JP2007218768A - Positron emission tomography equipment - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem, wherein in order to prevent counting gamma beams from areas other than the head part of the area to be inspected at data acquisition by emission scans in the head inspection using PET, even though a shielding body, having a hole section for passing the head of a subject to be examined at the vicinity of the center section, is provided, the hole section cannot provide sufficient shielding effect, because an extent that the person's shoulder width can pass is needed. <P>SOLUTION: The problem is solved, by employing a radiation screening device 10 arranged so as to surround the rear surface of the back region, the front surface of the breast region, and the top surfaces of both the shoulders of the subject 5 on a top panel 8. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a radiation shielding mechanism of a positron emission tomography apparatus.

  A positron emission tomography apparatus (hereinafter referred to as PET) includes a gantry 1 and a bed 9 as shown in FIG. 7, and the bed 9 includes a bed base 7 and a top plate 8 supported on the upper surface thereof so as to be horizontally movable. Then, the inspection site of the subject 5 placed on the top board 8, for example, the head is inserted into the tunnel portion 1A of the gantry 1. Reference numeral 6 denotes a headrest for placing the head of the subject 5, which is made of a material having little radiation absorption and fixed to the end of the top plate 8. Inside the gantry 1, an emission scan detector 2 and a transmission scan detector 3 are both arranged substantially concentrically with the tunnel portion 1A. In addition, a transmission scan source 4 which is a source of gamma rays is rotatably installed inside a circle formed by the transmission scan detector 3 so as to draw a circle concentric with 3. In addition to these, there are an image processing device that converts signals from both detectors in the gantry 1 into an image, a control unit that controls the rotation of the transmission scan source 4 and the movement of the top plate 8, and the like. Since it is not particularly related to the invention, illustration and description are omitted.

An example of an outline procedure for head examination by PET is shown below. However, a shield 18 constituted by a lead plate or the like having a circular hole 18A fixedly supported by a carriage 19 movable on the floor by wheels 19A is located close to the tunnel 1A of the gantry 1 and the hole. Although 18A is arranged so as to be substantially concentric with the tunnel portion 1A, it will be described as not existing for the time being.
<Procedure 1> The subject 5 is placed on the top board 8 and the headrest 6.
<Procedure 2> The top plate 8 is sent into the tunnel portion 1A, and the head of the subject 5 is stopped within the circle of the transmission scan detector 3 as indicated by a broken line in FIG.
<Procedure 3> The transmission scan source 4 is rotated around the head of the subject 5, and the gamma rays transmitted through the head are detected by the transmission scan detector 3. (Data collection by transmission scan)
<Procedure 4> The top plate 8 is pulled out and the head of the subject 5 is stopped in the circle of the emission scan detector 2 as shown by the solid line in FIG.
<Procedure 5> The subject 5 is caused to suck the gas labeled with the positron emitting nuclide.
<Procedure 6> The gamma ray emitted from the positron emitting nuclide circulating in the head of the subject 5 is detected by the emission scan detector 2. (Data collection by emission scan)
<Procedure 7> An image is generated using data collected by transmission scan and emission scan.

The general procedure for head inspection by PET is as described above, for example. Here, the data collection by the emission scan in the above <Procedure 6> should count only gamma rays from the head, but the opening diameter of the tunnel portion 1A so that the subject 5 can be inserted into the tunnel portion 1A. Is larger than the shoulder width of the subject 5, for example, by counting a part of gamma rays emitted from a part other than the examination part such as the chest and obliquely entering the emission scan detector 2, the S / The disadvantage of reducing the N ratio occurs. The shield 18 arranged so that the hole 18A for passing the head of the subject 5 at a position close to the tunnel portion 1A of the gantry 1 is substantially concentric with the tunnel portion 1A It is located between the head and shoulders to prevent this inconvenience by preventing gamma rays from entering the emission scan detector 2 from parts other than the head. (For example, refer to Patent Document 1).
JP-A-9-318754

  As described above, in the head inspection by PET, the shield 18 having the hole 18A for allowing the head to pass therethrough is used in order to prevent counting gamma rays from parts other than the head during data collection by the emission scan. Used. For this purpose, the hole 18A is preferably as narrow as possible so that the head of the subject 5 can pass through. However, in order to perform a transmission scan, the head of the subject 5 has to be sent into the circle of the transmission scan detector 3 arranged at the back of the gantry 1, so the hole 18A It is necessary to have a size that allows the shoulder of the examiner 5 to pass through, and it is difficult to sufficiently prevent gamma rays from entering the emission scan detector 2 from a portion other than the head. The present invention is intended to solve this problem.

  In order to achieve the above object, the invention according to claim 1 is a bed on which a subject is placed, a radiation detector is arranged in a circular shape inside, and the examination site of the subject is placed in the center. In a positron emission tomography apparatus having a gantry having an opening for insertion, the radiation detector for radiation emitted from other than the head when performing an emission scan of the head of the subject placed on the bed The present invention provides a positron emission tomography apparatus provided with a radiation shielding mechanism having a configuration that can be inserted into the opening while preventing incidence on the aperture.

