JP2012030035A - Phantom for determination of bone mineral quantity and cone beam x-ray ct apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a phantom for determination of bone mineral quantity capable of being used for a cone beam X-ray CT apparatus and correctly determining bone density in a dental implant treatment, and to provide the cone beam X-ray CT apparatus using it.SOLUTION: The phantom for determination of bone mineral quantity is used for a dental cone beam X-ray CT apparatus, and it has a soft tissue member comprising an equivalent material of a chin soft tissue and a bone block reference body which comprises hydroxyapatite in a resin at a fixed ratio and is buried in the soft tissue member, and it is characterized in that the shape of the phantom can be used for a chin rest. The bone block reference body preferably comprises a plurality of bone block reference bodies having variant contents of hydroxyapatite.

Description

 The present invention relates to a bone salt quantitative phantom and a cone beam X-ray CT apparatus used in a cone beam X-ray CT apparatus.

 In dentistry, it is important for diagnosis to know the conditions of the roots and bones of the jaws. For this reason, the conditions of the roots and the like are photographed mainly by simple X-ray photography and panoramic photography. However, when it is desired to know the situation of the affected area in more detail, these simple X-ray imaging and panoramic imaging are not sufficient, and an X-ray CT apparatus is used (for example, Patent Document 1).

 The X-ray CT apparatus includes a multi-slice CT (hereinafter referred to as “MSCT”) that irradiates a specimen with a band-shaped X-ray beam and a cone beam CT (hereinafter referred to as a cone-shaped or pyramid-shaped X-ray beam). "CBCT").

 The pixel value or voxel value obtained from the MSCT is considered to represent the absolute value of the bone density, and the bone density can be obtained directly from the measured value. On the other hand, pixel values and voxel values obtained from CBCT do not represent absolute values of bone density. For this reason, in order to measure the absolute value of the bone density, a bone mineral quantification phantom is measured at the same time, and the bone density is obtained by correction from the value.

The bone mineral quantification phantom is obtained by adding hydroxyapatite to a matrix resin such as urethane. For example, as shown in FIG. 8, from 20 blocks 101a to 101t containing 0 to 400 mg / cm ³ of hydroxyapatite. What is used.

JP-A-6-277214

 However, in the cone beam X-ray CT apparatus adopting the CBCT method, since the measurable region is narrow, it is difficult to install a large bone mineral quantification phantom having a length exceeding 200 mm. In addition, the cone beam X-ray CT apparatus has many scattered X-rays due to its characteristics, there are anatomical structures outside the imaging region, daily X-ray dose calibration is not performed, and the absolute value of bone density No measurements were made.

 The present invention has been made in view of the above-described conventional circumstances, and can be applied to a cone beam X-ray CT apparatus, and can accurately determine bone density in dental implant treatment or the like. It is another object of the present invention to provide a cone beam X-ray CT apparatus using the same.

 In dental implant treatment, it is necessary to measure the bone density to determine whether the implant can be attached to the jaw bone, but it is possible to embed the implant without obtaining the exact absolute value of the bone density. It suffices if it can be determined whether or not the threshold value of the bone density is exceeded. Inventors pay attention to this, and the type of bone block reference body can be reduced so that the bone mineral quantification phantom can be placed in a small measurement region, and the bone block reference phantom can be closely attached to the jaw so that there is no gap. We designed a bone mineral quantification phantom that can be shaped. And the jaw part of the patient who is going to perform an actual implant treatment was measured with the cone beam X-ray CT apparatus, and also compared with the measured value with the MSCT type X-ray CT apparatus. As a result, a simple proportional relationship is recognized between the measured values of the two, and it is possible to determine whether or not the bone density threshold at which the implant can be implanted is exceeded based on the measurement result of the cone beam X-ray CT apparatus. And found that it is possible enough.

 That is, the bone mineral quantification phantom according to the first aspect of the present invention is a bone mineral quantification phantom used in a dental cone beam X-ray CT apparatus, comprising a soft tissue member made of a soft tissue equivalent material of a jaw, and a hydroxyapatite resin. And a bone block reference body embedded in the soft tissue member, and has a shape that can be closely attached to the jaw so that there is no gap.

