JP2007278726A - Nuclear medicine diagnostic equipment and nuclear medicine diagnosis method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a nuclear medicine diagnostic equipment wherein the deviations between an X-ray CT image and a positron CT image is reduced, concerning the nuclear medicine diagnostic equipment, capable of performing X-ray CT photography and positron CT photography, and to provide a nuclear medicine diagnosis method. <P>SOLUTION: Assuming that an X-ray CT photography prescribed width is He1, and that a positron CT photography prescribed width is PET, a photographic position of a subject is moved, and the subject is photographed on the subject position, having a plurality of prescribed widths. Photographing of the subject in the prescribed width He1 by the X-ray CT and photography thereof in the prescribed width PET by the positron CT are alternately performed, while the photographic position of the subject is changed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a nuclear medicine diagnostic apparatus and a nuclear medicine diagnostic method that enable X-ray CT and positron CT imaging without moving a subject to a different apparatus for imaging, and in particular, using an X-ray CT image. The present invention relates to a technique used when correcting a positron CT image at the same position or when providing an image obtained by superimposing an X-ray CT image and a positron CT image at the same position.

  There has been proposed an X-ray CT combined positron CT apparatus capable of imaging the same position of a subject with X-ray CT and positron CT without moving the subject between apparatuses (see Patent Document 1). In this X-ray CT combined positron CT apparatus, the gantry of the positron CT apparatus and the gantry of the X-ray CT apparatus are arranged side by side and one bed is used in common. Then, coincidence count data and CT images of the same tomographic plane of the patient on the bed are obtained, and absorption correction is performed on the coincidence count data based on the CT image data.

  In such an X-ray CT combination type positron CT apparatus, by creating absorption correction data using an X-ray CT image, an attenuation amount of γ rays in the subject is calculated, and an X-ray CT image and The positron absorption correction is performed in the positron CT image obtained by photographing the same position. In addition, X-ray CT imaging can be performed in a short time of a few tens of seconds even if the whole body is imaged using a multi-slice CT helical scan, and absorption correction data creation by transmission images using a conventional external radiation source is possible. Compared to this, it is possible to shoot in a much shorter time.

  In addition, the X-ray CT image displays detailed information on the morphology in the subject, while one positron CT image visualizes the amount of radioisotope accumulated in a specific location such as cancer in the subject. In order to display the function information of the specimen, an X-ray CT image and a positron CT image at the same position can be overlaid to provide an image that clearly shows the site of cancer occurrence.

  Although there is no detailed description in Patent Document 1, as an imaging method using an X-ray CT combined positron CT apparatus, a necessary part is first imaged by X-ray CT, and a portion corresponding thereto is imaged by positron CT In some cases, necessary portions are imaged by positron CT, and then the same position is imaged by X-ray CT. FIG. 5 is a diagram showing a protocol process in the apparatus when the helical scan imaging of the X-ray CT is first performed in the conventional technique, and then the portion corresponding thereto is imaged by the positron CT.

  After completing the alignment of the subject, when the examination conditions are set on the console and the apparatus is instructed to perform the examination, the apparatus first starts collecting X-ray CT data. This starts by rotating an X-ray tube and an X-ray detector installed opposite to the X-ray detector around the subject, and then continuously moving the subject while irradiating the X-ray. X-ray transmission data will be collected. The transition of the photographing range at this time is as shown in (1) of FIG. An X-ray CT image is created by reconstructing the collected X-ray transmission data. The X-ray CT image obtained in this way is converted into absorption correction data for correcting the γ-ray collection data in the positron CT by further conversion processing calculation. In parallel with this, when the X-ray CT data collection in a necessary range is completed, the apparatus sets the position of the subject to a position for collecting positron CT data. When a γ-ray detector is installed around the subject at the first collection position, the apparatus starts collecting γ-rays generated from the subject. When the preset collection time ends, the apparatus sets the γ-ray detector at the next collection position. When the setting is completed, collection of γ rays generated from the subject is started again. This collection of γ-rays and setting of the γ-ray detector is performed until the collection in the inspection range designated in advance is completed. The transition of the collection range at this time is as shown in (2) to (8) of FIG. On the other hand, the γ-ray collection data is subjected to calculation processing after correction (attenuation correction) of the effect that γ-rays attenuate in the transmission process in the subject based on the previously created absorption correction data. A positron CT image is created.

