KR20210011487A - Control method for bolus tracking CT - Google Patents

Abstract

The present invention relates to a control method of bolus tracking CT, which detects movement of a subject prior to performing a diagnostic scan and drives and controls the CT device to stop the CT scan, thereby preventing the subject from being exposed to unnecessary radiation in advance and preventing the failure of the diagnostic scan to obtain objective and accurate CT images.

Description

Control method for bolus tracking CT

The present invention relates to a control method of a bolus tracking CT, and more particularly, a control method of a bolus tracking CT capable of preventing an error in which a diagnostic scan is automatically performed when the subject's breathing or body displacement in the bolus tracking CT It is about.

In the case of a CT scan in which a contrast agent is injected, scanning when the contrast enhancement of the contrast agent reaches the desired level of enhancement, that is, a threshold, is preferable in terms of enhancing the accuracy of the examination.

In particular, since the duration of the arterial phase after the injection of the contrast agent to the subject was short, about 20 to 50 seconds (depending on the injection amount and the injection speed of the contrast agent), it was difficult to match the timing of the appropriate CT scan. If this is not performed, an accurate CT image cannot be obtained.

To solve this problem, a technique of performing a CT scan when the blood vessel reaches the maximum contrast enhancement by observing the flow of the contrast agent administered to the subject is used. This concept can be expressed as a bolus tracking CT technique. .

Using this, it is possible to determine the delay time that accurately reflects each patient's contrast agent movement time.

The bolus tracking CT technique sets a region of interest (ROI) on the CT image displayed on the CT device as shown in FIG. 2 and repeats the scan at the same time as the contrast agent is injected to update the CT image while monitoring the enhancement of the contrast of the region of interest. This is a commonly used method of CT angiography in which a diagnostic scan is performed when the region of interest reaches a threshold value.

The bolus tracking CT technique is a technique for optimizing the degree of contrast enhancement in real time. By setting an area of interest inside the blood vessel (P), monitoring with contrast agent injection is performed, and a diagnostic scan is automatically performed when the blood vessel reaches the arterial phase. It can be defined as a running system.

That is, in the bolus tracking CT technique, just by marking the region of interest on the blood vessel, the amount of change in the HU of the blood vessel is measured in the CT image that is repeatedly scanned and updated, and the diagnostic scan is automatically performed when the HU of the blood vessel reaches 100. do.

As shown in FIG. 7, when the HU of the blood vessel reaches 100 (40 to 150 depending on the setting) after administration of the contrast agent, it is diagnosed as an arterial phase, and the duration of the arterial phase has a duration of about 20 to 50 seconds. The most accurate blood vessel CT image can be obtained only when a diagnostic scan is performed at this time.

Here, HU (Hounsfield Unit) is a value that relatively shows the degree of attenuation by each part when X-rays penetrate the body, and can be expressed as a relative index value as shown in the table below.

water bone air Abdominal soft tissue lungs 0 1000 -1000 40 to 80 -400 ~ -600

On the other hand, the behavior of the body by breathing causes a potential error in measuring the contrast medium in the abdomen. That is, if the region of interest is displaced by respiration in the process of monitoring contrast enhancement, the reliability of the image of the diagnostic scan may significantly decrease.

3 is a diagram showing that abdominal blood vessels P according to breathing move in an irregular direction, and the breathing movement of the subject acts as a factor that hinders accurate diagnosis in the bolus tracking CT technique and all CT scan techniques.

When the blood vessel (P) did not reach the arterial phase, and the blood vessel (P) and the region of interest were deviated by respiration, the program judged this as contrast enhancement, and a diagnostic scan was performed.

For example, when the subject increases breathing, blood vessels may be separated from the region of interest as well as the vertebrae may move toward the region of interest.

In this state, if the scan is repeatedly updated, the HU of the region of interest reaches the threshold and the contrast is enhanced. At this time, the CT device determines that it is the enhancement in the program and automatically performs the diagnostic scan.

