JP2801767B2 - Phantom for tomograph - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a phantom for a tomographic apparatus,
In particular, the present invention relates to a phantom for a tomographic apparatus that performs evaluation and correction of characteristics in a Z-axis direction of a tomographic apparatus that scans by a spiral scan method or the like.

[Prior Art] Conventionally, as a phantom for a tomographic apparatus of a spiral scan type such as a helical scan of this type, for example, December 1989
Arranging lead or beads at random and scanning it on pages 247 to 249 of “The Basic Study of CT 9th Report”, Vol. 16, No. 3, Issued on March 31 Discloses a phantom for a tomographic apparatus for evaluating and correcting characteristics of the tomographic apparatus.

[Problems to be Solved by the Invention] A conventional phantom for a tomographic apparatus such as a spiral scan method arranges a lead ball or a bead ball arbitrarily and scans it. If the position of the central axis changes, it may not be possible to determine whether the result of the cross-sectional diagnosis is the influence of the diameter of the lead ball or the bead ball or the effect of the Z-axis volume effect.

In addition, when outputting a diagnosis result as a tomographic data value for each bit, it was necessary to clarify the environment line.
When a phantom molded of a synthetic resin was placed in the atmosphere, the environmental ray of the phantom could not be clearly imaged because there was no significant change in the X-ray mass absorption coefficient.

Therefore, an object of the present invention is to provide a phantom for a tomographic apparatus in which the characteristics of the tomographic apparatus in the Z-axis direction appear directly in the diagnosis result, and the boundary line of the phantom is clear.

[Means for Solving the Problems] A tomographic apparatus phantom according to the invention of claim 1 includes an annular body and a pyramid, a closed container body having a substantially uniform wall thickness and incorporating the annular body and the pyramid; It has a liquid or gas filled between the annular body and the pyramid and the closed container.

The tomographic apparatus phantom according to the second aspect of the present invention is an annular body and a plurality of spheres formed with the same diameter, a closed container body containing the annular body and the plurality of spheres, and having a substantially uniform thickness. The liquid or gas filled between the annular body and the spherical body and the closed container is provided.

The phantom for a tomographic apparatus according to the third aspect of the present invention is an annular body, a sphere, and a pyramid, a spirally-shaped body, a sphere, and a pyramid. A liquid or gas filled between the body and the closed container body.

The annular body according to any one of claims 1 to 3 of the phantom for a tomographic apparatus according to the invention of claim 4 is formed by alternately stacking a predetermined shape of a ring and a disc.

[Operation] In the invention according to claim 1, a pyramid in addition to an annular body is built in a closed container having a substantially uniform thickness, and a liquid or gas is supplied between the annular body and the pyramid and the closed container. Since it is filled, the outline of the annular body is clarified by the difference in the density of the liquid or gas and the annular body, and the outline of the pyramid is clarified by the difference in the density of the liquid or gas and the pyramid, In a closed container having a substantially uniform thickness, at specific locations, for example, discontinuity such as X-ray diffraction and X-ray absorption does not cause disturbance in tomographic data of the annular body and the pyramid. Then, the reliability of the tomographic data of the rapidly changing subject in the pyramid can be examined.

In the invention of claim 2, a plurality of spheres formed and arranged with the same diameter in addition to the annular body are housed in a closed container having a substantially uniform thickness, and the annular body and the sphere and the closed container are interposed. Is filled with liquid or gas, so that the spheres can be arranged on the same line and the spheres do not shift between the spheres, so the continuous tomographic data of the spheres are located on the same line, Examination of the tomographic data of the sphere becomes easy. And, while clarifying the outline of the annular body by the difference in the density of the liquid or gas and the sphere, clarifying the outline of the sphere by the difference in the density of the liquid or gas and the sphere, always by the continuous fault of the annular body and the sphere It is possible to obtain predetermined tomographic data having different tomographic positions. by this,
The cross section in the Z-axis direction can be reconstructed. In addition, the sealed container body having a substantially uniform thickness is provided at a specific location, for example,
Disorders such as X-ray diffraction and X-ray absorption do not disturb the tomographic data of the annular body and the spherical body.