 The bone mineral density phantom of the present invention includes a soft tissue member made of a soft tissue equivalent material of a jaw, and a bone block reference body in which hydroxyapatite is contained in a predetermined ratio in a resin and embedded in the soft tissue member. Here, the soft tissue equivalent material of the jaw refers to a material having the same transmittance as that of the soft tissue of the jaw for X-rays. Since the bone block reference body contains hydroxyapatite, which is an actual tooth component, at a predetermined ratio, the bone block reference body exhibits a behavior close to that of an actual tooth. For this reason, the bone mineral quantification phantom of the present invention shows a behavior that is very similar to the transmission characteristics of an actual jaw with respect to X-rays, and can determine the bone density more accurately.

In addition, since the bone mineral quantification phantom of the present invention has a shape that can be closely attached to the jaw so that there is no gap, the cone beam X-ray transmittance is extremely high between the jaw and the phantom. There is no gap that tends to cause errors. For this reason, actual bone and tooth bone density can be measured more accurately.
Moreover, even if it is a dental cone beam X-ray CT apparatus with a small measurement area | region and the space where a phantom can be installed is narrow, a phantom can be installed.

 Therefore, the bone mineral quantification phantom of the present invention can be used in a cone beam X-ray CT apparatus, and can accurately determine the bone density in dental implant treatment.

 The bone salt quantification phantom according to the second aspect of the present invention has a shape that can be used as a chin rest. If this is the case, the chin rest will also serve as a bone mineral quantification phantom, and even a dental cone beam X-ray CT apparatus with a small measurement area and a small space for installing a phantom can be installed. Space can be achieved.

 In the bone salt quantification phantom of the third aspect of the present invention, a plurality of bone block reference bodies having different hydroxyapatite contents are provided. By doing so, since the bone density can be determined in a number of stages by comparison with each bone block reference body, the application timing of the dental implant can be accurately grasped. As the number of bone block reference bodies with different hydroxyapatite contents, the bone density can be classified more finely, but in order to make the bone mineral quantification phantom shape usable as a chin rest When many bone block reference bodies are provided, the bone block reference body per one becomes small, and it is difficult to accurately measure the bone density. For this reason, the number of suitable bone block references is 1 to 4, more preferably 2 to 3, and most preferably 2. If there are two bone block reference bodies having different hydroxyapatite contents, the jaw bone density can be discriminated into three groups, and the timing of application of the dental implant can be accurately grasped.

 In the bone salt quantification phantom according to the fourth aspect of the present invention, the plurality of bone block reference bodies having different hydroxyapatite contents are installed at intervals of 5 mm or more. If bone block references with different hydroxyapatite contents are too close to each other, one bone block reference will affect the X-ray absorption characteristics of the other bone block reference, thus measuring accurate bone density. It becomes difficult. More preferably, the plurality of bone block reference bodies having different hydroxyapatite contents are installed at an interval of 10 mm or more.

1 is a schematic diagram of a cone beam X-ray CT apparatus according to Embodiment 1. FIG. It is a perspective view of the chin rest of the cone beam X-ray CT apparatus of Example 1. FIG. It is a drawing substitute photograph of chin rest 6. 3 is a drawing substitute photograph in Example 1 and Comparative Example 1. FIG. FIG. 3 is a drawing-substituting photograph in which a CBCT image having a slice thickness of 2.8 mm is reconstructed on the mid-sagittal plane in Example 1. FIG. It is a graph which shows the relationship between the CBCT value and the bone density obtained from MSCT. It is a perspective view of the chin rest of the cone beam X-ray CT apparatus of Example 2. FIG. It is a perspective view of the bone mineral quantification phantom used for the X-ray CT apparatus using the conventional MSCT method.