In other words, in the bolus tracking CT technique, even if the subject's breathing or movement occurs, the diagnosis scan is performed automatically without detecting it.Therefore, errors in the test result often occur, resulting in a decrease in the quality of medical care, and accordingly, retesting is required. As a result, patient satisfaction was lowered, and exposure to radiation dose due to re-examination could not be excluded.

In particular, because of the serious side effects that the contrast agent can easily cause vomiting and dizziness, and severely lead to death of the subject, the psychological and physical burden of the patient due to the re-administration of the contrast agent for reexamination has emerged as a major problem.

Republic of Korea Patent Publication 10-2006-0050447

The present invention was created to solve the problems in consideration of the problems of the prior art, and since the CT device is driven and controlled so that the movement of the subject is detected and the CT scan is stopped before performing a diagnostic scan, The purpose of this is to provide a control method of bolus tracking CT that can prevent exposure to and obtain an objective and accurate CT image by preventing failure of diagnostic scans.

The present invention is a means for achieving the above object, (a) a scanning unit scans an arbitrary part of the subject's body to generate image data, and the processing unit of the image processing unit processes this to obtain a horizontal image slice and display it on the display unit. step; (b) In the horizontal image slice shown on the display unit, the main area of interest window and the auxiliary area of interest window are displayed on the part corresponding to the anatomical index, but the main area of interest window is manually displayed by the inspector and the auxiliary area of interest window is the processing unit. Automatically displaying according to the operation of; (c) measuring a Hounsfield Unit (HU) of the main region of interest window and the sub region of interest window while the scanning unit reacquires horizontal plane image slices at a predetermined period; (d) detecting, by a processing unit, a change amount of HU of the auxiliary region of interest window in the process of reacquiring the horizontal plane image slice at a predetermined period; And (e) driving and controlling the CT device based on the amount of change in HU of the auxiliary area of interest window, wherein the auxiliary area of interest window includes at least one of vertebrae, air, organs, and adipose tissue. When the main region of interest window is displayed on the blood vessel, and the amount of change in the secondary region of interest window HU displayed on the vertebrae is not detected in step (d), and only the change amount of the auxiliary region of interest window HU displayed in air is detected. It is characterized in that the processing unit drives and controls the CT device so that the CT scan of the subject is determined as a normal range of motion.

In addition, when the main region of interest window and the auxiliary region of interest window are displayed on the horizontal image slice in step (b), a fixed absolute coordinate value for the horizontal image slice is given, and in step (c), the main region of interest window and auxiliary It is characterized in that the processing unit measures HU based on the fixed absolute coordinate value of the ROI window.

In addition, in step (e), if the amount of change in the HU of the secondary region of interest window is not detected, the processing unit drives and controls the CT device so that the CT scan of the subject is performed when the HU of the main region of interest window becomes 100. .

In addition, in step (c), the reacquisition of the horizontal image slice is started 15 seconds after the administration of the contrast agent, and the reacquisition period of the horizontal image slice has a time range of 2 to 3 seconds.

Further, in step (d), when the amount of change in the secondary region of interest window HU displayed on the vertebrae is detected, the processing unit controls the operation of the CT device so that the CT scan of the subject is stopped by determining that the position of the subject is changed.

In addition, the main region of interest window and the sub region of interest window may have at least one of a rectangular, circular, or closed curve.

In the present invention, since the CT device is driven and controlled so that the movement of the subject is detected before performing the diagnosis scan and the CT scan is stopped, it is possible to prevent the subject from being exposed to unnecessary radiation in advance, and the failure of the diagnosis scan is prevented. It provides the effect of obtaining an objective and accurate CT image by preventing.

1 is a diagram showing a schematic configuration of a bolus tracking CT device.
2 is a diagram showing a slice of an image on a horizontal plane of a subject shown on the display unit.
3 is a diagram illustrating an exemplary displacement of a blood vessel according to a subject's breathing.
4 is a diagram showing the concept of a horizontal plane image slice.
5 is a diagram schematically showing a horizontal plane image slice in which the main region of interest window and the auxiliary region of interest window are displayed.
6 is a diagram illustrating the concept of absolute coordinates assigned to a main region of interest window and a secondary region of interest window within a horizontal plane image slice FOV.
7 is a graph showing the amount of change in HU in blood vessels according to the administration of a contrast agent.
8 is a diagram illustrating a state in which a subject's body is displaced within a horizontal plane image slice FOV.
9 is a diagram showing an example in which a horizontal plane image slice reacquired is updated in an image processing apparatus.
10 is a view showing a control process of the CT device according to the present invention.
FIG. 11A is a view showing a CT image before injection of a contrast agent, and FIG. 11B is a view showing a CT image when a threshold value is reached after injection of a contrast agent.