  When acquiring an image as described above, X-ray CT images can be captured in several tens of seconds by using multi-slice CT or performing a helical scan. However, since the positron CT requires several minutes to shoot one position, the detector position is reset and the image is taken again every time collection of a certain position is completed in accordance with the width of the detector. It is common to repeat this act. Since a normal positron CT detector has a width of several tens of centimeters, it is necessary to move the imaging position 7 to 8 times even when imaging the half body (from the top / neck to the neck), which is necessary for general examination. Therefore, the time for obtaining a whole body image with positron CT ranges from ten minutes to several tens of minutes.

As described above, since positron CT is used to image a plurality of locations of a subject over a long period of time (that is, tens of minutes to several tens of minutes), the subject may move during that time. There is no guarantee that the images acquired between the start and end of positron CT imaging coincide with the X-ray CT images at all positions of the subject. As described above, regardless of whether the X-ray CT imaging is performed before or after the positron CT imaging, the imaging is performed at a position where the imaging interval is present (for example, the collection position (8) in FIG. 5). The position of the image may not match that of the X-ray CT image (FIG. 6), and the shift is expected to increase with time. In the X-ray CT combined positron CT apparatus, the X-ray CT image and the positron CT image at the same position coincide with each other to perform attenuation correction and overlay image display. The fact that the positions of the two do not match is a fatal defect of the device.
Japanese Patent Laid-Open No. 7-20245

  The present invention provides a nuclear medicine diagnostic apparatus and a nuclear medicine diagnostic method in which a difference between an X-ray CT image and a positron CT image is reduced in a nuclear medicine diagnostic apparatus capable of performing X-ray CT imaging and positron CT imaging. For the purpose.

  The problem of positional displacement between the X-ray CT image and the positron CT image due to the movement of the subject is caused by the fact that the imaging time by the positron CT is long and it is difficult for the subject to remain stationary during that time. In order to eliminate such a cause, in the present invention, when X-ray CT and positron CT imaging at a plurality of positions are performed, the X-ray CT in the same range as the imaging at one position of the positron CT is performed after the imaging. Imaging of the positron CT at the position is performed.

  Specifically, the invention according to the aspect of the present invention includes a first medical image photographing unit and a second medical image photographing unit, and a plurality of subjects having a predetermined width by moving a photographing position of the subject. In the nuclear medicine diagnostic apparatus for photographing the position of the subject with the first medical image photographing means and the second medical image photographing means, The imaging position of the subject is changed while alternately performing imaging of the subject of the predetermined width of the subject by the second medical image imaging means. Note that the present invention is not limited to an apparatus, and can also be established as an invention of a diagnostic method realized by the apparatus.

  ADVANTAGE OF THE INVENTION According to this invention, in the nuclear medicine diagnostic apparatus which can perform X-ray CT imaging and positron CT imaging, the shift | offset | difference of an X-ray CT image and a positron CT image can be reduced.

  Embodiments of the present invention will be described with reference to the drawings. In the present invention, since it is necessary to obtain an X-ray CT image of the same tomographic plane imaged by the positron CT apparatus, for example, as shown in FIG. 1, the gantry 1 of the positron CT apparatus and the X-ray CT apparatus The gantry 2 is arranged side by side. One bed 3 can be used in common for the positron CT apparatus and the X-ray CT apparatus. The gantry 1 contains a large number of radiation detectors arranged in a ring shape (not shown) as in a normal positron CT apparatus, and the gantry 2 contains an X-ray (not shown) as in a normal X-ray CT apparatus. A tube, an X-ray detector, and a mechanism for scanning them are housed. By placing a subject (not shown) on the bed 3 and moving the bed 3 in the direction of the arrow in the figure, PET data and X-ray CT data can be collected for the same tomographic plane of the subject. ing.

