KR20180052090A - Magnetic resonance imaging apparatus and method of obtaining magnetic resonance image - Google Patents

Abstract

Disclosed is a magnetic resonance imaging apparatus which uses a single pulse sequence to acquire a plurality of magnetic resonance images having different contrasts. According to an embodiment of the present invention, the magnetic resonance imaging apparatus includes a control unit to control application of a pulse sequence of one cycle including a first acquisition section, during which a first inversion RF pulse for a first slice of a subject is applied, and a second acquisition section, during which a second inversion RF pulse for a second slice of the subject adjacent to the first slice is applied, to a plurality of slices of the subject, and sequentially acquire a first magnetic resonance signal for imaging a first magnetic resonance image for the first slice, a second magnetic resonance signal for imaging at least one second magnetic resonance image for the second slice of the subject adjacent to the first slice, and a third magnetic resonance signal for imaging at least one third magnetic resonance image for the first slice during the first acquisition section.

Description

TECHNICAL FIELD [0001] The present invention relates to a magnetic resonance imaging apparatus and a method for acquiring magnetic resonance imaging,

A magnetic resonance imaging apparatus and a method thereof. And more particularly, to a magnetic resonance imaging apparatus and a magnetic resonance imaging method for acquiring a plurality of magnetic resonance images having different contrast degrees using a single pulse sequence.

Magnetic resonance imaging (MRI) is a device that uses a magnetic field to photograph a subject. It is widely used for accurate disease diagnosis because it shows the bone as well as the disk, joint, nerve ligament, and heart in three dimensions from a desired angle.

On the other hand, images with different contrasts can be used to diagnose the disease. For example, T1 weighted images, T2 weighted images, T2 * weighted images, FLAIR images, and proton density (PD) weighted images may be used. Images with different degrees of contrast can be obtained by adjusting TE and TR. As a patent document on a method for acquiring images having different contrast degrees, there is United States Published Patent Application No. 2010-0013475 and the like.

Conventionally, it has been necessary to apply a plurality of pulse sequences corresponding to a plurality of contrast degrees in order to acquire magnetic resonance images having different contrast degrees. However, it takes a long time to acquire images of different contrast degrees for a plurality of slices, and the inconvenience of the patient may be increased.

In addition, since images obtained at different contrast degrees are different from each other, when the images of the same slice having different contrast degrees are compared, the position of the lesion included in the image for the same slice according to the movement of the organ Can be different from each other.

The disclosed embodiments aim to reduce the scan time by acquiring a plurality of magnetic resonance images having different contrasts using a single pulse sequence.

In addition, according to the disclosed embodiments, a plurality of cross-sections are stimulated using a single pulse sequence according to the multi-band imaging method, thereby obtaining images of different contrast degrees for a plurality of cross-sections.

 The MRI apparatus according to an embodiment includes a first acquisition period in which a first inversion RF pulse is applied to a first slice of a subject and a second acquisition period in which a second inversion RF pulse is applied to a second slice of the object adjacent to the first slice The pulse sequence of one period including the second acquisition period to which the second acquisition period is applied is applied to a plurality of slices of the object,

A method for imaging a first magnetic resonance image for imaging a first magnetic resonance image for a first slice, a first magnetic resonance signal for imaging a first slice and at least one second magnetic resonance image for a second slice of an adjacent object, And a controller for sequentially acquiring a second magnetic resonance signal and a third magnetic resonance signal for imaging at least one third magnetic resonance image for the first slice,

The first magnetic resonance image, the second magnetic resonance image, and the third magnetic resonance image according to an embodiment may be images having contrasts different from each other.

A controller according to an embodiment may acquire a first magnetic resonance signal by a gradient echo signal, and a first magnetic resonance image according to an embodiment may include a T2 * weighted image.

A second magnetic resonance signal according to one embodiment may be obtained during a time inversion by a first inverse RF pulse.

According to an embodiment, the at least one second magnetic resonance image includes a proton density (PD) image and a T2 weighted image, and the controller according to an exemplary embodiment may include a second magnetic resonance signal in a dual echo sequence And obtain a proton density image and a T2 weighted image by view sharing the second magnetic resonance signal.

At least one third magnetic resonance image according to an embodiment includes a reversed applied proton density image (PDIR) and a FLAIR image, and the controller according to an exemplary embodiment may acquire a third magnetic resonance signal by a dual echo sequence And acquire a reversed applied proton density image (PDIR) and a FLAIR image by viewing-sharing the third magnetic resonance signal.

The controller may acquire a third magnetic resonance signal for imaging the third magnetic resonance image before the second acquisition period after the inversion time (TI) is over.

The first acquisition interval according to an embodiment may be included in a half of a repetition time (TR), and the second acquisition interval according to an embodiment may be included in the other half of the repetition time.

The controller according to an embodiment may further comprise, during a second acquisition interval, a fourth magnetic resonance signal for imaging a fourth magnetic resonance image for a second slice, a second magnetic resonance signal for imaging at least one fifth magnetic resonance image for a first slice A sixth magnetic resonance signal for imaging the sixth magnetic resonance image for the first slice, and a sixth magnetic resonance signal for imaging the sixth magnetic resonance image for the second slice.

The controller according to an embodiment may acquire a fourth magnetic resonance signal by a gradient echo signal, and the first magnetic resonance image according to an embodiment may include a T2 * weighted image.

A fifth magnetic resonance signal according to an embodiment may be obtained during a time inversion by a second inverse RF pulse.

According to an exemplary embodiment, the at least one fifth magnetic resonance image includes a proton density (PD) image and a T2 weighted image, and the controller according to an exemplary embodiment may include a fifth magnetic resonance signal in a dual echo sequence And obtain a proton density image and a T2 weighted image by view sharing the fifth magnetic resonance signal.

The at least one sixth magnetic resonance image according to an embodiment includes a reversed applied proton density image (PDIR) and a FLAIR image,

The control unit according to an embodiment may acquire a sixth magnetic resonance signal by a dual echo sequence and acquire a reversed applied proton density image (PDIR) and a FLAIR image by view sharing the sixth magnetic resonance signal have.

