JP2019055193A - Goggle for head ct examination and head ct examination method - Google Patents

Abstract

To reduce a radiation exposure dose in a head CT examination, and enable image reading of an anatomical structure in the periphery of eyeballs.SOLUTION: A goggle for a head CT examination mounted in head CT scanning, which serves as a shield against radiation is provided with a pad that comes in contact with the face of a subject and a cover in which a bismuth sheet is stuck on the surface or which includes bismuth. When a distance between the cover in which the bismuth sheet or bismuth is included and the surface of the pad that comes in contact with the face of the subject is represented as d [mm], and a load [g/cm] of the bismuth of the cover in which the bismuth sheet or the bismuth is included is represented as g, d and g satisfy at least 3≤3.463+0.03817×d-0.2749×g-0.000154×d+0.00117×d×g+0.002361×g.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a head CT examination goggles and a head CT examination method.

  A head CT examination is performed as necessary in the event of a head injury or a headache, but the head CT examination involves radiation exposure because X-rays are used. CT is a problem that the radiation dose is larger than that of a plain radiograph, and head CT has a definite effect that cataract occurs after lens exposure and the probability that a tumor or genetic effect will occur. There are effects. In particular, children are known to have higher radiosensitivity than adults, and it is necessary to reduce the dose as much as possible in examinations involving radiation exposure including CT.

  It has been reported that bismuth has a radiation shielding effect and can reduce the exposure dose of each organ. For example, a radiation exposure dose reduction using a bismuth sheet during CT imaging has been reported (see Non-Patent Document 1).

Wang J et al, "Bismuth Shielding, Organ-based Tube Current Modulation, and Global Reduction of Tube Current for Dose Reduction to the Eye atHead CT", Radiology 2012, 262, 191-198

  However, bismuth sheets are not widely used in actual daily examinations. This is caused by poor visualization due to artifacts in the anatomical structure around the eyeball (for example, around the orbit) by attaching a bismuth sheet directly to the body surface, making it impossible to interpret the anatomical structure around the eyeball (for example around the orbit) In spite of the fact that the bismuth sheet is expensive, it was disposable.

  The present invention has been made in view of the above-described problems, and reduces head dose of radiation at the time of head CT examination and enables head CT examination goggles and head CT that can interpret anatomical structures around the eyeball. The purpose is to provide an inspection method.

The head CT examination goggles according to the first aspect of the present invention are head CT examination goggles that are worn and shielded against radiation when undergoing a head CT scan, a pad that hits the face of a subject, and a bismuth sheet Is attached to the surface or a cover containing bismuth, and the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that contacts the face of the subject is d [mm], When the load [g / cm ² ] of bismuth of the bismuth sheet or the cover containing the bismuth is g, d and g are at least
3 ≤ 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ²
Meet.

  According to this configuration, even if a poor drawing due to an artifact occurs in the anatomical structure around the eyeball (for example, around the orbit), the anatomical structure around the eyeball (for example, around the orbit) can be interpreted. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball. Moreover, since a bismuth sheet is not directly attached to the body surface, there is an advantage that it can be reused from the viewpoint of hygiene. Furthermore, when wearing a bismuth sheet directly on the body surface, there is a risk that it will fall off the body surface just by shaking the head a little, but using goggles will maintain stability and it will fall off the body surface. Can reduce the risk.

The head CT examination goggles according to the second aspect of the present invention are head CT examination goggles according to the first aspect, wherein the bismuth load of the cover containing the bismuth sheet or the bismuth is 3. In the case of 4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that contacts the face of the subject is at least 15 mm or more.

  According to this configuration, even if a poor drawing due to an artifact occurs in the anatomical structure around the eyeball (for example, around the orbit), the anatomical structure around the eyeball (for example, around the orbit) can be interpreted. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball. Moreover, since a bismuth sheet is not directly attached to the body surface, there is an advantage that it can be reused from the viewpoint of hygiene. Furthermore, when wearing a bismuth sheet directly on the body surface, there is a risk that it will fall off the body surface just by shaking the head a little, but using goggles will maintain stability and it will fall off the body surface. Can reduce the risk.

The head CT examination goggles according to the third aspect of the present invention are head CT examination goggles according to the first aspect, wherein (d, g) coordinates are
5 = 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ²
Located above the curve representing the function of.

  According to this configuration, since no artifact is generated in the anatomical structure around the eyeball (for example, around the orbit), there is no poor rendering due to the artifact, and the interpretation of the anatomical structure around the eyeball (for example, around the orbit) is not hindered. . As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.

The head CT examination goggles according to the fourth aspect of the present invention are head CT examination goggles according to the third aspect, wherein the bismuth load of the cover containing the bismuth sheet or the bismuth is 3. In the case of 4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that contacts the face of the subject is 30 mm or more.

  According to this configuration, since no artifact is generated in the anatomical structure around the eyeball (for example, around the orbit), there is no poor rendering due to the artifact, and the interpretation of the anatomical structure around the eyeball (for example, around the orbit) is not hindered. . As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.

  The head CT examination goggles according to the fifth aspect of the present invention are the head CT examination goggles according to any one of the first to fourth aspects, and are curved and fixed to the inside of the cover. The display further includes a display capable of displaying an image toward the inside of the head CT examination goggles, and the display displays an image based on an image signal input from the outside.

  According to this configuration, since an image (for example, an image such as an animation) can be displayed during the head CT examination, a subject (for example, a child under 15 years old) who is undergoing the head CT examination moves. Can be suppressed.