  In order to achieve the above object, the radiation shielding mechanism covers the whole or a part of the body surface other than the subject's head. The positron emission tomography apparatus according to claim 1 I will provide a.

  According to a third aspect of the present invention, in order to achieve the above object, the radiation shielding mechanism is constituted by a divided shielding body and a shielding body supporting portion that removably supports the shielding body. A tomography apparatus is provided.

  According to a fourth aspect of the present invention, in order to achieve the above object, the radiation shielding mechanism comprises a divided shielding body and a shielding body supporting portion that supports a part of the shielding body so as to be opened and closed. A positron emission tomography apparatus is provided.

  By using the radiation shielding mechanism according to the present invention, a part other than the subject's head is covered with a shield, so that gamma rays counted from a part other than the head, which is an examination part, are collected during emission scan data collection. Can be sufficiently prevented, and the head of the subject can be inserted to the position where the transmission scan is performed behind the tunnel portion of the gantry when data is collected by transmission scan.

  1, FIG. 4 and FIG. 5 are diagrams for explaining the outline when PET head inspection is performed using the radiation shielding mechanism of the present invention. In these drawings, the same reference numerals as those in FIG. 7 are used. Since the parts and the like are the same as those in FIG. 2 and 3 show an example of the radiation shielding mechanism of the present invention.

  First, an example of the configuration of the radiation shielding mechanism of the present invention will be described with reference to FIGS. The radiation shielding apparatus 10 is installed at the head side end of the top plate 8 and has a shape and size that surrounds the shoulder portion of the subject 5 and a gamma ray to prevent transmission. It is comprised by the shielding bodies 12-17 comprised by the lead plate etc. Then, as shown in FIG. 3, after the shield support part 11 is fixed to the top plate 8 with fixing screws 11B provided on both sides of the lower part, the shields 16 and 17 are respectively provided with holes 16A provided in itself. 17A and two screw holes 11C provided on the lower surface of the shield support 11 are fixed to the shield support 11 by screws. The shields 16 and 17 are formed in such a size that no gap or overlap occurs between them. As shown in FIG. 3, the shield 14 is inserted vertically into the guide rail provided facing the top and bottom of the front side front portion of the shield support portion 11 from the front side, and is fixedly disposed by the stopper 14A and the stopper groove 11A. . Similarly, the shield 15 is fixedly disposed by being inserted into the guide rail provided on the front surface of the shield support 11 from the other side. In this state, a gap with a certain width exists between the shields 14 and 15 as shown in FIG. 2, and this is for passing the neck portion of the subject 5. Similarly, the shields 12 and 13 are inserted and fixed horizontally on the guide rails provided facing the top surface of the shield support 11 from the front side and the far side as shown in FIG. In this state, the shields 12 and 13 are provided on the side closer to the face of the subject 5 as shown in FIG. 2 in order to reduce the feeling of pressure on the subject 5 and to suck the gas before the emission scan. The part has a slightly open shape.

Next, a procedure for head inspection by PET performed using the radiation shielding mechanism of the present invention will be described.
<Procedure 1> The top plate 8 is stopped at the position where the top plate 8 is pulled out from the tunnel portion 1A of the gantry 1, and the shield support portion 11 is attached to the head side end portion of the top plate 8 by two fixing screws 11B as shown in FIG. Install.
<Procedure 2> The shields 16 and 17 and the shields 12 and 13 are attached to predetermined positions on the lower surface and the upper surface of the shield support portion 11, respectively.
<Procedure 3> The subject 5 is placed on the headrest 6 through the space between the shields 12 and 13 and the shields 16 and 17 attached to the upper and lower surfaces of the shield support unit 11. Place on top plate 8.
<Procedure 4> The shields 14 and 15 are attached to predetermined positions of the shield support 11 from the left and right sides of the neck of the subject 5. Thus, the placement of the subject 5 on the top plate 8 and the mounting of the radiation shielding apparatus 10 at the inspection preparation position shown in FIG. (Figure 1)
<Procedure 5> The top plate 8 is moved, and the subject 5 covered with the radiation shielding device 10 from the neck to the vicinity of the chest is sent into the tunnel portion 1A, and the head is within the circle of the transmission scan detector 3. Place it at rest. (Fig. 4)
<Procedure 6> The transmission scan source 4 is rotated around the head of the subject 5, and the gamma rays transmitted through the head are detected by the transmission scan detector 3. (Data collection by transmission scan)
<Procedure 7> The top plate 8 is pulled out, and the head of the subject 5 is placed in the circle of the emission scan detector 2 to be stationary. (Fig. 5)
<Procedure 8> The subject 5 is caused to suck the gas labeled with the positron emitting nuclide.
<Procedure 9> Gamma rays emitted from the positron emitting nuclide circulating in the head of the subject 5 are detected by the emission scan detector 2. (Data collection by emission scan)
<Procedure 10> The top plate 8 is pulled out and the head of the subject 5 is pulled out from the tunnel portion 1A of the gantry 1. (Figure 1)
<Procedure 11> An image is generated using data collected by transmission scan and emission scan.