A method of acquiring a magnetic resonance image according to an exemplary embodiment includes a first acquisition period in which a first inversion RF pulse is applied to a first slice of a target object and a second acquisition period in which a second inversion RF And applying a pulse sequence of one cycle including a second acquisition period to which a pulse is applied to a plurality of slices of the object.

In addition, the method of acquiring a magnetic resonance image according to an embodiment may include, during a first acquisition interval,

Obtaining a first magnetic resonance signal for imaging a first magnetic resonance image for a first slice; Obtaining a second magnetic resonance signal for imaging at least one second magnetic resonance image for a second slice of a subject adjacent to the first slice; And obtaining a third magnetic resonance signal for imaging at least one third magnetic resonance image for the first slice,

The first magnetic resonance image, the second magnetic resonance image, and the third magnetic resonance image may be images having different degrees of contrast.

A program for implementing the magnetic resonance imaging method according to an embodiment may be recorded in a computer-readable medium.

According to the disclosed embodiments, the scan time can be reduced by acquiring a plurality of magnetic resonance images having different contrast degrees using one pulse sequence.

In addition, according to the disclosed embodiments, a plurality of cross-sections are stimulated using a single pulse sequence according to the multi-band imaging method, thereby obtaining images of different contrast degrees for a plurality of cross-sections.

1A is a block diagram illustrating a magnetic resonance imaging apparatus 100 according to an embodiment of the present invention.
FIG. 1B schematically shows an image obtained by the magnetic resonance imaging apparatus 100 of the present invention and a section corresponding thereto.
2 is a schematic diagram of a general MRI system 1.
3 is a flowchart illustrating a method for acquiring an image according to an embodiment.
4 is a diagram for explaining a part of a pulse sequence provided by the MRI apparatus 100 according to an embodiment.
5 is a diagram for explaining a pulse sequence provided by the MRI apparatus 100 according to an embodiment.
FIG. 6 is a view for explaining a method of acquiring an image in the MRI apparatus 100 according to an embodiment.
7 is a view for explaining a method of acquiring an image in the magnetic resonance imaging apparatus 100 according to an embodiment.
8 is a diagram for explaining a method of acquiring an image in the magnetic resonance imaging apparatus 100 according to an embodiment.

The present specification discloses the principles of the present invention and discloses embodiments of the present invention so that those skilled in the art can carry out the present invention without departing from the scope of the present invention. The disclosed embodiments may be implemented in various forms.

Like reference numerals refer to like elements throughout the specification. The present specification does not describe all elements of the embodiments, and redundant description between general contents or embodiments in the technical field of the present invention will be omitted. As used herein, the term " part " may be embodied in software or hardware, and may be embodied as a unit, element, or section, Quot; element " includes a plurality of elements. Hereinafter, the working principle and embodiments of the present invention will be described with reference to the accompanying drawings.

The image herein may include a medical image acquired by a medical imaging device, such as a magnetic resonance imaging (MRI) device, a computed tomography (CT) device, an ultrasound imaging device, or an x-ray imaging device.

As used herein, the term " object " may include a person, an animal, or a part thereof as an object of photographing. For example, the object may comprise a part of the body (organ or organ) or a phantom.

The MRI system acquires a magnetic resonance (MR) signal and reconstructs the acquired magnetic resonance signal into an image. A magnetic resonance signal refers to an RF signal emitted from an object.

The MRI system forms a static magnetic field that aligns the direction of the magnetic dipole moment of a specific nucleus of an object located in the sperm field with the direction of the sperm field. The oblique magnetic field coil can apply a gradient signal to the sperm field to form an oblique magnetic field, and can induce different resonance frequencies for each part of the object.

The RF coil is capable of examining the RF signal according to the resonance frequency of the desired site. Also, as the gradient magnetic field is formed, the RF coil can receive MR signals of different resonance frequencies radiated from various portions of the object. Through these steps, the MRI system acquires an image from the MR signal using an image reconstruction technique.

1A is a block diagram illustrating a magnetic resonance imaging apparatus 100 according to an embodiment of the present invention.

A magnetic resonance imaging apparatus 100 according to an embodiment is an apparatus for acquiring a plurality of magnetic resonance images having different contrasts.

In addition, the magnetic resonance imaging apparatus 100 shown in FIG. 1A may be a device for obtaining a magnetic resonance image by imaging a target object by magnetic resonance imaging. The magnetic resonance imaging apparatus 100 may be a device for acquiring a magnetic resonance image by processing magnetic resonance data obtained by capturing a magnetic resonance image of a target object.

For example, the magnetic resonance imaging apparatus 100 applies an RF pulse to a target object through a plurality of channel coils included in a high frequency multi-coil (not shown), and uses a magnetic resonance signal obtained through a plurality of channel coils And may be a device for reconstructing a magnetic resonance image.

The magnetic resonance imaging apparatus 100 may be a server apparatus that provides a pulse sequence to be applied to a target object and reconstructs a magnetic resonance image using a magnetic resonance signal obtained according to the pulse sequence. Here, the server device may be a medical server device in a hospital or other hospital where a patient performs magnetic resonance imaging.

Referring to FIG. 1A, a magnetic resonance imaging apparatus 100 may include a memory 110 and an image processing unit 120.

The memory 110 may store a pulse sequence to be applied to the object. In addition, the memory 110 may store the magnetic resonance signal obtained based on the pulse sequence.

The image processing unit 120 may provide a pulse sequence. For example, the image processing unit 120 may include a waveform generator (not shown) for generating a slope waveform, that is, a current pulse in accordance with a pulse sequence, and a tilt amplifier (not shown) for amplifying the generated current pulse and transmitting the amplified current pulse to a scanner (Not shown).

In addition, the image processing unit 120 can acquire a magnetic resonance signal based on a pulse sequence stored in the memory 110 of the MRI apparatus 100 or a pulse sequence received from an external apparatus (not shown).

