JP6144114B2 - Neutron capture therapy device and irradiation object position correction method - Google Patents

Description

  The present invention relates to a neutron capture therapy apparatus that irradiates an irradiated object with neutron rays and a position correction method for the irradiated object.

  Boron neutron capture therapy (BNCT) using a boron compound is known as a neutron capture therapy that kills cancer cells by neutron irradiation. In boron neutron capture therapy, a boron-containing drug is administered to a patient, boron is accumulated at a site where cancer cells are present, and the cancer cells are killed by irradiating the boron accumulated site with neutron beams.

  As a neutron capture therapy apparatus used in such neutron capture therapy, Patent Document 1 discloses a neutron emission apparatus that emits a neutron beam toward an irradiation target, and a neutron beam emitted from the neutron extraction apparatus is guided to the irradiation target. A therapeutic neutron irradiation apparatus including a vacuum conduit for focusing and a collimator that focuses neutron rays and increases the directivity of the neutron rays is described. In the therapeutic neutron irradiation apparatus of Patent Document 1, a test irradiation process is performed in which a test object is irradiated with a neutron beam on the irradiation target. Measure the actual activation when irradiated. Specifically, a gold wire for neutron measurement is attached to the surface and deep part of the target site in the irradiation target, and after irradiating the neutron beam for a certain time, the gold wire is pulled out and the activation amount of the gold wire is measured. The test irradiation process is performed.

JP 2004-233168 A

  By the way, the irradiation time of neutron beams in neutron capture therapy tends to be longer than the irradiation time of radiation in other radiotherapy. That is, in other radiotherapy, the irradiation time of the radiation is about several minutes, whereas in the neutron capture therapy, the irradiation time of the neutron beam is about several tens of minutes to one hour. In addition, in order to perform treatment with high accuracy by neutron capture therapy, it is necessary to restrain the irradiated object on the treatment table during neutron irradiation.

  Thus, in the neutron capture therapy, the irradiation time of the neutron beam to the irradiated object is long, and the patient must be restrained on the treatment table during the irradiation of the neutron beam, so that the patient is restrained for a long time. There is a problem that it causes pain. It is also conceivable to perform treatment without restraining the patient so as not to cause pain to the patient. However, the patient may move during irradiation with neutron beams. If the patient moves during irradiation with neutron beams in this way, the dose of neutron beams irradiated to the patient changes, which may reduce the accuracy of treatment.

  In view of such a problem, the present invention provides a neutron capture therapy apparatus that can suppress a reduction in treatment accuracy even when a patient moves during irradiation with a neutron beam, and a position correction method for a patient (irradiated body). Objective.

  The neutron capture therapy apparatus of the present invention is a neutron capture therapy apparatus that irradiates an irradiated object with a neutron beam, and a neutron beam generating part that generates a neutron beam, and a neutron beam generated by the neutron beam generating part A neutron beam irradiation unit that irradiates the irradiation object, a posture detection unit that detects the posture of the irradiated object when the neutron beam irradiation unit irradiates the irradiated object with the neutron beam, and an irradiation detected by the posture detection unit And a position correction unit that corrects the position of the irradiated object with respect to the neutron beam irradiation unit according to the posture of the body.

  According to the neutron capture therapy apparatus of the present invention, the posture detection unit detects the posture of the irradiated object during irradiation of the neutron beam, and the position correction unit corrects the position of the irradiated object according to the posture of the irradiated object. To do. Therefore, even if the irradiated body moves during neutron irradiation, the position detection unit detects the movement of the irradiated body and the position correction unit corrects the position of the irradiated body. It is possible to suppress the position shift in the vicinity. Accordingly, even if the irradiated body moves during irradiation with neutron radiation, the dose of neutron radiation irradiated to the irradiated body is unlikely to change, so that a reduction in treatment accuracy can be suppressed.

  Further, the irradiated object is placed on a treatment table movable with respect to the neutron irradiation unit, and the position correction unit may correct the position of the irradiated object by moving the treatment table. . In this way, the position correction unit moves the treatment table to correct the position of the irradiated object, so that, for example, the treatment table can be automatically moved or the treatment table can be moved by remote operation. Thus, the position of the irradiated object can be easily corrected.

  Further, the attitude detection unit includes a first neutron beam detection unit capable of detecting the neutron beam irradiated by the neutron beam irradiation unit, and the first neutron beam detection unit is attached to the irradiated object. Good. By the way, if the irradiated body moves during the irradiation of the neutron beam, the dose of the neutron beam in the vicinity of the irradiated body changes. Therefore, if the neutron beam dose is detected by attaching the first neutron beam detector to the irradiated body as described above, the change in the posture of the irradiated body is detected by detecting the change in the neutron beam dose. be able to. Accordingly, it is possible to detect the movement of the irradiated object during neutron irradiation, and to correct the position of the irradiated object when the irradiated object moves, thereby preventing a reduction in treatment accuracy. .

