KR20220129376A - Method and apparatus of magnetic field mode-shaping in magnetic resonance imaging, pad manufactured by using the same, computer program - Google Patents

Abstract

The present invention relates to a magnetic field mode shaping method and apparatus in magnetic resonance imaging, a pad manufactured using the same, and a computer program, wherein the magnetic field mode shaping method comprises the following steps of: modeling a cylindrical magnetic resonance imaging (MRI) system including an RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, a phantom formed on an inside of the pad and simulating an inspection target, and an air gap formed between the pad and the phantom; disposing the RF coil, shield, pad, and phantom in a structure sharing a first axis; acquiring a uniformity parameter indicating uniformity of the magnetic field formed in the phantom in a process of varying a mode shaping parameter for shaping a mode of the magnetic field formed by the RF coil, selected based on evanescent coupling between the phantom and the pad; and optimizing the mode of magnetic field of the modeled cylindrical MRI system by determining whether the obtained uniformity parameter satisfies a predefined mode shaping condition. A purpose of the present invention is to achieve global homogenization of the magnetic field.

Description

Method and apparatus for forming magnetic field mode in magnetic resonance imaging, a pad manufactured using the same, and a computer program

The present invention relates to a method and apparatus for forming a magnetic field mode in magnetic resonance imaging, a pad manufactured using the same, and a computer program, and more particularly, to an ultra-high magnetic resonance imaging method through magnetic field mode shaping based on evanescent coupling. To uniformly form a high-frequency signal magnetic field (B ₁ ⁺ ) in a magnetic resonance imaging method and apparatus for forming a magnetic field mode, a pad manufactured using the same, and a computer program.

A method of controlling the shape of a mode through evanescent coupling has been used in various fields of electromagnetic waves and optics, such as nano/micro particles, waveguides, resonators, etc. It has proven its usefulness by being utilized in various applications according to the combination of various electromagnetic waves and optical situations such as linear/nonlinear, polarization or spin in the structure of Among them, a double-clad W-type fiber is an inner cladding of a low dielectric constant material surrounding a core and an outer cladding made of a high dielectric constant material, It can perform a function of adjusting modal confinement or dispersion properties that cannot be obtained from a single clad-core structure. As a physically similar problem, there is a radio-frequency field (RF) magnetic field B ₁ ⁺ adjustment problem in Magnetic Resonance Imaging (MRI), which is a problem in a different frequency band in a large category of electromagnetic wave mode control. corresponds to the application of

Magnetic resonance imaging is an additional high-frequency radio frequency (RF) image with respect to the magnetization vector of nuclides (hydrogen, phosphorus, sodium, carbon, etc.) in the human body formed as a uniform main magnetic field B ₀ application. ) By applying a magnetic field B ₁ ⁺ pulse to resonate a specific nuclide (hydrogen, etc.), the magnetic resonance signal generated by the attenuation of the excited magnetization vector in the vertical plane direction is obtained, and it is reconstructed and imaged through a computer.

In order to improve the quality of an image obtained from a magnetic resonance imaging system, a method of increasing the intensity of a static magnetic field B ₀ is used. As the intensity of B ₀ is increased, signal-to-noise ratio (SNR), spatial and temporal resolutions, and image contrast are improved. However, the increase in this static magnetic field is accompanied by a decrease in the magnetic field pulse generated by the RF coil, that is, the Larmor frequency ω _L , which is the operating frequency of the high-frequency signal B ₁ ⁺ , and the corresponding Larmor wavelength λ _L . , at this time, if the Larmer wavelength in the living body is smaller than the size of the living body, the problem of inhomogeneity of B ₁ ⁺ in MRI occurs. For example, the above problem is conspicuous in the case of ultra-high-field (UHF) MRI of B ₀ = 7T or higher, which has been used recently. In the case of B ₀ = 7T , λ _L = 11 cm, which is similar to or smaller than the size of the human body, and as the human body operates as a magnetic field resonator larger than the wavelength, B ₁ ⁺ appears bright in the center of the human body and dark in the periphery, which again reduces the image quality.