In order to fully understand the present invention, preferred embodiments of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. This example is provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shape of the element in the drawings may be exaggerated to emphasize a clearer description. It should be noted that in each drawing, the same member may be indicated by the same reference numeral. Detailed descriptions of known functions and configurations that are determined to unnecessarily obscure the subject matter of the present invention will be omitted.

In the present invention,'image slice' and'image' may mean multidimensional data composed of discrete image elements. For example, the horizontal plane image slice HIS may include a medical image or the like scanned by a CT device.

The bolus tracking CT apparatus (hereinafter, referred to as CT apparatus) according to the present invention can provide a relatively accurate cross-sectional image for a subject by obtaining and processing image data several hundred times per second. As an example, the CT apparatus may include a scanning unit 10 and an image processing apparatus 20 as shown in FIG. 1. First, the scan unit 10 may be exemplified as a gantry 11, a table 12, a control unit (not shown), a generator 13, and a detection unit (not shown).

The subject may be positioned on the table 12, may move in a predetermined direction, and movement may be controlled by a controller.

The gantry 11 has a rotatable ring shape based on a rotation axis, and a generator 13 and a detection unit are installed inside the gantry 11 to face each other.

The generation unit 13 and the detection unit may be rotated within the gantry 11, and X-rays generated by the generation unit 13 may be emitted in a predetermined form by a collimator.

The detection unit may face the generation unit 13 to detect the X-ray transmitted through the subject and generate an electric signal corresponding to the detected X-ray intensity.

Data collected from the detection unit may be transmitted to the image processing apparatus 20.

The above-described scanning unit 10 may follow a known one, and a detailed description thereof will be omitted.

The image processing apparatus 20 may reconstruct a cross-sectional image with data received from the scan unit 10. Such a cross-sectional image may be a 2D or 3D image.

The image processing apparatus 20 may include, for example, a processing unit (not shown) and a display unit 21, for example, in the form of a general-purpose computer, a tablet PC, a smartphone, a medical terminal, a medical image information system, etc. Can be implemented.

Here, the display unit 21 may show a horizontal image slice (HIS) or receive an external input for a tomography condition or an image processing condition. The display unit 21 may be formed of a touch pad or may include an additional input device such as a keyboard, a mouse, a joystick, or the like.

The processing unit may generate horizontal image slice (HIS) data to be displayed on the display unit 21 from the image data.

The processing unit generates a screen view for displaying a horizontal image slice (HIS) and outputs it to the display unit 21, and the display unit 21 inputs the main region of interest window (W1) and the auxiliary region of interest window (W2) on the image slice. I can receive it.

The disclosed image processing apparatus 20 may be implemented as a S/W program including instructions stored in a computer-readable storage media.

In addition, the disclosed image processing apparatus 20 or a control method may be included in a computer program product and provided. Computer program products can be traded between sellers and buyers as commodities.

The computer program product may include a S/W program and a computer-readable storage medium storing the S/W program. For example, the computer program product may include a product (eg, a downloadable app) in the form of a S/W program that is electronically distributed through a manufacturer of a CT system or an electronic market.

The described scanning unit 10 and the image processing apparatus 20 are means for explaining the control method according to the present invention, and their embodiments are not limited and may be variously modified as necessary, and components according to the Since it may further include, a detailed description will be omitted below.

