KR101303700B1 - A thyroid uptake measurement apparatus with collimator for identifying radiation distribution - Google Patents

Abstract

The present invention relates to a thyroid uptake test apparatus equipped with a collimator for thyroid radiation dose distribution confirmation, in the present invention, in the device for testing the intake rate of the radioisotope ingested in the thyroid gland by detecting the radiation dose, A collimator having a pair of slits formed at an angle of 90 ° to each other is disposed on a shield plate made of a radiation shield on a front surface where radiation is incident, and the collimator is tilted 45 ° with a direction in which the pair of slits are formed. X-axis and Y-axis profile information of the radiation dose emitted from the thyroid gland by measuring the radiation dose detected through the pair of slits by driving one axis at a true angle to distribute the radioisotope ingested in the thyroid gland. Thyroid radiation dose to accurately know the amount of radiation, dose and thyroid gland Four provides a thyroid uptake test the collimator is provided with the device for confirmation.

Description

Thyroid uptake measurement apparatus with collimator for identifying radiation distribution

The present invention relates to a thyroid uptake test apparatus equipped with a collimator for thyroid radiation dose distribution confirmation, and more particularly, in the device for testing the intake rate of the radioactive isotope ingested in the thyroid by detecting the radiation dose, the thyroid uptake test A collimator having a pair of slits formed at an angle of 90 ° to each other is disposed on a shield plate made of a radiation shield on a front surface where radiation is incident on the device, and the collimator is 45 ° in a direction in which the pair of slits are formed. X-axis and Y-axis profile information of the radiation dose emitted from the thyroid gland is obtained by measuring the radiation dose detected through the pair of slits by driving one axis at an inclined angle, thereby obtaining the radioisotope ingested in the thyroid gland. Thyroid radiation to accurately determine the distribution, dose and size of the thyroid gland The thyroid gland is provided for the distribution of confirmed collimator uptake relates to the testing device.

The thyroid uptake test device is a device used to diagnose and treat thyroid disease.The thyroid gland has an abnormality and treatment status by identifying the degree of adsorption / ingestion of radioactive isotopes to the thyroid through oral administration or intravenous injection. It is used to figure out.

At this time, a representative example of radioisotopes introduced into the human body may include radioactive iodine, and some of the radioactive iodine injected into the human body is absorbed by the thyroid gland (30-50%), and the rest of the radioactive iodine is discharged into the body as it is.

The thyroid uptake test apparatus is a device for grasping the intake rate of radioisotopes introduced into the human body and absorbed by the thyroid gland, and is generally composed of a scintillator, a photomultiplier tube, and a signal processor.

Looking at the basic operation principle of the thyroid uptake test device, when radiation is emitted from the radioisotope adsorbed on the thyroid gland and enters the test device, the visible light reacts with the scintillator provided in the test device, and the visible light is generated by the photomultiplier tube. After passing through and converted into an electrical signal, the signal is processed through a quantitative analysis of the incident radiation.

However, the conventional thyroid uptake test apparatus as described above may be usefully applied to measure the total intake of radioisotopes introduced into the human body and absorbed / ingested into the thyroid gland, but ingested radioisotopes may be applied to any part of the thyroid gland. There is a problem that it is not possible to determine whether or not the amount is absorbed, and in particular, it is very important to accurately confirm the distribution of the isotope of such isotope in order to accurately grasp the treatment status of the thyroid gland.

As a result, it is difficult to accurately determine the distribution of isotopes ingested by the thyroid gland in the conventional thyroid intake test apparatus, and for this purpose, even if the thyroid intake tester is provided with a separate aimer, In order to confirm, a separate collimator and its driving system are required for two directions, the X-axis direction and the Y-axis direction. There is a problem that the cost for the operation and operation will inevitably increase.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems in the prior art. That is, an object of the present invention is a device for checking the intake rate of the radioisotope ingested in the thyroid gland through the detection of the radiation dose, 90 degrees to each other on a shielding plate made of a radiation shield on the front surface of the radiation incident to the thyroid intake rate tester The collimator is provided with a pair of slits formed at an angle of and the collimator is detected by passing through the pair of slits by uniaxially driving the collimator at an angle of 45 ° to the direction in which the pair of slits are formed. By measuring the radiation dose X- and Y-axis profile information of the radiation dose emitted from the thyroid gland, to provide a thyroid uptake test device that can accurately determine the distribution and exposure of the radioisotope ingested in the thyroid gland.