A general method taken in the past to correct this non-uniformity of B ₁ ⁺ is to use high-permittivity materials (HPM) that function to change the distribution of B ₁ ⁺ . In this method, the structure of a dielectric pad filled with water or a mixture having a higher dielectric constant is brought into contact with the human body to improve signal sensitivity around the pad. This approach is applicable to locally tune the field distribution through B ₁ ⁺ enhancement near the pad structure, but provides a global uniformity for the intensity of B ₁ ⁺ throughout the magnetic resonance image including the non-pad area. On the contrary, it leads to aggravating results.

The present invention was created to solve the problem of B ₁ ⁺ wide-area uniformity in the entire magnetic resonance image described above, and an object according to an aspect of the present invention is to achieve ultra-high Magnetic field mode shaping method and apparatus in magnetic resonance imaging for uniformly forming a magnetic field formed by an RF coil in magnetic resonance imaging, that is, a high-frequency signal B ₁ ⁺ , to achieve global homogenization, It is to provide a pad manufactured using the computer program.

In a magnetic resonance imaging method according to an aspect of the present invention, a method for forming a magnetic field mode in magnetic resonance imaging includes an RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, and formed inside the pad, Modeling a cylindrical magnetic resonance imaging (MRI) system including a phantom simulating an examination object, and an air gap formed between the pad and the phantom, wherein the RF coil, the shield, and the pad , wherein the phantom is arranged in a structure sharing a first axis, for shaping the magnetic field mode formed by the RF coil, selected based on the evanescent coupling between the phantom and the pad Acquiring a uniformity parameter indicative of the uniformity of a magnetic field formed in the phantom in a process in which the mode shaping parameter is varied, and a method of determining whether the obtained uniformity parameter satisfies a predefined mode shaping condition It characterized in that it comprises the step of optimizing the magnetic field mode of the modeled cylindrical MRI system.

In the present invention, the mode shaping parameters include the depth and width of a potential of the pad for determining the strength and width of the magnetic field in the pad, respectively, and the mode hybridization intensity of the phantom and the pad. and including the width of the air gap for determining .

In the present invention, the pad is modeled as a dielectric pad, and the depth of the potential of the pad is a dielectric constant of the pad.

In the present invention, the pad is modeled as a magnetic pad, and the mode molding parameter includes magnetic permeability of the pad.

In the present invention, the uniformity parameter is calculated based on the magnitude of the magnetic field formed radially with respect to the first axis of the phantom, the maximum value and the minimum value of the magnitude of the magnetic field B ₁ ⁺ formed on the axial plane of the phantom. It is characterized in that it is calculated as a ratio.

In the present invention, in the acquiring step, the depth and width of the potential of the pad are varied in a complementary manner.

In the step of optimizing in the present invention, if the currently obtained uniformity parameter is less than or equal to a predefined reference value, it is determined that the mode molding condition is satisfied, and the mode molding parameter corresponding to the currently acquired uniformity parameter is modeled. It is characterized by determining the optimal mode shaping parameters to optimize the magnetic field mode of the cylindrical MRI system.

The present invention provides a pad manufactured by a magnetic field mode molding method in magnetic resonance imaging, wherein the pad is manufactured by using a dielectric pad or a magnetic pad, or a combination of both.

A magnetic field mode shaping apparatus in magnetic resonance imaging according to an aspect of the present invention includes a processor, and a memory in which at least one instruction for magnetic field mode shaping in magnetic resonance imaging is stored, which is executed through the processor. The at least one command executed through the processor includes an RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, and a test target formed inside the pad. A command to model a cylindrical magnetic resonance imaging (MRI) system including a phantom to simulate and an air gap formed between the pad and the phantom, the RF coil, the shield, the pad, and the Mode shaping for shaping the magnetic field mode formed by the RF coil, selected based on a command, evanescent coupling between the phantom and the pad, wherein the phantom is arranged in a structure that shares a first axis A command to obtain a uniformity parameter indicative of the uniformity of the magnetic field formed in the phantom in the process of changing the parameter, and a method of determining whether the obtained uniformity parameter satisfies a predefined mode molding condition and instructions for optimizing the magnetic field mode of the modeled cylindrical MRI system.

A computer program according to an aspect of the present invention is combined with hardware to form an RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, and a pad formed inside the pad to simulate an inspection target Modeling a cylindrical magnetic resonance imaging (MRI) system including a phantom, and an air gap formed between the pad and the phantom, wherein the RF coil, the shield, the pad, and the phantom are The mode shaping parameters for shaping the magnetic field mode formed by the RF coil, selected based on the evanescent coupling between the phantom and the pad, are arranged in a structure that shares a first axis. obtaining a uniformity parameter indicative of the uniformity of the magnetic field formed in the phantom in the process of being varied, and determining whether the obtained uniformity parameter satisfies a predefined mode forming condition. It is characterized in that it is stored in a computer-readable storage medium for executing the step of optimizing the mode of the cylindrical MRI system.