The head CT examination goggles according to the sixth aspect of the present invention are head CT examination goggles according to any one of the first to fifth aspects, wherein the subject is a child under 15 years old, The bismuth sheet or bismuth when the major axis is a and the minor axis is b when the width along the curvature of the cover containing the bismuth sheet or the bismuth is an arc length, The chord length d of the cover including is expressed as t = arctan ((b / a) tan (θ)) where d = 2 × a × sin (t), and θ is at least 0.61 radians or more, Assuming that the number of days after birth of the subject to be tested is Age, a = 9.733 × 10 ⁻³ × Age + 126.8 and b = 7.731 × 10 ⁻³ × Age + 112.7.

  According to this configuration, since the crystalline lens can be shielded by the cover containing bismuth sheet or bismuth, the exposure dose of X-rays incident on the crystalline lens can be reduced.

  A head CT examination method according to a seventh aspect of the present invention performs a head CT scan on a subject wearing the head CT examination goggles according to any one of the first to sixth aspects. Process.

  According to this configuration, it is possible to reduce the radiation exposure dose to the head (for example, the crystalline lens) at the time of head CT examination and to interpret the anatomical structure around the eyeball.

  A head CT examination method according to an eighth aspect of the present invention performs a head CT scan on a subject wearing the head CT examination goggles according to the fifth aspect, and the head A step of displaying an image on the display during a CT scan.

  According to this configuration, since an image (for example, an image such as an animation) can be displayed during the head CT examination, a subject (for example, a child under 15 years old) who is undergoing the head CT examination moves. Can be suppressed.

  According to the present invention, poor rendering due to artifacts can be suppressed in the anatomical structure around the eyeball (for example, around the orbit), and the anatomical structure around the eyeball (for example, around the orbit) can be interpreted. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball. Moreover, since a bismuth sheet is not directly attached to the body surface, there is an advantage that it can be reused from the viewpoint of hygiene. In addition, when wearing a bismuth sheet directly on the body surface, there is a risk that it will fall off the body surface just by shaking the head a little, but stability is maintained by using goggles and the body surface is maintained. Can reduce the risk of falling.

It is a perspective view of the goggle for head CT inspection concerning this embodiment. It is the perspective view which looked at goggles for head CT inspection from the inside. It is a schematic diagram explaining the angle from the median face to the lens outer edge and the angle from the median face to the outer wall of the orbit. It is a table | surface showing the angle from the median face to the lens outer edge for every age, and the angle from the median face to the outer wall of the orbit. It is a schematic diagram of the experiment by the bismuth shield using a phantom. It is a table | surface which shows the shielding effect of a bismuth sheet. It is a table | surface which shows an exposure dose and a reduction rate. It is the figure which compared the influence on the head CT image of a bismuth sheet. It is a comparison of head CT images when the distance between the bismuth sheet and the surface of the pad that faces the subject's face (subject's body surface) is changed. It is a comparison between the average point of visual evaluation of the head CT image by three radiological diagnosis specialists and the bismuth distance. It is a graph which shows the relationship between a bismuth distance and an exposure reduction amount, and the relationship between the bismuth distance and the average point of visual evaluation of three radiation diagnostic specialists. It is a CT image of a phantom when the bismuth distance is 0 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and when there is no bismuth sheet. It is a CT image of a phantom when the bismuth distance is 20 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, 5 mm and when there is no bismuth sheet. It is a CT image of a phantom when the bismuth distance is 40 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and when there is no bismuth sheet. It is a table | surface which shows the result of the average score of the bismuth distance, the number of sheets of a bismuth sheet, and the visual evaluation of three radiologists. It is a graph showing the data of the table | surface of FIG. 15, and approximate expression (1). It is a graph which shows the relationship between the load of bismuth and the bismuth distance for every score. This is a comparison of CT images of a phantom at a distance of 0 mm from a radiation shield such as bismuth. It is a comparison of a CT image of a phantom at a distance of 10 mm from a radiation shield such as bismuth. It is a comparison of CT images of a phantom at a distance of 20 mm from a radiation shield such as bismuth. It is a comparison of CT images of a phantom at a distance of 30 mm from a radiation shield such as bismuth. It is a graph which shows the relationship between the distance with radiation shields, such as bismuth, and the average point of the visual evaluation of three radiation diagnostic specialists. It is a graph which shows the relationship between the distance with radiation shields, such as bismuth, and an exposure reduction amount, and the relationship between the bismuth distance and the average point of visual evaluation of three radiation diagnostic specialists. It is the schematic when the cross section of a head is approximated by the ellipse, and the schematic of the cross section of the goggles for head CT inspection.

  Each embodiment will be described below with reference to the drawings. However, more detailed description than necessary may be omitted. For example, detailed descriptions of already well-known matters and repeated descriptions for substantially the same configuration may be omitted. This is to avoid the following description from becoming unnecessarily redundant and to facilitate understanding by those skilled in the art.

<Configuration>
The configuration of the head CT examination goggles according to the present embodiment will be described with reference to FIG. The head CT inspection goggles according to the present embodiment are head CT inspection goggles that are worn when a head CT scan is performed and shield radiation. FIG. 1 is a perspective view of a head CT inspection goggles according to this embodiment. As shown in FIG. 1, the head CT examination goggles 1 includes a pad 11 that hits the face of a subject, a frame 12 to which a pad is fixed, and a cover 13 on which a bismuth sheet is stuck. The cover 13 is a lens, for example. The cover 13 is not limited to a bismuth sheet attached to the surface, and may be a cover containing bismuth as a material. The head CT inspection goggles 1 includes a band 14 connected to a frame 12. The band 14 is for fixing the head CT inspection goggles 1 to the head.