According to an aspect of the present invention, there is provided a thyroid uptake test apparatus for inspecting an intake rate of radioactive isotopes ingested in the thyroid gland by detecting radiation doses, the scintillator reacting with incident radiation to generate flashes; A photomultiplier tube connected to a rear end of the scintillator and converting the scintillation generated by the scintillator into an electrical signal; A signal processor which processes an electrical signal input from the photomultiplier tube; A radiation shield provided in a form surrounding the scintillator and the photomultiplier tube and having an opening formed at one side thereof to allow radiation to be incident to the scintillator; A collimator provided in front of the opening of the shield to selectively pass radiation incident to the scintillator through the opening; And a driving device connected to the collimator to move the collimator in one axis direction. The collimator includes a pair of slits formed at 90 ° angles to a shielding plate made of a radiation shielding material. And measure the radiation dose detected through the pair of slits through one scan of the single-axis drive by the drive device, thereby obtaining X- and Y-axis profile information of the radiation dose emitted from the thyroid gland. Characterized in that it can grasp the distribution of the radioisotope ingested.

The thyroid uptake test apparatus provided with the collimator for confirming the thyroid radiation dose distribution according to the present invention uses a collimator provided with a pair of slits formed at an angle of 90 ° to the radiation shielding plate, and the collimator is driven by only one axis of the collimator. It can be configured to obtain X- and Y-axis profile information of the radiation dose emitted from the thyroid gland by measuring the radiation dose detected through a pair of slits. The motion alone has the effect of accurately determining the intake distribution of radioactive isotopes in the thyroid gland.

In addition, it is possible to measure the total dose of the radiation dose through the above-described profile measurement of the radiation dose, and to accurately grasp the distribution of thyroid intake and the size of the thyroid gland, so that the inspection and treatment of the thyroid gland can be performed more effectively. There is.

1 is a view showing a schematic configuration of a thyroid uptake test apparatus equipped with a collimator for thyroid radiation dose distribution confirmation according to an embodiment of the present invention.
2 is a view showing the configuration of a collimator for thyroid radiation dose distribution confirmation according to an embodiment of the present invention.
3 is a view for explaining a method of obtaining the X-axis and Y-axis profile information of the radiation dose emitted from the thyroid gland through one-axis drive of the collimator according to an embodiment of the present invention.

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

1 is a view showing a thyroid intake rate inspection apparatus provided with a collimator 100 for thyroid radiation dose distribution confirmation according to an embodiment of the present invention, Figure 2 is a thyroid radiation dose distribution check according to an embodiment of the present invention A diagram showing the collimator 100.

First, as shown in Figure 1, the thyroid uptake test apparatus provided with a collimator 100 for checking the thyroid radiation dose distribution according to an embodiment of the present invention is a collimator 100, the shield 200, the scintillator 300 , A photomultiplier tube 400 and a signal processor (not shown) are configured.

The collimator 100 is formed by a pair of slits formed to form a shielding plate made of a radiation shield at an angle of 90 ° to each other, as shown in Figure 2, the shield plate formed of a rectangular plate type is horizontal to the incident surface The first slits 101 formed in the X-axis direction and the second slits 102 formed in the Y-axis direction are formed at an angle of 90 ° with each other.

At this time, the shape of the collimator 100 may be formed in a plate type of various forms, and the two slits formed on the plate also within the range to focus the incident radiation to the parallel beam of the X-axis and Y-axis Of course, it can be arranged in various ways.

The collimator 100 as described above is connected to the linear driving device 110 for driving the collimator 100 in one direction in an oblique direction at an angle of 45 degrees from the horizontal direction of the radiation incident surface.

The driving device 110 drives the collimator 100 uniaxially in a diagonal direction at an angle of 45 degrees from the horizontal direction of the radiation incident surface, so that the radiation emitted from the isotope ingested by the thyroid gland is formed in the collimator. And adjusting the incident light to the scintillator 300 of the inspection apparatus through the second slits 101 and 102 so as to detect the X-axis and Y-axis direction profiles of the emitted radiation amount. Specific measurement method for detecting the X-axis and Y-axis dose profile of the radiation emitted from the isotope ingested by the thyroid gland through the movement of the collimator 100 will be described in more detail with reference to FIG. Let's do it.

The shield 200 is formed to surround the scintillator 300 and the photomultiplier tube 400 to prevent incidence of other surrounding radiation other than the radiation emitted from the isotope ingested into the thyroid to the scintillator 300. In addition, an opening is formed in the front surface where radiation emitted from the isotope ingested in the thyroid gland is formed to form a radiation incident passage 210.

The scintillator 300 is composed of scintillation crystals such as NaI, Lutetium Oxyorthosilicate (LSO), Bismuth Germanate Oxide (BGO), or Lutepium-Yttrium Aluminate-Perovskite (LOYAP), and reacts with incident radiation to generate a scintillation signal.

The photomultiplier tube 400 is connected to the rear end of the scintillator 300 and converts the scintillator signal generated by the scintillator 300 into an electrical signal.

At this time, the photomultiplier tube 400 is composed of a plurality of micro cells, the radiation beam incident on the scintillator 300 of the inspection apparatus through the first and second slits 101 and 102 formed in the collimator 100 described above It will output an electrical signal.

