KR20180138452A - Method of aquisiting for cardiac image and apparatus thereof - Google Patents

Abstract

The present invention relates to a method for acquiring a heart image, which comprises: a step (a-1) of outputting a first frequency by synchronizing at a start point at which a patient subject to heart image acquisition stops breathing for several seconds; a step (a-2) of acquiring a heart image with a low frequency component of the patient subject to heart image acquisition as first image information by synchronizing at an output point of the first frequency outputted in step (a-1); a step (b-1) of outputting a second frequency by synchronizing at a point at which the patient subject to heart image acquisition starts free breathing; a step (b-2) of acquiring a heart image with a high frequency component of the patient subject to heart image acquisition as second image information by synchronizing at an output point of the second frequency outputted in step (b-1); and a step (c) of collecting the first image information acquired in step (a-2) and the second image information acquired in step (b-2). Therefore, the method for acquiring a heart image can acquire an accurate heart image even though a patient subject to heart image acquisition does not stop breathing for a long time.

Description

[0001] METHOD OF AQUISITING FOR CARDIAC IMAGE AND APPARATUS THEREOF [0002]

More particularly, the present invention relates to a technique for acquiring a high-quality heart image in a magnetic resonance imaging apparatus, even if the time required for acquiring an image in a state in which the patient is in a breathing state for acquiring a heart image is shortened .

BACKGROUND ART [0002] As a conventional method for acquiring a heart image by magnetic resonance imaging (MRI), an ECG (electrocardiography) device is used to check cardiac motion of a patient to be subjected to cardiac imaging, And acquires the heart image in one state.

The conventional method for acquiring a cardiac image of a patient has the inconvenience that the patient who receives the cardiac image should continuously take a breath to obtain the cardiac image, and this is difficult to obtain the cardiac image because the patient is difficult to perform.

In order to improve this, a self gating technique for estimating the heart condition based on a video signal has been proposed. However, since it acquires an image in a free breath state, the data acquisition time is long .

Korean Patent Laid-Open Publication No. 10-2014-0043655 (Image Enhancement Method and Apparatus of Magnetic Resonance Imaging Method Using Motion Error Data)

Disclosure of Invention Technical Problem [8] The present invention provides a magnetic resonance imaging apparatus and method for acquiring a heart image.

(A-1) outputting a first frequency in synchronization with a start point of time when a cardiac image acquisition object stops breathing for a few seconds; (a-2) acquiring, as first image information, a heart image of a low-frequency component for the cardiac image acquiring object in synchronization with an output timing of the first frequency outputted in the step (a-1); (b-1) outputting a second frequency by synchronizing with a time point at which the cardiac image acquisition object starts free breathing; (b-2) acquiring, as second image information, a heart image of a high-frequency component for the cardiac image acquiring object in synchronization with an output timing of the second frequency outputted in the step (b-2); And (c) collecting the first image information acquired in the step (a-2) and the second image information acquired in the step (b-2) Obtain heart images.

The step (a-2) is performed to preferentially scan a center portion of a low-frequency component heart image with respect to the cardiac image acquiring object.

In a preferred example, a step of outputting a first image information output signal from the acquired first image information according to the synchronization signal (a-3) between the step (a-2) and the step (b- ; ≪ / RTI >

The first frequency outputted in the step (a-1) is a low frequency in a frequency range corresponding to 30% or less of the frequency of the image information signal acquired by the MRI apparatus.

The step (b-2) is performed to preferentially scan a center part of a heart image of a high-frequency component with respect to the cardiac image acquiring object.

Outputting a second image information output signal from the acquired second image information according to (b-3) a blood flow synchronization signal between the step (b-2) and the step (c) .

The second frequency outputted in the step (b-1) is a high frequency in a frequency range exceeding 30% of the frequency of the image information signal acquired by the MRI apparatus.

A heart image acquiring apparatus according to an embodiment of the present invention includes a first image acquiring unit that acquires a low-frequency component heart image as a first image information, and a heart image of a high- An image acquiring unit including a second image acquiring unit acquiring the first image information as second image information; And an image information collecting unit for receiving the first image information and the second image information from the image acquiring unit and collecting the first image information and the second image information from the image information obtained by the magnetic resonance imaging apparatus, Information is acquired.

Wherein the first image acquiring unit comprises: a first frequency generator for generating and outputting a first frequency, which is a low frequency for acquiring a cardiac image of the low frequency component, in synchronization with a breathing stop start point of the cardiac image acquiring object; A first image information selection unit for preferentially obtaining an intermediate portion of the image information acquired by the first frequency generation unit and selecting the first image information as the first image information; And a first image information generator for outputting the selected first image information as a first image information output signal according to a synchronization signal.

