JP4476380B2 - Magnetic resonance diagnostic equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a magnetic resonance diagnostic apparatus for measuring in-vivo information of a subject from outside the body using a magnetic resonance phenomenon.
[0002]
[Prior art]
FIG. 5 shows the configuration of a conventional magnetic resonance diagnostic apparatus. In the figure, a gantry 101 includes a static magnetic field magnet 102, a gradient magnetic field coil 103, and an RF coil 104. The gradient coil 103 receives a current supply from the gradient amplifier 105 and generates a gradient magnetic field. This gradient magnetic field is superimposed on a uniform static magnetic field generated by the static magnetic field magnet 102. The RF coil 104 is supplied with a high-frequency current from the RF amplifier 105 and generates a high-frequency magnetic field. The nucleus excited by the high-frequency magnetic field is restored to the initial state through two types of relaxation processes, transverse relaxation and longitudinal relaxation, after the high-frequency magnetic field is cut. During this time, a magnetic resonance signal is induced in the RF coil 104. This magnetic resonance signal is sent to a computer (not shown) via the signal amplifier 107. The computer reconstructs a magnetic resonance image based on the magnetic resonance signal.
[0003]
The real-time system 108 includes a real-time sequencer 109, a waveform generator 110, an RF controller 111, a pre-processor 112, and a gradient magnetic field controller 113. The generation timing of the high-frequency magnetic field and gradient magnetic field, the waveform of the high-frequency magnetic field and gradient magnetic field, and magnetic resonance The basic pulse sequence data in which the sampling timing of the signal is described in, for example, a text format is decoded, changed and edited by the preprocessor 112 according to the user instruction from the workstation 114, and according to the decoded, changed and edited pulse sequence data. A high-frequency magnetic field waveform signal and a gradient magnetic field waveform signal are sent from the real-time sequencer 109 to the waveform generator 110, and a high-frequency magnetic field trigger signal is sent to the RF controller 111, so that the gradient magnetic field controller The roller 113 a trigger signal of the gradient magnetic field is sent, thereby so that the desired pulse sequence shown in FIG. 6 is executed.
[0004]
By the way, attempts are being made to capture phenomena such as CIDNP (Chemically Induced Dynamic Nuclear Polarization) caused by photoexcitation based on the intensity and spectrum fluctuations of magnetic resonance signals (MRI-SIGNAL) and to utilize them for medical diagnosis. Therefore, future trends are drawing much attention.
[0005]
However, the period in which the signal fluctuation occurs due to the optical excitation phenomenon such as the CIDNP phenomenon is very short, and therefore it is very difficult to control the timing of the optical excitation with respect to the generation timing of the high-frequency magnetic field and the gradient magnetic field and the sampling timing of the magnetic resonance signal.
[0006]
[Problems to be solved by the invention]
An object of the present invention is to provide a magnetic resonance diagnostic apparatus capable of controlling the optical excitation timing with high accuracy.
[0007]
[Means for Solving the Problems]
The present invention relates to a static magnetic field magnet, a gradient magnetic field coil, a gradient magnetic field amplifier that supplies a current to the gradient magnetic field coil to generate a gradient magnetic field, and a gradient that generates the gradient magnetic field trigger signal in the gradient magnetic field amplifier. A magnetic field controller; a high-frequency magnetic field coil; an RF amplifier that supplies a high-frequency current to the high-frequency magnetic field coil to generate a high-frequency magnetic field ; an RF controller that generates a trigger signal for the high-frequency magnetic field to the RF amplifier; A signal amplifier that amplifies a magnetic resonance signal from a subject received via a coil or other high-frequency magnetic field coil; a light irradiation unit that irradiates the subject with excitation light for exciting molecules; and the light irradiation. a light irradiation controller for generating a trigger signal of the excitation light unit, the generation timing of the gradient magnetic field, the high-frequency magnetic field Pulse sequence data describing the generation timing of the excitation light or the generation timing of the excitation light as a pre-pulse and the duration together with the raw timing, the waveform of the gradient magnetic field, the waveform of the high-frequency magnetic field, and the reception timing of the magnetic resonance signal In accordance with the gradient magnetic field controller , the RF controller, and the signal amplifier, a real-time sequencer that controls the light irradiation controller , and the gradient magnetic field to correct a temporal error in the generation timing of the excitation light with respect to the gradient magnetic field And a delay controller for delaying at least one of the trigger signal of the gradient magnetic field from the controller and the trigger signal of the excitation light from the light irradiation controller .