  In the head CT inspection goggles 1, the distance between the cover 13 containing bismuth sheet or bismuth and the surface of the pad 11 that contacts the subject's face is preferably at least 15 mm. With this configuration, as shown in the experimental results described below, it is possible to suppress poor rendering due to artifacts in the anatomical structure around the eyeball (for example, around the orbit), and to interpret the anatomical structure around the eyeball (for example, around the orbit) It is. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.

  Moreover, since a bismuth sheet is not directly attached to the body surface, there is an advantage that it can be reused from the viewpoint of hygiene. Furthermore, when wearing a bismuth sheet directly on the body surface, there is a risk that it will fall off the body surface just by shaking the head a little, but using goggles will maintain stability and it will fall off the body surface. Can reduce the risk.

  The distance between the bismuth sheet or the cover containing bismuth and the surface of the pad that contacts the subject's face is more preferably 30 mm or more. With this configuration, as shown in the experimental results to be described later, since no artifact is generated in the anatomical structure around the eyeball (for example, around the orbit), there is no poor rendering due to the artifact, and the anatomical structure around the eyeball (for example, around the orbit) Will not interfere with the interpretation. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.

  FIG. 2 is a perspective view of the head CT inspection goggles as seen from the inside. As shown in FIG. 2, the head CT examination goggles 1 are curved and fixed inside the cover 13 and can display an image toward the inside of the head CT examination goggles 1. Further, a signal line 16 for transmitting a video signal to the display 15 is further provided. The display 15 displays a video based on a video signal input from the outside via the signal line 16. With this configuration, since an image (for example, an image such as an animation) can be displayed during the head CT examination, movement of a subject (for example, a child under 15 years old) during the head CT examination is suppressed. be able to.

  The head CT inspection method according to the present embodiment includes a step of performing a head CT scan on a subject wearing the head CT inspection goggles 1. With this configuration, it is possible to reduce the radiation exposure dose to the head (for example, the crystalline lens) during the head CT examination and to interpret the anatomical structure around the eyeball.

  In addition, the head CT examination method according to the present embodiment performs a head CT scan on a subject wearing the head CT examination goggles 1, and displays 15 during the head CT scan. There may be a step of displaying an image. With this configuration, since an image (for example, an image such as an animation) can be displayed during the head CT examination, movement of a subject (for example, a child under 15 years old) during the head CT examination is suppressed. be able to.

  FIG. 3 is a schematic diagram illustrating an angle from the median face to the outer edge of the crystalline lens and an angle from the median face to the outer wall of the orbit. FIG. 3 shows the crystalline lens CL. As shown in FIG. 3, α is an angle from the median face to the outer edge of the lens, and β is an angle from the median face to the outer wall of the orbit.

  FIG. 4 is a table showing the angle from the median face to the outer edge of the lens and the angle from the median face to the outer wall of the orbit for each age. The table in FIG. 4 calculates the average of the angle from the median face to the outer lens edge and the angle from the median face to the outer wall of the orbit in 10 cases per year for each child up to 15 years of age. It is a thing. In the table of FIG. 4, the average and standard deviation of each angle are shown.

  As shown in FIG. 4, in a child up to 15 years old, the outer edge of the lens is located up to 35 degrees from the midline of the face. From this, when the subject is a child 15 years or younger, the cover including the bismuth sheet or bismuth according to the present embodiment preferably extends at least 35 degrees to the left and right with respect to the subject's midline. That is, when the subject is a child under 15 years old, the cover including the bismuth sheet or bismuth according to the present embodiment is preferably configured to extend at least 35 degrees to the left and right with respect to the subject's midline. . With this configuration, the crystalline lens can be shielded with a bismuth sheet or a cover containing bismuth, so that the exposure dose of X-rays incident on the crystalline lens can be reduced.

  As shown in FIG. 4, in a child up to 15 years old, the outer wall of the orbit is located from the median face to 45 degrees. From this, when the subject is a child under 15 years old, it is more preferable that the cover including the bismuth sheet or bismuth according to the present embodiment extends at least 45 degrees to the left and right with respect to the midline of the subject. That is, when the subject is a child 15 years or younger, the cover including the bismuth sheet or bismuth according to the present embodiment is more configured to extend at least 45 degrees to the left and right with respect to the midline of the subject. preferable. With this configuration, the entire eye can be shielded by the cover containing bismuth sheet or bismuth, so that the exposure dose of X-rays incident on the entire eye can be reduced.

<Devices used>
The CT apparatus is Revolution CT (GE Healthcare), and the CTDI phantom is 16 cm. Absorbed dose was detected using ACCU-GOLD + compact X-ray analyzer (Radical) in a 10X6-3CT CTDI chamber.

  FIG. 5 is a schematic diagram of an experiment using a bismuth shield using a phantom. As shown in FIG. 5, the insertion hole of the CTDI ionization chamber was installed vertically (measurement position angle 0 degree). Thereafter, a 5 mm thick urethane foam was placed on the phantom, and a bismuth sheet was placed thereon, thereby measuring a dose in a state where the bismuth sheet was separated from the phantom surface by 0 to 50 mm.

  Dose measurement was performed at a distance of 0 to 50 mm from the phantom surface to the bismuth sheet (hereinafter also referred to as bismuth distance) at three points of 10 mm, 40 mm, and 80 mm in depth from the phantom surface. Each measurement was performed five times, and irradiation conditions were as follows assuming CT imaging of a pediatric head.

<Irradiation conditions>
The size of the detector (Detector) is 0.625 mm, the number of columns is 224, the tube voltage is 120 kV, the tube current is 250 mA, and the rotation is 0.5 seconds.