Wherein the second image acquiring unit includes: a second frequency generator for generating and outputting a second frequency that is a low frequency for acquiring a heart image of the high frequency component in synchronization with the free breathing start time of the cardiac image acquiring object; A second image information selection unit for preferentially acquiring an intermediate portion of the image information acquired by the second frequency generation unit and selecting the intermediate image as second image information; And a second image information generator for outputting the selected second image information as a second image information output signal according to a blood flow synchronization signal.

According to this aspect, by applying the cardiac image acquisition method according to an embodiment of the present invention, it is possible to obtain an accurate cardiac image even if the patient to be acquainted with the cardiac image does not stop breathing for a long time.

1 is a block diagram showing a schematic structure of a cardiac image acquiring apparatus according to an embodiment of the present invention.
2 is a block diagram illustrating a structure of a first image acquiring unit of a cardiac image acquiring apparatus according to an embodiment of the present invention.
3 is a block diagram illustrating a structure of a second image acquiring unit of a cardiac image acquiring apparatus according to an embodiment of the present invention.
4 is a diagram illustrating a signal acquisition sequence of a cardiac imaging apparatus according to an embodiment of the present invention.
5 is a flowchart illustrating a cardiac image acquisition method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Hereinafter, a method and apparatus for acquiring cardiac images according to an embodiment of the present invention will be described with reference to the accompanying drawings. First, a cardiac image acquiring apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3. FIG.

FIG. 1 is a block diagram illustrating a schematic structure of a cardiac image acquiring apparatus 100 according to an embodiment of the present invention. FIG. 2 is a block diagram illustrating a structure of a first image acquiring unit of a cardiac image acquiring apparatus according to an embodiment of the present invention. FIG. 3 is a block diagram illustrating a structure of a second image acquiring unit of a cardiac image acquiring apparatus according to an embodiment of the present invention. FIG. 4 is a block diagram of a heart image acquiring apparatus according to an embodiment of the present invention. Signal acquisition sequence.

In the present embodiment, the cardiac image acquisition apparatus 100 includes an image acquisition unit 110 including a first image acquisition unit 111 and a second image acquisition unit 112 that acquire images using a magnetic resonance imaging apparatus, And an image information collecting unit 120 connected to the image acquiring unit 110 and collecting the image acquired by the image acquiring unit 110 as image information.

The image acquiring unit 110 acquires images by changing settings of the image acquiring period and the image acquiring time of the first image acquiring unit 111 and the second image acquiring unit 112 according to a control signal received from the outside And transmits the acquired images to the image information collecting unit 120, respectively.

The first image obtaining unit 110 includes a first frequency generating unit 1111, a first image information selecting unit 1112, a phase synchronizing unit 1113, and a first image information generating unit 1114, Related image information from the imaging device.

The first frequency generator 1111 generates and outputs a first frequency, and generates a first frequency according to a control signal applied from the outside. In one example, the first frequency generation unit 1111 outputs the first frequency in synchronization with the moment when the patient of the cardiac image acquisition object stops breathing.

At this time, the first frequency generator 1111 outputs the first frequency in synchronization with the signal inputted at the moment when the subject of cardiac image acquisition stops breathing.

In one example, in order to acquire a heart image at the moment when the patient is stopped breathing, in order to acquire the heart image, the administrator performing the cardiac image acquisition verbally transmits the patient to the cardiac image acquiring patient to stop breathing temporarily, It is possible to pre-record and output the audio signal.

The first frequency generator 1111 outputs a low frequency in a frequency range corresponding to 30% or less of the frequency of the image information signal acquired by the MRI apparatus as a first frequency.

The first image information selection unit 1112 acquires the first image information. The first image information selection unit 1112 synchronizes with the output of the first frequency by the first frequency generation unit 1111, Information as first video information.

At this time, the image information obtained by the MRI apparatus is image information obtained by the image acquisition frequency ( ₂ ), and the image acquisition frequency is the frequency of the entire image range.

At this time, the respiratory state and cardiac state acquisition frequency (? ₁ ) are the frequencies outputted to obtain the respiratory state and the cardiac state, and are the frequencies of the DC signal range.

The first image information selection unit 1112 selects the image information part obtained from the MRI apparatus while the respiration of the cardiac image acquisition subject stops for 3 to 5 seconds and divides the image information part into the cardiac signal phase intervals, And acquires the image from the low-frequency signals at both ends of the divided section, following the image obtained first.

Since the first image information selecting unit 1112 selects the image information portion obtained from the MRI apparatus in the above order, the patient who has acquired the heart image stops breathing for a short period of time, The user first selects the valid image information by scanning.