The image processing unit 120 according to an exemplary embodiment may acquire a magnetic resonance signal for a target object generated based on a pulse sequence. The image processing unit 120 may store the magnetic resonance signal in the memory 110 in the form of k spatial data.

For example, the magnetic resonance signal may be a signal received from a scanner (not shown). Further, the magnetic resonance signal can be received from the memory 110 of the magnetic resonance imaging apparatus 100 or from an external device (not shown).

Here, the pulse sequence may be a gradient echo (GRE) sequence, a spin echo (SE) sequence, a fast spin echo (FSE) sequence, a single shot fast spin echo, a fluid attenuated inversion (FLAIR) sequence, -and Spin-Echo) sequences, and the like.

The image processing unit 120 can acquire an image of a target object based on the acquired magnetic resonance signal for the target object. The image processing unit 120 may include a module for reconstructing a magnetic resonance image.

The image processing unit 120 according to an exemplary embodiment may control one RF pulse to be applied to a target object during a repetition time including a first acquisition time interval and a second acquisition time interval.

Wherein the one-week RF pulse may include at least one of the pulse sequences described above. According to one embodiment, one-week RF pulses may include a gradient echo (GRE) sequence, a fast spin echo (FSE) sequence, and the like.

The image processing unit 120 may acquire a magnetic resonance signal for a plurality of slices during the repetition time TR.

A first inversion RF pulse for the first slice of the object may be applied during the first acquisition time interval.

The image processing unit 120 may acquire a first magnetic resonance signal for imaging the first magnetic resonance image for the first slice during the first acquisition time interval. In addition, the image processing unit 120 may acquire a second magnetic resonance signal for imaging at least one second magnetic resonance image for the second slice of the object adjacent to the first slice during the first acquisition time interval. In addition, the image processing unit 120 may acquire a third magnetic resonance signal for imaging at least one third magnetic resonance image for the first slice during the first acquisition time interval.

In addition, the image processing unit 120 may sequentially acquire the first magnetic resonance signal, the second magnetic resonance signal, and the third magnetic resonance signal during the first acquisition time interval

According to one embodiment, the first magnetic resonance image may comprise a T2 * weighted image. Also, the at least one second magnetic resonance imaging may include a proton density (PD) image and a T2 weighted image. In addition, the at least one third magnetic resonance image may include a reversed applied proton density (PDIR) image and a FLAIR image. According to an exemplary embodiment, the image processing unit 120 may include an inversion time The second magnetic resonance signal can be obtained during the time inversion.

The inversion time may be the time it takes for the magnetic resonance signal to the fluid of the subject (e.g., CSF, cerebral spinal fluid) portion to be minimized after applying the first inverse RF pulse. Specifically, the magnetic resonance imaging apparatus 100 applies a first inverse RF pulse to a target object, minimizes an undesired signal after the inversion time has elapsed, and then applies pulses for acquiring a third magnetic resonance signal .

The second magnetic resonance signal is a signal for imaging the second magnetic resonance image for the second slice, the first inverted RF pulse and the third magnetic resonance signal comprise at least one third magnetic resonance image for the first slice, .

Since the second magnetic resonance signal is a signal for the second slice, it is not affected by the first inverse RF pulse for the first slice, so it can be obtained even after a sufficient time has elapsed after applying the first inverse RF pulse.

The magnetic resonance imaging apparatus 100 may shorten the scan time by acquiring at least one second magnetic resonance image for the second slice during the inversion time after applying the first inverse RF pulse to the object to the first slice have.

The image processing unit 120 may acquire the second magnetic resonance signal by a dual echo sequence. In addition, the image processing unit 120 may acquire a proton density image and a T2 weighted image by performing a view sharing of the second magnetic resonance signal.

View sharing means acquiring a plurality of images having different contrast degrees using a multiple echo sequence, and uses data corresponding to high frequencies of k spatial data when imaging a plurality of images in the same manner. At this time, data corresponding to the low frequency among k spatial data for a plurality of images can be obtained in each effective echo time (TE) in the multiple echo sequence.

The third magnetic resonance signal for imaging at least one third magnetic resonance image may be obtained before the second acquisition time interval after the inversion time (TI) is over. The first acquisition time interval may be included in half of the repetition time, and the second acquisition time interval may be included in the other half of the repetition time.

Further, the image processing unit 120 can acquire the third magnetic resonance signal by the dual echo sequence. In addition, the image processing unit 120 can acquire the inversion-applied proton density image and the FLAIR image by view-sharing the third magnetic resonance signal. The inversion-applied proton density image (PDIR) may be a proton density image for the first slice affected by the first inversion RF pulse.

The image processing unit 120 according to an exemplary embodiment may acquire a T1 weighted image using a proton density image and a proton density image to which an inversion is applied. For example, assuming that the values of the image signal of the proton density image and the image signal of the proton density image to which the inversion is applied are PDIR and PD, respectively, and T1 is the signal of the T1 weighted image, T1 The value of the signal of the weighted image can be obtained.

On the other hand, a second inversion RF pulse for the second slice may be applied during the second acquisition time interval.

The image processing unit 120 may acquire a fourth magnetic resonance signal for imaging the fourth magnetic resonance image for the second slice during the second acquisition time interval. In addition, the image processing unit 120 may acquire a fifth magnetic resonance signal for imaging at least one fifth magnetic resonance image for the first slice during the second acquisition time interval. Also, during the second acquisition time interval, the image processing unit 120 may acquire a sixth magnetic resonance signal for imaging at least one sixth magnetic resonance image for the second slice.

According to one embodiment, the image processing unit 120 may acquire the fifth magnetic resonance signal during the inversion time by the second inverse RF pulse.

The magnetic resonance imaging apparatus 100 shown in FIG. 1A may acquire images having various contrasts for the first slice and the second slice during the first acquisition time interval and the second acquisition time interval.

For example, the magnetic resonance imaging apparatus 100 may generate a T2 * weighted image, a T2 weighted image, a proton density image, a FLAIR image, and a T2 * weighted image for the first slice and the second slice based on the magnetic resonance signals obtained for one repetition time And T1 weighted images.