According to one aspect of the present invention, the present invention models a cylindrical MRI system and acquires a uniformity parameter indicating the uniformity of a magnetic field formed in a phantom in the process of changing a predetermined mode shaping parameter, thereby forming a predefined mode. By adopting a method of optimizing the magnetic field mode of the modeled cylindrical MRI system in a way that determines whether the condition is satisfied, the magnetic field formed by the RF coil, that is, the high-frequency signal B ₁ ⁺ A topology can be provided to form Furthermore, based on the advantage that the effect is wide, it is possible to secure 2D wide area uniformity of axial B ₁ ⁺ that can be used for axial 2D MRI scanning, which is widely used clinically. In addition, freedom and flexibility in design can be provided by revealing the material/spatial complementarity of the structure.

1 is a block diagram illustrating an apparatus for forming a magnetic field mode in a magnetic resonance imaging method according to an embodiment of the present invention.
2 is a flowchart illustrating a method of forming a magnetic field mode in a magnetic resonance imaging method according to an embodiment of the present invention.
3 is an exemplary diagram illustrating a cylindrical MRI system modeled in a magnetic field mode shaping method in a magnetic resonance imaging method according to an embodiment of the present invention.
4 is an exemplary view showing the distribution of the magnetic field B ₁ ⁺ in the r direction in the z = 0 plane in the magnetic field mode shaping method in the magnetic resonance imaging method according to an embodiment of the present invention.
5 is an exemplary view showing the effect of the depth of the pad potential on the mode shaping in the magnetic field mode shaping method in the magnetic resonance imaging method according to an embodiment of the present invention.
6 is an exemplary view showing the effect of the width of the pad potential on the mode shaping in the magnetic field mode shaping method in the magnetic resonance imaging method according to an embodiment of the present invention.
7 is an exemplary view showing the effect of the width of the air gap on the mode shaping in the magnetic field mode shaping method in the magnetic resonance imaging method according to an embodiment of the present invention.
8 is an exemplary diagram illustrating the effect of the magnetic permeability of a pad on mode shaping as an additional degree of design freedom in a magnetic field mode shaping method in a magnetic resonance imaging method according to an embodiment of the present invention.
9 is an exemplary view showing a result of uniformity of the magnetic field B ₁ ⁺ with respect to the spheroid phantom in the magnetic field mode forming method in the magnetic resonance imaging method according to an embodiment of the present invention.

Hereinafter, an embodiment of a method and apparatus for forming a magnetic field mode in a magnetic resonance imaging method, a pad manufactured using the same, and a computer program according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, definitions of these terms should be made based on the content throughout this specification.

1 is a block diagram for explaining an apparatus for forming a magnetic field mode in a magnetic resonance imaging method according to an embodiment of the present invention. Referring to FIG. 1 , an apparatus for forming a magnetic field mode in a magnetic resonance imaging method according to the present embodiment. may include the memory 100 and the processor 200 .

At least one command for forming a magnetic field mode in the magnetic resonance imaging method may be stored in the memory 100 . In this embodiment, the magnetic field mode shaping in the magnetic resonance imaging method means the magnetic field formed by the RF coil in UHF MRI to which an ultra-high magnetic field (eg, B ₀ = 7T) is applied as a static magnetic field, that is, the mode form of B ₁ ⁺ It is defined as controlling and increasing the signal uniformity, and is defined as the ratio (MmR, to be described later) of the magnetic field B ₁ ⁺ formed at a position radially spaced apart from the first axis of the phantom as a mode shaping condition as described later. It is quantitatively optimized by the uniformity parameter. The memory 100 for storing instructions for magnetic field mode shaping may be implemented as a volatile storage medium and/or a non-volatile storage medium, for example, a read only memory (ROM) and/or a random access memory ( RAM: Random Access Memory).