This is because the patient who has acquired the cardiac image stops breathing for 15 to 20 seconds and sequentially acquires image information by sequentially scanning the cardiac phase of the image information acquired by the magnetic resonance imaging apparatus for the relevant time, It is possible to shorten the time required to acquire clear image information from a conventional method of sequentially scanning from a low frequency signal.

At this time, the first image information selecting unit 1112 selects the first image information from the image information acquired by the MRI apparatus through the slice selection method.

The first image information selection unit 1112 selects a slice selection signal SS for selecting an object plane to be acquired when the first image information selection unit 1112 acquires first image information of a low frequency component using a slice selection method, Synchronously with the output of the first frequency.

The phase synchronization unit 1113 generates a signal for synchronizing a position on the K-space (k-space) to acquire image information. The first image information selection unit 1112 selects a position It outputs the synchronization signal (PE) for phase selection.

The first image information generating unit 1114 outputs the first image information which is the image selected by the first image information selecting unit 1112. The first image information generating unit 1114 generates the first image information according to the slice selection signal SS and the synchronization signal PE, Output information.

At this time, as the phase synchronization unit 1113 outputs the uplink synchronization signal and the downlink synchronization signal as different types of synchronization signals PE, the first image information generation unit 1114 generates the synchronization signals PE The first image information generation start time and the first image information generation end time are synchronized with each other to output a first image information output signal RO.

In this embodiment, the second image obtaining unit 112 includes a second frequency generating unit 1121, a second image information selecting unit 1122, and a second image information generating unit 1123, And acquires a video signal.

The second frequency generation unit 1121 generates and outputs a second frequency, and generates a second frequency according to a control signal applied from the outside. In one example, the second frequency generation 1121 may output 30% of the frequency of the image information signal acquired by the magnetic resonance imaging apparatus, And outputs the high frequency of the exceeding frequency range as the second frequency.

As the second frequency generator 1121 outputs the second frequency, the second image information selector 1122 extracts some image information from the image information of the high-frequency component acquired by the MRI apparatus through the intercept selection method 2 Select it as image information.

In obtaining the second image information of the high frequency component using the second image information selection unit 1122, the second image information selection unit 1122 selects the intercept selection signal SS for selecting the object face And outputs the second frequency in synchronization with the output timing.

The second image information selection unit 1122 outputs a blood flow synchronization signal (VENC) after the intercept selection signal SS to synchronize the second image information with the blood flow velocity of the heart.

The second image information generating unit 1123 outputs the second image information which is the image selected by the second image information selecting unit 1122. The second image information generating unit 1123 generates the second image information by using the intercept selection signal SS and the blood flow synchronization signal VENC, Information generation start time is synchronized to output the second image information output signal RO.

The first image acquiring unit 111 and the second image acquiring unit 112 acquire the first image information and the second image information, respectively. The image information collecting unit 120 acquires the first image information and the second image information, And the second image information from the second image acquiring unit 112, respectively, and merges the reconstructed image information.

In one example, the image information collecting unit 120 may combine the first image information and the second image information using a parallel image technique.

According to the structure described with reference to FIGS. 1 to 4, the cardiac image acquiring apparatus 100 according to the present embodiment is capable of acquiring a vivid It is possible to obtain cardiac image information.

5 is a flowchart illustrating a cardiac image acquisition method according to an embodiment of the present invention.

In this embodiment, the cardiac image acquisition method includes a step of outputting a first frequency (S100) during a respiration stop period, a step S200 of acquiring first image information from image information of a low frequency component, A step S400 of outputting a video information output signal S300, a step S400 of outputting a second frequency during a free breathing period, a step S500 of acquiring second image information from the image information of a high frequency component, And outputting a second image information output signal in step S600.

The cardiac image acquiring method is a method of acquiring a heart image of a patient to be acquired by using a magnetic resonance imaging apparatus. The cardiac image acquiring apparatus 100 controls a signal output from a magnetic resonance imaging apparatus to acquire a heart image And a heart image is generated by using the acquired signal.

First, in step S100 of outputting the first frequency during the respiratory stop period, in order to acquire the low frequency component of the heart image of the patient to be acquired from the heart image during the stop of breathing for several seconds, Output. In this step S100, the first frequency is synchronously outputted at the moment when the subject to be cardiac image acquisition stops breathing.

As the step S100 is performed, the MRI apparatus acquires image information in synchronization with the output of the first frequency.

In the next step S200, the image information of the low frequency component is acquired from the image information using the segment selection method, and the first image information is obtained by scanning the middle part of the obtained low frequency component image information.

In acquiring the first image information in step S200, the center part of the low-frequency image information is preferentially scanned so that the time required for acquiring the first image information can be efficiently shortened compared with the conventional acquisition of image information have.

