JP4031092B2 - Magnetic resonance diagnostic equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a magnetic resonance diagnostic apparatus capable of three-dimensional MR angiography (blood flow imaging method) that effectively captures blood flow of a head or the like by applying fat suppression.
[0002]
[Prior art]
FIG. 10 shows a pulse sequence of a conventional three-dimensional MR angiography based on the field echo method. The principle of MR angiography is that stationary objects such as brain parenchyma and organs in the imaging volume are excited one after another while their longitudinal magnetization has not recovered much, so the signal level gradually decreases. Since (water) always flows into the volume in a fresh state, the signal drop is not as high as that of a stationary object. For this reason, an image (blood flow image) in which blood flow is relatively emphasized as compared with a stationary object is obtained.
[0003]
In such MR angiography, various contrivances have been made to improve image quality. Typically, each time the imaging sequence is repeated, a fat suppression pulse is applied as a pre-pulse immediately before the imaging sequence to suppress fat suppression (see FIG. 11).
[0004]
In recent years, an RF pulse called an MTC (Magnetization Transfer Contrast) pulse composed of a SINC pulse and an offset pulse and slightly shifted from the resonance frequency of water protons is applied as a pre-pulse immediately before the imaging sequence, Due to the MTC effect between the protons of water and the protons of macromolecules mainly constituting the brain parenchyma, the signal from the brain parenchyma is made relatively weaker than the signal from the water (blood), and the blood flow Techniques have been developed to increase extraction ability.
[0005]
Further, by applying this technique, as disclosed in Japanese Patent Laid-Open No. 6-319715, an MTC pulse is applied together with a slice selective gradient magnetic field (SORS pulse), and the SORS pulse is applied from the imaging region 22 from the heart. A technique for enhancing arterial flow by exciting the far region 21 has also been developed (FIG. 12).
[0006]
Although the three-dimensional MR angiography is devised in various ways as described above, since the fat suppression pulse is applied every time the MR sequence is acquired by repeating the imaging sequence as described above, the entire region of the three-dimensional k-space is obtained. Over time, the side lobe (broadband) of the fat suppression pulse is affected with magnetic field inhomogeneity, and the proton of water is suppressed together with fat, resulting in a situation where the blood flow image is completely dropped. There was a possibility.
[0007]
In order to reduce the influence of the side lobe of the fat suppression pulse, it is effective to extend the fat suppression pulse having a sinc waveform from ± π length to ± 4 · π length, for example, to narrow the band. However, if the fat suppression pulse is lengthened, the imaging time must be extended accordingly, which causes clinical inconvenience. Furthermore, in MR angiography, as described above, insufficient recovery of longitudinal magnetization is used to reduce the signal of a stationary object. Therefore, it is very unacceptable to extend a fat suppression pulse that increases the repetition time TR. .
[0008]
[Problems to be solved by the invention]
An object of the present invention is to provide a magnetic resonance diagnostic apparatus capable of three-dimensional MR angiography, in which MR signals from the bloodstream do not decrease so much and the fat control effect can be sufficiently maintained.
[0009]
[Means for Solving the Problems]
An aspect of the present invention includes a gradient magnetic field applying unit capable of applying a gradient magnetic field superimposed on a static magnetic field, and an RF transmission / reception capable of transmitting an RF pulse to a subject in the static magnetic field and receiving an MR signal from the subject. And a control means for controlling the gradient magnetic field applying means and the RF transmitting / receiving means, wherein the control means includes a fat suppression pulse and an MTC pulse for a low frequency region in the k space. As a pre-pulse and MR signals are collected by an imaging sequence, and in the high-frequency region in the k space, the MTC pulse is applied without applying the fat suppression pulse and MR signals are collected by the imaging sequence. For this purpose, the gradient magnetic field applying means and the RF transmitting / receiving means are controlled.
[0010]
(Function)
The influence of the side lobe of the fat saturation pulse with the magnetic field inhomogeneity is not limited to the whole area of the three-dimensional k-space as in the past, but only to a partial area near the origin that is dominant in the image contrast. The blood flow signal does not drop so much, and an additional effect by the pre-pulse can be exhibited.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a magnetic resonance diagnostic apparatus according to the present invention will be described with reference to the drawings. FIG. 1 shows the configuration of a magnetic resonance diagnostic apparatus according to this embodiment. The coil gantry 20 is provided with a static magnetic field magnet 1, a gradient magnetic field coil 2, and an RF coil 3. The gradient coil 2 receives current from gradient magnetic field power supplies 7, 8, and 9 corresponding to three orthogonal XYZ axes, and applies XYZ to the static magnetic field formed by the static magnetic field magnet 1 and the static magnetic field control device 4. It is provided to superimpose the gradient magnetic field of each axis. These three-axis gradient magnetic fields are individually or appropriately combined to determine the width and position of the imaging volume, and to apply slice encoding to the MR signal, gradient magnetic field G _S (G _SE ), and phase encode the MR signal. A gradient magnetic field G _PE for applying a frequency gradient and a gradient magnetic field G _RO for applying frequency encoding to an MR signal are formed.