  The posture detection unit includes a second neutron beam detection unit capable of detecting the neutron beam irradiated by the neutron beam irradiation unit, and the second neutron beam detection unit is fixed around the irradiated object. May be. If the second neutron beam detector is fixed around the irradiated body in this way, the movement of the irradiated body during neutron irradiation is detected by detecting the neutron beam dose around the irradiated body. Can be detected.

  The neutron beam generation unit includes an accelerator that emits a charged particle beam and a target that generates a neutron beam when irradiated with the charged particle beam, and detects a current of the charged particle beam irradiated to the target. A current monitor may be further provided. By the way, when detecting a change in the posture of the irradiated object by detecting a change in the dose of the neutron beam in the vicinity of the irradiated object, the irradiation is performed when the change in the neutron beam is caused by a defect in the neutron beam generating unit. There is a possibility that a change in posture of the body is erroneously detected. However, as in the present invention, if a current monitor for detecting the current of the charged particle beam irradiated to the target is provided, a fault in the neutron beam generation unit can be detected by detecting a change in the current of the charged particle beam. Can do. Therefore, if the neutron dose in the vicinity of the irradiated object changes and the detected value of the current monitor changes, the cause of the change in the neutron beam dose in the vicinity of the irradiated object is identified as a malfunction of the neutron beam generation unit. be able to. Therefore, by detecting the current change with the current monitor, the possibility of erroneous detection of the movement of the irradiated object can be reduced.

  Further, the neutron beam irradiation unit has a collimator having an opening for shaping the irradiation field of the neutron beam, and the neutron beam generation unit is provided between the neutron beam outlet and the neutron beam generation unit in the collimator. The 3rd neutron beam detection part which can detect the neutron beam produced | generated by (4) may be provided. As described above, if the third neutron beam detection unit capable of detecting the neutron beam generated by the neutron beam generation unit is provided, a defect of the neutron beam generation unit is detected by detecting the neutron beam generated by the neutron beam generation unit. Can be detected. Therefore, when detecting the neutron beam dose in the vicinity of the irradiated body to detect the posture of the irradiated body, the neutron beam dose in the vicinity of the irradiated body changes and the detection value in the third neutron beam detector is When it has changed, the cause of the change in the neutron beam dose in the vicinity of the irradiated object can be identified as a defect in the neutron beam generation unit. Therefore, the possibility that the third neutron beam detection unit detects the dose of the neutron beam on the neutron beam generation unit side can erroneously detect the motion of the irradiated object can be reduced.

  An irradiation object position correction method according to the present invention is an irradiation object position correction method performed using a neutron capture therapy apparatus that irradiates an irradiation object with neutron rays, and a neutron beam generation step for generating a neutron beam A neutron beam irradiation step for irradiating the irradiated body with the neutron beam generated in the neutron beam generation step, and an attitude detection step for detecting the attitude of the irradiated body when the irradiated neutron beam is irradiated on the irradiated body And a position correction step for correcting the position of the irradiated object in accordance with the position of the irradiated object detected in the posture detecting step.

  According to the method for correcting the position of the irradiated object according to the present invention, the position of the irradiated object is detected in the position detecting step and the position of the irradiated object is corrected in the position correcting step during the neutron beam irradiation. Therefore, even if the irradiated object moves during the neutron irradiation, the movement of the irradiated object is detected and the position of the irradiated object is corrected, so that the displacement of the vicinity of the affected part with respect to the neutron irradiated part is suppressed. It becomes possible to do. Therefore, even if the irradiated body moves during irradiation with neutron beams, the state of the neutron beam irradiated to the irradiated body is unlikely to change, so that it is possible to suppress a reduction in treatment accuracy.

  ADVANTAGE OF THE INVENTION According to this invention, even if a patient moves during irradiation of a neutron beam, it can suppress the precision fall of a treatment.

It is a figure which shows arrangement | positioning of the neutron capture therapy apparatus of 1st Embodiment. It is a figure which shows the neutron beam irradiation part vicinity in the neutron capture therapy apparatus of FIG. It is a perspective view which shows the treatment table in the neutron capture therapy apparatus of FIG. It is a figure which shows a scintillation detector. It is a figure which shows the neutron beam irradiation part vicinity in the neutron capture therapy apparatus of 2nd Embodiment.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a neutron capture therapy apparatus and an irradiation object position correction method according to the present invention will be described in detail with reference to the drawings.