According to the third aspect of the present invention, the annular body, the sphere and the pyramid are housed in a closed container having a substantially uniform thickness, and a liquid or gas is filled between the annular body, the sphere and the pyramid and the closed container. Therefore, the contours of the ring, sphere, and pyramid are clarified by the difference in density between the liquid or gas and the ring, sphere, and pyramid. Can be obtained, and the ball centers can be arranged on the same line, so that the ball centers do not shift between the balls. In addition, in a closed container having a uniform thickness, X-rays and the like are not disturbed at a specific location.
Then, the reliability of the tomographic data of the rapidly changing subject in the pyramid can be examined.

According to the fourth aspect of the present invention, the ring and the disk of a specific shape are alternately stacked, and the shapes of the cut surfaces of the ring and the disk by scanning are corrected with the actual ring and the disk. However, since it is only necessary that all the outer shapes have the same dimensions, the correction is easy.

[Example] Hereinafter, an example of the present invention will be described.

FIG. 1 is a sectional view showing a phantom for a tomographic apparatus according to a first embodiment of the present invention. FIG. 3 is a sectional view taken along section line XX of FIG.

In the figure, the spiral body 1 as the annular body of the present embodiment is made of a synthetic resin, and in particular, in this embodiment, the spiral body is made of a synthetic resin such as acrylic. The hermetically sealed container 2 is made of a synthetic resin. In the present embodiment, in particular, the hermetically sealed container 2 has a cylindrical shape having both end faces made of a synthetic resin such as acryl, has the spiral body 1 built therein, and has a uniform thickness. The liquid 4 of the present embodiment is provided between the spiral 1 and the closed container 2.
Is filled with water.

As described above, the phantom for a tomographic apparatus according to the present embodiment is a spiral body 1, a sealed container body 2 having the spiral body 1 built therein and having a uniform thickness, and is filled between the spiral body 1 and the sealed container body 2. Liquid 4.

The phantom for a tomographic apparatus according to the present embodiment usually has a spiral 1
In the direction perpendicular to the paper plane (not shown) of the tomographic apparatus (Z
(Axial direction).

In this state, when a test scan of the tomographic apparatus is started, the transmission condition of the X-rays to the spiral 1 is substantially the same as that of 360 degrees around the direction perpendicular to the length direction, and the same predetermined condition where the tomographic position is different is the same. It becomes shape tomographic data,
The characteristics of the tomographic device can be visually evaluated, and the characteristics of the tomographic device can be corrected based on the tomographic data of the spiral 1. That is, since the tomographic data of the spiral 1 has only the same relative angle with respect to the tomographic object in accordance with the difference in the tomographic position, the tomographic data has the same predetermined shape. Can be corrected.

In particular, even in a tomographic apparatus that scans the tomographic apparatus in the Z-axis direction at a speed of 5 [mm / s] by a helical scan method with a wide cutting interval of about 20 seconds, etc. If corrected, a cross section at any position between 10 [mm] widths can be obtained.

Further, as a result, it is only necessary to correct the tomographic position of the tomographic data of the spiral 1 so that the length direction of the spiral 1 and the Z-axis direction of the tomographic apparatus preferably coincide with each other. Even if the length direction of the sealed container body 2 does not exactly match the Z-axis direction of the tomographic apparatus, no error occurs thereby.

In the present embodiment, the spiral body 1 is disposed so as to be in contact with the closed container body 2. However, the spiral body 1 may be provided in the closed container body 2 by a predetermined support member formed of a synthetic resin such as acrylic. Good.

FIG. 2 is a sectional view corresponding to FIG. 1 of the phantom for a tomographic apparatus according to the second embodiment of the present invention, and FIG. 3 is a sectional view taken along a cutting line YY in FIG. In the drawings, the same reference numerals and symbols as those in the above-described embodiment denote the same or corresponding parts as those in the above-described embodiment.

