KR101072421B1 - Mri apparatus - Google Patents

Abstract

One aspect of the present invention, the main magnet for generating a main magnetic field, a signal collection unit for collecting a magnetic resonance signal for the subject in the main magnetic field, a breath measuring unit for detecting the respiratory state of the subject, The MRI device may include a controller configured to generate an alternating current according to the respiratory state of the subject measured by the respiratory measurement unit, and at least one local coil generating a corrected magnetic field by the alternating current.

MRI, magnetic field, distortion

Description

MRI device {MRI APPARATUS}

The present invention relates to an MRI apparatus, and more particularly, to an MRI apparatus capable of preventing magnetic field fluctuations caused by breathing of a subject.

MRI (Magnetic Resonance Image) device, which obtains images for diagnosis and treatment in medicine using Nuclear Magnetic Resonance (NMR) phenomenon, is obtained with high contrast images of organs and tissues in the human body. We show power for diagnosis of cancer and tumor, disease. In addition, MRI has the advantage of non-invasive to the human body, unlike the X-ray, CT device, and the like, there is no damage to the radiation, the demand is increasing recently.

When the test is performed using the MRI device, the magnetic field is generated using the main magnetic and the magnetic resonance signal for the subject is measured within the magnetic field. It is important for the subject not to move for accurate measurement. The amount of air in the local region of the human body is changed by the breathing of the subject and the magnetization rate is changed by the amount of air, which may cause magnetic field distortion in the local region. have. There is a problem that accurate measurement of the inside of the human body is difficult due to such magnetic distortion.

In order to solve the above problems, it is an object of the present invention to provide an MRI device that can compensate for the magnetic field fluctuations caused by breathing of the subject.

One aspect of the present invention, the main magnet for generating a main magnetic field, a signal collection unit for collecting a magnetic resonance signal for the subject in the main magnetic field, a breath measuring unit for detecting the respiratory state of the subject, The MRI device may include a controller configured to generate an alternating current according to the respiratory state of the subject measured by the respiratory measurement unit, and at least one local coil generating a corrected magnetic field by the alternating current.

The AC current may generate a correction magnetic field through the at least one local coil, and may have a period and a size to compensate for the magnetic field distortion generated by respiration in a local region of the subject.

The at least one local coil may be disposed in a local region of the subject.

The control unit may include an estimator estimating a magnetic field distortion to be generated in a subject according to a respiratory state detected by the respiratory measuring unit, and a correction magnetic field that cancels the magnetic field distortion estimated by the estimating unit in the at least one local coil. It may include a power supply for generating an alternating current flowing through the local coil to be generated.

The estimator may obtain a predetermined distortion field estimation curve according to the breathing cycle and the breathing size of the subject.

The power supply unit may generate an AC current having a period equal to a period of the distortion magnetic field estimation curve and having a magnitude corresponding to the magnitude of the distortion magnetic field estimation curve.

The at least one local coil may generate a correction magnetic field that makes the magnetic field in the subject uniform by supplementing the magnetic field distortion shown in the distortion magnetic field estimation curve.

According to the present invention, it is possible to compensate for the magnetic field fluctuations that may occur inside the subject by breathing of the subject, thereby obtaining an MRI device with more accurate measurement results.

Hereinafter, with reference to the accompanying drawings will be described in detail the present invention.

1 is a configuration diagram of an MRI (Magnetic Resonance Image) device according to one embodiment of the present invention.

Referring to FIG. 1, the MRI apparatus 100 according to the present embodiment includes a main magnet 110, a signal collecting unit 120, a respiration measuring unit 130, a control unit 140, and a local coil 150. can do.

The main magnet 110 may generate a main magnetic field. In the present embodiment, the main magnet 110 is composed of a pair of permanent magnets can generate a static magnetic field received by the subject in the imaging space. The main magnet 110 may generate a static magnetic field so that the direction of the main magnetic field is aligned in a direction parallel to the direction of the body axis of the subject. In another embodiment, the main magnet may include a superconducting magnet.

In this embodiment, an RF coil (not shown) is formed in a region where a magnetic field of the main magnet 110 is generated, and the RF coil is an imaging space in which a magnetic field is generated by the main magnet 110 by RF pulses, which are electromagnetic waves. It transmits to a subject inside, and generates a high frequency magnetic field, and it can excite both spins in the imaging area of a subject. The RF coil may then receive an electromagnetic wave generated by both excited in the subject as a magnetic resonance signal.