The control method of the CT apparatus according to the present invention for CT scan of the subject can be performed by the above-described CT apparatus, and the scanning unit 10 obtains a horizontal image slice (HIS) for an arbitrary part of the subject's body. (S10), displaying the main region of interest window (W1) and the auxiliary region of interest window (W2) on a portion corresponding to an anatomical index in the horizontal image slice (HIS) (S20), and the scanning unit 10 is constant Measuring the HU (Hounsfield Unit) of the main region of interest window (W1) and the secondary region of interest window (W2) while reacquiring the horizontal plane image slice (HIS) at intervals (S30), and re-reading the horizontal plane image slice (HIS) at regular intervals. In the process of obtaining, the processing unit detects a change amount of HU of the auxiliary region of interest window W2 (S40), and the processing unit drives and controls the CT device based on the change amount of HU of the auxiliary region of interest window W2 (S60). ,S70) may be defined as including.

When the CT scan of the subject starts, first, in step (S10), image data is generated by scanning the subject's body located on the table 12, and processed as a horizontal image slice (HIS) as shown in FIG. 5 to display the display unit 21 ).

The horizontal image slice HIS may be shown on the display unit 21 in a screen view format, and an examiner can visually check the anatomical index obtained from the horizontal image slice HIS. The anatomical index may include vertebrae (B), blood vessels (P), various organs, fat, skin tissue, air (A), and the like.

In the step (S20), the main region of interest window W1 and the auxiliary region of interest window W2 are input to the display unit 21, and the inspector manipulates a mouse to slice the horizontal image shown on the display unit 21. It can be displayed by directing it to (HIS) or automatically displayed on arbitrary coordinates. At this time, the main region of interest window W1 is preferably displayed on blood vessels P such as the aorta, pulmonary artery, and carotid artery shown in the horizontal image slice HIS, and the auxiliary region of interest window W2 is the vertebrae B ), air (A), it is preferable to be displayed in at least one of the organs or adipose tissue.

The main region of interest window (W1) and the secondary region of interest window (W2) are defined as different regions arranged on the horizontal image slice (HIS), and the positions of the plurality of windows can be determined independently of each other and displayed so that they do not overlap each other. It is desirable to be.

The area shape of the main area of interest window W1 and the sub area of interest window W2 may have a shape such as, for example, a rectangle, a circle, an area defined by a closed curve, and preferably, the main area of interest window W1 ) And the FOV of the auxiliary area of interest window W2 are made of a square with a side length of 1 cm.

It is preferable that the main region of interest window W1 is directly displayed manually under the judgment of the examiner, and the auxiliary region of interest window W2 is preferably automatically displayed according to an operation of the processing unit.

In order to automatically display the auxiliary region of interest window W2, the processing unit may calculate HU of an anatomical index from a horizontal image slice HIS.

That is, the processing unit calculates HU from the horizontal image slice HIS obtained in step (S10), and automatically displays the auxiliary region of interest window W2 based on this. In this case, it is preferable that the display of the auxiliary region of interest window W2 is automatically set at the maximum and minimum points of the HU within the horizontal image slice HIS. For example, as shown in FIG. 5, when two auxiliary region of interest windows W2 are displayed, the processing unit is the absolute coordinate value of the air (A) part where HU is the minimum point and the vertebrae (B) part where HU is the maximum point. By calculating, two sub-regional windows W2 can be automatically placed at this coordinate value. In addition, it is preferable that the main area of interest window W1 is displayed on the blood vessel P in which the contrast enhancement is performed after the administration of the contrast agent. On the other hand, in the horizontal image slice (HIS) obtained in step (S10), the HU of the blood vessel (P) may be roughly similar to that of the water. When a contrast agent is administered into the body for angiography, the HU of the blood vessel (P) is within a certain range. Will increase to.

7 is a graph showing the amount of change in HU in blood vessels according to the administration of the contrast agent, and it can be seen that HU increases as time passes after administration of the contrast agent, and shows the highest HU between 20 and 50 seconds.

This is the time when the maximum contrast enhancement of the contrast medium is exerted, and it is most desirable to perform a diagnostic scan at this time in that accurate diagnosis results can be obtained.

If a diagnostic scan is performed before this period or after this period, an objective CT image of blood vessels cannot be obtained.