In the figure, the spiral body 1 as an annular body of the present embodiment is made of a synthetic resin and has the same shape as the above embodiment.
Also, the sealed container body 12 is also made of synthetic resin,
In this embodiment, it is a rectangular parallelepiped (hollow prismatic shape) having both end faces formed of acrylic, and has the spiral body 1 built therein, and is integrally formed by a hexahedron 12b having a uniform thickness, and its side 12a
Is different from that of the hexahedron 12b having a uniform thickness. Therefore, the rectangular parallelepiped shape (hollow prismatic shape) having both end surfaces has a substantially uniform thickness. That is, it is formed by bonding six hexahedral plates having a uniform thickness.
The space between the spiral body 1 and the sealed container body 12 is filled with water as the liquid 4 of the present embodiment.

As described above, the phantom for a tomographic apparatus according to the present embodiment includes the spiral body 1, the rectangular parallelepiped closed container body 12 having the spiral body 1 built therein, and having a substantially uniform thickness, and the spiral body 1 and the closed container body 12.
And the liquid 4 filled between them.

The phantom for a tomographic apparatus of the present embodiment is easy to arrange at a predetermined position and stable because the lower surface of the sealed container 12 is flat.

Then, when a test scan of the tomographic apparatus is started in this installed state, the transmission condition of the X-rays to the spiral 1 is substantially the same as that of 360 degrees around the direction perpendicular to the length direction of the sealed container body 12. Strictly speaking, when irradiating from the direction of the rectangular parallelepiped side 12a, the tomographic data is slightly affected by the difference in thickness between the hexahedron 12b and the side 12a, and the X-ray diffraction
Although a difference occurs in the tomographic data due to discontinuities such as line absorption, the tomographic data has substantially the same shape, and the characteristics of the tomographic apparatus can be visually evaluated. In the same manner as described above, the tomographic plane of the tomographic apparatus can be corrected.

Further, similarly to the first embodiment, it is only necessary to correct the tomographic data tomographic position of the spiral 1 as a result, so that the length direction of the sealed container 12 and the Z-axis direction of the tomographic apparatus are different. Even if they do not exactly match, no error is caused.

FIG. 4 is a sectional view showing a phantom for a tomographic apparatus according to a third embodiment of the present invention, and is a view corresponding to FIG.
In the drawings, the same reference numerals and symbols as those in the above embodiments are used.
The figure shows the same or corresponding parts as the constituent parts of each of the above embodiments.

In the figure, the spiral body 11 as an annular body of the present embodiment is made of a synthetic resin. In particular, in the present embodiment, the spiral bodies 11 are closely connected to each other without gaps and have a spiral shape. Other configurations are the same as those of the above embodiments.

As described above, the phantom for a tomographic apparatus according to the present embodiment includes the spiral body 11 having a dense spiral shape without a gap, and the spiral body 11
A sealed container body 2 having a substantially uniform wall thickness and a liquid 4 filled between the spiral body 11 and the sealed container body 2 are provided.

Therefore, similarly to the above embodiments, when the test scan of the tomographic apparatus is started in the installed state, the transmission condition of the X-ray to the spiral body 11 is set in the longitudinal direction of the closed container 2 in the same manner as in each of the above embodiments. Around the vertical direction is substantially the same condition as 360 degrees, and the tomographic data has substantially the same shape although the tomographic positions are different from each other, so that the characteristics of the tomographic apparatus can be visually evaluated. The tomographic data can be used to correct the tomographic plane of the tomographic apparatus as in the first and second embodiments.

In particular, the spiral body 11 may be formed by appropriately changing the spiral pitch, the thickness of the cross section, and the spiral direction of the spiral body 11 according to the cutting interval of the spiral scanning type tomographic apparatus.
A desired correction of the characteristics of the tomographic apparatus based on the tomographic data can be performed.