The processor 200 is a subject that performs magnetic field mode shaping in the magnetic resonance imaging method, and may be implemented as a central processing unit (CPU) or a system on chip (SoC), and operates an operating system or application to A plurality of hardware or software components connected to the processor 200 may be controlled, and various data processing and operations may be performed. The processor 200 may be configured to execute at least one command stored in the memory 100 , and store the execution result data in the memory 100 .

At least one command stored in the memory 100 and executed by the processor 200 includes: i) an RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, and formed inside the pad and a command to model a cylindrical magnetic resonance imaging (MRI) system including a phantom that simulates the object to be inspected, and an air gap formed between the pad and the phantom, and ii) evanescent between the phantom and the pad A command to obtain a uniformity parameter indicative of the uniformity of the magnetic field formed in the phantom in the process of changing the mode shaping parameter for shaping the magnetic field mode formed by the RF coil, selected based on Evanescent Coupling, and , iii) to optimize the magnetic field mode of the modeled cylindrical MRI system in such a way as to determine whether the obtained uniformity parameter satisfies a predefined mode shaping condition.

Hereinafter, a specific process of magnetic field mode shaping in the magnetic resonance imaging method will be described in detail with reference to FIGS. 2 to 9 .

2 is a flowchart for explaining a method of forming a magnetic field mode in magnetic resonance imaging according to an embodiment of the present invention, and FIG. 3 is a method of forming a magnetic field mode in magnetic resonance imaging according to an embodiment of the present invention. It is an exemplary view showing a modeled cylindrical MRI system, and FIG. 4 is the distribution of magnetic field B ₁ ⁺ in the r direction in the z = 0 plane in the magnetic resonance imaging method in the magnetic resonance imaging method according to an embodiment of the present invention. is an exemplary view showing the effect of the depth of the pad potential on the mode shaping in the magnetic resonance imaging method in the magnetic field mode shaping method according to an embodiment of the present invention, Figure 6 is an exemplary view of the present invention It is an exemplary view showing the effect of the width of the pad potential on the mode shaping in the magnetic resonance imaging method in the magnetic resonance imaging method according to an embodiment, Figure 7 is the magnetic field in the magnetic resonance imaging method according to an embodiment of the present invention. It is an exemplary view showing the effect of the width of the air gap on the mode shaping in the mode shaping method, and FIG. 8 is the magnetic permeability of the pad as an additional degree of design freedom in the magnetic resonance imaging method in the magnetic resonance imaging method according to an embodiment of the present invention. It is an exemplary view showing the effect on mode shaping, and FIG. 9 shows the result of uniformizing the magnetic field B ₁ ⁺ for the spheroid phantom in the magnetic field mode shaping method in the magnetic resonance imaging method according to an embodiment of the present invention It is also an example.

Referring to FIG. 2 , first, the processor 200 models a cylindrical MRI system as a premise for mode shaping of a magnetic field B ₁ ⁺ and increasing signal uniformity through magnetic field mode shaping in magnetic resonance imaging (S100). 3 is an example of a cylindrical MRI system, and shows a structure and a layout of a potential corresponding thereto when a pad is applied for correction of a magnetic field B ₁ ⁺ in a magnetic resonance image.

As shown in FIG. 3 , the cylindrical MRI system includes an RF coil that forms a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, and a pad formed inside the pad, and uses an object to be examined (eg, the head of a human body) It is modeled to include the simulated phantom and an air gap formed between the pad and the phantom. In FIG. 3 , only a half portion corresponding to 0°≤θ≤180° is shown in order to help understanding of the embodiment. The RF coil can be modeled as a surface current source having a set size, shape, and number (eg, a rectangle of 1 cm x 18 cm, 16) as an RF excitation source of magnetic field B ₁ ⁺ , and each source is described later. It can be configured as a rotationally symmetric structure to have radial equal spacing (eg, 360°/16 = 22.5°) based on the phantom of It can be modeled to be driven through a sinusoidal driving signal having a phase difference of . The shield surrounds the RF coil and can be modeled as a structure having a set size and physical properties (eg, a perfect electric conductor (PEC) with a radius of 17 cm and a height of 18 cm). The phantom has a set size and physical properties (height 18cm, radius 7cm, relative permittivity 74.2, electrical conductivity 0.87S/m) and can be modeled to simulate an object to be examined (eg, the human head) through magnetic resonance imaging. The pad may be modeled as a structure surrounding the phantom through an air gap, and the air gap functions as a potential barrier between the phantom and the pad.