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, a magnetic resonance diagnostic apparatus of the present invention will be described in detail according to a preferred embodiment with reference to the drawings. FIG. 1 is a block diagram of a magnetic resonance diagnostic apparatus according to this embodiment. In the figure, a gantry 1 has a static magnetic field magnet 2, a gradient magnetic field coil 3, and an RF coil 4. The gantry 1 is provided with a cylindrical imaging region into which a subject is inserted. Light that can irradiate a subject in this imaging region with an excitation light (Irradiation) for inducing a CIDNP (Chemically Induced Dynamic Nuclear Polarization) phenomenon in an arbitrary direction and an arbitrary position. An irradiation unit 8 is provided in the cylinder of the gantry 1 or at any place in the photographing room. As the excitation light generated by the light irradiation unit 8, a specific wavelength pulse laser, a specific wavelength light transmitted through a filter from a xenon lamp, or the like is used. An ultrashort pulse laser can be excited in a wide band. The light irradiation control may be performed on the optical system in the light irradiation unit 8 regardless of whether the light source is on or off.
[0015]
A static magnetic field generated by the static magnetic field magnet 2 is formed in this imaging region. The static magnetic field includes a gradient magnetic field (slice selection gradient magnetic field pulse (SLICE), readout gradient magnetic field pulse (RO), phase encoding gradient magnetic field) generated from the gradient magnetic field coil 3 supplied with current from the gradient magnetic field amplifier 5. Pulse (PE)) is superimposed. The RF coil 4 is supplied with a high frequency current from the RF amplifier 6 and generates a high frequency magnetic field (Rf). The nucleus excited by the high-frequency magnetic field is restored to the initial state through two types of relaxation processes, transverse relaxation and longitudinal relaxation, after the high-frequency magnetic field is cut. During this time, a magnetic resonance signal is induced in the RF coil 4. This magnetic resonance signal is sent to the workstation 17 via the signal amplifier 7. In the workstation 17, clinically effective information is generated based on the fluctuation of the magnetic resonance signal due to the CIDNP phenomenon or the like.
[0016]
The real-time system 9 includes a light irradiation controller 10, a real-time sequencer 11, a waveform generator 12, an RF controller 13, a preprocessor 14, and a gradient magnetic field controller 15. Work with basic pulse sequence data that describes the waveform of the high-frequency magnetic field and gradient magnetic field, the sampling timing of the magnetic resonance signal, the generation timing of the excitation light, the duration of the excitation light, the number of times the excitation light is generated, etc. In accordance with the user instruction from the station 17, the preprocessor 14 decodes, modifies and edits the signal, and in accordance with the decoded, modified and edited pulse sequence data, the real-time sequencer 11 sends the waveform signal of the high frequency magnetic field and the waveform signal of the gradient magnetic field to the waveform generator 110. Sent, also a trigger signal of the high frequency magnetic field is sent to the RF controller 13, a trigger signal of the gradient magnetic field is sent to the gradient controller 15, a trigger signal of the excitation light is further sent to the light irradiation controller 10.
[0017]
As a result, a desired pulse sequence as shown in FIGS. 2, 3, and 4 is executed. In FIG. 2, excitation light (Irradiation) is generated in a single shot in synchronization with the high-frequency magnetic field pulse (Rf) and the slice selection gradient magnetic field pulse (SLICE). In FIG. 3, a plurality of excitation lights (Irradiation 1 and Irradiation 2) are generated in two shots in synchronization with the high-frequency magnetic field pulse (Rf) and the slice selection gradient magnetic field pulse (SLICE). In FIG. 4, the excitation light (Irradiation) is generated as a pre-pulse prior to the high-frequency magnetic field pulse (Rf) and the slice selection gradient magnetic field pulse (SLICE). The excitation light as the prepulse is effective for controlling the excitation state of the molecule, electron transfer, and the like, and for promoting the light excitation in a deeper place by utilizing the light absorption saturation phenomenon. In FIGS. 2, 3 and 4, the field echo (FE) method is shown as an example of the pulse sequence. However, the present invention is not limited to this, and any of various currently used pulse sequences can be applied. Is possible.
[0018]
In the present embodiment, the trigger signal from the light irradiation controller 10 and the trigger signal from the gradient magnetic field controller 15 are respectively supplied to the light irradiation unit 8 and the gradient magnetic field amplifier 5 via the delay controller 16. Therefore, it is possible to relatively easily correct the temporal error in the generation timing of the excitation light with respect to the gradient magnetic field pulse.
[0019]
A magnetic resonance signal received via the RF coil 4 or the reception-dedicated RF coil is taken into the workstation 17 via the signal amplifier 7 and the RF controller 13. In the workstation 17, clinically effective information is generated based on the fluctuation of the magnetic resonance signal due to the CIDNP phenomenon or the like. For example, the magnetic resonance image (reference image) is reconstructed based on the magnetic resonance signal collected in the state where the excitation light is not irradiated, and the magnetic resonance is acquired in the state where the excitation light is irradiated by the pulse sequence shown in FIG. A magnetic resonance image (variation image) is reconstructed based on the signal. Then, a new image is generated as clinically effective information from which the variation is extracted by subtracting the reference image between frames from the variation image.