For example, by making the helical pitch of the helical body 11 different from the helical pitch of the helical scan type tomographic apparatus, the tomographic data of the helical body 11 has the same shape in which the relative angle to the tomographic object differs according to the difference in the tomographic position. Therefore, the tomographic plane of the tomographic apparatus can be corrected using the difference in the relative angle. Further, when the spiral pitch of the spiral 11 is the same as the spiral pitch of the spiral scanning type tomographic apparatus, the tomographic data of the spiral 11 at all the tomographic positions,
Since the same tomographic data is obtained for both the relative angle and the shape of the tomographic object, the tomographic plane of the tomographic device cannot be corrected,
It is possible to confirm whether or not there is a deviation in the helical pitch of the tomographic apparatus.

Further, even when the spiral direction of the spiral body 11 and the spiral direction of the spiral scan type tomographic apparatus are set to opposite directions, the spiral direction of the spiral body 11 and the spiral direction of the spiral scan type tomographic apparatus are set as described above. The same effect as in the case of the same direction is obtained. That is, by making the helical pitch of the helical body 11 different from the helical pitch of the helical scan type tomographic apparatus, the tomographic data of the helical body 11 has the same phase angle with the to-be-tomected body in accordance with the difference in the tomographic position. Since it becomes the tomographic data of the shape, the tomographic plane of the tomographic apparatus can be corrected. Also,
When the helical pitch of the helical body 11 is the same as the helical pitch of the helical scan type tomographic apparatus, the tomographic data of the helical body 11 has the same relative angle and shape with respect to the tomographic body at any tomographic position. Since the data is data, it is possible to confirm whether or not there is a deviation in the helical pitch of the tomographic apparatus. However, when the spiral direction of the spiral body 11 and the spiral direction of the spiral scan type tomographic apparatus are set to opposite directions, the spiral body
The eleventh tomographic data has a smaller tomographic area than the tomographic data when the spiral direction is the same.

FIG. 5 is a sectional view showing a phantom for a tomographic apparatus according to a fourth embodiment of the present invention. In the drawings, the same reference numerals and symbols as those of the above-described embodiments indicate the same or corresponding parts as those of the above-described embodiments.

In the figure, the spiral body 1 as an annular body of the present embodiment is made of a synthetic resin and has the same shape as the above embodiment.
Each of the pyramids 21A and 21B is made of a synthetic resin, and in particular, in this embodiment, is a quadrangular pyramid formed of acrylic. Others
The configuration is the same as each of the above embodiments.

As described above, the phantom for a tomographic apparatus according to the present embodiment includes the spiral 1 and the pyramids 21A and 21B, and the spiral 1 and the pyramid 2
It comprises a sealed container body 2 containing 1A and 21B and having a uniform thickness, and a liquid 4 filled between the spiral body 1 and the pyramids 21A and 21B and the sealed container body 2.

Therefore, when the tomographic device phantom of the present embodiment is also placed in the installed state and the test scan of the tomographic device is started,
The X-ray transmission conditions for the spiral 1 and the pyramids 21A and 21B are 360 degrees around the vertical direction to the longitudinal direction of the closed container 2.
Under the same conditions, the tomographic data is less likely to be disturbed due to discontinuities such as X-ray diffraction and X-ray absorption as in the above embodiments. The characteristics can be evaluated, and the tomographic plane of the tomographic apparatus can be corrected based on the tomographic data.
In particular, the reliability of the tomographic data of the subject that rapidly changes in the length direction of the pyramids 21A and 21B can be examined by the pyramids 21A and 21B.

By the way, in the above-described embodiment, the case where one spiral 1 and two pyramids 21A and 21B are provided has been described, but one spiral 1 and one pyramid may be used. In the embodiment in which the spiral 1 and the plurality of pyramids 21A and 21B are housed, the pyramids 21A and 21B can have the same shape or different sizes. Preferably, in any of the embodiments, the axis is arranged on a straight line. In the pyramid 21, the inclination of the two or four surfaces may be different.

FIG. 6 is a sectional view of a phantom for a tomographic apparatus according to a fifth embodiment of the present invention. In the drawings, the same reference numerals and symbols as those of the above-described embodiments indicate the same or corresponding parts as those of the above-described embodiments.