The RF coil, shield, pad, and phantom may be disposed in a structure that shares a first axis (ie, the central axis of the phantom), and in FIG. 3 , the first axis is the z-axis direction, and the radial direction (r) of the cylindrical MRI system. direction) is shown in the x-axis direction. Such a cylindrical MRI system may minimize mode mixing in radial (r), sagittal (z), and azimuthal (θ) directions while having translational symmetry in the z -axis direction.

The cylindrical MRI system modeled as described above treats the MRI system consisting of the human body and the RF coil as a cylindrical waveguide operating at a specific Larmer wavelength, and adjusts the mode shape in the human body through evanescent coupling. It serves as a configuration for applying a high permittivity cladding layer (ie, a cylindrical permittivity pad) to act as an auxiliary EM potential well.

After step S100, the processor 200 selects based on the evanescent coupling between the phantom and the pad, the mode shaping parameter for shaping the mode of the magnetic field B ₁ ⁺ formed by the RF coil is formed in the phantom in the process of being changed A uniformity parameter indicating the uniformity of the magnetic field B ₁ ⁺ is obtained (S200).

Specifically, when looking at the cylindrical MRI system modeled in step S100 from the perspective of evanescent coupling, the adjustment of the depth and width of the pad potential determines the strength and width of the magnetic field B ₁ ⁺ at the pad (and accordingly, the mode within the phantom). shape), and the control of the potential barrier determines the evanescent coupling and mode hybridization, ultimately achieving mode shaping. Accordingly, in this embodiment, the mode shaping parameters are the depth and width of the pad potential for determining the strength and width of the magnetic field B ₁ ⁺ in the pad, respectively, and the depth and width of the air gap for determining the hybridization strength between the phantom and the pad mode. Width can be included. The depth of the pad potential is adjustable by the permittivity of the pad (ε _p ), the width of the pad potential is adjustable by the width of the pad (W _p ), and the potential barrier is controlled by the width of the air gap (W _b ). It is possible.

₄ shows the concept of evanescent mode coupling when the pad potential is applied ^. distribution is shown. FIG. 4 compares the case where only the phantom exists (yellow curve), the case where only the pad potential exists (blue curve), and the case where the phantom and the pad potential exist simultaneously (red curve) in the cylindrical MRI system, respectively. In the example of FIG. 4 , the permittivity (ε _p ) of the pad was 180, the width of the pad (W _p ) was 2 cm, and the width of the air gap (W _b ) was 2 cm, and the yellow shaded range indicates the area of the phantom, and the blue The shaded range indicates the area of the pad.

As described above, in step S200, the processor 200 acquires a uniformity parameter indicating the uniformity of the magnetic field B ₁ ⁺ formed in the phantom while the mode shaping parameter is varied, and in this embodiment, the uniformity parameter is the phantom. It is calculated based on the magnitude of the magnetic field B ₁ ⁺ formed radially with respect to the first axis. Specifically, the uniformity parameter is defined as the ratio of the maximum value and the minimum value of the magnitude of the magnetic field B ₁ ⁺ formed on a specific axial plane of the phantom, the axial B ₁ ⁺ maximum/minimum ratio (MmR) In the following embodiment, it is represented by a value at a position where z = 0 (at a position mainly causing non-uniformity of B ₁ ⁺ ), which is the center.

After step S200, the processor 200 optimizes the magnetic field mode of the modeled cylindrical MRI system in such a way that it is determined whether the uniformity parameter obtained in step S200 satisfies a predefined mode molding condition (S300).

Specifically, in step S300, the processor 200 determines that the mode molding condition is satisfied when the currently acquired uniformity parameter is less than or equal to a predefined reference value, and sets the mode molding parameter corresponding to the currently acquired uniformity parameter in step S100. Determine the optimal mode shaping parameters to optimize the magnetic field mode of the modeled cylindrical MRI system. The above-mentioned reference value is the value of MmR, and may be predefined in the processor 200 or the memory 100 as a specific value (eg, 2) determined in consideration of the designer's experiment and specifications of the MRI system to be designed. have.