In FIG. 1A, the MRI apparatus 100 acquires images for the first slice and the second slice. However, the first slice and the second slice are not limited to one slice.

For example, the first slice may correspond to even-numbered slices and the second slice may correspond to odd-numbered slices. Also, the first slice may correspond to odd-numbered slices, and the second slice may correspond to even-numbered slices.

FIG. 1B schematically shows an image obtained by the magnetic resonance imaging apparatus 100 of the present invention and a section corresponding thereto.

The magnetic resonance imaging apparatus 100 illustrated in FIG. 1A can acquire images of different contrast degrees for a plurality of sections by stimulating a plurality of sections using one pulse sequence according to a multi-band imaging method.

Referring to FIG. 1B, the magnetic resonance imaging apparatus 100 may acquire images of different degrees of contrast corresponding to the first slice corresponding to the odd-numbered slices and the second slice corresponding to the even-numbered slices.

Specifically, the magnetic resonance imaging apparatus 100 can acquire a T2 * weighted image, a reversed applied proton density (PDIR) image, and a FLAIR image for the first slice 101 in the first acquisition period. In addition, the magnetic resonance imaging apparatus 100 may acquire a proton density (PD) image and a T2 weighted image for the second slice 103 in the first acquisition period.

In addition, the magnetic resonance imaging apparatus 100 acquires the proton density (PD) image and the T2 weighted image for the first slice 101 in the second acquiring section in the second acquiring section, the magnetic resonance imaging apparatus 100 acquires can do. In addition, a T2 * weighted image, a reversed applied proton density (PDIR) image, and a FLAIR image for the second slice 103 can be obtained.

2 is a schematic view of the MRI system 1. Fig.

Referring to FIG. 2, the MRI system 1 may include an operating unit 10, a control unit 30, and a scanner 50. Here, the control unit 30 may be implemented independently as shown in FIG. Alternatively, the control unit 30 may be divided into a plurality of components and included in each component of the MRI system 1. Hereinafter, each component will be described in detail.

The scanner 50 may be embodied in a shape (for example, a bore shape) in which an internal space is empty and an object can be inserted. A static magnetic field and an oblique magnetic field are formed in the internal space of the scanner 50, and the RF signal is irradiated.

The scanner 50 may include a sperm filament forming portion 51, a gradient magnetic field forming portion 52, an RF coil portion 53, a table portion 55, and a display portion 56. The sperm filament forming section 51 forms a sperm filament for aligning the directions of the magnetic dipole moments of the nuclei included in the target in the sperm length direction. The sperm field forming unit 51 may be realized as a permanent magnet or a superconducting magnet using a cooling coil.

The oblique magnetic field forming section 52 is connected to the control section 30. A slope is applied to the static magnetic field according to the control signal transmitted from the control unit 30 to form a gradient magnetic field. The oblique magnetic field forming section 52 includes X, Y, and Z coils that form oblique magnetic fields in the X-axis, Y-axis, and Z-axis directions orthogonal to each other. And generates an inclination signal corresponding to the position.

The RF coil unit 53 is connected to the control unit 30 and can receive an RF signal from a target object in response to a control signal transmitted from the control unit 30 and receive an MR signal emitted from the target object. The RF coil unit 53 can transmit an RF signal having a frequency equal to the frequency of the car motions to an object nucleus performing car wash motion to the object, stop the transmission of the RF signal, and receive the MR signal emitted from the object.

The RF coil portion 53 is formed of a transmitting RF coil for generating an electromagnetic wave having a radio frequency corresponding to the type of the atomic nucleus and a receiving RF coil for receiving the electromagnetic wave radiated from the atomic nucleus, Lt; RTI ID = 0.0 > transmit / receive < / RTI > In addition to the RF coil portion 53, a separate coil may be mounted on the object. For example, a head coil, a spine coil, a torso coil, a knee coil, or the like may be used as a separate coil depending on a shooting region or a mounting region.

A display unit 56 may be provided on the outside and / or inside of the scanner 50. The display unit 56 may be controlled by the control unit 30 to provide information related to medical image capturing to the user or the object.

In addition, the scanner 50 may be provided with an object monitoring information acquisition unit (not shown) for acquiring and transmitting monitoring information on the state of the object. For example, the object monitoring information obtaining unit may include a camera (not shown) for photographing the movement and position of the object, a respiration measuring device (not shown) for measuring respiration of the object, an ECG measuring device for measuring the electrocardiogram ) Or a body temperature measuring device (not shown) for measuring the body temperature of the subject, and may transmit the monitoring information to the controller 30. Accordingly, the control unit 30 can control the operation of the scanner 50 using the monitoring information about the object. Hereinafter, the control unit 30 will be described.

The control unit 30 can control the overall operation of the scanner 50. [

The control unit 30 may control a sequence of signals formed inside the scanner 50. The control unit 30 can control the oblique magnetic field forming unit 52 and the RF coil unit 53 according to a pulse sequence or a designed pulse sequence received from the operating unit 10. [

The pulse sequence includes all information necessary for controlling the oblique magnetic field forming section 52 and the RF coil section 53. For example, the pulse sequence may be a pulse sequence signal indicating the intensity of a pulse signal applied to the oblique magnetic field forming section 52 , The application duration time, the application timing, and the like.

The control unit 30 includes a waveform generator (not shown) for generating a slope waveform, that is, a current pulse in accordance with a pulse sequence, and a gradient amplifier (not shown) for amplifying the generated current pulse and transmitting the amplified current pulse to the gradient magnetic field forming unit 52 So that the formation of the oblique magnetic field of the oblique magnetic field forming portion 52 can be controlled.

The control unit 30 can control the operation of the RF coil unit 53. [ For example, the control section 30 can supply an RF pulse of a resonance frequency to the RF coil section 53 to irradiate the RF signal, and receive the MR signal received by the RF coil section 53. [ At this time, the control unit 30 controls the operation of a switch (for example, a T / R switch) capable of adjusting the transmission / reception direction through the control signal, and controls the irradiation of the RF signal and the reception of the MR signal according to the operation mode.