The signal collector 120 may collect a magnetic resonance signal for a subject under the main magnetic field. In the present embodiment, the signal collector 120 may collect the magnetic resonance signal received by the RF coil. The signal collection unit 120 may include a phase detector for detecting a magnetic resonance signal received by the RF coil, and an A / D converter for converting the magnetic resonance signal, which is an analog signal, into a digital signal. The signal collection unit 120 may be connected to a display device (not shown), and may display a magnetic resonance image signal of a subject collected in the signal collection unit 120 through the display device.

The respiration measurement unit 130 may detect a respiratory state of the subject. The respiration measurement unit 130 may detect the size of the breath and the cycle of respiration caused by the respiratory movement of the subject. The respiration measuring unit 130 may detect the size and the period of the breath of the subject by detecting the displacement of the diaphragm of the subject that changes according to the breathing movement of the subject. As described above, the breathing state of the subject may be indicated by the size and the cycle of the subject's breathing.

The controller 140 may generate an alternating current according to the information on the respiratory state of the subject measured by the respiratory measuring unit 130. The alternating current generated by the controller may have a period and a magnitude to compensate for magnetic field distortion generated by a change in the amount of air in a local region of the subject according to respiration.

In the present embodiment, the control unit 140 may include an estimating unit 141 and a power supply unit 142. The estimator 141 may estimate the magnetic field distortion to be generated in the local region of the subject according to the respiratory state detected by the respiratory measuring unit 130. In the present embodiment, the estimator 141 may obtain a magnetic field distortion estimation curve preset according to the breathing cycle and the size of the subject. That is, since the breathing shape represented by the size and the cycle of the subject's breath can be generally expressed in the form of a sine wave, it occurs in the local region of the subject by the cycle and the size of the breath measured in the breathing measuring unit 130. The magnetic field distortion can be estimated, and the shape of the magnetic field distortion can be expressed as a sinusoidal curve between time and the magnetic field. In order to obtain a magnetic field distortion estimation curve according to the period and size of the breathing, a database of experiments may be included in the estimator 141 in advance. In addition, the estimator 141 may calculate an optimal position of at least one local coil through which an AC current generated by the power supply unit 142 flows using the database.

The power supply unit 142 may generate an alternating current that may compensate for the magnetic field distortion estimated by the estimating unit 141. In order to obtain an accurate medical image of the subject, it is necessary to homogenize the magnetic field in the subject. Since the magnetic field distortion has been generated in the subject by the breathing of the subject as much as the estimated magnetic field distortion, the magnetic field in the subject may be uniformed by canceling the generated magnetic field distortion. In the present embodiment, a correction magnetic field may be generated in the local coil 150 to cancel the magnetic field distortion. The power supply unit 142 may generate an alternating current flowing through the local coil 150. The correction magnetic field generated in the local coil may be proportional to the current flowing in the local coil. Therefore, in the present embodiment, the AC current generated by the power supply unit 142 has a period equal to the period of the sinusoidal magnetic field distortion curve estimated by the estimation unit 141, and the magnitude is the magnetic field distortion estimated by the estimation unit. It can be made into the size corresponding to.

An AC current generated by the controller 140 may flow in the local coil 150. In this embodiment, the local coil 150 may be disposed in the local region of the subject. The position where the local coil is disposed may be calculated using a database stored in the estimator 141. When the AC current flows through the local coil, a magnetic field may be generated in the local coil by the AC current. The strength of the magnetic field generated by the local coil is proportional to the strength of the current flowing through the local coil. In the present embodiment, the alternating current has the same period as the period of the magnetic field distortion curve estimated by the estimating unit, and has a magnitude corresponding to the magnitude of the magnetic field distortion, so that the magnetic field generated by the alternating current is the test object. It may have a size and period that can cancel the magnetic field distortion generated in the local region of. In the present embodiment, only one local coil has been described, but a plurality of the local coils may be formed. The magnetic field distortion may be compensated for by adjusting the length, thickness, and position of each local coil for a plurality of local coils. When a plurality of local coils are used, the positions where the plurality of local coils are arranged may be calculated through the data previously stored in the database and the respiratory measurement unit previously stored in the estimator.

The magnetic field generated by the breathing of the subject is compensated for by the magnetic field generated by the local coil 150, and thus may be referred to as a correction magnetic field. The correction magnetic field generated by the local coil 150 may offset the magnetic field distortion generated by the breathing of the subject to make the magnetic field in the subject uniform.