  FIG. 6 is a table showing the shielding effect of the bismuth sheet. FIG. 6 shows that in the experimental system shown in FIG. 5, when there is no bismuth sheet when the ionization chamber position is set at 40 degrees and 90 degrees when the face midline is 0 degrees, there is no bismuth sheet covering the area. In some cases, the measurement results are obtained when there is a bismuth sheet covering a wide area. The depth from the phantom surface is 10 mm. As shown in FIG. 6, the smaller the angle is, that is, the closer to the center of the bismuth sheet, the higher the radiation shielding effect by the bismuth sheet. Further, the wider the area covered by the bismuth sheet, the higher the radiation shielding effect.

  FIG. 7 is a table showing the exposure dose and the reduction rate. The dose is the average of 5 measurements. As shown in FIG. 7, the dose is reduced by placing a bismuth sheet at each measurement position. Moreover, the reduction rate decreases as the distance from the phantom surface to the bismuth sheet increases.

  FIG. 8 is a diagram comparing the influence of the bismuth sheet on the head CT image. FIG. 8a is a head CT image when there is no bismuth sheet, and FIG. 8b is a head CT image when a large bismuth sheet is placed directly on the body surface without wearing goggles. FIG. 8c is a head CT image when a small bismuth sheet is placed directly on the body surface without wearing goggles. In FIG. 8b and FIG. 8c, there is an artifact in which the surface of the body surface (mainly the eye socket) around the bismuth sheet is whitened by halation.

  FIG. 8d is a head CT image when the subject wears the goggles according to this embodiment when the bismuth sheet is large. FIG. 8e is a head CT image when the subject wears the goggles according to this embodiment when the bismuth sheet is small. The distance between the surface on which the bismuth sheet in FIGS. 8d and 8e hits the face of the subject (the body surface of the subject) is 25 mm. In FIGS. 8d and 8e, artifacts that cause the surface of the body surface to whiten due to halation are reduced compared to FIGS. 8b and 8c.

  FIG. 8f shows that when the bismuth sheet is small, the goggle according to the present embodiment is configured such that the distance between the surface of the pad that contacts the face of the subject (the body surface of the subject) is 35 mm. It is a head CT image in the case of doing. FIG. 8f is shown for comparison in order to display a head CT image without artifacts. In Figs. 8d and 8e, an artifact that the surface of the body surface is whiter than that in Fig. 8f is slightly observed. In Fig. 8d, the bismuth sheet is larger than that in Fig. 8e, and in Fig. 8d, the artifact is slightly larger than in Fig. 8e. ing.

  Subsequently, a head CT image was taken in a state where the distance from the phantom surface to the bismuth sheet (hereinafter also referred to as bismuth distance) was changed every 5 mm from 0 to 50 mm. Visual evaluation of the images was performed. In visual evaluation, the higher the score is, the higher the evaluation is. Score 1 is "No visualization around the orbit due to artifacts", Score 2 is "poor visualization due to artifacts" and score 3 is "artifacts but interpretation is somehow" “Fair”, score 4 is “artifact is slight, but interpretation is almost good (good)”, and score 5 is “excellent” (excellent).

  FIG. 9 is a comparison of head CT images when the distance between the bismuth sheet and the surface of the pad that faces the subject's face (subject's body surface) is changed. In addition, 0 mm is a case where a bismuth sheet is directly placed on the body surface of the subject. As shown in FIG. 9, when the distance between the bismuth sheet and the surface of the pad that hits the subject's face (subject's body surface) is 0 mm, the surface of the body surface appears whitened due to halation. Yes. When the distance is 10 mm, artifacts are smaller than when the distance is 0 mm. When the distance is 20 mm, artifacts are further reduced than when the distance is 10 mm. When the distance is 30 mm, no artifact occurs.

FIG. 10 is a comparison between the average point of visual evaluation of a head CT image by three radiological diagnosis specialists and the bismuth distance. As shown in FIG. 10, the bismuth distance at which the average score of the three radiological diagnosis specialists exceeds the score 3 of “there is an artifact but can be interpreted (fair)” for the first time is 15 mm. Therefore, the distance between the bismuth sheet or the cover containing bismuth and the surface of the pad that contacts the face of the subject is preferably at least 15 mm or more. Even if a poor rendering due to an artifact occurs in the anatomical structure around the eyeball (for example, around the orbit), the anatomical structure around the eyeball (for example, around the orbit) can be interpreted. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.
In addition, the bismuth distance at which the average score of the three radiological diagnosis specialists exceeds the score of “4, although there are few artifacts but is almost good for interpretation” is 20 mm. Therefore, the distance between the cover containing bismuth sheet or bismuth and the surface of the pad that contacts the face of the subject is more preferably 20 mm or more.

  As shown in FIG. 10, the bismuth distance is 30 mm or more when the average score of the three radiological diagnosis specialists becomes “excellent” (score 5). Therefore, the distance between the cover containing bismuth sheet or bismuth and the surface of the pad that contacts the face of the subject is more preferably 30 mm or more. Artifacts are not generated in the anatomical structure around the eyeball (for example, around the orbit), so that poor rendering due to the artifact does not occur, and interpretation of the anatomical structure around the eyeball (for example, around the orbit) is not hindered. As described above, it is possible to reduce the radiation exposure dose to the head (eg, the crystalline lens) at the time of the head CT examination and to interpret the anatomical structure around the eyeball.

In the above embodiment, as an example, a description is given of a bismuth sheet having a bismuth load of 3.4 g / cm ² and a thickness of 1 mm. In addition, in the cover containing bismuth, since the same result is obtained when the load of bismuth is 3.4 g / cm ² , the load of the cover containing bismuth may be 3.4 g / cm ² . Similarly, the following description will be made assuming that the bismuth sheet has a thickness of 1 mm and a bismuth load of 3.4 g / cm ² as an example.