(First embodiment)
As shown in FIGS. 1 and 2, the neutron capture therapy apparatus 1 for cancer treatment with boron neutron capture therapy, patients boron ^{(10 B)} has been administered (irradiation object) boron S is integrated It is a device that treats cancer by irradiating the site with neutrons. The neutron capture therapy apparatus 1 has an irradiation chamber 2 that irradiates a patient S restrained by a treatment table 3 with a neutron beam N and treats the patient S with cancer. A camera 4 for photographing is arranged. This camera 4 is, for example, a CCD camera.

  Preparatory work such as restraining the patient S on the treatment table 3 is performed in a preparation room (not shown) outside the irradiation room 2, and the treatment table 3 on which the patient S is restrained is moved from the preparation room to the irradiation room 2. . The neutron capture therapy apparatus 1 includes a neutron beam generator 10 that generates a neutron beam N for treatment, and a neutron beam irradiator that irradiates the patient S restrained by the treatment table 3 in the irradiation chamber 2 with the neutron beam N. 20.

  The neutron beam generation unit 10 scans the charged particle beam L with respect to the target T by scanning the charged particle beam L, the beam transport path 12 for transporting the charged particle beam L generated by the cyclotron 11, and the charged particle beam L with respect to the target T. The charged particle beam scanning unit 13 that controls the irradiation of the current and the current monitor 16 that measures the current of the charged particle beam L are provided. The cyclotron 11 and the beam transport path 12 are disposed in a charged particle beam generation chamber 14 having a substantially rectangular shape. The charged particle beam generation chamber 14 is a closed space covered with a concrete shielding wall W. is there. The charged particle beam scanning unit 13 controls the irradiation position of the charged particle beam L with respect to the target T, for example, and the current monitor 16 measures the current of the charged particle beam L irradiated to the target T.

  The cyclotron 11 is an accelerator that generates charged particle beams L such as proton beams by accelerating charged particles such as protons. The cyclotron 11 has, for example, a beam radius of 40 mm and a capability of generating a charged particle beam L of 60 kW (= 30 MeV × 2 mA). Instead of the cyclotron 11, another accelerator such as a synchrotron, a synchrocyclotron, or a linac may be used.

  One end of the beam transport path 12 is connected to the cyclotron 11. The beam transport path 12 includes a beam adjusting unit 15 that adjusts the charged particle beam L. The beam adjustment unit 15 includes a horizontal steering and a horizontal vertical steering that adjust the axis of the charged particle beam L, a quadrupole electromagnet that suppresses the divergence of the charged particle beam L, and a four-way slit that shapes the charged particle beam L. Etc. The beam transport path 12 only needs to have a function of transporting the charged particle beam L, and the beam adjustment unit 15 may not be provided.

  The charged particle beam L transported by the beam transport path 12 is irradiated to the target T with the irradiation position controlled by the charged particle beam scanning unit 13. The charged particle beam scanning unit 13 may be omitted, and the charged particle beam L may always be irradiated to the same portion of the target T. The target T generates a neutron beam N when irradiated with the charged particle beam L. The target T is made of, for example, beryllium (Be), lithium (Li), tantalum (Ta), or tungsten (W), and has a disk shape with a diameter of 160 mm. The neutron beam N generated by the target T is irradiated toward the patient S in the irradiation chamber 2 by the neutron beam irradiation unit 20.

  The neutron beam irradiation unit 20 includes a moderator 21 that decelerates the neutron beam N emitted from the target T, and a shield 22 that shields radiation such as neutron beam N and gamma rays from being emitted to the outside. The moderator 21 and the shield 22 constitute a moderator.

  The moderator 21 has, for example, a laminated structure made of a plurality of different materials, and the material of the moderator 21 is appropriately selected according to various conditions such as the energy of the charged particle beam L. Specifically, for example, when the output from the cyclotron 11 is a proton beam of 30 MeV and a beryllium target is used as the target T, the material of the moderator 21 can be lead, iron, aluminum, or calcium fluoride. When the output from the cyclotron 11 is a proton beam of 11 MeV and a beryllium target is used as the target T, the material of the moderator 21 can be heavy water (D2O) or lead fluoride.