In the figure, the sphere 31A and the sphere 31B are made of synthetic resin, and in this embodiment, are spheres formed of acrylic. The sphere 31A has a smaller diameter than the sphere 31B,
The spheres 31A and 31B are arranged such that their centers are on the same straight line. The closed container 2 is made of a synthetic resin, and is made of acrylic in the present embodiment.
The sphere 31A and the sphere 31B are contained therein, and are further filled with water as the liquid 4 of the present embodiment.

As described above, the phantom for a tomographic apparatus according to the present embodiment includes one spiral body 1 as an annular body according to the present embodiment and a plurality of 2 spiral bodies.
A row of spheres 31A and a row of spheres 31B arranged in rows, a sealed container body 2 containing the helical body 1, spheres 31A and spheres 31B and having a uniform thickness, and the helical body 1, spheres 31A and spheres 31B And a liquid 4 filled between the container 2 and the closed container 2.

When the tomographic device phantom of the present embodiment is also placed in the installed state and scanning of the tomographic device is started, the spiral 1 and the sphere 31A
And the transmission condition of the X-ray to the sphere 31B is substantially the same condition as 360 degrees, the tomographic data of the spiral 1 has a predetermined shape,
The tomographic data of the sphere 31A and the sphere 31B are circular, and the characteristics of the tomographic apparatus can be visually evaluated, and the tomographic plane of the tomographic apparatus can be corrected based on the tomographic data.

FIG. 7 is a sectional view of a phantom for a tomographic apparatus according to a sixth embodiment of the present invention. In this embodiment, the embodiment shown in FIGS. 5 and 6 is basically synthesized. In the drawing, the same reference numerals and symbols as those in the above-described embodiments indicate the same or corresponding parts as the components in the above-described embodiments.

The phantom for a tomographic apparatus according to the present embodiment is arranged in one spiral 1 as an annular body in this embodiment, a plurality of rows of spheres 31A and a plurality of rows of spheres 31B arranged in two rows, and two rows. The pyramid 21A and the pyramid 21B, the spiral body 1, the spherical body 31A and the spherical body 31B, the sealed container body 2 having the built-in pyramid 21A and the pyramid 21B and having a uniform thickness, and the spiral body 1, the spherical body 31A and the spherical body 31B, a pyramid 21A, and a liquid 4 filled between the pyramid 21B and the closed container 2.

When the tomographic device phantom of the present embodiment is also placed in the installed state and scanning of the tomographic device is started, the spiral 1 and the sphere 31A
X-ray transmission conditions for the sphere 31B, the pyramid 21A, and the pyramid 21B are substantially the same as 360 degrees, the tomographic data of the spiral 1 has a predetermined shape, and the tomographic data of the sphere 31A and the sphere 31B have a circular shape. Pyramid 21A and pyramid 21B
Of the tomographic device can be visually evaluated, and the tomographic plane of the tomographic device can be corrected based on the tomographic data.

In each of the above embodiments, the spiral body 1 has been used as the annular body. However, the present invention is not necessarily limited to the spiral body 1 when practicing the present invention. FIG. 8 shows an example.

FIG. 8 is a development view of a laminated body of a phantom for a tomographic apparatus according to a seventh embodiment of the present invention. In the drawings, the same reference numerals and symbols as those of the above-described embodiments indicate the same or corresponding parts as those of the above-described embodiments.

In FIG. 8, a ring 51 as an annular body of the present embodiment is shown.
In this embodiment, the A and the disc body 51B are formed of a synthetic resin such as acrylic. These are a laminated body 51 in which a ring 51A and a disk body 51B are alternately joined and integrated. The stacked body 51 of the ring 51A and the disk body 51B can be directly used as a phantom for a tomographic apparatus in a stacked state.

Further, a hollow body 51a inside the ring 51A, which is a laminated body 51 of the ring 51A and the disc body 51B, filled with water as the liquid 4 of the present embodiment can be used as a phantom for a tomographic apparatus. .

Then, a cavity 51a inside the ring 51A, which is a laminated body 51 of the ring 51A and the disc body 51B, is filled with water as the liquid 4 of the present embodiment, or is not filled with water,
It can be sealed in a cylindrical closed container 2 (not shown) having both end faces formed of a synthetic resin such as acrylic.
Of course, the space between the laminate 51 of the ring 51A and the disk 51B and the closed container 2 (not shown) may be filled with the liquid 4.