The control unit 30 can control the movement of the table unit 55 in which the object is located. Before the photographing is performed, the control unit 30 can advance the table unit 55 in accordance with the photographing part of the object.

The control unit 30 can control the display unit 56. [ For example, the control unit 30 can control the on / off state of the display unit 56 or the screen displayed on the display unit 56 through the control signal.

The control unit 30 includes an algorithm for controlling the operation of components in the MRI system 1, a memory (not shown) for storing data in a program form, and a processor (not shown) for performing the above- Not shown). At this time, the memory and the processor may be implemented as separate chips. Alternatively, the memory and the processor may be implemented on a single chip.

The operating unit 10 can control the overall operation of the MRI system 1. The operating unit 10 may include an image processing unit 11, an input unit 12, and an output unit 13.

In addition, the operating unit 10 may further include the memory 110 shown in FIG. 1A.

The image processing unit 11 stores the MR signal received from the control unit 30 using a memory and applies image restoration using an image processor to generate image data for the object from the stored MR signal .

For example, when the image processing unit 11 fills the k-space (e.g., Fourier space or frequency space) of the memory with digital data and k-space data is completed, (For example, by performing inverse Fourier transform on the k-space data) to restore the k-space data to the image data.

In addition, various signal processes applied to the MR signal by the image processing unit 11 can be performed in parallel. For example, a plurality of MR signals received by a multi-channel RF coil may be subjected to signal processing in parallel to restore image data. Meanwhile, the image processing unit 11 may store the restored image data in a memory or may be stored in an external server through the communication unit 60, as will be described later.

In addition, the image processing unit 11 may include the image processing unit 120 shown in FIG. 1A.

The input unit 12 may receive a control command related to the overall operation of the MRI system 1 from a user. For example, the input unit 12 can receive object information, parameter information, scan conditions, information on pulse sequences, and the like from a user. The input unit 12 may be implemented as a keyboard, a mouse, a trackball, a voice recognition unit, a gesture recognition unit, a touch screen, or the like.

The output unit 13 can output the image data generated by the image processing unit 11. The output unit 13 may output a user interface (UI) configured to allow a user to input a control command related to the MRI system 1. The output unit 13 may be implemented as a speaker, a printer, a display, or the like.

2, the operating unit 10 and the control unit 30 are shown as separate objects, but they may be included in one device as described above. Also, the processes performed by the operating unit 10, and the control unit 30, respectively, may be performed on other objects. For example, the image processing unit 11 may convert the MR signal received by the control unit 30 into a digital signal, or the control unit 30 may directly convert the MR signal.

The MRI system 1 includes a communication unit 60 and an external device (not shown) (for example, a server, a medical device, a portable device (smartphone, tablet PC, wearable device, etc.) Lt; / RTI >

The communication unit 60 may include one or more components that enable communication with an external device and may include at least one of a local communication module (not shown), a wired communication module 61 and a wireless communication module 62 . ≪ / RTI >

The communication unit 60 receives the control signal and data from the external device and transmits the received control signal to the control unit 30 so that the control unit 30 controls the MRI system 1 in accordance with the received control signal It is possible.

Alternatively, the control unit 30 may transmit a control signal to the external device via the communication unit 60, thereby controlling the external device according to the control signal of the control unit.

For example, the external device can process data of the external device according to a control signal of the control unit 30 received through the communication unit 60. [

The external device may be provided with a program capable of controlling the MRI system 1, and the program may include an instruction to perform a part or all of the operation of the control unit 30. [

The program may be installed in an external device in advance, or a user of the external device may download and install the program from a server that provides the application. The server providing the application may include a recording medium storing the program.

3 is a flowchart illustrating a method for acquiring an image according to an embodiment.

A method for acquiring a magnetic resonance image according to an embodiment may be performed in the magnetic resonance imaging apparatus 100. [ The magnetic resonance imaging apparatus 100 may provide one-week RF pulses during a repetition time including a first acquisition time interval and a second acquisition time interval.

In step S310, the magnetic resonance imaging apparatus 100 may acquire a first magnetic resonance signal for imaging the first magnetic resonance image for the first slice (S310).

In step S320, the magnetic resonance imaging apparatus 100 may acquire a second magnetic resonance signal for imaging the at least one second magnetic resonance image for the second slice of the object adjacent to the first slice (S320).

The magnetic resonance imaging apparatus 100 may acquire a second magnetic resonance signal during a time inversion by a first inverse RF pulse after a first inversion RF pulse for the first slice is applied .

In step S330, the magnetic resonance imaging apparatus 100 may acquire a third magnetic resonance signal for imaging the third magnetic resonance image for the first slice (S330).

4 is a diagram for explaining a part of a pulse sequence provided by the MRI apparatus 100 according to an embodiment.

The pulse sequence diagram 400 shown in FIG. 4 represents a pulse sequence for a first acquisition time interval included in the repetition time TR provided in the magnetic resonance imaging apparatus 100. According to one embodiment, the first acquisition time interval may correspond to half of the repetition time.

Pulse Sequence The first pulse sequence 410, the second pulse sequence 420 and the third pulse sequence 430 shown in the schematic diagram 400 correspond to at least one of a gradient echo sequence, a fast spin echo sequence, and a FLAIR sequence .

The MRI apparatus 100 may apply the first pulse sequence 410 to the first slice before applying the inverted RF pulse 401 to the first slice. The first pulse sequence 410 may be, for example, a gradient echo sequence. Also, the first pulse sequence 410 may be an echo plane image (EPI) sequence.

The magnetic resonance imaging apparatus 100 may acquire a first magnetic resonance signal for imaging the first magnetic resonance image for the first slice based on the first pulse sequence 410. [ For example, the first magnetic resonance image may include a T2 * emphasis image.