Accordingly, the signal processor (not shown) detects the X- and Y-axis dose profiles of the radiation emitted from the isotope ingested in the thyroid gland based on the electrical signal of the radiation dose input from the photomultiplier tube 400. Accurately determine the intake distribution of radioactive isotopes in the thyroid gland.

3 is a view for explaining in detail the method of obtaining the X-axis and Y-axis profile information of the radiation dose emitted from the thyroid gland through one-axis drive of the collimator according to an embodiment of the present invention.

As shown in FIG. 3, the first slit 101 of the collimator 100 is formed in the X-axis direction, and the second slit 102 is formed in the Y-axis direction.

Using this, in the process of detecting the radiation emitted from the thyroid 10, first, as shown in Figure 3 (a1), by moving the collimator 100 through the drive device 110, the collimator 100 The upper right side of the first slit 101 is positioned to correspond to the lower part of the thyroid 10, and then the collimator 100 is moved along the oblique direction at an angle of 45 degrees from the horizontal direction of the radiation incident surface through a driving device. As shown in (a2) of FIG. 3 while moving upwards, scanning until the lower left side of the first slit 101 of the collimator 100 leaves the upper part of the thyroid gland 10, thereby scanning the radiation emitted from the thyroid gland 10. An X-axis radiation dose profile can be obtained.

When the scan in the X-axis direction as described above is completed, as shown in FIG. 3 (b1), the collimator 100 is moved through the driving device 110, so that the second slit 102 of the collimator 100 is moved. After the lower left side is positioned to correspond to the right side of the thyroid gland 10, the collimator 100 is moved downwardly along the oblique direction at an angle of 45 degrees from the horizontal direction of the radiation incident surface through the driving device. As in (b2), by scanning until the upper right side of the second slit 101 of the collimator 100 deviates to the left of the thyroid 10, the Y-axis radiation dose profile of the radiation emitted from the thyroid 10 is Can be obtained.

The above-described scan order of the X-axis and the Y-axis is simply for explaining the process of acquiring the axial profile of the radiation dose through a scan, and the operating method of the thyroid uptake test apparatus according to the present invention is not necessarily limited thereto. For example, when the driving device is operated in the order of (b1) → (b2) → (a2) → (a1) of FIG. 3, the radioactive intake to the thyroid gland is only one scan through one-axis driving in one direction. By obtaining the X- and Y-axis radiation dose profiles of the radiation emitted from the isotopes, it is possible to accurately grasp the distribution of intakes of the isotopes taken up by the thyroid gland.

As described above, the thyroid uptake test apparatus provided with the collimator for confirming the thyroid radiation dose distribution according to the present invention, using a collimator having a pair of slits formed at an angle of 90 ° to the radiation shielding plate, It is configured to acquire the X-axis and Y-axis profile information of the radiation dose emitted from the thyroid gland with only one scan process through one-axis driving. It can be effective.

In addition, it is possible to measure the total dose of the radiation dose through the above-described profile measurement of the radiation dose, and to accurately grasp the distribution of thyroid intake and the size of the thyroid gland, so that the inspection and treatment of the thyroid gland can be performed more effectively. There is.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be obvious to those who have knowledge of.

10: thyroid 100: collimator
101: first slit 102: second slit
110: drive device 200: shield
210: radiation incident path 300: scintillation body
400: photomultiplier

Claims (3)

In the thyroid uptake test device for testing the intake rate of the radioisotope ingested in the thyroid gland by detecting the radiation dose,
Scintillators that react with incident radiation to generate flashes;
A photomultiplier tube connected to a rear end of the scintillator and converting the scintillation generated by the scintillator into an electrical signal;
A signal processor which processes an electrical signal input from the photomultiplier tube;
A radiation shield provided in a form surrounding the scintillator and the photomultiplier tube and having an opening formed at one side thereof to allow radiation to be incident to the scintillator;
A collimator provided in front of the opening of the shield to selectively pass radiation incident to the scintillator through the opening; And
It is configured to include; a drive device connected to the collimator to move the collimator in one axis direction
The collimator includes:
A shield plate made of a radiation shielding material is provided with a pair of slits formed at an angle of 90 ° to each other,
Intake into the thyroid gland by acquiring the X- and Y-axis profile information of the radiation dose emitted from the thyroid gland by measuring the radiation dose detected through the pair of slits through one scan of the single-axis drive by the drive unit. Thyroid intake test device, characterized in that configured to grasp the distribution of the radioactive isotope. The method of claim 1,
The pair of slits formed in the collimator,
And a first slit formed parallel to the horizontal direction of the radiation incident surface, and a second slit formed in a direction perpendicular to the first slit. The method of claim 1,
The driving device includes:
And the collimator is configured to uniaxially drive in a diagonal direction at an angle of 45 degrees from the horizontal direction of the radiation incident surface.

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