That is, the ring 51A and the disk 51B as the annular body can be used in place of the spiral body 1 as the annular body in each of the above embodiments.

As shown in FIG. 8, the ring 51A and the disc 51B
Scans the result as shown in the characteristic diagram of Fig. 9.
The fact that the transmittance changes depending on the joint between the 51A and the disk body 51B, and the positions of the maximum and minimum points of the transmittance are clarified by the spiral scan.

According to the characteristic diagram of FIG. 9, the laminated body 51 of the present embodiment actually used is a disk body 51B having a thickness of 5 [mm] at the left end, and a ring of 5 [mm] thickness, 5 [mm]. mm] thick disk 51B, 5 [m
m] thick ring, 3 [mm] thick disk 51B, 3 [mm] thick ring 51A, 3 [mm] thick disk 51B, 3 [mm] thick ring 51A, 5 [mm] This is an actual measurement value obtained by laminating the disk with the thick disk 51B and scanning them spirally. According to this, although a slight error is recognized between the traveling direction of the spiral scan and the phantom for the tomographic apparatus, the position of the 5 [mm] thick disk 51B at 10 [mm] from the left. If the data is removed, it can be considered that the position of the phantom for the tomographic apparatus is almost continuously expressed.

Therefore, the ring 51A and the disc 51B as the annular body
Accordingly, the same effect as the spiral body 1 of each of the above embodiments can be obtained. Further, the possibility of ignoring the value of the end portion makes it possible to adopt a shape that allows the end disk member 51B to be stably placed in the tomographic apparatus.

Note that, in the present embodiment, the case of the laminated body 51 in which the ring 51A and the disk body 51B are alternately laminated has been described, but in the case where the present invention is practiced, the ring 51A or the disk body 51B is a cylindrical container. They may be arranged on the body at a predetermined pitch.

The phantom for a tomographic apparatus according to the present embodiment is generally arranged such that the length direction of the environment body including the spiral body 1, the ring 51A, and / or the disk body 51B is aligned with the Z-axis direction of the tomographic apparatus.

In this state, when the test scan of the tomographic apparatus is started, the transmission condition of the X-rays to the annular body including the spiral 1, the ring 51A and / or the disc 51B, and the like is determined around the direction perpendicular to the length direction. The conditions are substantially the same as 360 degrees, and the tomographic data has the same predetermined shape with different tomographic positions. The characteristics of the tomographic apparatus can be numerically evaluated. In addition, the spiral 1, ring 51A and / or disk The characteristics of the tomographic apparatus can be corrected based on the tomographic data of the annular body composed of 51B or the like. That is, the spiral 1 and the ring 51
Since the tomographic data of the annular body composed of the A and / or the disc 51B or the like has only a different relative angle to the tomographic object in accordance with the difference in the tomographic position, the tomographic data has the same predetermined shape.
From the difference in the relative angle, the tomographic plane of the tomographic apparatus can be corrected.

In particular, the movement of the tomograph in the Z-axis direction is performed at a speed of [mm / s].
Even with a tomographic apparatus that scans using a spiral scan method with a wide cutting interval of about 20 seconds, if the cut position is corrected from the cut section, a cut section at an arbitrary position between 10 [mm] widths can be obtained. be able to.

Further, as a result, it is only necessary to correct the tomographic position of the tomographic data of the annular body composed of the spiral 1, the ring 51A and / or the disk 51B, etc., so that the spiral 1, the ring 51A and / or the circle It is desirable that the length direction of the annular body composed of the plate 51B and the like coincides with the Z-axis direction of the tomographic apparatus. If not, this does not cause an error.

In the present embodiment, the annular body composed of the spiral body 1, the ring 51A and / or the disc body 51B and the like is disposed in contact with the closed container body 2. However, a predetermined support member formed of a synthetic resin such as acrylic is used. Alternatively, the annular body may be disposed in the closed container 2.