  The shield 22 is provided so as to surround the moderator 21, and has a function of shielding the neutron beam N and radiation such as gamma rays generated with the generation of the neutron beam N from being emitted to the outside of the shield 22. Have The shield 22 is at least partially embedded in a wall W1 separating the charged particle beam generation chamber 14 and the irradiation chamber 2. Further, a wall body 23 that forms a part of the side wall surface of the irradiation chamber 2 is provided between the irradiation chamber 2 and the shield 22. The wall body 23 is provided with a collimator mounting portion 23a serving as an output port of the neutron beam N. A collimator 31 for defining an irradiation field of the neutron beam N is fixed to the collimator mounting portion 23a.

  In the neutron beam irradiation unit 20 described above, the target T is irradiated with the charged particle beam L, and the target T generates the neutron beam N along with this. The neutron beam N generated by the target T is decelerated while passing through the moderator 21, and the neutron beam N emitted from the moderator 21 passes through the collimator 31 to the patient S on the treatment table 3. Irradiated. Here, as the neutron beam N, a thermal neutron beam or an epithermal neutron beam having relatively low energy can be used.

  The treatment table 3 functions as a mounting table used in neutron capture therapy, and can be moved from the preparation room (not shown) to the irradiation room 2 while the patient S is placed thereon. The treatment table 3 includes a base portion 32 that constitutes the base of the treatment table 3, a caster 33 that enables the base portion 32 to move on the floor surface, a top plate 34 on which the patient S is placed, and a top plate 34. And a robot arm 35 for moving the frame relative to the base portion 32.

  As shown in FIG. 3, the base portion 32 includes a rectangular parallelepiped base portion 32 a and a rectangular parallelepiped support portion 32 b that is positioned above the base portion 32 a and supports the robot arm 35. In plan view, the support portion 32b is housed inside the base portion 32a, and the robot arm 35 is fixed to the upper surface of the support portion 32b. Four casters 33 are attached to the lower portion of the base portion 32a. Here, a driving force such as a motor may be applied to the casters 33. In this case, since the casters 33 can be easily rolled on the floor surface, the treatment table 3 can be easily moved in the horizontal direction. become.

  The robot arm 35 is for moving the top plate 34 relative to the base portion 32, and can move the patient S restrained on the top plate 34 relative to the collimator 31. . The robot arm 35 includes an elevating unit 35a disposed on the upper surface of the base unit 32, a first arm unit 35b provided at one end thereof so as to be rotatable about the vertical rotation axis A1 with respect to the elevating unit 35a, and a first arm unit 35b. A second arm portion 35c provided to be rotatable about a vertical rotation axis A2 with respect to the other end side of the arm portion 35b. As described above, the robot arm 35 has two vertical rotation axes A1 and A2 that are separated in the horizontal direction.

  The top plate 34 has a rectangular shape in plan view, and the length in the longitudinal direction of the top plate 34 is a length that allows the patient S to lie on the top plate 34 (for example, 2 m). ing. The position of the top plate 34 relative to the base portion 32 can be adjusted three-dimensionally by the movement and rotation of the robot arm 35. The top plate 34 is attached to the second arm portion 35c so as to be rotatable about the vertical rotation axis A3. The top plate 34 may be provided with a restraining tool (not shown) for restraining the patient S on the top plate 34.

  Further, in the robot arm 35 described above, the first arm portion 35b is rotated about the vertical rotation axis A1 with respect to the lifting and lowering portion 35a, and the second arm portion 35c is rotated with respect to the first arm portion 35b. The top plate 34 can be moved to a desired position in the horizontal plane by rotating around the A2 and rotating the top plate 34 around the vertical rotation axis A3 with respect to the second arm portion 35c. Further, the top plate 34 can be moved in the vertical direction with respect to the base portion 32 by moving the elevating portion 35 a up and down relative to the support portion 32 b of the base portion 32. Thus, since the top plate 34 can be moved three-dimensionally with respect to the base portion 32, the degree of freedom of the posture of the patient S relative to the collimator 31 can be increased.

  The patient S restrained on the top plate 34 is irradiated with the neutron beam N that has passed through the opening 31 a of the collimator 31. The collimator 31 has a substantially rectangular parallelepiped shape, for example, and has an opening 31a for defining the irradiation range of the neutron beam N at the center. The outer shape of the collimator 31 corresponds to the inner shape of the collimator mounting portion 23 a in the wall body 23, and the collimator 31 is fixed in a state of being fitted to the collimator mounting portion 23 a of the wall body 23.