[0020]
As described above, in this embodiment, the magnetic resonance diagnostic apparatus includes the static magnetic field magnet 2, the gradient magnetic field coil 3, the high frequency magnetic field coil 4, and the like, and the light irradiation unit 8 that irradiates the subject with excitation light for exciting molecules. Since it is equipped, the light irradiation unit 8 is controlled in accordance with the pulse sequence data together with the gradient magnetic field coil 3 and the high frequency magnetic field coil 4 to adjust the generation timing of the excitation light with respect to the gradient magnetic field and the high frequency magnetic field with high accuracy. Can do.
[0021]
The present invention is not limited to the embodiments described above, and can be implemented with various modifications.
[0022]
【The invention's effect】
According to the present invention, the magnetic resonance diagnostic apparatus is equipped with a light irradiation unit that irradiates a subject with excitation light for exciting molecules together with a static magnetic field magnet, a gradient magnetic field coil, a high frequency magnetic field coil, and the like. By controlling the light irradiation unit together with the magnetic field coil and the high frequency magnetic field coil, the generation timing of the excitation light can be adjusted with high accuracy with respect to the gradient magnetic field and high frequency magnetic field.
[Brief description of the drawings]
FIG. 1 is a block diagram showing the configuration of a magnetic resonance diagnostic apparatus according to an embodiment of the present invention.
FIG. 2 is a diagram showing a field echo pulse sequence with single light irradiation according to the present embodiment.
FIG. 3 is a view showing a field echo pulse sequence with double light irradiation according to the present embodiment.
FIG. 4 is a view showing a field echo pulse sequence with optical pre-irradiation according to the present embodiment.
FIG. 5 is a block diagram showing a configuration of a conventional magnetic resonance diagnostic apparatus.
FIG. 6 is a diagram showing a conventional field echo pulse sequence.
[Explanation of symbols]
1 ... Gantry,
2. Static magnetic field magnet,
3. Gradient magnetic field coil,
4 ... RF coil,
5 ... Gradient amplifier,
6 ... RF amplifier,
7 ... Signal amplifier,
8 ... Light irradiation unit,
9 ... Real-time system,
10: Light irradiation controller,
11 ... Real-time sequencer,
12 ... Waveform generator,
13 ... RF controller,
14: Pre-processor,
15 ... Gradient field controller,
16 ... delay controller,
17 ... Workstation.

Claims (7)

A static magnetic field magnet,
A gradient coil,
A gradient amplifier for supplying a current to the gradient coil to generate a gradient magnetic field;
A gradient controller that generates a trigger signal of the gradient magnetic field in the gradient magnetic field amplifier;
A high-frequency magnetic field coil;
An RF amplifier for supplying a high-frequency current to the high-frequency magnetic field coil to generate a high-frequency magnetic field;
An RF controller for generating a trigger signal of the high-frequency magnetic field in the RF amplifier;
A signal amplifier for amplifying a magnetic resonance signal from the subject received via the high-frequency magnetic field coil or another high-frequency magnetic field coil;
A light irradiation unit for irradiating the subject with excitation light for exciting molecules;
A light irradiation controller for generating a trigger signal of the excitation light in the light irradiation unit;
The excitation light generation timing or the excitation light is generated as a pre-pulse together with the generation timing of the gradient magnetic field, the generation timing of the high-frequency magnetic field, the waveform of the gradient magnetic field, the waveform of the high-frequency magnetic field, and the reception timing of the magnetic resonance signal. A real-time sequencer for controlling the light irradiation controller together with the gradient magnetic field controller , the RF controller and the signal amplifier according to pulse sequence data in which timing and duration are described;
In order to correct a temporal error in the generation timing of the excitation light with respect to the gradient magnetic field, at least one of a trigger signal of the gradient magnetic field from the gradient magnetic field controller and a trigger signal of the excitation light from the light irradiation controller A magnetic resonance diagnostic apparatus comprising a delay controller for delaying .   The magnetic resonance diagnostic apparatus according to claim 1, wherein the pulse sequence data describes a timing and a duration for repeatedly generating the excitation light.   2. The magnetic resonance diagnostic apparatus according to claim 1, further comprising means for controlling the generation of the excitation light based on the fluctuation of the magnetic resonance signal due to the excitation of the molecule to adjust the excited state of the molecule. .   The image processing apparatus further includes means for subtracting an image reconstructed based on the magnetic resonance signal collected in a state where the excitation light is not irradiated from an image reconstructed based on the magnetic resonance signal collected in the state where the excitation light is irradiated. The magnetic resonance diagnostic apparatus according to claim 1. The magnetic resonance diagnostic apparatus according to claim 1, wherein the excitation light is generated in a single shot in synchronization with the high-frequency magnetic field and the gradient magnetic field used for slice selection. The magnetic resonance diagnostic apparatus according to claim 1, wherein the excitation light is generated in two shots in synchronization with the high-frequency magnetic field and the gradient magnetic field used for slice selection. 2. The magnetic resonance diagnostic apparatus according to claim 1, wherein the excitation light is generated as a pre-pulse prior to the gradient magnetic field used for the high-frequency magnetic field and slice selection.

Images