By the way, the sphere of the phantom for the tomographic apparatus of the above embodiment
31A and 31B are solid synthetic resin spheres. However, when the present invention is implemented, the hollow or the center thereof may be filled with a material of another density to form a multilayer structure. In any case, when practicing the present invention, the accuracy of the spheres of the spheres 31A and 31B may be determined according to the characteristics of the tomographic apparatus in the Z-axis direction and the intended use, and any sphere can be used.

Further, the sealed container bodies 2 and 12 having substantially uniform thickness of the phantom for the tomographic apparatus of the above embodiment are cylindrical with both end faces, or rectangular parallelepiped (hollow prismatic shape) with both end faces, or
For example, a hexahedron having a uniform thickness may be integrally formed, the corners thereof may be formed into a smooth curved surface, and a substantially rectangular parallelepiped (hollow prismatic) having the same thickness as the hexahedron may be used.

When the present invention is carried out, it is limited to a cylindrical shape having both end surfaces, a rectangular parallelepiped shape having both end surfaces (hollow prismatic shape), or a substantially rectangular parallelepiped shape having substantially chamfered corners (substantially hollow prismatic shape). Instead, the container may have a closed structure and a substantially uniform thickness. However, when implementing the present invention, it is desirable that the closed container has a configuration in which any of the 360-degree surrounding transmission coefficients are unchanged.

Further, the liquid 4 filled in the closed container body of the phantom for a tomographic apparatus of the above embodiment uses water in the present embodiment, but in the case of implementing the present invention, the pyramids 21A and 21B, the spheres Any liquid or gas having a different density from that of 31A, 31B and sealed container bodies 2, 12 may be used.

Furthermore, although the pyramids 21A and 21B of the phantom for the tomographic device of the above embodiment are solid synthetic resin spheres,
When practicing the present invention, the hollow or its center may be filled with a material of another density to form a multilayer structure. In any case, when implementing the present invention, the inclination and accuracy of the pyramids 21A and 21B may be determined according to the characteristics of the tomographic apparatus in the Z-axis direction and the intended use.

In addition, the sealed container body constituting the phantom for the tomographic apparatus of the present invention has a sealed structure suitable for portability,
When implementing this type of tomographic device phantom, an open container can be used. Further, the liquid of this embodiment can be replaced with a gas (gas) such as xenon gas.

The ring, the disk, and the spiral as an annular body in each of the above embodiments can have a substantially circular or substantially elliptical or substantially rectangular cross section.

Furthermore, in the closed container having a substantially uniform thickness of the present invention,
The area around the direction perpendicular to the length direction is formed in a substantially rectangular parallelepiped shape having a substantially uniform thickness, and the area around the direction perpendicular to the length direction is formed into a substantially cylindrical shape having an approximately uniform thickness. Can be implemented. The annular body of the present invention may be embodied as a ring or disk having a predetermined shape, a ring in which a ring and a disk having a predetermined shape are alternately stacked, or a spiral.

[Effects of the Invention] As described above, the tomographic apparatus phantom according to the first aspect of the present invention is built in a closed container having a substantially uniform thickness in addition to the annular body, and the pyramid is provided with the annular body and the pyramid body. With a simple configuration in which a liquid or a gas is filled between the closed container and the closed container, it is possible to examine the reliability of tomographic data based on the cutting width of the subject, which changes rapidly due to the pyramidal tomographic structure. And, as described above, while clarifying the outline of the annular body by the difference in the density of the liquid or gas and the annular body, clarifying the outline of the pyramid by the difference in the density of the liquid or gas and the pyramid, The closed container body having a uniform thickness does not have discontinuous points such as diffraction and absorption at a specific location, and does not cause disturbance in tomographic data.

