KR20210027724A - Fabric sheet for shielding radiation - Google Patents

Abstract

The present invention relates to a medical shielding fabric using a dose shielding fiber. More specifically, in a shielding fiber which can shield scattered radiation in order to prevent exposure to radiation to a non-interested area of a patient while transmitting radiation to the patient in real time, the shielding fiber is formed in a size that can be applied to the entire patient body part, but comprises a transmitting part formed to allow scattered radiation to pass through the region of interest among the patient′s body parts, and a shielding part which can shield scattered radiation in uninterested areas.

Description

Fabric sheet for shielding radiation

The present invention relates to a medical shielding fabric using a dose-shielding fiber, and more particularly, to prevent exposure to radiation to an uninterested area of a patient during an ongoing operation or procedure while transmitting radiation to a patient in real time.

Of the total radiation exposed to us, natural radiation is about 85%, and most of the rest are exposed by medical radiation such as X-ray examination, and radiological examinations using radiation in medical institutions are used in the medical field by securing the legitimacy of the action. I'm doing it.

In addition, according to the concept of As Low As Reasonably Achievable (ALARA) recommended by the International Commission on Radiological Protection (ICRP), it is recommended to minimize the dose received by the patient while obtaining an optimal image. Medical imaging using radiation uses the transmittance of radiation, and exposure to radiation cannot be avoided in order to create an image using radiation. Therefore, the necessity of radiation protection may emerge for a region that is particularly sensitive to radiation among various organs of the human body.

To this end, in Korean Patent Laid-Open Publication No. 10-2018-0096253,'Medical Image Shooting Protective Equipment', a shielding means containing a contrast material and attached to the bottom of the shielding means to separate the shielding means 10 from the body part by a predetermined distance. In the protective equipment for medical imaging that includes a gap-maintaining member, when using a shielding means containing a contrast material capable of shielding radiation, a woman's breast or breast during a medical imaging examination such as a computerized tomography (CT) examination, a general photographic examination, or a fluoroscopy examination. It was proposed to effectively protect specific body parts of patients with high radiation sensitivity, such as the thyroid gland, lens, and gonads.

Meanwhile, ICRP 85, recently published by the International Commission on Radiological Protection (ICRP), recommends the prevention of radiation disorders during interventional procedures. Unlike general radiographs, since the procedure is performed while fluoroscopy is mainly performed for a long time and includes several angiography, the risk of radiation exposure is inevitably increased compared to general radiographic examinations. Because of this, side effects such as radiation injury are likely to occur on the skin, so it is desirable to minimize the exposure dose received by the patient in the interventional procedure.

For example, among the procedures performed while transmitting radiation to the patient in real time, the most representative procedure is hepatic arterial chemoembolization (TACE). Continuously undergoing long-term tests involving Medical exposure from interventional procedures can increase the risk of exposure to radiation damage in that the benefits of exposure are justified for the patient and are excluded from the dose limit. In Korea, a multi-center study was conducted in 2007 in the'evaluation of patient exposure doses in the field of interventional radiation'. Among the research results, the average duration of the TACE procedure is 59 minutes, and the average fluoroscopy time is 17 minutes. The average incident dose of Abdomen is 511.75 mGy, and the maximum incident dose is about 4,346 mGy, which is difficult or takes a long time. He pointed out that in the case of the procedure, attention should be paid to the patient's skin damage.

However, as described above, the high dose rate around the patient that occurs during the procedure while the radiation is transmitted to the patient in real time comes from the radiation backscattered from the patient.If the X-ray tube is placed under the bed where the patient is located, the scattered radiation directed to the medical staff As it passes through the patient's body, it is attenuated, so the dose to the operator's head, upper body, and hands can be greatly reduced. On the other hand, as shown in FIG. 1, there is a problem in that the patient is continuously exposed during the procedure even in the non-interested region other than the region of interest required for treatment during an operation or procedure while being transmitted to the patient in real time as shown in FIG. 1. In addition, in the case of known technologies, it is intended to transmit only the minimum amount of radiation to a specific body part to be photographed during fluoroscopic examination such as computed tomography (CT), or radiation of workers located in places exposed to radiation. Since most of them are aimed at limiting exposure, there is a need for a method for minimizing radiation exposure to the non-interested area of the patient during an operation or procedure performed while transmitting radiation for an actual long time.