The bone mineral content phantom of the present invention includes a soft tissue member made of a soft tissue equivalent material of a jaw, and a bone block reference body in which hydroxyapatite is contained in a resin in a predetermined ratio and embedded in the soft tissue member. .
The soft tissue member made of the soft tissue equivalent material of the jaw is not particularly limited as long as it has a material with the same transmittance as that of the soft tissue of the jaw. For example, a thermoplastic resin such as a polyurethane resin or a thermosetting resin such as an epoxy resin can be used.
Further, the resin used for the bone block reference body is not particularly limited, but a thermoplastic resin such as a polyurethane resin or a thermosetting resin such as an epoxy resin can be used.

 Further, the bone mineral content phantom of the present invention has a shape that can be closely attached to the jaw so that there is no gap. For this purpose, it is preferable that the shape of the bone mineral quantification phantom matches the shape of the jaw. However, even if the bone mineral quantification phantom is a simple plate and does not necessarily match the shape of the jaw, it can be brought into close contact with the jaw by pressing the bone mineral phantom against the jaw. I just need it. This is because there is no gap that causes an error between the jaw and the bone mineral quantification phantom.

 Moreover, there is no limitation in particular also about the shape of the bone block reference body embedded in the soft tissue member, and it can be made into a square pillar shape or a cylindrical shape.

Embodiments and comparative examples embodying the present invention will be described below with reference to the drawings.
Cone beam X-ray of Example 1 after a total of 15 subjects (2 males and 13 females) who underwent dental implant treatment with mandibular bone graft between January and July 2009 Imaging by the CT apparatus and imaging of MSCT by the X-ray CT apparatus of Comparative Example 1 were performed. The average age of those who have undergone CBCT imaging is 55.2 years old (SD standard deviation 12.5). The average period between CBCT and MSCT was 3.8 years. (Range 2.5-6.7 years, standard deviation 1.1)

<Measurement equipment and measurement conditions>
Example 1
Structure In Example 1, Alphard VEGA (manufactured by Asahi Roentgen Kogyo Co., Ltd.) equipped with a flat panel detector was used. This apparatus is a CBCT type X-ray CT apparatus that irradiates cone beam X-rays. As shown in FIG. 1, an X-ray generator 1 and an image receiving unit 2 are provided between the X-ray generator 1 and the image receiving unit 2. A fixing portion 3 for fixing the position is provided. The fixing portion 3 is provided with a head support 4 for positioning the frontal head, an ear rod 5 for positioning the head left and right, and a chin rest 6 for positioning the head up and down. It has been. Below the fixed portion 3, a chair 7 is installed for the person to be inspected to sit on. Further, the X-ray generator 1 and the image receiving unit 2 are connected by an arm 8 at the upper side, and the X-ray generator 1, the image receiving unit 2, and the arm 8 rotate with the vertical direction passing through the center of the chin rest 6 as an axis. It is possible.

As shown in FIG. 2, the chin rest 6 has a structure in which a bone mineral metering phantom 10 having the same shape and a thickness of 10 mm is pasted on a chin rest main body 6a having a front and rear length of 45 mm and a width of 60 mm. The bone mineral density phantom 10 includes a soft tissue portion 10a made of urethane resin, which is a soft tissue equivalent material of the jaw, and a bone block reference body 10b (30 × 15 × 10 mm) embedded in the soft tissue member 10a. The bone block reference body 10b is made of urethane resin containing hydroxyapatite 200 mg / cm ³ . A substitute drawing of the actual picture of the chin rest 6 is shown in FIG.

Measurement The measurement was carried out after the patient's jaw was placed on the bone mineral quantification phantom 10 shown in FIG. 1 and the positions of the head support 4, ear rod 5 and chin rest 6 were adjusted.
The measurement conditions are as follows.
-The irradiation field (image size) height was 102 mm and the diameter was 102 mm.
・ The voxel size was 0.2 mm x 0.2 mm x 0.2 mm.
• Scanning was performed with an X-ray tube voltage of 80 kV and a tube current of 5 mA.
・ Each patient's occlusal surface was set to be parallel to the floor using ear rod 5 and chin rest 6 ・ Axis image DICOM (Digital Imaging and Communication in Medicine ... medical image format) file is portable Saved to hard disk.