[0012]
The RF coil 3 is provided for applying an RF pulse to the subject P together with the transmitter 5 and for receiving an MR signal from the subject together with the receiver 6. Here, the RF coil 3 is used for both transmission and reception, but transmission and reception may be provided separately.
[0013]
The sequencer 10 controls the transmitter 5, the receiver 6, and the gradient magnetic field power supplies 7, 8, 9 according to a predetermined pulse sequence described later. The computer system 11 has an arithmetic function for reconstructing an MR image, here, a blood flow image from the MR signal from the receiver 6 according to the 3DFT (three-dimensional Fourier transform) method, in addition to the function as a host computer of the entire apparatus. is doing. A blood flow image reconstructed by the computer system 11 is displayed on the display unit 12.
[0014]
FIG. 2 shows a low-frequency region on a three-dimensional k-space that is selectively subjected to fat suppression according to the present embodiment, and FIG. 3A shows an MR signal for collecting the low-frequency region of FIG. FIG. 3B shows a pulse sequence for collecting MR signals in a high frequency region other than the low frequency region in FIG. As can be seen from these figures, the imaging sequence is assembled according to the short TR field echo method and the 3DFT (three-dimensional Fourier transform) method. The imaging sequence may be a combination of a 3DFT method and a generation sequence such as an echo other than the short TR field echo method.
[0015]
In this embodiment, when acquiring MR signals in a low-frequency region dominant in image contrast with respect to the slice encoding direction on the three-dimensional k-space in this imaging sequence, a SORS pulse and a fat suppression pulse are used as prepulses immediately before that. However, when MR signals in the high frequency region are collected, the SORS pulse and the fat suppression pulse are not applied.
[0016]
As described above, since the SORS pulse and the fat saturation pulse are not applied in the high frequency region, the influence of the side lobe of the fat saturation pulse caused by the magnetic field inhomogeneity is, as in the conventional case, the entire area of the three-dimensional k space. Not only the low-frequency region that is dominant in the image contrast, but the blood flow signal does not drop drastically, and there are additional effects such as a fat suppression effect and a brain parenchyma suppression effect by SORS pulse. it can.
[0017]
Further, since the SORS pulse and the fat suppression pulse are not applied in the high frequency region, as shown in FIG. 4, the repetition time TR _HIGH when collecting MR signals in the high frequency region on the three-dimensional k space by the imaging sequence is low frequency. The imaging time can be shortened by shortening the repetition time TR _LOW when collecting MR signals in the region.
[0018]
The excitation pulse in the imaging sequence may be an ISCE pulse developed for the purpose of rendering blood flow far from the heart in the artery with a contrast equivalent to blood flow close to the heart. In the arterial blood flow far from the heart, the number of excitations is larger than in the arterial blood flow close to the heart, and the signal level may be reduced in the same way as a stationary object depending on the number of excitations.
[0019]
A power profile file of a general excitation pulse is formed almost constant as shown in FIG. On the other hand, in the ISCE pulse, as shown in FIG. 5B, the power profile is shaped such that the power increases as the distance from the heart increases. According to such a power profile, the farther away from the heart, the deeper the flip angle can be made, so that a decrease in signal level can be compensated.
[0020]
According to the present embodiment, blood flow is sufficiently drawn to the periphery even though fat and brain parenchyma are sufficiently suppressed.
[0021]
In the above description, when collecting the MR signal in the low frequency region with respect to the slice encoding direction on the three-dimensional k space, the SORS pulse and the fat suppression pulse are applied immediately before, but when collecting the MR signal in the high frequency region, Although it has been described that the SORS pulse and the fat saturation pulse are not applied immediately before that, as shown in FIGS. 6A and 7, when acquiring MR signals in the low frequency region with respect to the phase encoding direction in the three-dimensional k space. When the SORS pulse and the fat saturation pulse are applied immediately before that, and the MR signal in the high frequency region in the phase encoding direction is collected, the SORS pulse and the fat saturation pulse may not be applied immediately before that. Also, as shown in FIG. 6B and FIG. 8, only when a columnar low-frequency MR signal is acquired in both the slice encoding and phase encoding directions on the three-dimensional k-space, the SORS pulse and When the fat suppression pulse is applied and MR signals in other regions are collected, the SORS pulse and the fat suppression pulse may not be applied immediately before that.
[0022]
Further, in the above description, when collecting MR signals in a low-frequency region on the three-dimensional k space, each time the image sequence is repeated, the SORS pulse and the fat suppression pulse are applied. However, as shown in FIG. After applying the SORS pulse and the fat suppression pulse once, the image sequence may be repeated while the effect is maintained to some extent.