  By the way, in the neutron capture therapy performed using the neutron capture therapy apparatus 1 configured as described above, the irradiation of the patient S with the neutron beam N is performed in comparison with the irradiation time of radiation when treatment is performed using other radiation. It takes a long time and it is necessary to restrain the patient S on the treatment table 3 during irradiation with the neutron beam N. Thus, since the patient S is restrained on the treatment table 3 for a long time, the patient S may be painful. It is also conceivable to perform treatment without restraining the patient S so as not to give pain to the patient S, but the affected part of the patient S may move during irradiation with the neutron beam N. If the affected part of the patient S moves during the irradiation of the neutron beam N, the dose of the neutron beam N irradiated to the patient S changes, so the irradiation of the neutron beam N cannot be performed according to the treatment plan, and the accuracy of the treatment is lowered. there's a possibility that.

  Therefore, in order to solve the above-described problems, the neutron capture therapy apparatus 1 corrects the position of the patient S on the treatment table 3 and the position of the patient S with respect to the neutron beam irradiation unit 20. And a position correction unit 50. The posture detection unit 40 and the position correction unit 50 are, for example, software built in a computer provided in a monitoring room (not shown) separate from the irradiation chamber 2, and the posture of the patient S by the posture detection unit 40. Detection and position correction of the patient S by the position correction unit 50 can be automatically performed.

  As shown in FIGS. 2 and 4, the attitude detection unit 40 is connected to a scintillation detector (first neutron beam detection unit) 41. The scintillation detector 41 photoelectrically converts the light transmitted from the scintillator 41a that converts the incident neutron beam N into light, the light guide 41b that transmits light from the scintillator 41a, and the light guide 41b, and generates an electric signal E Is provided.

  The scintillator 41a is a phosphor that converts the neutron beam N incident on the scintillator 41a into light, and an internal crystal is excited according to the amount of incident neutron beam N to generate scintillation light. The scintillator 41a is attached to the head of the patient S with a tape, for example, and receives the neutron beam N irradiated on the head of the patient S to emit light. The light guide 41b is composed of a bundle of flexible optical fibers, for example, and extends from the irradiation chamber 2 to a separate monitoring room. The light guide 41b transmits the light generated by the scintillator 41a to the photodetector 41c in the monitoring room. The light detector 41 c detects light from the light guide 41 b and outputs an electric signal E to the attitude detection unit 40. As the photodetector 41c, for example, a phototube or a photomultiplier tube can be used.

  The posture detection unit 40 detects the posture of the patient S placed on the treatment table 3 by receiving the electric signal E from the photodetector 41c. That is, when the patient S moves on the treatment table 3, the neutron field around the scintillator 41a changes, so that the optical signal and the electrical signal E of the scintillator 41a change. Further, since the posture detection unit 40 holds in advance data that associates the state of the neutron field around the scintillator 41a with the posture state of the patient S, the posture of the patient S is determined from the state of the neutron field detected by the scintillator 41a. Can be specified. Therefore, the posture detection unit 40 detects the movement near the affected part of the patient S by detecting a change in the electrical signal E accompanying the fluctuation of the neutron field, and detects the movement near the affected part of the patient S when detecting the movement near the affected part of the patient S. A signal to the effect that the movement is detected is output to the position correction unit 50.

  In addition, a signal relating to the current of the charged particle beam L is output from the above-described current monitor 16 to the attitude detection unit 40. The posture detection unit 40 detects the posture of the patient S as described above when the signal indicating that the signal related to the current has changed from the current monitor 16 has not been received. However, when the posture detection unit 40 receives a signal indicating that the current has changed from the current monitor 16, the posture detection unit 40 stops detecting the posture of the patient S and generates a neutron beam, assuming that a problem has occurred in the neutron beam generation unit 10. The output of the neutron beam N by the unit 10 is stopped.

  When the position correction unit 50 receives from the posture detection unit 40 a signal indicating that the movement in the vicinity of the affected part of the patient S has been detected, the position correction unit 50 includes the lifting unit 35a (see FIG. 3) in the robot arm 35 of the treatment table 3, and the first and first The position of the patient S with respect to the neutron beam irradiation unit 20 is corrected by outputting a signal to the second arm portions 35b and 35c and driving the elevating unit 35a and the arm portions 35b and 35c. At this time, the position correction unit 50 corrects the position of the patient S so that the dose of the neutron beam N irradiated to the patient S that has changed as the patient S moves is restored. That is, the position correction unit 50 corrects the position of the patient S with respect to the neutron beam irradiation unit 20 and controls the position of the patient S so that the affected part of the patient S is irradiated with the neutron beam N as planned.