(Comparative Example 1)
In Comparative Example 1, “Hispeed NX / i pro (device name)” (manufactured by GE Yokogawa Medical Systems), which is an X-ray CT apparatus of the MSCT method, was used. Images were taken at 120 kV and tube current 200 mA.

-Evaluation-
<Measurement of voxel value>
In the CBCT image in Example 1 and the MSCT image in Comparative Example 1, the voxel value of the mandibular cancellous bone was measured by the method of Naitoh et al. (Naitoh, M., Hirukawa, A., Katsumata, A. & Ariji, E (2009d) Evaluation of voxel values in mandibular cancellous bone: relationship between cone-beam computed tomography and multislicehelical computed tomography. Clinical Oral Implants Research 20: 503-506.).
That is, using a computer (Macintosh, G4, manufactured by Apple Computer) using three-dimensional analysis software (OsiriX), CBCT and MSCT dentition cross-sectional images of slice thickness 2.8 mm,
・ Mandibular front teeth area (between middle and side incisors)
-Mandibular canine region-Genital hole region-Mandibular molar region (first molar region)
Created in.
Subsequently, in each image, the region of interest ROI (area 7.1 mm 2) was set in the mandibular cancellous bone. The total ROI is 120 sites (ie 15 patients x 2 devices x 4 sites). The position of the cross section and the position of the ROI were visually matched as much as possible between the CBCT image and the MSCT image. The volume of ROI was 2.8 mm x 7.1 mm, and the number of voxels was 2.48 x 10 ^{3 for} CBCT and 6.5 x 10 ^{2 for} MSCT. In MSCT, CT values were converted to bone density using a bone density chart. The bone density between 0 to 400 mg / cm ³ of hydroxyapatite was determined by interpolation, and was calculated by extrapolation in the outer area.
Drawing substitute photographs showing the results are shown in FIG. 4a (Example 1 taken by CBCT) and FIG. 4b (Comparative Example 1 taken by MSCT).

Furthermore, in Example 1, a CBCT image having a slice thickness of 2.8 mm was reconstructed on the median sagittal plane. The results are shown in FIG.
ROI (region of interest) has been set at 0.2cm ^2. As measured by MSCT, 45 sites total 120 in site (sometimes referred to as the "HA") hydroxyapatite was the value of ^{100mg / cm 3 ~300mg / cm 3} .
HA was less than 200 mg / cm ³ at 16 sites and HA was greater than 200 mg / cm ³ at 29 sites. Voxel values at each site were classified into two grades, greater than or less than the bone block reference value.

-Result-
-Voxel value obtained from CBCT of mandibular cancellous bone tissue Table 1 shows the voxel value obtained from CBCT of mandibular cancellous bone tissue.
The value is 30-175 mg / cm ³
The total average was 327 mg / cm ³ HA (standard deviation 235).

-Bone density obtained from MSCT of mandibular cancellous bone tissue Bone density of mandibular cancellous bone tissue is shown in Table 2. Values ranged from 22 to 1104 mg / cm ³ HA, with a total average of 316 mg / cm ³ HA (standard deviation 235).

・ Difference in bone density obtained from CBCT and MSCT
The difference between the HA value of CBCT and MSCT is in the range of 1~123mg / cm ³ in 15 patients 120 sites, the overall average value was 38 mg / cm ³ HA (Table 3).
At 73 sites (60.8%), the HA difference was less than 38 mg / cm ³ and the median HA was 32 mg / cm ³ .

・ Evaluation using bone block reference body By using the reference body, 45 sites (100 mg / cm ³
The bone density at 38 sites (84%) in HA-300 mg / cm ³ HA) was accurately assessed.
Furthermore, 15 sites (94%) out of 16 sites below 200 mg / cm ³ HA were accurately evaluated, and 23 sites (79%) out of 29 sites above 200 mg / cm 3 HA were accurately evaluated (FIG. 6).
From the above results, even in the case of the CBCT type X-ray CT apparatus as in the first embodiment, if one bone block reference body is placed on the chin rest and compared with it, the determination of the bone density necessary for the implant treatment is made. It was found that this can be performed sufficiently.