The phantom for a tomographic apparatus according to the second aspect of the present invention is characterized in that a plurality of spheres formed and arranged with the same diameter in addition to the spiral body are housed in a closed container having a substantially uniform thickness, and the annular body and the sphere and the closed container are connected to each other. With the simple configuration that liquid or gas is filled between the spheres, the spheres can be arranged on the same line, and the spheres do not shift between the spheres, so the tomographic data is that the spheres are located on the same line, Examination of the fault data becomes easy. In addition to clarifying the outline of the annular body by the difference in the density of the liquid or gas and the annular body, clarifying the outline of the sphere by the difference in the density of the liquid or gas and the spherical body, the tomography of the predetermined shape is always performed by the annular body fault Since data can be obtained and circular tomographic data can always be obtained from a spherical tomographic section, a cross section in the Z-axis direction can be reconstructed from these data, and characteristics in the Z-axis direction can be evaluated and corrected. In addition, the sealed container body with a substantially uniform thickness is
For example, disturbance in tomographic data due to discontinuity such as diffraction and absorption does not occur.

The phantom for a tomographic apparatus according to the third aspect of the present invention includes a ring-shaped body, a spherical body, and a pyramid built in a closed container having a substantially uniform thickness, and a liquid between the ring-shaped body, the spherical body, and the pyramid and the closed container. Or with a simple configuration of gas filling,
These tomographic data can be obtained at the same time by the tomograms of the annular body, the sphere, and the pyramid, and the spheres can be arranged on the same line, so that the spheres do not shift between the spheres. In addition, the reliability of the tomographic data can be examined based on the cutting width of the subject that changes rapidly due to the pyramidal tomographic structure. In the closed container body having a uniform thickness, disturbance due to discontinuity such as diffraction and absorption does not occur at a specific location.

A phantom for a tomographic apparatus according to a fourth aspect of the present invention is obtained by alternately stacking a predetermined shape of a ring and a disc.
The correction between the shapes of the cut surfaces of the ring and the disk by scanning and the actual ring and the disk may be performed so that both outer shapes have the same dimensions, and therefore, the correction is facilitated.

[Brief description of the drawings]

FIG. 1 is a sectional view showing a phantom for a tomographic apparatus according to a first embodiment of the present invention. FIG. 2 is a sectional view corresponding to FIG. 1 of the phantom for a tomographic apparatus according to a second embodiment of the present invention. FIG. 4 is a cross-sectional view taken along a cutting line XX in FIG. 1 and a cutting line YY in FIG. 2, FIG. 4 is a cross-sectional view showing a phantom for a tomographic apparatus according to a third embodiment of the present invention, and FIG. FIG. 6 is a sectional view showing a phantom for a tomographic apparatus according to a fourth embodiment of the present invention, FIG. 6 is a sectional view showing a phantom for a tomographic apparatus according to a fifth embodiment of the present invention, and FIG. FIG. 8 is a sectional view showing a phantom for a tomographic apparatus, FIG. 8 is a development view of a laminated body of the phantom for a tomographic apparatus according to a seventh embodiment of the present invention, and FIG. FIG. In the figure, 1: spiral 21A, 21B: pyramid 31A, 31B: sphere 2, 12: closed container 4: liquid 51: laminated body 51A: ring 51B: disk. In the drawings, the same reference numerals and symbols indicate the same or corresponding parts.

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) A61B ^6/ 00-6/14 A61B 5/055

Claims (4)

(57) [Claims] An annular body, a pyramid, a sealed container body containing the annular body and the pyramid, and having a uniform thickness in a direction perpendicular to the length direction thereof; and the annular body and the pyramid. A phantom for a tomographic apparatus, comprising: a liquid or a gas filled between the container and a closed container. 2. An annular body, a plurality of spheres formed and arranged with the same diameter, a closed container body containing the annular body and the plurality of spheres and having a substantially uniform thickness, and the sphere and the closed container body. A phantom for a tomographic apparatus, comprising: a liquid or a gas filled between the two. 3. An annular body, a sphere, and a pyramid; a closed container body containing the annular body, a sphere, and a pyramid, and having a substantially uniform thickness; and the annular body, a sphere, a pyramid, and a closed container. A phantom for a tomographic apparatus, comprising: a liquid or a gas filled between the two. 4. The phantom for a tomographic apparatus according to claim 1, wherein the annular body is formed by alternately stacking a ring and a disk having a predetermined shape.