More specifically, when the main region of interest window (W1) and the secondary region of interest window (W2) are displayed on the horizontal image slice (HIS), a fixed absolute coordinate value for the field of view (FOV) of the horizontal image slice (HIS) is given. It becomes (S25). In step (S30), the processor measures HU based on the fixed absolute coordinate values of the main region of interest window W1 and the sub region of interest window W2.

This is to detect a change in the position of the subject's body located on the table 12, and will be described in more detail in a step to be described later.

In step (S30), as shown in FIG. 9, the horizontal plane image slice (HIS) is re-acquired at regular intervals, and the main region of interest window W1 and the auxiliary region of interest window W2 in the re-acquired horizontal image slice HIS are HU is measured together.

At this time, the reacquisition of the horizontal image slice (HIS) is started 15 seconds after the administration of the contrast agent, and the reacquisition period of the horizontal image slice (HIS) preferably has a time range of 2 to 3 seconds.

In step (S40), the HU of the secondary region of interest window (W2) measured in step (S30) is detected.If there is no body displacement of the subject during the re-acquisition process of the horizontal image slice (HIS), it is fixed by the fixed absolute coordinate value. There is no change in HU of the secondary region of interest window W2. However, when the position of the subject's body changes due to breathing, etc., as shown in FIG. 8, the subject's body moves relative to the FOV of the horizontal image slice (HIS), and a fixed absolute coordinate value, such as (x ₁ ,y ₁ ,z The secondary region of interest window (W2) HU fixed to the coordinate value of) is changed.

In step (S20), when the auxiliary region of interest window W2 is displayed on the vertebrae B, the auxiliary region of interest window W2 and HU is measured as 1000. Subsequently, when the subject's body moves when reacquiring the horizontal image slice (HIS) at a certain period in step (S30), the subject's vertebrae (B) deviates from the auxiliary area of interest window (W2), and the auxiliary area of interest window (W2). ) Of the HU is changed, and in this case, the HU change amount of the auxiliary region of interest window W2 is detected in step (S40).

In step (S15) after step (S40), it is determined whether the amount of change in the sub-regional window (W2) HU of the reacquired horizontal plane image slices (HIS) is detected.

On the other hand, in the case of breathing in the normal range, the behavior of the vertebrae (B) rarely occurs, but in the case of breathing large enough to twist the body, the behavior of the vertebrae (B) occurs in general.

Therefore, it is important whether the amount of change in the HU of the auxiliary region of interest window W2 displayed on the vertebrae B is detected among the air (A) and the vertebrae (B).

If the amount of change in the auxiliary area of interest window (W2) HU indicated on the vertebrae (B) is not detected, and only the change amount of the auxiliary area of interest window (W2) HU indicated in the air (A) is detected, it is determined as the range of normal motion. Thus, when the HU of the main region of interest window W1 becomes 100, the processing unit may control the driving of the CT device (S70) so that the CT scan of the subject is performed. Here, the HU in the main region of interest window W1 shows an increasing trend as shown in FIG. 7 according to the administration of the contrast agent.

On the other hand, when the amount of change in the HU of the secondary region of interest window W2 displayed on the vertebrae B is detected, it may be determined as a change in the subject's position due to respiration or movement.

Accordingly, in the step (S40), when the amount of change in the HU of the secondary region of interest window W2 displayed on the vertebrae B is measured, it is determined that the change in the position of the subject is determined and the CT scan of the subject is stopped. Drive control is performed (S60).

The meaning that the HU of the secondary region of interest window W2 indicated on the vertebrae (B) has changed means that the subject's body was displaced from the FOV of the gantry 11 due to the subject's breathing or movement. When a diagnostic scan is performed, a CT image for accurate diagnosis cannot be obtained.

In summary, if only the amount of change in the secondary region of interest window (W2) HU indicated in the air (A) is detected in step (S40), it is desirable to determine that it is a normal range of motion and continue the CT scan. If the HU of the auxiliary area of interest (W2) or the HU of the auxiliary area of interest (W2) indicated on the vertebrae (B) and the auxiliary area of interest window (W2) indicated on the air (A) occur at the same time, it is a change in the subject's position. The processing unit drives and controls the CT device so that it is determined and the CT scan of the subject is stopped.