  In the X-ray CT combined positron CT apparatus, after the subject is set up, an inspection is performed by selecting a predetermined inspection protocol on the console. 2 and 3 show protocol processing in the X-ray CT combined positron CT apparatus according to one embodiment of the present invention, corresponding to the case of the prior art (FIGS. 5 and 6). FIG. 4 shows a flow of protocol processing according to an embodiment of the present invention.

  After completing the positioning of the subject, set the examination conditions on the console. In this case, the operator designates the scan range of the subject with a scanogram (positioning image). Then, the X-ray CT combined positron CT apparatus automatically divides this scan range and performs scanning. The divided state is displayed so that it can be grasped on the scanogram. When the apparatus is instructed to perform inspection, the apparatus first starts collecting X-ray CT data. This starts by rotating the X-ray tube and the X-ray detector installed opposite thereto around the subject (step S1), and then moving the subject while irradiating the X-ray ( In step S2), X-ray transmission data of the subject is continuously collected (step S3). In this way, X-ray CT data collection is performed by helical scanning. Imaging at this time is performed only in the same range as the collection range of the positron CT at the first position to be subsequently performed. A reconstruction calculation process is performed on the collected X-ray transmission data, and an X-ray CT image is created (step S4). The X-ray CT image thus obtained is converted into absorption correction data for correcting the γ-ray collection data in the positron CT by further conversion processing calculation (step S5). In parallel with this, when the X-ray CT data acquisition of the first range is completed, the apparatus sets the position of the subject to a position for positron CT data acquisition (step S6).

  When the γ-ray detector is installed around the subject at the first collection position, the apparatus starts collecting γ-rays generated from the subject (step S7). When the preset collection time ends (step S8), the apparatus resets the position of the subject to collect X-ray CT data at the next collection position (step S9), and again the position of the positron CT. X-ray CT data collection for the collection range is performed (steps S1 to S3). When the collection of X-ray CT data is completed, the apparatus resets the position of the subject in order to collect positron CT data at the same position of the subject (step S7). When the setting is completed, collection of γ rays generated from the subject is started (step S7). In this way, X-ray CT data collection and γ-ray collection at the same position are repeated until the entire inspection range designated in advance is completed.

  The transition of the collection range at this time is as shown in (1) to (14) of FIG. As described above, in the present invention, X-ray CT data acquisition and positron CT data acquisition at a position corresponding to the X-ray CT data are alternately performed. One X-ray CT data acquisition is performed for several seconds, and positron CT data acquisition is performed for 1 to 2 minutes. Complete with degree. For this reason, it is possible to minimize the displacement of the subject position due to the subject itself moving between the X-ray CT data collection and the positron CT collection (see FIG. 3). From the γ-ray collection data collected in this way, γ-rays are attenuated during the transmission process in the subject based on the absorption correction data created from the X-ray CT data at the same position as in the prior art. After effect correction (attenuation correction) is performed (step S10), a positron CT image is created by arithmetic processing (step S11).

Due to the effects of the present invention, the X-ray CT image (or the absorption correction data obtained therefrom) and the positron CT image, both in attenuation correction and in the case of overlaying an X-ray CT image and a positron CT image, Position shift is minimized. (Figure 3)
In the above embodiment, X-ray CT data acquisition and positron CT data acquisition at the same position are alternately performed in the X-ray CT built-in type positron CT apparatus. However, when the collection position is moved alternately using a bed or top plate on which the subject is placed as a moving body, it is necessary to reduce the movement of the subject due to acceleration of the subject at the start or stop of movement. There is. In order to realize this easily, a method of fixing the subject firmly to the moving body using a fixing band or a fixture or controlling the acceleration to be low can be considered. However, there is a possibility that the subject's discomfort increases and the efficiency of the examination time decreases.

  In order to avoid this, a detector that collects X-ray CT data and positron CT data, or a positron CT apparatus incorporating X-ray CT that moves a gantry incorporating the subject, without moving the subject itself, is used. It is preferable to apply an inspection protocol in which X-ray CT data acquisition and positron CT data acquisition at the same position are alternately performed.

  Thereby, in addition to reducing the active movement of the subject itself, it is also possible to reduce the passive movement of the subject by the apparatus.