Steps S200 and S300 will be described as specific examples according to FIGS. 5 to 7 . 5 to 7 show the above-described three-mode molding parameters (depth of pad potential (= dielectric constant (ε _p ) of pad)), width of pad potential (= width of pad (W _p )), and potential barrier (= air gap) (W _b )) shows the effect of modal shape on the mode shaping The purpose of this embodiment to induce mode shaping suitable for axial 2D MRI scanning, which is widely used clinically, is clearly explained. In each figure, the magnitude and distribution of the normalized magnetic field B ₁ ⁺ in the sagittal plane (θ = 0) are shown along with a contour. The contour represents the magnetic field B ₁ ⁺ value of B at the center of the phantom. B ₁ ⁺ /B ₁ ⁺ _center normalized to ₁ ⁺ value 1 (red), 1/2 (yellow), and 1/4 (blue) indicate points of interest. ) is indicated by a black rectangle, and the pad is indicated by a black dashed rectangle.

5 shows the effect of the pad potential depth (ε _p ) on the phantom mode, and may be implemented in a manner in which the dielectric constant (ε _p ) of the pad is adjusted. In the example of FIG. 5 , in a state where the width (W _p ) of the pad potential is set to 2 cm and the width (W _b ) of the potential barrier is set to 2 cm, the depth (ε _p ) of the pad potential is 1, 60, 120, 180, 240, respectively. The magnetic field B ₁ ⁺ distribution in the case of . When the pad potential is shallower than the phantom potential (ε _p < 74.2), the mode shaping effect by the pad potential is insignificant, and the deep and wide phantom potential dominates the overall potential. On the other hand, in the case of a deep pad potential of ε _p > 200, the magnetic field B ₁ ⁺ is strongly focused on the pad and prevents coupling with the phantom. W _p = 2 cm, W _b = 2 cm, ε _p = 180, the equalization parameter in the phantom, that is, MmR, has a minimum value of 1.2. This is significantly reduced compared to the MmR value of 4.3 when only the phantom is present, and the above figure means that the distribution of the magnetic field B ₁ ⁺ is flattened in the radial direction to optimize mode shaping.

In step S200 , the width (W _p ) of the pad potential may be varied in a manner complementary to the depth (ε _p ) of the pad potential, which can be confirmed through the example of FIG. 6 . 6 shows the width and depth (W _p , ε _p ) of the pad potential in a state where the width (W _b ) of the potential barrier is set to 2 cm, respectively (3 cm, 140), (2 cm, 180), (1 cm, 300) The magnetic field B ₁ ⁺ distribution in the case of . The potentials in each case form the same mode, and MmR is also equal to 1.2. This gives a degree of freedom in selecting the physical properties of the pad, and it means that the variables to consider when designing the pad can be reduced.

7 shows the effect of the width (W _b ) of the potential barrier on mode shaping, and may be implemented in a manner in which the width (W _b ) of the air gap is adjusted. In the example of FIG. 7 , the depth (ε _p ) of the pad potential is set to 180, the width (W _p ) of the pad potential is set to 2 cm, and when the width (W _b ) of the potential barrier is 0, the pad is in contact with the phantom. This corresponds to the case where there is, and the case where the width (W _b ) of the potential barrier is greater than 0 corresponds to the case where the phantom potential and the pad potential form an evanescent coupling. By controlling the width (W _b ) of the air gap, the strength of the evanescent bond can be controlled, and the uniformity of the magnetic field B ₁ ⁺ can be improved through this additional degree of freedom. For a contact-type pad where the width (W _b ) of the potential barrier is 0 in the range of the depth (ε _p ) of the pad potential in the range of 1 to 250, the MmR at z = 0 is 2.6 or more, while the width (W _b ) of the potential barrier is greater than or equal to 2.6. ) is greater than 0 (that is, when the phantom potential and the pad potential form an evanescent coupling), an MmR value of 1.2 can be obtained.

In the process described above, that is, in the process of varying the depth (ε _p ) of the pad potential, the width (W _p ) of the pad potential, and the width (W _b ) of the potential barrier as a mode shaping parameter, the processor 200 is formed in the phantom. When MmR is obtained as a uniformity parameter indicating the uniformity of the magnetic field, and the obtained MmR is less than or equal to a reference value (eg 2), the corresponding mode shaping parameter is the optimal mode for optimizing the magnetic field mode of the cylindrical MRI system. It is determined by the molding parameters.