Korean Patent Publication No. 10-2018-0096253 (2018.08.29) Korean Patent Publication No. 10-2014-0029502 (2014.03.10) Korean Patent Publication No. 10-2015-0009812 (2015.01.27) Korean Patent Publication No. 10-2011-0064988 (2011.06.15)

Therefore, the present invention uses an X-ray tube to transmit radiation to an area of interest for a long period of time and use a dose-shielding fiber for a patient in need of an operation or procedure. It is an object of the present invention to provide a medical shielding fabric using a dose shielding fiber that can prevent unnecessary radiation disturbances of patients by minimizing exposure by scattered radiation.

In order to achieve the above object, the present invention is a shielding fabric capable of shielding scattered radiation, wherein the shielding fabric is formed in a size that can be applied to the entire body part of the patient, but scattered radiation is applied to the region of interest among the patient body parts. It includes a transmitting portion formed to be transmitted and a shielding portion capable of shielding scattered radiation in an uninterested area.

In addition, the outer diameter of the transmission part has a distance L separated by at least 5 cm from the outer periphery of the region of interest of the patient through which the scattered radiation is transmitted.

In addition, the shielding fabric is made in the form of a fabric sheet.

In addition, the shielding fabric contains any one of barium sulfate (BaSO4), iodine, lead (Pb), bismuth, or tungsten.

In addition, it further includes a shielding fabric having a small transmission part diameter so that the diameter of the transmission part of the shielding fabric can be adjusted.

According to the present invention, radiation is transmitted to the region of interest for a long time using an X-ray tube. There is an effect of minimizing the exposure by scattered radiation to prevent unnecessary radiation disorders in the patient.

In addition, since the position through which the scattered radiation is transmitted can be adjusted according to the treatment site of the patient, there is a convenient effect in use.

1 is a dose distribution diagram showing the dose around the patient when the radiation is transmitted through the region of interest.
Figure 2 is a perspective view of a medical shielding fabric using a dose shielding fiber according to a temporary example of the present invention
3 is a state diagram of use of a medical shielding fabric using a dose shielding fiber according to a temporary example of the present invention
Figure 4 is a rear view when using a medical shielding fabric using a dose shielding fiber according to a temporary example of the present invention
5 is a diagram of an interventional procedure equipment used in an experimental example according to the present invention
6 is a view of a glass dosimeter for measuring dose used in an experimental example according to the present invention
7 is a diagram of an area dosimeter used in an experimental example according to the present invention

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, this is for explaining in detail enough that a person of ordinary skill in the art can easily carry out the invention, and this does not mean that the technical spirit and scope of the present invention are limited.

1 is a dose distribution diagram showing the dose around the patient when the radiation is transmitted to the region of interest, FIG. 2 is a perspective view of a medical shielding fabric using a dose-shielding fiber according to a temporary example of the present invention, and FIG. It is a state diagram of use of a medical shielding fabric using a dose shielding fiber according to an example, and FIG. 4 is a rear state diagram when a medical shielding fabric using a dose shielding fiber is used according to a temporary example of the present invention.

1 is a dose distribution diagram showing the dose around the patient when the radiation is transmitted to the region of interest. After laying the patient P on the bed 14 of the radiographic apparatus 10, the X-ray tube 11 located under the bed is shown. When the radiation is irradiated after being moved to the specific region of interest T of the patient P, as shown in FIG. 1, it can be confirmed that the radiation is transmitted to the non-interested region in addition to the specific region of interest T to obtain an actual image. . In this case, the patient P is exposed to radiation even in the uninterested area.

Hereinafter, a medical shielding fabric 100 using a dose shielding fiber according to an embodiment of the present invention will be described in detail with reference to FIGS. 2 to 4.

In the present invention, in the shielding fabric 100 capable of shielding scattered radiation for preventing exposure by radiation to the non-interested region of the patient P, the shielding fabric can cover the entire body part of the patient. It is formed in a size, and includes a transmitting part 110 formed to transmit scattered radiation to the region of interest T among the patient's body parts, and a shielding part 120 capable of shielding the scattered radiation from the non-interested region.

The shielding fabric 100 is to prevent exposure to the non-interested area of the patient P by radiation, so that the entire body of the patient P located on the bed 14 of the radiographic apparatus 10 can be applied. It is desirable to manufacture it in the size of. The shielding fabric 100 should be made to have a size enough to cover the entire body so that the shielding fabric 100 will be applied to the entire body even when the position of the transmission unit 110 described later is changed according to the region of interest (T). It is to make it possible.