Next, referring to FIG. 11, the bismuth distance and exposure in the case of one bismuth sheet having a bismuth load of 3.4 g / cm ² (thickness 1 mm), two sheets stacked, and three sheets stacked. The relationship between the amount of reduction and the relationship between the bismuth distance and the average score of the visual evaluations of the three radiological diagnosis specialists will be described.

  FIG. 11 is a graph showing the relationship between the bismuth distance and the exposure reduction amount, and the relationship between the bismuth distance and the average point of the visual evaluation of the three radiological diagnosis specialists. In FIG. 11, a broken line L1 represents an exposure reduction amount in the case of one bismuth sheet, a broken line L2 represents an exposure reduction amount in the case of two bismuth sheets, and a broken line L3 represents an exposure reduction amount in the case of three bismuth sheets. Represent. As the number of bismuth sheets increases at the same bismuth distance, the exposure reduction amount is improved.

  In FIG. 11, the polygonal line L4 represents the average point of the visual evaluation of the radiological diagnosis specialist with one bismuth sheet, the broken line L5 represents the average point of the visual evaluation of the radiological diagnosis specialist with two bismuth sheets, and the polygonal line L6. Represents the average score of the visual evaluation of the radiological diagnosis specialist in the case of three bismuth sheets. At the same bismuth distance, as the number of bismuth sheets increases, the average score of the radiological diagnosis specialist's visual evaluation tends to decrease.

In addition, the case where two bismuth sheets with a thickness of 1 mm and a bismuth load of 3.4 g / cm ² are stacked is a bismuth sheet with the same thickness of 1 mm and a bismuth load of 6.8 g / cm ² . It has the same exposure reduction effect as one sheet, and the average point of visual evaluation of the same radiological diagnosis specialist can be obtained. The case where three bismuth sheets having a thickness of 1 mm and a bismuth load of 3.4 g / cm ² are stacked is a bismuth sheet having a thickness of 1 mm and a bismuth sheet 1 having a bismuth load of 10.2 g / cm ^2. It has the same exposure reduction effect as a sheet, and the average point of visual evaluation of the same radiological diagnosis specialist can be obtained.

Therefore, when the load of the bismuth of 6.8g / cm ² has only to bismuth sheet obtained 6.8g per 1 cm ^2, in the case of 1 cm ² per 6.8g of a single bismuth sheets, a plurality This includes the case of 6.8 g per 1 cm ² with one bismuth sheet. That is, when the load of bismuth is Xg / cm ² , the following description will be made assuming that Xg bismuth is included in the thickness direction per 1 cm ² in the plane of the bismuth sheet.

Comparison of phantom CT images with bismuth distances of 0 mm, 20 mm, and 40 mm, bismuth sheet thicknesses of 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and no bismuth sheet using FIGS. To do. Here, as an example, the bismuth sheet having a thickness of 1 mm is a case where the bismuth sheet having a bismuth load of 3.4 g / cm ² (thickness 1 mm) is one sheet, and the bismuth sheet having a thickness of 2 mm is Two bismuth sheets with a thickness of 1 mm are stacked, a bismuth sheet with a thickness of 3 mm is a stack of three bismuth sheets with a thickness of 1 mm, and a bismuth sheet with a thickness of 4 mm is The four bismuth sheets having a thickness of 1 mm are stacked, and the bismuth sheet having a thickness of 5 mm is a stack of five bismuth sheets having a thickness of 1 mm.

  FIG. 12 is a CT image of the phantom when the bismuth distance is 0 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and when there is no bismuth sheet. FIG. 13 is a CT image of a phantom when the bismuth distance is 20 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and when there is no bismuth sheet. FIG. 14 is a CT image of a phantom when the bismuth distance is 40 mm, the thickness of the bismuth sheet is 1 mm, 2 mm, 3 mm, 4 mm, and 5 mm and when there is no bismuth sheet.

  12 (A), 13 (A), and 14 (A), the thickness of the bismuth sheet is 1 mm, and FIGS. 12 (B), 13 (B), and 14 (B) are bismuth sheets. 12 (C), FIG. 13 (C), and FIG. 14 (C), the thickness of the bismuth sheet is 3 mm, and FIG. 12 (D), FIG. 13 (D), and FIG. 14 (D) has a bismuth sheet thickness of 4 mm, and FIGS. 12 (E), 13 (E), and 14 (E) have a bismuth sheet thickness of 5 mm, and FIG. FIGS. 13 (F) and 14 (F) show the case where there is no bismuth sheet.

  12A to 12F when the bismuth distance is 0 mm, any bismuth sheet causes artifacts due to the bismuth sheet in the CT image, and as the thickness of the bismuth sheet increases, CT increases. Artifacts due to bismuth sheets in the image are large.

  13A to 13F when the bismuth distance is 20 mm, when the thickness of the bismuth sheet is 1 mm, there is almost no artifact due to the bismuth sheet in the CT image, but the thickness of the bismuth sheet is 2 mm or more. In this case, as the thickness of the bismuth sheet increases, the artifact due to the bismuth sheet in the CT image increases.

  14A to 14F when the bismuth distance is 40 mm, when the thickness of the bismuth sheet is 1 mm, there is no artifact due to the bismuth sheet in the CT image, but the thickness of the bismuth sheet is 2 mm or more. As the thickness of the bismuth sheet increases, the artifact due to the bismuth sheet in the CT image increases.