  Next, a method for correcting the position of the patient S in the neutron capture therapy apparatus 1 will be described in detail. In the following description, it is assumed that the affected part (cancer cell) of the patient S exists in the head of the patient S. First, preparation work such as placing the patient S on the treatment table 3 is performed in a preparation room (not shown) separate from the irradiation room 2. After moving the treatment table 3 on which the patient S is placed into the irradiation chamber 2, the robot arm 35 is driven so that the head of the patient S approaches the opening 31 a of the collimator 31 and irradiates the neutron beam N. The patient S is aligned with the collimator 31 so that the position is located at the affected part of the patient S. Thereafter, treatment is started by irradiating the patient S with the neutron beam N. In addition, when the affected part of the patient S exists in the head of the patient S, the patient S is positioned so that the head of the patient S is in contact with the collimator 31 as described above, but the affected part exists in another part. When doing so, the patient S is positioned so that the part contacts the collimator 31.

  Specifically, as shown in FIG. 1, the cyclotron 11 generates a charged particle beam L and irradiates the target T with the charged particle beam L via the beam transport path 12 and the charged particle beam scanning unit 13. Then, as shown in FIG. 2, the target T generates a neutron beam N (neutron beam generation step). The neutron beam N generated by the target T is irradiated toward the patient S after being decelerated by the moderator 21 and after the irradiation range is defined by the opening 31a of the collimator 31 (neutron beam irradiation step).

  As described above, when the patient S moves on the treatment table 3 while the neutron beam N is irradiated toward the patient S, the neutron field around the scintillator 41a changes accordingly, and is output from the scintillation detector 41. The electric signal E (see FIG. 4) changes. The posture detection unit 40 detects the posture of the patient S by detecting a change in the electric signal E (posture detection step).

  When the posture detection unit 40 detects the posture of the patient S, the position correction unit 50 moves the lift unit 35a and the arm units 35b and 35c of the robot arm 35 according to the posture of the patient S detected by the posture detection unit 40. By driving, the position of the patient S is corrected with respect to the neutron beam irradiation unit 20 (position correction step). In this position correction, for example, the scintillation detector 41 outputs the scintillator 41a with respect to the neutron beam irradiation unit 20 when the position of the scintillator 41a deviates below a normal position (a position where the patient S can be irradiated with a dose according to the treatment plan). When the electrical signal E changes, the patient S is moved upward by the elevating part 35a. Thus, during the irradiation of the neutron beam N, the patient S is detected by the posture detection unit 40 and the position of the patient S by the position correction unit 50 so that the patient S is irradiated with the neutron beam N according to the treatment plan. Correction is performed.

  As described above, according to the position correction method of the patient S using the neutron capture therapy device 1 and the neutron capture therapy device 1, the posture detection unit 40 detects the posture of the patient S during irradiation of the neutron beam N, and the patient S The position correction unit 50 corrects the position of the patient S according to the posture. Therefore, even if the patient S moves during the irradiation of the neutron beam N, the posture detection unit 40 detects the movement of the patient S near the affected part and the position correction unit 50 corrects the position of the patient S. It is possible to suppress a position shift near the affected part with respect to the part 20.

  Therefore, even if the patient S moves during the irradiation of the neutron beam N, the dose of the neutron beam N irradiated to the patient S becomes difficult to change, so that it is possible to suppress a decrease in the accuracy of treatment. Furthermore, since the position of the patient S relative to the neutron beam irradiation unit 20 is corrected even when the patient S moves, it is not necessary to strongly restrain the patient S on the treatment table 3. Therefore, it becomes possible to relieve the pain of the patient S due to restraint.

  The patient S is placed on the treatment table 3 that is movable with respect to the neutron beam irradiation unit 20, and the position correction unit 50 drives the robot arm 35 of the treatment table 3 to position the patient S. Is corrected. Thus, since the position correction by the position correction unit 50 is automated, the position correction of the patient S can be easily performed. Moreover, since the position of the patient S with respect to the neutron beam irradiation unit 20 can be moved three-dimensionally by including the robot arm 35, highly accurate position correction by the position correction unit 50 is realized.

  In addition, the posture detection unit 40 detects the posture of the patient S by detecting a change in the state of the neutron beam N using the scintillator 41 a attached to the patient S. The scintillator 41a is affixed near the affected area of the patient S. Therefore, when the position of the affected area of the patient S changes, the neutron field around the scintillator 41a is surely changed, so that the posture detecting section 40 can detect a change in the position near the affected area of the patient S. As described above, the movement of the patient S near the affected part at the time of irradiation with the neutron beam N can be detected, and the position of the patient S can be corrected when the patient S moves. be able to.