In addition, the shielding fabric 100 includes a transmitting part 110 formed to transmit scattered radiation to the region of interest T among the patient's body parts, and a shielding part 120 capable of shielding the scattered radiation in the non-interested region, respectively. do. The transmission unit 110 is located in the region of interest during an operation or procedure that is performed while transmitting the radiation to the patient in real time, and when radiation is irradiated through the X-ray tube 11 located above or below the region of interest (T), the radiation is transmitted to the corresponding region of interest. It is a configuration that allows it to penetrate. At this time, when radiation is transmitted to the region of interest of the patient P through the transmission unit 110, the image of the region of interest T of the patient P photographed through the image receiving unit 12 of the radiographic apparatus 10 is monitored (13). ), and medical staff can perform surgery or procedures through the image.

In this case, the outer diameter of the transmission part 110 is characterized by having a distance L (L) separated by at least 5 cm from the outer periphery of the region of interest T of the patient through which the scattered radiation is transmitted. The transmitting unit 110 can acquire a desired image only when the radiation irradiated through the X-ray tube 11 is not shielded by the shielding unit 120 and passes through the region of interest T accurately. Therefore, when the outer diameter of the transmission part 110 is smaller than the region of interest T of the patient, an accurate image of the region of interest T cannot be obtained, so the outer diameter of the transmission part 110 must be wider than the region of interest T. In addition, when the outer diameter of the transmission unit 110 and the region of interest (T) are the same, or the outer diameter of the transmission unit 110 is separated by less than 5 cm from the outer periphery of the region of interest (T) of the patient (P), the outer diameter of the transmission unit 110 A streak artifact (a phenomenon in which image reading is difficult due to the occurrence of artificial shading due to the difference in radiation absorption rate) occurs, and due to this phenomenon, there is a problem that an accurate image of the region of interest (T) cannot be obtained. (110) In consideration of the streak artifact phenomenon that may occur in the outer diameter, it is desirable that the outer diameter of the transmitting part 110 be at least 5cm apart from the outer periphery of the region of interest T of the patient P through which radiation is transmitted. Do.

However, if the transmission part 110 exceeds 15 cm or more from the outer periphery of the region of interest T of the patient P, other organs adjacent to the region of interest T of the patient P are exposed to radiation for a long time or Since there is a problem in that the skin damage caused by it is enlarged, it is preferable that the diameter of the transmission part 11 does not exceed 15 cm or more from the outer periphery of the region of interest (T). When the transmitting part 110 of the shielding fabric 100 exceeds 15 cm or more from the outer periphery of the region of interest T of the patient P, the upper or lower part of the transmitting part 110 of the shielding fabric 100 By stacking a shielding fabric 100' having a small permeable portion 110' to adjust the diameter of the permeable portion 110, the permeable portion 110' of the shielding cloth 100' is Keep it less than 15cm from the outer periphery.

In addition, the shielding fabric 100 may be manufactured in the form of a fabric sheet or pad. For example, it is produced by mixing barium sulfate (BaSO4), iodine, lead (Pb), bismuth, or tungsten when making synthetic fibers, or barium sulfate (BaSO4), iodine in the existing fabric sheet. (Iodine), lead (Pb), bismuth (Bismuth) or tungsten (tungsten) coating method, such as coating can also be produced. In addition, the shielding fabric 100 can also be manufactured in the form of a pad. If the shielding fabric 100 is manufactured in the form of a pad, it is installed when the X-ray tube 11 is installed on the bed 14 according to the region of interest (T) or surgery and treatment method. Since it may not be easy, it is preferable that the shielding fabric 100 be made of a fabric sheet so that the shielding fabric 100 can be accurately applied to various surgical and surgical methods or areas of interest.

Hereinafter, the effects according to the experimental examples of the present invention will be described in detail with reference to FIGS. 5 to 7.

5 is an experimental example according to the present invention, Philips Allura Xper FD 20 (Philips, Eindhoven, Netherlands) was used as a surgical or surgical equipment performed while transmitting radiation to a patient in real time, and this equipment is the presence or absence of abnormalities in blood vessels in the human body. It is a digital angiography diagnostic device that performs contrast diagnosis and treatment of blood vessels. In addition, to measure the dose, a glass dosimeter (GD-352M, AGC TECHNO GLASS CO., LTD) can measure the dose of a diagnostic radiation generator with a dose range of 0.01 mGy to 10 Gy and an energy of 120 keV or less. After reproducibility: 3% or less at 0.1 mGy and 2% or less at 1 mGy were selected and used. For reading of the irradiated glass dosimeter, the dose was read with an FGD-1000 reader (AGC TECHNO GLASS CO, LTD).