According to one embodiment, if the first pulse sequence 410 is a gradient echo sequence for acquiring a T2 * emphasis image, the first pulse sequence 410 may comprise RF pulses with small flip angles. Accordingly, a recovery time (T _recovory ) for the first slice can be relatively small. The recovery time T _recovory for the first slice may be the time until the first pulse sequence 410 is applied to the first slice and then the third pulse sequence 430 is applied to the first slice. In addition, when the first pulse sequence 410 includes RF pulses having a small flip angle, the application of the first pulse sequence 410 is performed on the contrast of the magnetic resonance image acquired by the third pulse sequence 430 It may not give a great deal of influence.

According to one embodiment, it is also possible that the first pulse sequence 410 is arranged after the third pulse sequence 430.

According to one embodiment, the magnetic resonance imaging apparatus 100 may apply the second pulse sequence 420 to the second slice after applying the inverted RF pulse 401 to the first slice. The second pulse sequence 420 may be, for example, a fast spin echo sequence. The magnetic resonance imaging apparatus 100 may acquire a second magnetic resonance signal for imaging at least one second magnetic resonance image for the second slice based on the second pulse sequence 420. [ For example, at least one second magnetic resonance imaging may comprise a T2-weighted image. Also, at least one second magnetic resonance imaging may include a T2 weighted image and a proton density image.

The magnetic resonance imaging apparatus 100 may apply the second pulse sequence 420 within the inversion time TI. The inversion time TI may be approximately 2.5 seconds, for example, when the magnetic resonance imaging apparatus 100 operates in a magnetic field of 3T.

According to one embodiment, the magnetic resonance imaging apparatus 100 may apply a third pulse sequence 430 to the first slice after the inversion time TI has elapsed. The third pulse sequence 430 may be, for example, a fast spin echo sequence. The magnetic resonance imaging apparatus 100 may acquire a third magnetic resonance signal for imaging the third magnetic resonance image for the first slice based on the third pulse sequence 430. [ In addition, the magnetic resonance imaging apparatus 100 can image the FLAIR image and the reversed applied proton density (PDIR) image based on the third magnetic resonance signal.

5 is a diagram for explaining a pulse sequence provided by the MRI apparatus 100 according to an embodiment.

The pulse sequence diagram 500 shown in FIG. 5 is a pulse sequence diagram showing a first acquisition time interval 510 and a second acquisition time interval 520 included in the repetition time TR provided in the magnetic resonance imaging apparatus 100, Sequence.

According to one embodiment, the first acquisition time interval 510 corresponds to half of the iteration time and the second acquisition time interval 520 can correspond to the other half of the iteration time.

The first pulse sequence 512, the first inverted RF pulse 514, the second pulse sequence 516 and the third pulse sequence 518 applied during the first acquisition time interval 510 correspond to those described in FIG. The description will be omitted.

5, a fourth pulse sequence 522, a second inverse RF pulse 524, and a second inversion pulse 524 are generated at 520 in a second acquisition time interval after the first acquisition time interval 510, A fifth pulse sequence 526, and a sixth pulse sequence 528 may be applied.

The fourth pulse sequence 522, the fifth pulse sequence 526 and the sixth pulse sequence 528 may correspond to at least one of a gradient echo sequence, a fast spin echo sequence, and a FLAIR sequence, respectively.

5, the magnetic resonance imaging apparatus 100 may apply a fourth pulse sequence 522 to a second slice before applying a second inverse RF pulse 524 to the second slice. have. The fourth pulse sequence 522 may be, for example, a gradient echo sequence. Also, the fourth pulse sequence 522 may be an echo plane image (EPI) sequence.

The magnetic resonance imaging apparatus 100 may acquire a fourth magnetic resonance signal for imaging the fourth magnetic resonance image for the second slice based on the fourth pulse sequence 522. [ For example, the fourth magnetic resonance image may include a T2 * emphasis image.

The magnetic resonance imaging apparatus 100 may acquire a fifth magnetic resonance signal for imaging at least one fifth magnetic resonance image for the first slice based on the fifth pulse sequence 526. [ The at least one fifth magnetic resonance imaging may include a T2-weighted image. Also, at least one fifth magnetic resonance imaging may include a T2 weighted image and a proton density image.

According to one embodiment, the magnetic resonance imaging apparatus 100 may acquire a fifth magnetic resonance signal for the first slice during the inversion time 530 by the second inversion RF pulse 524. The inversion time 530 may be approximately 2.5 seconds, for example, when the magnetic resonance imaging apparatus 100 is operated at a magnetic field of 3T.

According to one embodiment, the magnetic resonance imaging apparatus 100 may be configured to generate a second magnetic resonance imaging signal for imaging the sixth magnetic resonance image for the second slice, based on the sixth pulse sequence 528 after the inverse time 530 has elapsed 6 magnetic resonance signal can be obtained. In addition, the magnetic resonance imaging apparatus 100 can image the FLAIR image and the reversed applied proton density (PDIR) image for the second slice based on the sixth magnetic resonance signal.

According to one embodiment, the magnetic resonance imaging apparatus 100 acquires a T1 weighted image for the second slice using a proton density image for the second slice and an inverted applied proton density (PDIR) image for the second slice .

For example, a proton density image for the second slice may be obtained based on the magnetic resonance signal obtained during the first acquisition time interval 510. [ In addition, an inverted applied proton density (PDIR) image for the second slice may be obtained based on the magnetic resonance signal obtained during the second acquisition time interval 520. [

Referring to FIG. 5, after the second pulse sequence 516 included in the first acquisition time interval 510 is applied to the second slice, the time required until the influence of the second pulse sequence 516 can be ignored is represented by t1 ( 540).

Accordingly, the fourth pulse sequence 522 included in the second acquisition time interval 520 is generated after the second pulse sequence 516 included in the first acquisition time interval 510 is applied to the second slice, 540) has elapsed, it may be applied to the second slice.

According to one embodiment, the magnetic resonance imaging apparatus 100 is configured to generate a first acquisition time interval 510 and a second acquisition time interval 520 based on a magnetic resonance signal obtained during a repetition time including a first acquisition time interval 510 and a second acquisition time interval 520, A magnetic resonance image having various contrasts for the second slice can be obtained.