  In addition, since the neutron capture therapy apparatus 1 includes the current monitor 16 that measures the current of the charged particle beam L irradiated to the target T, the neutron beam generation unit 10 is measured by measuring the current change of the charged particle beam L. Can be detected. Therefore, when the electric signal E output from the scintillation detector 41 changes and the detection value of the current monitor 16 changes, the cause of the change in the electric signal E output from the scintillation detector 41 is determined as a neutron beam generator. Ten defects can be identified. Therefore, by measuring the current change with the current monitor 16, it is possible to reduce the possibility that the posture detection unit 40 erroneously detects the movement of the patient S near the affected part.

(Second Embodiment)
As shown in FIG. 5, the neutron capture therapy apparatus 61 of the second embodiment is different from the neutron capture therapy apparatus 1 of the first embodiment in that a scintillator 41 a is replaced with a scintillation detector 41 attached to a patient S. The scintillators 71a and 81a use scintillation detectors (second neutron beam detectors) 71 and 81 fixed around the patient S, and the scintillation detector (third neutron beam) instead of the current monitor 16 (Detection part) 101 is mentioned. Therefore, below, the description which overlaps with 1st Embodiment is abbreviate | omitted, and demonstrates scintillation detector 71,81,101 mainly.

  The scintillation detectors 71 and 81 mainly measure the neutron beam N reflected or scattered from the patient S. The scintillation detector 71 includes a scintillator 71a, a light guide 71b, and a light detector 71c, like the scintillation detector 41 of the first embodiment. The scintillation detector 71 is different from the scintillation detector 41 of the first embodiment in that the scintillator 71 a is fixed by a support portion 37 located near the head of the patient S. The support portion 37 is attached to the side surface of the top plate 34 so as to extend upward from the top plate 34.

  The scintillation detector 81 includes a scintillator 81a, a light guide 81b, and a light detector 81c, like the scintillation detector 41 of the first embodiment. The scintillation detector 81 is different from the scintillation detector 41 of the first embodiment in that the scintillator 81a is attached to the side surface of the top plate 34 near the head of the patient S.

  The scintillation detector 101 also includes a scintillator 101a, a light guide 101b, and a light detector 101c, like the scintillation detector 41 of the first embodiment. The scintillation detector 101 is provided to measure not the neutron beam N irradiated to the patient S but the neutron beam N generated by the neutron beam generator 10.

  The scintillator 101a is fixed in a hole 22b formed in the opening 22a of the shield 22 that communicates with the opening 31a of the collimator 31, and is fixed in a state of being buried in the hole 22b of the moderator. The scintillator 101a measures the neutron beam N generated by the target T. The light guide 101b extends from the scintillator 101a toward the outside of the shield 22, and is connected to, for example, a photodetector 101c provided in a monitoring room outside the irradiation chamber 2. The photodetector 101c outputs an electrical signal E3 to the attitude detection unit 90 as the neutron beam N is detected by the scintillator 101a. The attitude detection unit 90 can measure the dose of the neutron beam N generated by the neutron beam generation unit 10 (irradiated from the neutron beam generation unit 10) by receiving the electrical signal E3 from the photodetector 101c. ing.

  Similar to the posture detection unit 40 of the first embodiment, the posture detection unit 90 receives the electric signals E1 and E2 from the photodetectors 71c and 81c, detects the posture of the patient S, and moves around the affected part of the patient S. Is detected, a signal indicating that the movement of the patient S near the affected part has been detected is output to the position correction unit 50. Note that since the posture detection method of the patient S in the posture detection unit 90 is the same as the posture detection method of the patient S in the posture detection unit 40 of the first embodiment, detailed description thereof is omitted.

  The posture detection unit 90 detects the posture of the patient S when the signal indicating that the dose of the neutron beam N irradiated from the neutron beam generation unit 10 has changed has not been received from the scintillation detector 101. However, when the attitude detection unit 90 receives a signal from the scintillation detector 101 indicating that the dose of the neutron beam N irradiated from the neutron beam generation unit 10 has changed, a problem has occurred in the neutron beam generation unit 10. As described above, the posture detection of the patient S is stopped and the output of the neutron beam N by the neutron beam generation unit 10 is stopped.

  As described above, according to the position correction method of the patient S using the neutron capture therapy device 61 and the neutron capture therapy device 61, the posture detection unit 90 detects the posture of the patient S during irradiation of the neutron beam N, and the patient S The position correction unit 50 corrects the position of the patient S according to the posture. Therefore, even if the patient S moves during irradiation with the neutron beam N, the posture detection unit 90 detects the movement of the patient S near the affected part and the position correction unit 50 corrects the position of the patient S. The same effect as the form can be obtained.