-Discussion-
The bone height, bucopharyngeal bone width, and bone density at the site of implantation required for dental implant placement are measured on images prior to surgery. The accuracy of CBCT images has been reported to be high for linear measurements (Naitoh, M., Katsumata, A., Mitsuya, S., Kamemoto, H. & Ariji, E. (2004) Measurement of mandibles with
microfocus X-ray computerized tomography and compact computerized tomography for dental use.The International Journal of
Oral & Maxillofacial Implants 19: 239-246.).

In addition, the tube structure of the mandibular neurovascular system (eg, the bifurcated mandibular canal in the mandibular branch and the paramental foramen) was clearly observed (Naitoh, M., Hiraiwa, Y., Aimiya, H. & Ariji, E. (2009b) Observation of bifid mandibular canal using cone-beam computed tomography. The International Journal of Oral & Maxillofacial Implants
24: 155−159. Naitoh, M., Hiraiwa, Y., Aimiya, H., Gotoh, K. & Ariji, E. (2009c) Accessory mental foramenassessment using cone-beam computed tomography. Radiology Endodontics 107: 289-294.Naitoh, M., Nakahara, K., Hiraiwa, Y., Aimiya, H.,
Gotoh, K. & Ariji, E. (2009e) Observation of buccal for amen in mandibular body using cone-beam computed tomography. Okajimas Folia Anatomica Japonica 86: 25-29.).

The radiation dose of CBCT is less than that of helical CT (Ludlow, JB & Ivanovic, M. (2008) Comparative dosimetry of dental CBCT devices and 64-slice CT for oral and maxillofacial radiology. : 106-114., Okano, T., Hirata, Y., Sugihara, Y., Sakaino, R., Tsuchida, R., Iwai, K., Seki, K. & Araki, K. (2009) Absorbed and (effective doses from cone-beam volumetric imaging for implant planning.Dentomaxillofacial Radiology 38: 79-85.)

Since pixel or voxel values obtained from CBCT images are not absolute values, various methods have been proposed to assess bone density.
(Araryarachkul, P., Caruso, J., Gantes, B., Schulz, E., Riggs, M., Dus, I., Yamada, J. & Crigger, M. (2005) Bone density assessments of dental implant
sites: 2. Quantitative cone-beam computerized tomography. The International Journal of Oral & Maxillofacial Implants 20: 416-424.
Hua, Y., Nackaerts, O., Duyck, J., Maes, F. & Jacobs, R. (2009) Bone quality assessment based on cone-beam computed tomography imaging. Clinical Oral Implants Research 20: 767-771. Naitoh, M., Aimiya, H., Hirukawa, A. & Ariji, E. (2009a) Morphometric analysis of mandibular trabecular bone using cone-beam computerized tomography: an in vitro study.The International Journal of Oral & Maxillofacial Implants (in Naitoh, M., Hirukawa, A., Katsumata, A. & Ariji, E. (2009d) Evaluation of voxel values in mandibular cancellous bone: relationship between cone-beam computed tomography and multislice helical computed tomography. Clinical Oral Implants Research 20: 503-506.)

The use of regression lines has been proposed for estimating the bone density of the mandibular cancellous bone in the large field (wide imaging range) CBCT (Naitoh, M., Hirukawa, A., Katsumata, A. & Ariji , E. (2009d) Evaluation of voxel values in mandibular cancellous bone: relationship between
cone-beam computed tomography and multislicehelical computed tomography. Clinical Oral Implants Research 20: 503-506.).

 In small-field CBCT, morphometric analysis of mandibular trabeculae was performed, and trabecular volume / total tissue volume (BV / TV) can be used to assess bone density of mandibular cancellous bone it can. (Naitoh, M., Aimiya, H., Hirukawa, A. & Ariji, E. (2009a) Morphometric analysis of mandibular trabecular bone using cone-beam computerized tomography: an in vitro study.The International Journal of Oral & Maxillofacial Implants ( in press).)