  In the above embodiment, an example in which the shields 12 to 17 are divided into six pieces has been described. However, as long as the incidence of gamma rays from a portion other than the head to the emission scan detector 2 can be sufficiently prevented. The number of divisions may be more or less than this.

  In the above embodiment, the sides facing the necks of the shields 14 and 15 arranged on the left and right of the neck of the subject 5 are straight lines. You may make it the shape which approaches.

  In the above embodiment, the shields 12 and 13 are partly open on the side close to the face of the subject 5 when attached to the shield support 11 as shown in FIG. May be.

  In the above embodiment, the case where the emission scan detector 2 is arranged closer to the bed 9 than the transmission scan detector 3 in the gantry 1 is described. The invention is equally effective.

  Although the said Example demonstrated the structure which attaches / detaches the divided shielding bodies 12-17 to the shielding body support part 11 about the radiation shielding apparatus 10, you may comprise so that a part of shielding body may be opened and closed to right and left. . An example of the radiation shielding apparatus 20 configured as described above is shown in FIG. Here, FIG. 6A is a view of the radiation shielding device 20 attached to the bed 9 as seen from the foot side of the subject 5 placed on the top plate 8 in a supine position, and FIG. (A) is the figure which looked at the right side. 1 and the like are the same as those shown in FIG. 1, and the description thereof is omitted. Among the shields 21 to 23 made of a lead plate or the like constituting the radiation shielding device 20, the flat shield 23 that shields gamma rays radiated from the subject 5 to the back surface is fixed on the top plate 8. However, the shield 21 that covers the left half of the subject 5 has a structure in which a horizontal flat plate that shields radiation toward the front of the chest and a vertical flat plate that shields radiation above the shoulder are joined without gaps. A columnar shaft 26 attached horizontally to the lower left end of the vertical flat plate is rotatably held by two holding fittings 24 attached to the top plate 8. The shield 22 that covers the right half of the subject 5 has a structure that is substantially symmetrical to the shield 21. When the subject 5 gets on and off the top board 8, the shields 21 and 22 are opened to the left and right, respectively, as shown by the broken line in FIG. 6A, and closed during the examination as shown by the solid line. The structure covers the chest of the examiner 5 and the like.

  The present invention relates to a radiation shielding mechanism of a positron emission tomography apparatus.

It is a figure for demonstrating the test | inspection using the radiation shielding mechanism of this invention. It is a figure which shows an example of the radiation shielding mechanism of this invention. It is a figure which shows the structure of the radiation shielding mechanism of FIG. It is a figure for demonstrating the test | inspection using the radiation shielding mechanism of this invention. It is a figure for demonstrating the test | inspection using the radiation shielding mechanism of this invention. It is a figure which shows another example of the radiation shielding mechanism of this invention. It is a figure for demonstrating the test | inspection using the conventional radiation shielding mechanism.

Explanation of symbols

1: Gantry 1A: Tunnel portion 2: Emission scan detector 3: Transmission scan detector 4: Transmission scan source 5: Subject 6: Headrest 7: Bed base 8: Top plate 9: Bed 10: Radiation Shielding device 11: Shield support 11A: Stopper groove 11B: Fixing screw 11C: Screw hole 12: Shield 13: Shield 14: Shield 14A: Stopper 15: Shield 16: Shield 16A: Hole 17: Shield Body 17A: Hole 18: Shield 18A: Hole 19: Bogie 19A: Wheel 20: Radiation shielding device 21: Shield 22: Shield 23: Shield 24: Holding bracket 26: Shaft

Claims (4)

In a positron emission tomography apparatus including a bed on which a subject is placed and a gantry having a radiation detector arranged in a circumferential shape inside and having an opening for inserting the examination site of the subject at a central portion When performing an emission scan of the head of the subject placed on the bed, the radiation that is emitted from other than the head is prevented from entering the radiation detector and can be inserted into the opening. A positron emission tomography apparatus provided with a radiation shielding mechanism. 2. The positron emission tomography apparatus according to claim 1, wherein the radiation shielding mechanism covers all or a part of the body surface other than the head of the subject. 2. The positron emission tomography apparatus according to claim 1, wherein the radiation shielding mechanism includes a divided shielding body and a shielding body support portion that detachably supports the shielding body. The positron emission tomography apparatus according to claim 1, wherein the radiation shielding mechanism includes a divided shielding body and a shielding body supporting portion that supports a part of the shielding body so as to be opened and closed.

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