If a diagnostic scan is performed while the subject's body is displaced, the exposure dose increases because re-images are required.

In the present invention, since the CT apparatus is driven and controlled so that the motion of the subject is detected before the diagnosis scan is performed and the CT scan is stopped, it is possible to prevent the subject from being exposed to unnecessary radiation.

On the other hand, if the amount of change in HU of the secondary region of interest window W2 is not detected in step (S40), the processing unit controls the operation of the CT device so that the CT scan of the subject is performed when the HU of the main region of interest window W1 becomes 100. It is preferable to do (S70).

Since the meaning that the amount of change in HU in the secondary area of interest window (W2) was not detected means that the subject's body displacement did not occur, the HU of the main area of interest window (W1) became 100, so that the blood vessels were able to increase the maximum contrast. When it is reached, a diagnostic scan is made to obtain an objective and accurate CT image.

The embodiments of the present invention described above are merely exemplary, and those of ordinary skill in the art to which the present invention pertains will appreciate that various modifications and other equivalent embodiments are possible. Therefore, it will be appreciated that the present invention is not limited to the form mentioned in the detailed description above. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims. In addition, the present invention is to be understood as including the spirit of the present invention as defined by the appended claims and all modifications, equivalents and substitutes within the scope thereof.

10: scan unit 20: image processing unit
W1: Main area of interest window W2: Secondary area of interest window

Claims (6)

(a) the scanning unit scans an arbitrary part of the subject's body to generate image data, and the processing unit of the image processing apparatus processes this to obtain a horizontal image slice and display it on the display unit;
(b) In the horizontal image slice shown on the display unit, the main area of interest window and the auxiliary area of interest window are displayed on the part corresponding to the anatomical index, but the main area of interest window is manually displayed by the inspector and the auxiliary area of interest window is the processing unit. Automatically displaying according to the operation of;
(c) measuring a Hounsfield Unit (HU) of the main region of interest window and the auxiliary region of interest window while the scanning unit reacquires horizontal plane image slices at a predetermined period;
(d) detecting, by a processing unit, a change in HU of the auxiliary region of interest window in the process of reacquiring the horizontal plane image slice at a predetermined period; And
(e) controlling, by the processing unit, driving and controlling the CT device based on the change amount of the HU of the auxiliary region of interest window,
The secondary region of interest window is displayed on at least one of vertebrae, air, organs, and adipose tissue, and the main region of interest window is displayed on blood vessels,
In step (d), if the amount of change in the secondary region of interest window HU displayed on the vertebrae is not detected, and only the amount of change in the secondary region of interest window HU displayed in the air is detected, it is determined as a normal range of motion so that the subject's CT scan is performed. A control method of a bolus tracking CT, characterized in that the processing unit drives and controls the CT device. The method according to claim 1,
In step (b), when the main region of interest window and the auxiliary region of interest window are displayed on the horizontal image slice, a fixed absolute coordinate value for the horizontal image slice is given,
In step (c), the processing unit measures HU based on the fixed absolute coordinate values of the main region of interest window and the secondary region of interest window. The method according to claim 1,
A bolus, characterized in that the processing unit drives and controls the CT device so that the CT scan of the subject is performed when the HU of the main region of interest window becomes 100 if the amount of change in the HU of the secondary region of interest window is not detected in step (e). Control method of tracking CT. The method according to claim 1,
In step (c), the re-acquisition of the horizontal plane image slice starts 15 seconds after the administration of the contrast agent by the subject, and the re-acquisition period of the horizontal plane image slice has a time range of 2 to 3 seconds. . The method according to claim 1,
In step (d), when the amount of change in the secondary region of interest window HU displayed on the vertebrae is detected, the processing unit drives and controls the CT device so that the CT scan of the subject is stopped by determining that the position of the subject is changed. CT control method. The method according to claim 1,
The control method of a bolus tracking CT, wherein the main region of interest window and the auxiliary region of interest window have at least one of a rectangular, circular, or closed curve.

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