  Subsequently, the results of the average score of the visual evaluation of the three radiological diagnosis specialists using the phantom CT images shown in FIGS. 12 to 14 will be described with reference to FIG. FIG. 15 is a table showing the results of the average points of the bismuth distance, the number of bismuth sheets, and the visual evaluation of three radiological diagnosis specialists. The number of bismuth sheets represents the thickness of the bismuth sheet, and bismuth sheets 1 to 5 correspond to thicknesses 1 to 5, respectively.

  In FIG. 15, in the case of each of 1 to 5 bismuth sheets, the average when three radiological diagnosis specialists visually evaluated the phantom CT images obtained when the bismuth distance was increased from 0 to 5 mm. A dot is displayed. Here, when there is one bismuth sheet and the bismuth distance is 30 mm or more, the average score of the visual evaluation is 5. Similarly, when there are two bismuth sheets and the bismuth distance is 65 mm or more, the average score of the visual evaluation is 5. Similarly, when there are three bismuth sheets and the bismuth distance is 115 mm or more, the average score of the visual evaluation is 5. Similarly, when the number of bismuth sheets is four and the bismuth distance is 140 mm or more, the average score of the visual evaluation is 5. Similarly, when there are five bismuth sheets and the bismuth distance is 165 mm or more, the average score of the visual evaluation is 5.

The distance between the bismuth sheet or the cover containing bismuth and the surface of the pad that touches the subject's face is d [mm], the load of bismuth [g / cm2] is g, and the average point of the visual evaluation (hereinafter, S) is also referred to as a score.
Score S is calculated using g and d
S = p00 + p10 × d + p01 × g + p20 × d ² + p11 × d × g + p02 × g ²
Can be approximated by If the data in the table of FIG. 15 is used, the parameters of this approximate expression are as follows. The contents in parentheses are 95% confidence intervals.

p00 = 3.463 (3.057, 3.87)
p10 = 0.03817 (0.03351, 0.04283)
p01 = -0.2749 (-0.345, -0.2048)
p20 = -0.000154 (-0.0001738, -0.0001342)
p11 = 0.00117 (0.0009518, 0.001387)
p02 = 0.002361 (-0.0008424, 0.005565)

  Therefore, the approximate expression is expressed as follows.

S = 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ² (1)

  FIG. 16 is a graph showing the data in the table of FIG. 15 and the approximate expression (1). FIG. 15 shows a plot of data in the table of FIG. 15, and the above approximate expression (1) is shown as an approximate curved surface.

  FIG. 17 is a graph showing the relationship between bismuth load and bismuth distance for each score. In FIG. 17, a curve C1 is a curve showing the relationship between the bismuth load and the bismuth distance when the score is 3.5. Similarly, the curve C2 is a curve showing the relationship between the bismuth load and the bismuth distance when the score is 4.0. Similarly, the curve C3 is a curve showing the relationship between the bismuth load and the bismuth distance when the score is 4.5. Similarly, the curve C4 is a curve showing the relationship between the bismuth load and the bismuth distance when the score is 4.7. Similarly, the curve C5 is a curve showing the relationship between the bismuth load and the bismuth distance when the score is 4.9. Similarly, the curve C6 is a curve indicating the criticality where the score is 5.0. If the coordinate is a set of a bismuth load and a bismuth distance, located in the area above the curve C6, the score is 5.0.

  For example, when the measurement distance is 30 mm, the bismuth load is 14 g / cm 2 or more for the score to be 5.

In the head CT inspection goggles according to the present embodiment, the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that touches the face of the subject is defined as d.
Since interpretation requires at least a score of 3 or more, in order to obtain a score of 3 or more, d and g must be at least
3 ≤ 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ²
Meet.

As an example of this, when the bismuth load of the cover containing bismuth sheet or bismuth is 3.4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that faces the subject's face is It is at least 15 mm or more.

To get a score of 5 with no artifacts, the (d, g) coordinates are
5 = 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ²
Located above the curve representing the function of.

As an example of this, when the bismuth load of the cover containing bismuth sheet or bismuth is 3.4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that faces the subject's face is 30 mm or more.

  Subsequently, a CT image of a phantom is compared in the case of a bismuth sheet, a multi-element composite-lead-containing sheet, and a multi-element composite-lead-free sheet with reference to FIGS. Multi-elements include metals such as copper.

  FIG. 18 is a comparison of phantom CT images at a distance of 0 mm from a radiation shield such as bismuth. FIG. 19 is a comparison of CT images of a phantom at a distance of 10 mm from a radiation shield such as bismuth. FIG. 20 is a comparison of CT images of a phantom at a distance of 20 mm from a radiation shield such as bismuth. FIG. 21 is a comparison of CT images of a phantom at a distance of 30 mm from a radiation shield such as bismuth.

  18 (A), FIG. 19 (A), FIG. 20 (A), and FIG. 21 (A), the thickness of the bismuth sheet is 1 mm, and FIG. 18 (B), FIG. 19 (B), FIG. B) and FIG. 21B show the thickness of the bismuth sheet is 2 mm. FIGS. 18C, 19C, 20C, and 21C show the thickness of the bismuth sheet. Is 3 mm. FIGS. 18D, 19D, 20D, and 21D are multi-element composite-lead-containing sheets (thickness 0.4 mm, lead equivalent 0.13 mmPb). FIGS. 18E, 19E, 20E, and 21E are multi-element composite-lead-free sheets (thickness 0.4 mm, lead equivalent 0.13 mmPb). 18 (F), FIG. 19 (F), FIG. 20 (F), and FIG. 21 (F) are multi-element composite-lead-free sheets (thickness 0.8 mm, lead equivalent 0.25 mmPb).