As described above, in the MRI apparatus according to the present embodiment, a local coil in which an alternating current flows in a local region of a subject is arranged to cancel a magnetic field distortion caused by breathing of the subject to maintain a uniform magnetic field inside the subject. Can be. A correction magnetic field is generated in the local coil by the AC current, and the magnetic field distortion may be compensated by the correction magnetic field. Therefore, the magnetic field distortion generated by the breathing of the subject can be corrected in real time, and MRI examination for a more accurate subject can be performed.

2 is a graph showing a distortion magnetic field curve (a) estimated by the estimation unit of the MRI apparatus according to an embodiment of the present invention and a correction magnetic field curve (b) generated by a local coil.

1 and 2, the estimator 141 in the controller 140 estimates a magnetic field distortion generated by respiration inside the subject by the breathing state of the subject measured by the breath measuring unit 130. Can be. The breathing form of the subject has a certain period and changes in size with time, and can be generally expressed in sine wave form in relation to time and size. Since the magnetic field distortion generated by the breath is mainly affected by the size of the breath, the magnetic field distortion curve (a) estimated by the estimator 141 by the period and size of the breath measured by the breath measuring unit 130 (a). ) Can also be expressed in the form of a sine wave in the relationship between time and magnetic field. This may indicate that the intensity of the magnetic field inside the subject changes according to the subject's breathing with a certain period.

 In order to obtain an accurate image of the subject, it is necessary to homogenize the magnetic field in the subject. In other words, it is necessary to cancel the magnetic field distortion caused by the breathing of the subject.

In the present exemplary embodiment, a correction magnetic field may be generated in the local coil 150 to cancel the magnetic field distortion. The correction magnetic field curve b representing the correction magnetic field may have a size and a period capable of canceling the magnetic field distortion generated in the local region of the subject. That is, the period of the correction magnetic field curve (b) is the same as the period of the magnetic field distortion curve (a), the magnitude thereof may have a size opposite to the magnitude of the distorted magnetic field so as to cancel the magnetic field distortion.

It is intended that the invention not be limited by the foregoing embodiments and the accompanying drawings, but rather by the claims appended hereto. Accordingly, various forms of substitution, modification, and alteration may be made by those skilled in the art without departing from the technical spirit of the present invention described in the claims, which are also within the scope of the present invention. something to do. That is, the shape of the local coil and the position of the local coil may be variously modified.

1 is a configuration diagram of an MRI apparatus according to one embodiment of the present invention.

Fig. 2 is a graph of the corrected magnetic field generated by the distortion magnetic field and the local coil estimated by the estimating unit of the MRI apparatus according to the embodiment of the present invention.

<Code Description of Main Parts of Drawing>

110: main magnet 120: signal collector

130: respiration measurement unit 140: control unit

150: local coil

Claims (7)

A main magnet generating a main magnetic field; A respiration measurement unit for detecting a respiratory state of the subject; A controller for generating an alternating current according to the breathing state of the subject measured in the breathing measuring unit; At least one local coil generating a corrected magnetic field to compensate for magnetic field distortion caused by the breathing state of the subject according to the alternating current; And Including a signal collecting unit for collecting the magnetic resonance signal for the subject in the main magnetic field and the correction magnetic field, to generate a magnetic resonance image signal for the subject, The control unit, An estimator estimating a magnetic field distortion to be generated in the subject according to the respiratory state detected by the respiratory measuring unit; And A power supply unit generating an alternating current flowing through the at least one local coil such that a correction magnetic field canceling the magnetic field distortion estimated by the estimating unit is generated in the at least one local coil MRI apparatus comprising a. The method of claim 1, The alternating current is MRI device, characterized in that to generate a correction magnetic field through the at least one local coil to compensate for the magnetic field distortion caused by respiration in the local region of the subject. The method of claim 2, The at least one local coil, MRI device, characterized in that disposed in the local area of the subject. delete The method of claim 1, The estimating unit, An MRI apparatus characterized by obtaining a predetermined distortion magnetic field estimation curve according to the breathing cycle and the breathing size of the subject. The method of claim 5, The power supply unit, And an alternating current having a period equal to the period of the distortion magnetic field estimation curve and having a magnitude corresponding to the magnitude of the distortion magnetic field estimation curve. The method of claim 6, The at least one local coil, MRI apparatus, characterized in that for generating a correction magnetic field to make the magnetic field in the subject homogenous (Homogeneous) by supplementing the magnetic field distortion shown in the distortion magnetic field estimation curve.

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