Meanwhile, in the above, it has been described that the pad of this embodiment is modeled as a dielectric (non-magnetic) pad, and accordingly, the depth of the pad potential is the dielectric constant of the pad. However, according to the embodiment, the pad is modeled as a magnetic pad. Accordingly, an embodiment in which the mode shaping parameter further includes the magnetic permeability (μ _p ) of the pad may be prepared. That is, in terms of refractive index, the magnetic permeability of the pad operates with the same potential as the dielectric constant with respect to the magnetic field B ₁ ⁺ , which can be confirmed through the example of FIG. 8 . 8 shows that in a state where the width (W _p ) of the pad potential is set to 2 cm and the width (W _b ) of the potential barrier is set to 2 cm, the magnetic permeability and the permittivity (μ _p , ε _p ) are (2, 135), (4, 98) and (130, 1) show the magnetic field B ₁ ⁺ distribution when the magnetic pad is applied. It can be confirmed that a pattern of magnetic field B ₁ ⁺ is formed, which is the same as in the case of a non-magnetic (dielectric) pad with magnetic permeability and permittivity (μ _p , ε _p ) composed of (1, 180), which is also It provides one degree of freedom and means the applicability of high magnetic materials including metamaterials.

9 shows a result of uniformizing the magnetic field B ₁ ⁺ for the spheroid phantom based on the above-described mode forming technique. In the example of FIG. 9, a more realistic form of a prolate spheroidal phantom was applied, the semi-axes in the x- and y-directions are 7 cm, and the semi-axes in the z-direction are 9 cm, and the constituent materials are as described above. It is the same as that of the cylinder phantom used in the embodiments. The depth of the pad potential (ε _p ), the width of the pad potential (W _p ), and the width of the potential barrier (W _b ) were applied as 188, 2 cm, and 2 cm, respectively. As a result, the z-direction slice in the entire phantom area It was confirmed that the 2D wide area uniformity of on-axis B ₁ ⁺ , which was improved by up to 57% compared to the case without the pad, with MmR having a value of 2 or less for the plane, could be secured.

The above mode molding technique can be utilized to manufacture a pad applied to an MRI system to which axial 2D MRI scanning is applied, which is currently widely used clinically, and the pad manufactured according to the above technique is a dielectric pad or It may be implemented as a magnetic pad.

On the other hand, the magnetic field mode forming method in the magnetic resonance imaging method according to the present embodiment may be written as a computer program for executing steps S100 to S300 described above in combination with hardware, and is stored in a computer-readable recording medium. It can be implemented in a general-purpose digital computer running the computer program. The computer-readable recording medium includes magnetic media such as ROM, RAM, hard disk, floppy disk, and magnetic tape, optical media such as CD-ROM and DVD, and floppy disk. A hardware device specially configured to store and execute program instructions, such as a magneto-optical media, such as a flash memory, may correspond.

As such, the present embodiment models a cylindrical MRI system to obtain a uniformity parameter indicating the uniformity of a magnetic field formed in a phantom in a process in which a predetermined mode shaping parameter is varied, and whether a predefined mode shaping condition is satisfied By adopting _a method of optimizing the magnetic field mode of the modeled ^cylindrical MRI system in such a way as to determine can provide Furthermore, based on the advantage that the effect is wide, it is possible to secure 2D wide area uniformity of axial B ₁ ⁺ that can be used for axial 2D MRI scanning, which is widely used clinically. In addition, freedom and flexibility in design can be provided by revealing the material/spatial complementarity of the structure.

Implementations described herein may be implemented in, for example, a method or process, an apparatus, a software program, a data stream, or a signal. Although discussed only in the context of a single form of implementation (eg, discussed only as a method), implementations of the discussed features may also be implemented in other forms (eg, as an apparatus or program). The apparatus may be implemented in suitable hardware, software and firmware, and the like. A method may be implemented in an apparatus such as, for example, a processor, which generally refers to a computer, a microprocessor, a processing device, including an integrated circuit or programmable logic device, or the like. Processors also include communication devices such as computers, cell phones, portable/personal digital assistants ("PDA") and other devices that facilitate communication of information between end-users.

Although the present invention has been described with reference to the embodiment shown in the drawings, this is merely exemplary, and it is understood that various modifications and equivalent other embodiments are possible by those of ordinary skill in the art. will understand Accordingly, the true technical protection scope of the present invention should be defined by the following claims.