Here, as an example, the bismuth sheet having a thickness of 1 mm is a case where the bismuth sheet having a bismuth load of 3.4 g / cm ² (thickness 1 mm) is one sheet, and the bismuth sheet having a thickness of 2 mm is Two bismuth sheets having a thickness of 1 mm are stacked, and a bismuth sheet having a thickness of 3 mm is a stack of three bismuth sheets having a thickness of 1 mm.

  When comparing FIGS. 18A to 18F in the case where the distance from the radiation shielding object such as bismuth is 0 mm, artifacts are formed in the CT image. Bismuth sheet thickness 2 mm, 3 mm, multi-element composite-lead-containing sheet (thickness 0.4 mm), multi-element composite-lead-free sheet (thickness 0.4 mm), multi-element composite-lead-free sheet (thickness 0. In the case of 8 mm), the artifact is large.

  19A to 19F when the distance to the radiation shielding material such as bismuth is 10 mm, the thickness of the bismuth sheet is 1 mm, and the multi-element composite-lead-free sheet (thickness 0.4 mm) Some artifacts appear. When the thickness of the bismuth sheet is 2 mm, 3 mm, the multi-element composite-lead-containing sheet (thickness 0.4 mm), and the multi-element composite-lead-free sheet (thickness 0.8 mm), the artifact is large.

  20A to 20F when the distance to the radiation shielding material such as bismuth is 20 mm, the thickness of the bismuth sheet is 1 mm, and the multi-element composite-lead-free sheet (thickness 0.4 mm) There are almost no artifacts. Artifacts appear in the thickness of the bismuth sheet of 2 mm and 3 mm, the multi-element composite-lead-containing sheet (thickness 0.4 mm), and the multi-element composite-lead-free sheet (thickness 0.8 mm).

  21A to 21F when the distance to the radiation shielding object such as bismuth is 30 mm, the thickness of the bismuth sheet is 1 mm, and the multi-element composite-lead-free sheet (thickness 0.4 mm) There are almost no artifacts. Bismuth sheet thicknesses of 2 mm and 3 mm, multi-element composite-lead-free sheet (thickness 0.8 mm) and multi-element composite-lead-containing sheet (thickness 0.4 mm) show some artifacts.

  FIG. 22 is a graph showing the relationship between the distance from a radiation shield such as bismuth and the average point of visual evaluation of three radiological diagnosis specialists. In FIG. 22, a broken line L11 represents an average point of visual evaluation in the case of one bismuth sheet, a broken line L12 represents an average point of visual evaluation in the case of two bismuth sheets, and a broken line L13 represents a case of three bismuth sheets. Represents the average score of visual evaluation. The polygonal line L14 represents the average point of visual evaluation in the case of a multi-element composite-lead-containing sheet (thickness 0.4 mm), and the polygonal line L15 represents the vision in the case of a multi-element composite-lead-free sheet (thickness 0.4 mm). The average point of evaluation is represented, and the broken line L16 represents the average point of visual evaluation in the case of a multi-element composite-lead-free sheet (thickness 0.8 mm).

When compared from the viewpoint of visual evaluation, one bismuth sheet is most preferable, and then a multi-element composite-lead-free sheet (thickness 0.4 mm) is next preferable. Next, two bismuth sheets or a multi-element composite-lead-containing sheet (thickness 0.4 mm) is preferable. Next, three bismuth sheets or a multi-element composite-lead-free sheet (thickness 0.8 mm) is preferable.
When comparing multi-element composite-leaded sheet (thickness 0.4 mm) and multi-element composite-lead-free sheet (thickness 0.4 mm), multi-element composite-lead-free sheet (thickness 0.4 mm) Since visual evaluation is good, it is preferable that the sheet does not contain lead.

  FIG. 23 is a graph showing the relationship between the distance from a radiation shield such as bismuth and the exposure reduction amount, and the relationship between the bismuth distance and the average point of visual evaluation of three radiological diagnosis specialists. The broken line L21 represents the exposure reduction amount in the case of the multi-element composite-lead-free sheet (thickness 0.4 mm), the broken line L22 represents the exposure reduction amount in the case of one bismuth sheet, and the broken line L23 represents one bismuth sheet. In this case, the average point of visual evaluation is represented, and the broken line L24 represents the average point of visual evaluation in the case of a multi-element composite-lead-free sheet (thickness 0.4 mm).

  When comparing one bismuth sheet and a multi-element composite-lead-free sheet (thickness 0.4 mm) at the same measurement distance, the exposure reduction is better with a multi-element composite-lead-free sheet, but one bismuth sheet is better for visual evaluation. Therefore, it is desirable that bismuth is included when considering the influence of artifacts on diagnosis.

  FIG. 24 is a schematic diagram of a cross section of the head approximated by an ellipse and a schematic diagram of a cross section of the head CT inspection goggles. FIG. 24 shows the cover 13 and the bismuth sheet 13b attached to the surface of the cover 13 in the head CT inspection goggles. As shown in FIG. 24, the major axis is defined as a, the minor axis is defined as b, and the distance (width) from the median to one end of the bismuth sheet is defined as w. Let θ be the angle formed by a straight line from the elliptical point P perpendicular to the major axis to the center of the ellipse and the major axis.

  An approximate expression of the major axis a [mm] and the minor axis b [mm] obtained from the regression analysis based on the actual CT data is expressed by the following formula.

a = 9.733 × 10 ^-3 × Age + 126.8
b = 7.731 × 10 ^-3 × Age + 112.7

  Here, Age is the number of days since birth. For example, if the subject is a 15th birthday, the number of days after birth is 5475, so the major axis a of the head is estimated to be 180 mm and the minor axis b is estimated to be 140 mm.