According to an embodiment of the present invention,
By alternately collecting X-ray CT data and positron CT data at a position corresponding to the X-ray CT data, that is, one X-ray CT data is collected in the same range as imaging at one position of positron CT data. Further, it is possible to minimize the displacement of the subject position due to the subject itself moving between the time of collecting the X-ray CT data and the time of collecting the positron CT. For this reason, in the case of attenuation correction and in the case of overlaying an X-ray CT image and a positron CT image, the X-ray CT image (or absorption correction data obtained therefrom) and the positron CT image show a deviation in the position of the subject. Can be minimized. In addition, since the gantry is moved instead of the bed in the X-ray CT combined positron CT apparatus, even if the movement for adjusting the collection position to the X-ray CT combined positron CT apparatus is repeated at high speed, the patient The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the invention at the stage of implementation. For example, in the above embodiment, the X-ray CT combined positron CT apparatus has been exemplified. However, the present invention is applied to a SPECT-X-ray CT apparatus which is combined so that X-ray CT data acquisition and SPECT data acquisition can be performed. May be. The present invention can be applied to other combinations. Further, the interval of division by the X-ray CT combined positron CT apparatus may not be the collection range for each rotation of the positron CT apparatus. For example, two rotations of the positron CT apparatus may be set as one division range. Further, the above embodiments include inventions at various stages, and various inventions can be extracted by appropriately combining a plurality of disclosed constituent elements.

  In addition, for example, even if some structural requirements are deleted from all the structural requirements shown in each embodiment, the problem described in the column of the problem to be solved by the invention can be solved, and the effect described in the effect of the invention Can be obtained as an invention.

It is a figure showing a schematic structure of a nuclear medicine diagnostic device concerning one embodiment of the present invention. It is a figure which shows the protocol process in the X-ray CT combination type | mold positron CT apparatus which concerns on one Embodiment of this invention. It is a figure which shows the protocol process in the X-ray CT combination type | mold positron CT apparatus which concerns on one Embodiment of this invention. It is a figure which shows the flow of the protocol process which concerns on one Embodiment of this invention. It is a figure which shows the protocol process in the conventional X-ray CT combination type positron CT apparatus. It is a figure which shows the protocol process in the conventional X-ray CT combination type positron CT apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Gantry of positron CT apparatus 2 ... Gantry of X-ray CT apparatus 3 ... Bed

Claims (5)

First medical image photographing means and second medical image photographing means are provided, and the photographing positions of the subject are moved so that the positions of the subjects having a plurality of predetermined widths are the first medical image photographing means and the first medical image photographing means. In the nuclear medicine diagnostic apparatus for photographing with the medical image photographing means of 2,
The imaging of the subject with the predetermined width of the subject by the first medical image capturing means and the imaging of the subject with the predetermined width of the subject by the second medical image capturing means are alternately performed. A nuclear medicine diagnostic apparatus characterized by changing a photographing position. 2. The nuclear medicine diagnosis apparatus according to claim 1, wherein the first medical image photographing means is a positron CT and the second medical image photographing means is an X-ray CT. The nuclear medicine diagnosis apparatus according to claim 1 or 2, wherein the predetermined width is a width of a detector of the first medical image photographing means. The nuclear medicine diagnosis apparatus according to any one of claims 1 to 3, wherein a plurality of predetermined points of the subject are moved while moving the first medical image photographing means and the second medical image photographing means. A nuclear medicine diagnostic apparatus characterized by imaging a position of a subject having a width. First medical image photographing means and second medical image photographing means are provided, and the photographing positions of the subject are moved so that the positions of a plurality of subjects are determined. The first medical image photographing means and the second medical image photographing means In a nuclear medicine diagnostic method applied to a nuclear medicine diagnostic apparatus that photographs with an image photographing means,
The second medical image photographing means images the subject in accordance with the photographing width of the first medical image photographing means in which one photographing width is defined,
The first medical image photographing means performs photographing of the subject at the same position as the position photographed by the second medical image photographing means,
A nuclear medicine diagnosis method characterized in that imaging by the second medical image photographing means and the first medical image photographing means is alternately performed while moving the subject.

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