In previous studies, the difference in bone density between CBCT and MSCT has been 1 to 182 mg / cm ³
HA, average value was 46 mg / cm ³ HA (Naitoh, M., Hirukawa, A., Katsumata, A. & Ariji, E. (2009d) Evaluation of voxel values in mandibular cancellous bone: relationship between cone-beam computed tomography and multislice helical computed tomography. Clinical Oral Implants Research 20: 503-506.). In the present specification, using the same regression line as above, a 1~123mg / cm ³ HA, mean 38mg / cm ³ HA. The usefulness of regression lines for bone density assessment was confirmed in mandibular cancellous bone. On the other hand, it is considered difficult to obtain a regression line using other CBCT devices. Therefore, the usefulness of the bone block reference was evaluated to measure the density of the mandibular cancellous bone.

 MSCT values were converted to bone density using a bone density chart with five bone block references (Naitoh, M., Kurosu, Y., Inagaki, K., Katsumata, A., Noguchi, T. & Ariji , E. (2007) Assessment of mandibular buccal and lingual cortical bones in postmenopausal women.Oral Surgery Oral Medicine Oral Pathology Oral Radiology Endodontics)

However, since the size of the CBCT image in Example 1 was limited to 102 mm, one bone block reference was used to evaluate low bone density.
Misch, CE (1999) Contemporary Implant Dentistry. 2nd edition, 109-118. St Louis: Mosby. Classified the cancellous bone density of the jawbone into five stages:
D1:> 1250 HU
D2: 850-1250HU
D3: 350 ~ 850HU
D4: 150 ~ 350HU
D5: <150HU According to CT value of medical CT In addition, CT value was converted into bone density by previous studies (Naitoh, M., irukawa, A., Katsumata, A. & Ariji, E. (2009d ) Evaluation of voxel values in
mandibular cancellous bone: relationship between cone-beam computed tomography and multislice helical computed tomography. Clinical Oral Implants Research 20: 503-506.).
D1:> 1.02 × 103 mg / cm ³ HA
D2: 7 × 102 to 1.02 × 103 mg / cm ³ HA
D3: 2.9 × 102 〜7 × 102 mg / cm ³ HA
D4: 1.3 × 102 to 2.9 × 102 mg / cm ³ HA
D5: <1.3 × 102 mg / cm ³ HA
Therefore, the bone density of the 200 mg / cm ³ HA bone block reference was approximately the median of D4.

Bone density of 45 sites ^{(100mg / cm 3 HA~300mg / cm} 3 HA in MSCT) 38 parts (84%) in the, by using the reference member was evaluated accurately.
In 5 out of 7 sites, which were inaccurate, the bone density by MSCT was within the range of 180-200 mg / cm ³ HA. The measured concentrations of mandibular cancellous bone and bone block reference were different.

In addition, the soft tissue volume of the mandibular cancellous bone was larger than the bone block reference and there was a mandibular branch outside the X-ray field.
These affect the bone density value of CBCT.
The threshold of CBCT corresponded to about 1.8 × 102 mg / cm ³ of HA in MSCT.
Further, differences in the true value of the bone density and (200 mg / cm @ 3 HA) with the threshold value was approximately 20 mg / cm ³ HA, and its value was less than that using the regression line (median: 32 mg / cm ³ HA).

The 200 mg / cm ³ HA bone block reference may be useful for assessing mandibular cancellous bone with low bone density in CBCT with a large imaging range.
In addition, it is considered that mandibular cancellous bone with high bone density can be evaluated by using a bone block reference body with high mineral content.

-Conclusion-
The difference in bone density of the mandible by CBCT and MSCT ranges from 1~123mg / cm ³ HA, the average value was 38mg / cm ³ HA. For this value, the regression line obtained in the above literature was used. Bone block reference also helped to assess the low bone density of mandibular cancellous bone in CBCT with a wide imaging range.