  Subsequently, the distance w from the median to one end of the bismuth sheet is expressed by the following equation.

  w = a × sin (t)

  Here, the parameter t is expressed by the following equation.

  t = arctan ((b / a) tan (θ))

  Since the chord length d of the bismuth sheet is twice the distance w, it is expressed by the following equation.

  d = 2 × a × sin (t)

  In a child up to 15 years old, the outer edge of the lens is located at 35 degrees from the midline of the face. Therefore, when the subject is a child under 15 years old, the cover containing bismuth sheet or bismuth according to this embodiment is the midline of the subject. Is preferably at least 35 degrees to the left and right, and θ is preferably 0.61 radians or more corresponding to 35 degrees.

That is, when the width along the curve of the cover containing bismuth sheet or bismuth is the arc length, the major axis when the cross section of the head is approximated by an ellipse is a, the bismuth sheet when the minor axis is b The chord length d of the cover containing bismuth is expressed as t = arctan ((b / a) tan (θ)) where d = 2 × a × sin (t), and θ is at least 0.61 radians or more Assuming that the number of days after the birth of the subject is Age, it is expressed as a = 9.733 × 10 ⁻³ × Age + 126.8, b = 7.731 × 10 ⁻³ × Age + 112.7.

  Here, in the case of a child under 15 years of age, the size of the head increases with age, so the cover containing bismuth sheet or bismuth only needs to be wide enough to cover the outer edge of the 15-year-old lens. From the above formula, a = 180 mm and b = 140 mm may be used instead of the above formula using the estimated major axis 180 mm at the age of 15 and the minor axis 140 mm of the estimated head at the age of 15.

  In addition, in a child up to 15 years old, the outer wall of the orbit is located at 45 degrees from the midline of the face. Therefore, when the subject is a child under 15 years old, the cover containing the bismuth sheet or bismuth according to this embodiment is Since it is more preferable that it is configured to extend at least 45 degrees to the left and right with respect to the median line, θ is preferably 0.79 radians or more corresponding to 45 degrees.

That is, when the width along the curve of the cover containing bismuth sheet or bismuth is the arc length, the major axis when the cross section of the head is approximated by an ellipse is a, the bismuth sheet when the minor axis is b The chord length d of the cover containing bismuth is expressed as t = arctan ((b / a) tan (θ)) with d = 2 × a × sin (t), θ is 0.79 radians or more, Assuming that the number of days after birth of the subject is Age, it is expressed as a = 9.733 × 10 ⁻³ × Age + 126.8, b = 7.731 × 10 ⁻³ × Age + 112.7.

  Here, in the case of a child under 15 years of age, the size of the head increases with age, so the cover containing bismuth sheet or bismuth only needs to be wide enough to cover the outer edge of the 15-year-old lens. From the above formula, a = 180 mm and b = 140 mm may be used instead of the above formula using the estimated major axis 180 mm at the age of 15 and the minor axis 140 mm of the estimated head at the age of 15.

  As described above, the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

1 Head CT Inspection Goggles 11 Pad 12 Frame 13 Cover 14 Band 15 Display 16 Signal Line

Claims (8)

A head CT examination goggles that is worn when receiving a head CT scan and shields radiation,
A pad that hits the subject's face,
A cover on which a bismuth sheet is affixed or containing bismuth;
With
The distance between the bismuth sheet or the cover containing bismuth and the surface of the pad that contacts the face of the subject is d [mm], and the bismuth load of the cover containing the bismuth sheet or bismuth [g / cm ² ] Is g, d and g are at least
3 ≤ 3.463 + 0.03817 × d -0.2749 × g -0.000154 × d ² + 0.00117 × d × g + 0.002361 × g ²
Goggles for head CT inspection satisfying the requirements. When the load of bismuth of the bismuth sheet or the cover containing bismuth is 3.4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that faces the subject's face is: The goggle for head CT inspection according to claim 1, wherein the goggles are at least 15 mm or more. (D, g) coordinates are
5 = 3.463 + 0.03817 x d -0.2749 x g -0.000154 x d ² + 0.00117 x d x g + 0.002361 x g ²
The head CT examination goggles according to claim 1, wherein the goggle is located above a curve representing a function of the head CT examination. When the load of bismuth of the bismuth sheet or the cover containing bismuth is 3.4 g / cm ² , the distance between the cover containing the bismuth sheet or bismuth and the surface of the pad that faces the subject's face is: The head CT inspection goggles according to claim 3, which is 30 mm or more. A display that is curved and fixed to the inside of the cover and capable of displaying an image toward the inside of the head CT inspection goggles;
The head CT examination goggles according to any one of claims 1 to 4, wherein the display displays an image based on an image signal input from the outside. The subject is a child under 15 years old,
The bismuth sheet or bismuth when the major axis is a and the minor axis is b when the width along the curvature of the cover containing the bismuth sheet or the bismuth is an arc length, The chord length d of the cover including is expressed as t = arctan ((b / a) tan (θ)) where d = 2 × a × sin (t), and θ is at least 0.61 radians or more, When the number of days after birth of the subject of interest and ^{Age, a = 9.733 × 10 -3} × Age + 126.8, any one of claims 1 to 5 represented by ^{b = 7.731 × 10 -3 × Age} + 112.7 Head goggles for CT examination according to one item. A head CT examination method comprising a step of performing a head CT scan on a subject wearing the head CT examination goggles according to any one of claims 1 to 6. A head CT scan is performed on a subject wearing the head CT examination goggles according to claim 5, and an image is displayed on the display during the head CT scan. CT examination method.