And Figure 6 is a glass dosimeter (GD-352M, AGC TECHNO GLASS CO., LTD), the dose range is 0.01 mGy ~ 10 Gy, it is possible to measure the dose of the diagnostic radiation generator with energy less than 120 keV, reproducibility 0.1 after calibration Dosimeters of 3% or less for mGy and 2% or less for 1 mGy were selected and used. For reading of the irradiated glass dosimeter, the dose was read with an FGD-1000 reader (AGC TECHNO GLASS CO, LTD). In addition, FIG. 7 is an area dosimeter using a dosimeter (KermaX plus DDP) capable of measuring the dose of the entire irradiated surface irradiated by the radiographic apparatus, measuring the dose according to the area, and measuring the patient's exposure dose.

In addition, as for the dose-reducing fibers, a total of four types of dose-reducing fibers as shown in [Table 1] were used in the experiment according to the content of barium sulfate and the coating thickness (product names: DRF01, DRF02, DRF03, DRF04).

[Table 2] shows the incident dose in the region of interest (T) before radiation is transmitted through the phantom in the experimental example, the measured value of the scattered dose measured at a distance of 10 cm outside the region of interest (T), and the reduction effect according to the type of dose reduction fiber (DRF). This is a table that summarizes. The measured value of the incident dose in the area irradiated with radiation before the radiation is transmitted to the phantom is 13360 μGy, and the measured value of the scattered rays measured at a distance of 10 cm from the end of the irradiation area is 1745 μGy. When four types of dose-reducing fibers were used, the measured values were 14761 μGy, 395 μGy, 1270 μGy, and 1204 μGy, respectively. Depending on the type of dose-reducing fiber (DRF), 15%, 20%, 27%, and 31% reduction effects were shown.

As can be seen in the above experimental example, the scattering dose could be reduced by 15 to 31% in areas other than the region of interest (T) depending on the content of _{barium sulfate (BaSO 4) and the coating thickness.} Therefore, the use of dose-reducing fibers is a method of shielding scattered radiation in non-interested regions other than the region of interest during TACE procedure, while transmitting the radiation to the patient in real time while reducing the scattered dose without affecting the medical image quality during surgery or procedure It is believed that it is possible to reduce the patient's exposure dose by reducing it, and to reduce the exposure of the operator by reducing the scattered radiation generated from the patient's body.

Although several embodiments have been exemplarily described above, the fact that the present invention can be embodied in various forms without departing from the spirit and scope thereof is obvious to those of ordinary skill in the art. Accordingly, the above-described embodiments should be regarded as illustrative rather than restrictive, and all implementations within the scope of the appended claims and equivalents thereof will be said to be included within the scope of the present invention.

10: radiographic device
11: X-ray tube 12: image receiver
13: monitor 14: bed
P: patient
100, 100': shielding cloth
110,100': transmitting part 120: shielding part

Claims (5)

In a shielding fabric capable of shielding scattered radiation,
The shielding fabric 100 is formed in a size capable of applying the entire body part of the patient, but scattering in the transmitting part 100 formed to transmit the scattered radiation to the region of interest (T) among the body parts of the patient and the non-interested region. Medical shielding fabric using a dose shielding fiber, characterized in that it comprises a shielding unit 120 capable of shielding radiation.
The method according to claim 1,
The outer diameter of the transmission part 110 is a medical shielding fabric using a dose shielding fiber, characterized in that it has a distance (L) separated by at least 5cm from the outer periphery of the patient's region of interest (T) through which scattered radiation is transmitted.
The method according to claim 1,
The shielding fabric 100 is a medical shielding fabric using a dose shielding fiber, characterized in that made in the form of a fabric sheet.
The method according to claim 1,
The shielding fabric 100 is a medical shielding fabric using a dose shielding fiber, characterized in that it contains any one of barium sulfate (BaSO4), iodine, lead (Pb), bismuth (Bismuth), or tungsten. .
The method according to claim 1,
Medical shielding fabric using a dose shielding fiber, characterized in that it further comprises a shielding fabric (100') having a small diameter of the transmission portion (110') so as to adjust the diameter of the transmission portion (110) of the shielding fabric (100).

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