For example, the MRI apparatus 100 may acquire a T2 * weighted image, a T2 weighted image, a proton density image, a FLAIR image, and a T1 weighted image for each of the first slice and the second slice during one repetition time have.

According to one embodiment, the magnetic resonance imaging apparatus 100 is capable of generating a T2 * weighted image, a T2 weighted image, a proton density image, a FLAIR image, and a T1 weighted image in about half the time Can be saved.

FIG. 6 is a view for explaining a method of acquiring an image in the MRI apparatus 100 according to an embodiment.

The pulse sequence diagram 600 shown in FIG. 6 is a pulse sequence diagram showing a pulse sequence during a first acquisition time interval 610 and a second acquisition time interval 620 included in the repetition time TR provided in the magnetic resonance imaging apparatus 100 Sequence.

6, the first slice and the second slice are divided into odd-numbered slices (first slice, third slice, fifth slice, n-1 slice) and even slice (Slice # 2, slice # 4, slice # n, n slice). In this case, the pulse sequences included in the pulse sequence diagram 600 may be applied to all the slices to be obtained.

For example, when applying the pulse sequence included in the first block 610, the magnetic resonance imaging apparatus 100 may include a first pulse sequence 612 on the first slice, an inverted RF pulse 614 on the first slice A first pulse sequence 612 on slice 3, an inverted RF pulse 614 on slice 3, a first pulse sequence 612 on slice 5, an inverted RF pulse 614 on slice 5, and so on. the first pulse sequence included in the first block 610 can be applied to the first slice in the order of the first pulse sequence 612 on the (n-1) th slice and the inverse RF pulse 614 on the (n-1) have.

The magnetic resonance imaging apparatus 100 also includes a second pulse sequence 616 on the second slice 616, a second pulse sequence 616 on the fourth slice 616, The second pulse sequence 616 can be applied to the second slice in the order of the second pulse sequence 616, ..., and the second pulse sequence 616 to the nth slice.

When the third pulse sequence 618 is applied to the resonance imaging apparatus 100, the third pulse sequence 618 is applied to the first slice, the third pulse sequence 618 is applied to the third slice, The third pulse sequence 618 can be applied to the first slice in the order of the third pulse sequence 618, ..., and the third pulse sequence 618 on the (n-1) th slice.

_Referring to FIG. 6, the recovery time (T _recovory ) for the second slice may be 4000 _ms , for example. Where the recovery time T _recovory for the second slice may be the time after the second pulse sequence 616 is applied to the second slice and before the second slice is read out in the second acquisition period 620 . In addition, the time inversion by the first inverted RF pulse may be 2100 ms, for example.

7 is a view for explaining a method of acquiring an image in the magnetic resonance imaging apparatus 100 according to an embodiment.

7 specifically shows that the magnetic resonance imaging apparatus 100 acquires an image based on the first pulse sequence 712 and the inverted RF pulse 714 during the first acquisition period 710. [

The magnetic resonance imaging apparatus 100 can acquire the first magnetic resonance image in accordance with the application of the first pulse sequence 712. [ The first magnetic resonance image acquired based on the first pulse sequence 712 may comprise a T2 * weighted image.

For example, a first pulse sequence 712 may be applied to a slice # 1 before applying an inverse RF pulse 714 to the slice # 1. The first pulse sequence 712 may be, for example, a gradient echo sequence. Also, the first pulse sequence 712 may be an echo plane image (EPI) sequence. In addition, the inverted RF pulse 714 may include a 180 degree pulse.

When the first pulse sequence 712 and the inverted RF pulse 714 are applied to the first slice, the magnetic resonance imaging apparatus 100 outputs the first pulse sequence 712 and the inverted RF pulse 714 to the slice # 3 .

An inverted RF pulse 714 may then be used to obtain a third magnetic resonance signal for acquiring the FLAIR image and the PDIR image for the first slice.

8 is a diagram for explaining a method of acquiring an image in the magnetic resonance imaging apparatus 100 according to an embodiment.

FIG. 8 specifically shows that the magnetic resonance imaging apparatus 100 acquires an image based on the dual echo FSE sequence during the first acquisition period 810. FIG.

The magnetic resonance imaging apparatus 100 can acquire the second magnetic resonance signal based on the dual echo FSE sequence. In addition, the magnetic resonance imaging apparatus 100 can acquire the proton density image and the T2 weighted image by view sharing the second magnetic resonance signal based on the dual echo FSE sequence.

When acquiring a plurality of images having different contrast degrees using view sharing, the magnetic resonance imaging apparatus 100 acquires data corresponding to high frequencies of k spatial data only once, The data corresponding to the low frequency in the k spatial data can be obtained in each effective echo time (effective TE) in the multiple echo sequence.

Referring to FIG. 8, the magnetic resonance imaging apparatus 100 shows a second pulse sequence 800 for acquiring a second magnetic resonance signal for a second slice.

The magnetic resonance imaging apparatus 100 may acquire a proton density image PD and a T2 weighted image based on the second pulse sequence 800 while using view sharing.

The second pulse sequence 800 according to one embodiment may be used to obtain an image having two contrasts corresponding to two effective echo times and may be referred to as a dual echo sequence.

For example, referring to FIG. 8, an Echo train length (ETL), which is the total number of echoes included in one cycle of the second pulse sequence 800, may be twelve.

The first four echoes may be for the effective echo time to obtain k spatial data corresponding to TE1. In addition, the last four echoes may be for obtaining k spatial data corresponding to the effective echo time TE2.

Further, the four middle echoes may be used to acquire k-space data shared when acquiring an image having two contrasts, as data corresponding to a high frequency of the k-space data.

The magnetic resonance imaging apparatus 100 can acquire the proton density image PD and the T2 weighted image corresponding to the effective echo times TE1 and TE2 by adjusting the phase gradient (G _phase ).