Next, the first image information output signal is outputted from the first image information obtained in the above step S200 according to the uplink synchronization signal and the downlink synchronization signal (S300). The first image information output signal outputted in this step S300 is a low frequency component signal synchronized with the breathing point.

As a next step, a step S400 of outputting a second frequency for acquiring a high frequency component of a heart image during a free breathing period is performed. In this step (S400), the second frequency is output in order to acquire the high-frequency component of the heart image of the subject of cardiac image acquisition while the patient undergoing cardiac image acquisition performs free breathing.

As the step S400 is performed, the MRI apparatus acquires the image information in synchronization with the output of the second frequency. In the next step S500, the MRI apparatus acquires the high frequency component Acquires image information, and acquires second image information by scanning the middle part of the image information of the obtained high-frequency component.

In acquiring the second image information in step S500, the center part of the high-frequency image information is preferentially scanned so that the time required for acquiring the second image information can be effectively shortened as compared with the conventional acquisition of image information have.

Next, according to the blood flow synchronization signal, the second image information output signal is outputted from the second image information obtained in the above step S500 (S600). The second image information output signal outputted in this step S600 is a high frequency component signal which is cardiac data.

According to the embodiment of the cardiac image acquiring method described with reference to FIG. 5, a heart image of a patient for acquiring a cardiac image can be obtained as a clear image without stopping breathing for a long time.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

100: cardiac image acquisition device 110:
111: first image obtaining unit 112: second image obtaining unit
120:

Claims (10)

(a-1) outputting a first frequency synchronized with a starting point of time at which the cardiac image acquisition object stops breathing for several seconds;
(a-2) acquiring, as first image information, a heart image of a low-frequency component for the cardiac image acquiring object in synchronization with an output timing of the first frequency outputted in the step (a-1);
(b-1) outputting a second frequency by synchronizing with a time point at which the cardiac image acquisition object starts free breathing;
(b-2) acquiring, as second image information, a heart image of a high-frequency component for the cardiac image acquiring object in synchronization with an output timing of the second frequency outputted in the step (b-2); And,
(c) collecting the first image information acquired in the step (a-2) and the second image information acquired in the step (b-2) And acquiring a cardiac image. The method according to claim 1,
Wherein the step (a-2) is performed to preferentially scan a center part of a low-frequency component heart image with respect to the cardiac image acquiring object. The method according to claim 1,
Between the step (a-2) and the step (b-1)
(a-3) outputting a first image information output signal from the acquired first image information according to a synchronization signal. The method according to claim 1,
Wherein the first frequency outputted in the step (a-1) is a low frequency in a frequency range corresponding to 30% or less of the frequency of the image information signal acquired by the MRI apparatus. The method according to claim 1,
Wherein the step (b-2) is performed to preferentially scan the center part of the heart image of the high-frequency component to the cardiac image acquiring object. The method according to claim 1,
Between the step (b-2) and the step (c)
(b-3) outputting a second image information output signal from the acquired second image information according to a blood flow synchronization signal. The method according to claim 1,
Wherein the second frequency outputted in the step (b-1) is a high frequency in a frequency range exceeding 30% of the frequency of the image information signal acquired by the MRI apparatus. A first image acquiring unit for acquiring a heart image of a low frequency component of a heart image acquiring object as first image information and a second image acquiring unit acquiring a heart image of a high frequency component of the heart image acquiring object as second image information An image obtaining unit; And,
And an image information collecting unit for receiving the first image information and the second image information from the image acquiring unit and collecting the heart image information from the image information obtained by capturing the heart image acquiring object in the magnetic resonance imaging apparatus, And acquiring the heart image. 9. The method of claim 8,
The first image acquiring unit acquires,
A first frequency generator for generating and outputting a first frequency which is a low frequency for acquiring a cardiac image of the low frequency component in synchronization with a respiration stop start point of the cardiac image acquisition object;
A first image information selection unit for preferentially obtaining an intermediate portion of the image information acquired by the first frequency generation unit and selecting the first image information as the first image information; And
And a first image information generator for outputting the selected first image information as a first image information output signal according to a synchronization signal. 9. The method of claim 8,
Wherein the second image acquiring unit comprises:
A second frequency generator for generating and outputting a second frequency, which is a low frequency for acquiring the heart image of the high frequency component, in synchronization with the free breathing start time of the cardiac image acquisition object;
A second image information selection unit for preferentially acquiring an intermediate portion of the image information acquired by the second frequency generation unit and selecting the intermediate image as second image information; And
And a second image information generator for outputting the selected second image information as a second image information output signal according to a blood flow synchronization signal.

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