100: memory
200: processor

Claims (11)

A method for shaping a magnetic field mode in magnetic resonance imaging, performed on a computing device, comprising:
An RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, a phantom formed inside the pad to simulate an inspection object, and an air gap formed between the pad and the phantom Modeling a cylindrical magnetic resonance imaging (MRI) system including an (Air Gap), wherein the RF coil, the shield, the pad, and the phantom are disposed in a structure sharing a first axis;
The uniformity of the magnetic field formed in the phantom in the process of changing the mode shaping parameter for shaping the magnetic field mode formed by the RF coil, selected based on the evanescent coupling between the phantom and the pad obtaining an indicative uniformity parameter; and
optimizing the magnetic field mode of the modeled cylindrical MRI system in such a way as to determine whether the obtained uniformity parameter satisfies a predefined mode shaping condition;
A method of forming a magnetic field mode in magnetic resonance imaging, comprising:
According to claim 1,
The mode shaping parameters are the depth and width of the potential of the pad for determining the strength and width of the magnetic field in the pad, respectively, and the mode hybridization strength of the phantom and the pad. A magnetic field mode shaping method in magnetic resonance imaging, characterized in that it includes the width of the air gap.
3. The method of claim 2,
The pad is modeled as a dielectric pad, and the depth of the potential of the pad is a dielectric constant of the pad, the magnetic resonance imaging method of forming a magnetic field mode.
3. The method of claim 2,
The pad is modeled as a magnetic pad, and the mode shaping parameter includes a magnetic permeability of the pad.
3. The method of claim 2,
The uniformity parameter is calculated based on the magnitude of the magnetic field formed radially with respect to the first axis of the phantom, and is calculated as the ratio of the maximum value and the minimum value of the magnitude of the magnetic field B ₁ ⁺ formed on the axial plane of the phantom A method of forming a magnetic field mode in a magnetic resonance imaging method, characterized in that.
6. The method of claim 5,
In the acquiring step, the depth and width of the potential of the pad are varied in a complementary manner, the magnetic field mode shaping method in magnetic resonance imaging.
6. The method of claim 5,
In the optimizing step, if the currently acquired uniformity parameter is less than or equal to a predefined reference value, it is determined that the mode molding condition is satisfied, and the mode molding parameter corresponding to the currently acquired uniformity parameter is set as the modeled cylindrical MRI. A magnetic field mode shaping method in magnetic resonance imaging, characterized in that it is determined as an optimal mode shaping parameter for optimizing the magnetic field mode of the system.
The pad manufactured by the magnetic field mode molding method in the magnetic resonance imaging method according to claim 1 .
9. The method of claim 8,
The pad, characterized in that made of a dielectric pad or a magnetic pad, pad.
processor; and
A memory that is executed through the processor and stores at least one instruction for forming a magnetic field mode in magnetic resonance imaging.
The at least one instruction executed by the processor includes:
An RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, a phantom formed inside the pad to simulate an inspection object, and an air gap formed between the pad and the phantom A command to model a cylindrical magnetic resonance imaging (MRI) system comprising an (Air Gap), wherein the RF coil, the shield, the pad, and the phantom are disposed in a structure sharing a first axis, the command,
The uniformity of the magnetic field formed in the phantom in the process of changing the mode shaping parameter for shaping the magnetic field mode formed by the RF coil, selected based on the evanescent coupling between the phantom and the pad instructions to obtain an indicative uniformity parameter, and
and instructions for optimizing the magnetic field mode of the modeled cylindrical MRI system in a manner to determine whether the obtained uniformity parameter satisfies a predefined mode shaping condition. of magnetic field mode shaping device.
combined with hardware,
An RF coil forming a magnetic field, a shield surrounding the RF coil, a pad formed inside the shield, a phantom formed inside the pad to simulate an inspection object, and an air gap formed between the pad and the phantom Modeling a cylindrical magnetic resonance imaging (MRI) system including an (Air Gap), wherein the RF coil, the shield, the pad, and the phantom are disposed in a structure sharing a first axis;
The uniformity of the magnetic field formed in the phantom in the process of changing the mode shaping parameter for shaping the magnetic field mode formed by the RF coil, selected based on the evanescent coupling between the phantom and the pad obtaining an indicative uniformity parameter; and
optimizing the magnetic field mode of the modeled cylindrical MRI system in such a way as to determine whether the obtained uniformity parameter satisfies a predefined mode shaping condition;
A computer program stored in a computer readable storage medium to execute the computer program.

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