Although not shown in the drawing, the magnetic resonance imaging apparatus 100, similarly to the method of acquiring the proton density image (PD) and the T2 weighted image, can view the third magnetic resonance signal based on the dual echo FSE sequence, (PDIR) and FLAIR images can be acquired by applying the inverse.

Meanwhile, the disclosed embodiments may be embodied in the form of a computer-readable recording medium for storing instructions and data executable by a computer. The command may be stored in the form of program code, and when executed by the processor, may generate a predetermined program module to perform a predetermined operation. In addition, the instructions, when executed by a processor, may perform certain operations of the disclosed embodiments.

The embodiments disclosed with reference to the accompanying drawings have been described above. It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims. The disclosed embodiments are illustrative and should not be construed as limiting.

Claims (20)

A first acquiring interval in which a first inversion RF pulse is applied to a first slice of the object and a second acquiring interval in which a second inverse RF pulse is applied to a second slice of the object adjacent to the first slice, And to apply the pulse sequence of one cycle including the target pulse sequence to a plurality of slices of the object,
A first magnetic resonance signal for imaging a first magnetic resonance image for the first slice during the first acquisition period, at least one second magnetic resonance image for a second slice of the object adjacent to the first slice, And a third magnetic resonance signal for imaging the at least one third magnetic resonance image with respect to the first slice,
Wherein the first magnetic resonance image, the second magnetic resonance image, and the third magnetic resonance image are images having different contrast degrees from each other. The apparatus of claim 1, wherein the control unit obtains the first magnetic resonance signal based on a gradient echo signal,
Wherein the first magnetic resonance image comprises a T2 * weighted image. The method according to claim 1,
Wherein the second magnetic resonance signal is obtained during a time inversion by the first inverse RF pulse. 2. The method of claim 1, wherein the at least one second magnetic resonance image comprises a proton density (PD) image and a T2 weighted image,
The control unit acquires the second magnetic resonance signal by a dual echo sequence and acquires the proton density image and the T2 weighted image by view sharing the second magnetic resonance signal, Magnetic resonance imaging device. 2. The method of claim 1, wherein the at least one third magnetic resonance imaging comprises a reversed applied proton density image (PDIR) and a FLAIR image,
Wherein,
Acquire the third magnetic resonance signal by a dual echo sequence, and obtain reversible applied proton density image (PDIR) and FLAIR image by view sharing the third magnetic resonance signal. The apparatus of claim 1, wherein the control unit
And acquires the third magnetic resonance signal after the inversion time (TI) before the second acquisition period. 2. The method of claim 1, wherein the first acquisition interval is included in a half of a repetition time (TR)
And the second acquisition period is included in the remaining half of the repetition time. The method according to claim 1,
The control unit
A fourth magnetic resonance signal for imaging a fourth magnetic resonance image for the second slice during the second acquisition period, a fifth magnetic resonance imaging for imaging at least one fifth magnetic resonance image for the first slice, Signal and a sixth magnetic resonance signal for imaging a sixth magnetic resonance image for the second slice. 9. The apparatus of claim 8, wherein the controller acquires the fourth magnetic resonance signal by a gradient echo signal,
Wherein the fourth magnetic resonance image comprises a T2 * weighted image. 9. The method of claim 8,
And the fifth magnetic resonance signal is obtained during a time inversion by the second inversion RF pulse. 9. The method of claim 8, wherein the at least one fifth magnetic resonance imaging comprises a proton density (PD) image and a T2 weighted image,
Wherein the controller acquires the fifth magnetic resonance signal by a dual echo sequence and acquires the proton density image and the T2 weighted image by view sharing the fifth magnetic resonance signal Magnetic resonance imaging device. 9. The method of claim 8, wherein the at least one sixth magnetic resonance imaging comprises a reversed applied proton density image (PDIR) and a FLAIR image,
Wherein,
And acquires the sixth magnetic resonance signal by a dual echo sequence and obtains a reversed applied proton density image (PDIR) and a FLAIR image by view-sharing the sixth magnetic resonance signal. A method for acquiring a magnetic resonance image,
A first acquiring interval in which a first inversion RF pulse is applied to a first slice of the object and a second acquiring interval in which a second inverse RF pulse is applied to a second slice of the object adjacent to the first slice, Applying a pulse sequence of one cycle to a plurality of slices of the object; And
During the first acquisition interval,
Obtaining a first magnetic resonance signal for imaging a first magnetic resonance image for the first slice;
Obtaining a second magnetic resonance signal for imaging at least one second magnetic resonance image for a second slice of the subject adjacent to the first slice; And
Obtaining a third magnetic resonance signal for imaging at least one third magnetic resonance image for the first slice,
Wherein the first magnetic resonance image, the second magnetic resonance image, and the third magnetic resonance image are images having different contrast degrees from each other. 14. The method of claim 13, wherein the first magnetic resonance signal is obtained based on a gradient echo signal,
Wherein the first magnetic resonance image comprises a T2 * weighted image. 14. The method of claim 13,
Wherein the second magnetic resonance signal is obtained during a time inversion by the first inverse RF pulse. 14. The method of claim 13, wherein the at least one second magnetic resonance image comprises a proton density (PD) image and a T2 weighted image, the second magnetic resonance signal is acquired by a dual echo sequence,
Further comprising obtaining the proton density image and the T2 weighted image by view sharing the second magnetic resonance signal. 14. The method of claim 13, wherein the at least one third magnetic resonance image comprises a reversed applied proton density image (PDIR) and a FLAIR image, the third magnetic resonance signal is acquired by a dual echo sequence,
Further comprising obtaining an inversion applied proton density image (PDIR) and a FLAIR image by view sharing the third magnetic resonance signal. 14. The method of claim 13,
Wherein the third magnetic resonance signal is obtained before the second acquisition period after an inversion time (TI) is over. 14. The method of claim 13, wherein the first acquisition interval is included in half of a repetition time (TR)
And the second acquisition period is included in the remaining half of the repetition time. 15. A program recorded on a computer readable medium for implementing the method of claim 13.

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