[0023]
In addition, the low-frequency region on the three-dimensional k space that exhibits the effects of the SORS pulse and the fat saturation pulse may be a partial region including the vicinity of the origin of the three-dimensional k space, and does not necessarily include zero encoding. That is, when collecting MR signals at the origin of the three-dimensional k-space, the SORS pulse and the fat suppression pulse may not be applied.
[0024]
Further, the low-frequency region that gives the effect of the SORS pulse on the three-dimensional k-space and the low-frequency region that gives the effect of the fat suppression pulse are not necessarily the same (may be different), for example, three-dimensional The effect of the SORS pulse may be applied to the low frequency region related to the phase encoding direction in the k space, and the effect of the fat suppression pulse may be applied to the low frequency region related to the slice encoding direction in the three-dimensional k space.
[0025]
In addition, when collecting MR signals in the low frequency region on the three-dimensional k space, the SORS pulse and the fat suppression pulse are applied, and the SORS pulse and the fat suppression pulse are not applied in the high frequency region. May be selectively applied in this manner, and a SORS pulse may be applied at all times so that the SORS effect extends over the entire area of the three-dimensional k-space.
[0026]
Alternatively, only the fat suppression pulse may be selectively applied in this way, and the SORS pulse may not be applied at all times so that the SORS effect is not exerted over the entire area of the three-dimensional k-space. Only the pulse may be selectively applied in this way, and the fat suppression pulse may not always be applied so that the fat suppression effect is not exhibited over the entire area of the three-dimensional k-space.
[0027]
In addition, the present invention is not limited to the above-described embodiment, and can be variously modified and implemented.
[0028]
【The invention's effect】
According to the present invention, the MR signal from the bloodstream does not decrease so much and additional effects such as fat suppression can be sufficiently maintained.
[Brief description of the drawings]
FIG. 1 is a block diagram of a magnetic resonance diagnostic apparatus of an embodiment.
FIG. 2 is a view showing a low-frequency region on a three-dimensional k-space to which fat suppression is selectively applied according to the present embodiment.
3A shows a pulse sequence for collecting MR signals in the low frequency region of FIG. 2, and FIG. 3B shows pulses for collecting MR signals in a high frequency region other than the low frequency region of FIG. The figure which shows a sequence.
4A shows the repetition time of FIG. 3A, and FIG. 4B shows the repetition time of FIG. 3B.
FIG. 5A shows a power spectrum of a general excitation pulse, and FIG. 5B shows a power spectrum of an ISCE pulse.
6A is a diagram showing another low-frequency region on a three-dimensional k-space to which fat suppression is applied, and FIG. 6B is another low-frequency region on a three-dimensional k-space to which fat suppression is applied. The figure which shows an area | region.
7A shows a pulse sequence for collecting MR signals in the low frequency region of FIG. 6A, and FIG. 7B shows MR signals in a high frequency region other than the low frequency region of FIG. 6A. FIG. 6 is a diagram showing a pulse sequence for collecting the signals.
8A shows a pulse sequence for collecting MR signals in the low frequency region of FIG. 6B, and FIG. 8B shows MR signals in a high frequency region other than the low frequency region of FIG. 6B. FIG. 6 is a diagram showing a pulse sequence for collecting the signals.
9 is a diagram showing a modification of FIG.
FIG. 10 is a diagram showing a pulse sequence for conventional three-dimensional MR angiography.
FIG. 11 is a diagram showing a conventional fat suppression region on a three-dimensional k-space.
FIG. 12 is an explanatory diagram of a SORS pulse.
[Explanation of symbols]
1 ... Static magnetic field magnet,
2. Gradient magnetic field coil,
3 ... RF coil,
4 ... Static magnetic field control device,
5 ... Transmitter,
6 ... Receiver,
7 ... X-axis gradient magnetic field power supply,
8 ... Y axis gradient magnetic field power supply,
9 ... Z-axis gradient magnetic field power supply,
10 ... Sequencer,
11 ... computer system,
12 ... display part,
20: Coil gantry.

Claims (2)

A gradient magnetic field applying means capable of applying a gradient magnetic field superimposed on a static magnetic field; an RF transmitting / receiving means capable of transmitting an RF pulse to the subject in the static magnetic field and receiving an MR signal from the subject; and the gradient magnetic field In a magnetic resonance diagnostic apparatus comprising an applying means and a control means for controlling the RF transmitting / receiving means,
The control means applies a fat suppression pulse and an MTC pulse as pre-pulses for a low frequency region in the k space and collects MR signals by an imaging sequence, and the fat suppression for the high frequency region in the k space. A magnetic resonance diagnostic apparatus that applies the MTC pulse without applying a pulse and controls the gradient magnetic field applying means and the RF transmitting / receiving means to collect MR signals by the imaging sequence. The magnetic resonance diagnostic apparatus according to claim 1, wherein the MTC pulse is applied together with a slice selective gradient magnetic field.

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