from the position 4, it is predicted that the slice position is set in a region outside the uniform static magnetic field space 28.

FIG. 5 is a view showing the state of slice position setting more specifically. In FIG. 5, reference numeral 55 designates a diseased part in the tomographic image 41 for positioning, and the same reference numerals as those in FIG. 4 designate the same or corresponding portions. Show. As shown in the drawing, when setting the slice position, first, the positioning tomographic image 41 along the line AA ′ is read from the magnetic disk device 18 to the RAM 31 and displayed on the display device 20. When the CPU 8 executes the program stored in the ROM 31 on the positioning tomographic image 41, the circular display 42 according to the above equation (1) is executed on the display device 20.

Next, the slice setting cursor 54 is also displayed on the display device 20, and the keyboard 33 and the trackball 34 are operated while visually recognizing the positioning tomographic image 41 and the circular display 42, and shown in the slice setting cursor 54. The slice position center 51, the slice effective visual field 52, the slice thickness 53, etc. are adjusted. For example, as shown in the figure, the slice position center 51 is aligned near the affected area 55, the slice effective visual field 52 is accommodated within the circular display 42, and the slice setting cursor 54 is adjusted so that the affected area 55 is accommodated within the slice thickness 53. , The slice position (imaging position) of the diagnostic tomographic image is set.

According to this, the slice position of the diagnostic tomographic image is set in the uniform static magnetic field space 28, and a diagnostic tomographic image without distortion can be obtained.

[0034]

As described above, according to the present invention, when the positioning tomographic image is displayed on the display device and the slice positioning of the diagnostic tomographic image is performed on the positioning tomographic image, the positioning is performed at that time. Since the area on the display screen of the uniform static magnetic field space is displayed together with the tomographic image, it is prevented that the slice position of the diagnostic tomographic image is set to an area outside the uniform static magnetic field space, and there is no image distortion. There is an effect that a diagnostic tomographic image can be obtained.

[Brief description of drawings]

FIG. 1 is a block diagram showing an embodiment of a device of the present invention.

FIG. 2 is a perspective view of a gantry using a permanent magnet that forms a magnetic field generating means of a static magnetic field generating magnetic circuit of the above apparatus.

FIG. 3 is a partially cut side view of FIG.

FIG. 4 is a diagram showing a relationship between a uniform static magnetic field space, a tomographic image for positioning, and an area display (circular display) on the display screen of the uniform static magnetic field space displayed on the display device together with the tomographic image for positioning. .

FIG. 5 is a diagram more specifically showing a state of slice position setting.

[Explanation of symbols]

 1 subject 2 magnetic field generating magnetic circuit 3 gradient magnetic field generating system 4 transmitting system 5 receiving system 6 signal processing system (uniform static magnetic field region display means) 7 sequencer 8 CPU 18 magnetic disk device 19 magnetic tape device 20 display device 28 uniform static Magnetic field 31 ROM 32 RAM 33 Keyboard 34 Trackball 41 Positioning tomographic image 42 Circular display 43 Static magnetic field center 44 Slice position 51 of positioning tomographic image Center 52 Slice position center 52 Slice effective field 53 Slice thickness 54 Slice setting cursor 55 Affected part

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Claims (1)

[Claims] 1. A magnetic field generation means for applying a static magnetic field and a gradient magnetic field to a subject, and a transmission system for irradiating a high frequency signal in order to cause nuclear magnetic resonance in atomic nuclei of atoms constituting the biological tissue of the subject. A receiving system that detects an echo signal emitted by the nuclear magnetic resonance, and a signal processing system that performs a tomographic image reconstruction operation using the echo signal detected by the receiving system,
A display device for displaying a tomographic image reconstructed by the signal processing system, displaying a positioning tomographic image obtained in advance on the display device, and performing a diagnostic on the positioning tomographic image separately from the diagnostic tomographic image. In a magnetic resonance imaging apparatus capable of slice positioning of a tomographic image for diagnosis, when performing slice positioning of a tomographic image for diagnosis on the tomographic image for positioning, a uniform static magnetic field space is displayed on the display device together with the tomographic image for positioning. A magnetic resonance imaging apparatus comprising: a uniform static magnetic field region display means for displaying a region on a screen.