 In Example 1, as shown in FIG. 2, only one bone block reference body 10b is embedded in the chin rest 6, but instead of this, two or three or more different hydroxyapatite contents are used. The bone block reference body may be embedded. In this case, since the bone density can be determined in many stages by comparison with each bone block reference body, the timing of application of the dental implant can be accurately grasped.

(Example 2)
In Example 2, the following chin rest type jaw bone bone density phantom was manufactured. That is, as shown in FIG. 8, the jawbone bone density phantom 20 of Example 2 has a bone block of 15 mm square and 10 mm thickness on a soft tissue portion 21 made of urethane resin having a longitudinal length of 48 mm, a lateral width of 62 mm, and a thickness of 10 mm. Reference bodies 21a and 21b are embedded side by side in symmetrical positions. The X-ray transmittance of the urethane resin forming the soft tissue portion 21 is equivalent to the soft tissue of the jaw. The bone block reference body 22a is made of urethane resin containing 100 mg / cm ^{3 of} hydroxyapatite, and the bone block reference body 22b is made of urethane resin containing hydroxyapatite 300 mg / cm ^3. Yes. The distance between the bone block reference body 22a and the bone block reference body 22b is 10 mm.

<Measurement>
Using the same apparatus as the dental cone beam CT used in Example 1 and the multi-slice CT used in Comparative Example 1, the head phantom and the jawbone bone density phantom 20 of Example 2 were set on them. Measured under the same conditions.

<Result>
Table 4 shows the measurement results at 25 locations of the lower cancellous bone. The six regions determined to be less than 100 mg / cm ³ in the dental cone beam CT were all determined to be less than 100 mg / cm ³ in the multi-slice CT. The region of six that are judged to 100 mg / cm ³ or more 300 mg / cm ³ or less in the dental cone beam CT, in multi-slice CT, 5 points is determined to 100 mg / cm ³ or more 300 mg / cm ³ or less, One site was determined to be less than 100 mg / cm ³ . Furthermore, 13 areas determined to be 300 mg / cm ³ or less in the dental cone beam CT are determined to be 300 mg / cm ³ or less in 12 areas in the multi-slice CT, and one area is 100 mg / cm ³ or more and 300 mg / cm ³ or less. It was determined to be ³ cm or less.
That is, in the 25 measurement locations, there is a coincidence of determination at 23 locations, and if the jawbone bone density phantom of Example 2 is used, the applicability of the implant is determined even using the dental cone beam CT. It turns out that it is possible enough.

 The present invention is not limited to the description of the embodiments and examples of the invention described above. Various modifications are also included in the present invention as long as those skilled in the art can easily conceive without departing from the scope of the claims.

DESCRIPTION OF SYMBOLS 10 ... Bone salt fixed quantity phantom 10a ... Soft tissue member 10b ... Bone block reference body 6 ... Chin rest

Claims (6)

A bone mineral quantification phantom used in a dental cone beam X-ray CT apparatus,
A soft tissue member made of a soft tissue equivalent material of the jaw, and a bone block reference body that contains hydroxyapatite in a predetermined ratio in the resin and is embedded in the soft tissue member, so that there is no gap in the jaw A bone mineral quantification phantom characterized by having a shape that can be closely attached.  The bone mineral quantification phantom according to claim 1, wherein the bone salt quantification phantom is configured to be usable as a chin rest.  The bone mineral quantification phantom according to claim 1 or 2, comprising a plurality of bone block reference bodies having different hydroxyapatite contents.  The bone mineral content determination phantom according to any one of claims 1 to 3, wherein the plurality of bone block reference bodies having different hydroxyapatite contents are installed at intervals of 5 mm or more. .  The bone mineral content phantom according to any one of claims 1 to 4, comprising two bone block reference bodies having different hydroxyapatite contents. A dental cone beam X-ray CT apparatus with a chin rest,
A dental cone beam X-ray CT apparatus, wherein the chin rest comprises the bone mineral quantification phantom according to any one of claims 1 to 5.