  In the neutron capture therapy device 61, since the scintillation detectors 71 and 81 are fixed around the patient S, the dose of the neutron beam N around the patient S is measured to measure the dose of the neutron beam N. The movement of the patient S near the affected part can be detected. Since each scintillator 71a and 81a is being fixed around patient S, even if patient S moves, each scintillator 71a and 81a does not fall off. Furthermore, since the plurality of scintillators 71a and 81a are fixed around the patient S, the neutron beam N reflected or scattered from the patient S can be detected at a plurality of locations. Therefore, since the neutron field around the patient S can be detected three-dimensionally, the detection accuracy of the movement of the patient S and the accuracy of position correction of the patient S can be improved.

  Further, since the neutron capture therapy apparatus 61 includes the scintillation detector 101 that can measure the neutron beam N generated by the neutron beam generation unit 10, the neutron beam generation unit 10 generates (neutron beam generation unit 10). By measuring the neutron beam N (irradiated from the above), the malfunction of the neutron beam generation unit 10 can be detected. Therefore, when measuring the dose of the neutron beam N in the vicinity of the patient S and detecting the posture of the patient S, the electric signal E3 in which the dose of the neutron beam N in the vicinity of the patient S is changed and output from the scintillation detector 101 is obtained. When changed, the cause of the change in the dose of the neutron beam N in the vicinity of the patient S can be identified as a malfunction of the neutron beam generation unit 10. Therefore, when the scintillation detector 101 measures the dose of the neutron beam N irradiated from the neutron beam generation unit 10, the possibility that the posture detection unit 90 erroneously detects the movement of the patient S can be reduced.

  As mentioned above, although embodiment of this invention was described, this invention is not restricted to the said embodiment, You may change in the range which does not change the summary described in each claim.

  In the above embodiment, the position correction unit 50 drives the robot arm 35 of the treatment table 3 to correct the position of the patient S with respect to the neutron beam irradiation unit 20, but the position correction method of the patient S is not limited to the above embodiment. . For example, the position correction of the patient S may be performed by prompting the patient S to correct the posture by voice. Furthermore, in addition to the position correction of the patient S, the irradiation time and irradiation position of the neutron beam N on the patient S may be changed.

  In the above embodiment, the posture of the patient S is detected by the scintillation detectors 41, 71, 81. However, the posture detection method of the patient S is not limited to the above. For example, the posture of the patient S may be detected by the camera 4 in the irradiation chamber 2, or the posture of the patient S may be detected by an optical monitor.

  Moreover, although the scintillator 41a of 1st Embodiment was affixed on the patient S and the scintillators 71a and 81a of 2nd Embodiment were being fixed around the patient S, these scintillators 41a, 71a, and 81a should be used simultaneously. Is also possible. Further, the current monitor 16 of the first embodiment may be provided in the neutron capture therapy apparatus 61 of the second embodiment, and the scintillation detector 101 of the second embodiment is provided in the neutron capture therapy apparatus 1 of the first embodiment. May be. Further, instead of the scintillation detectors 41, 71, 81, another neutron beam detector may be used.

  Further, the scintillator 41a of the first embodiment may be attached to a place other than the head of the patient S, and the means for attaching the scintillator 41a is not limited to a tape. That is, the scintillator 41a may be attached to the patient S with, for example, an adhesive seal. Further, the scintillator 41a may be affixed to the headgear or the like attached to the patient S, and may be indirectly affixed to the patient S in this way.

  Further, the attachment positions of the scintillators 71a and 81a of the second embodiment are not limited to the above embodiment. That is, the scintillators 71a and 81a of the second embodiment may be fixed anywhere around the patient S, for example, may be fixed to the wall of the irradiation chamber 2. Further, the number and arrangement of scintillators in the above embodiment can be changed as appropriate.

  In addition, the scintillator 101 a of the second embodiment is fixed in the hole 22 b formed in the opening 22 a of the shield 22. However, the arrangement position of the scintillator 101a is not limited to the above, and may be arranged anywhere from the target T to the exit of the neutron beam N in the collimator 31.

  Moreover, although the patient S was mounted so that it might lie on the treatment table 3, the patient S may be mounted in the sitting state. Furthermore, the configuration of the treatment table 3, the neutron beam generation unit 10, and the neutron beam irradiation unit 20 and the arrangement of each device in the neutron capture therapy apparatus 1 can be appropriately changed.

  Further, the patient S may be placed on the treatment table 3 without being restrained, and the patient S may be lightly restrained on the treatment table 3. Here, “slightly restrained” means that the patient S is restrained to such an extent that the patient S can move the body to some extent. For example, the patient S is provided with a gap so that the patient S does not fall from the treatment table 3. For example, the body can be wound with a restraining band.

DESCRIPTION OF SYMBOLS 1 ... Neutron capture therapy apparatus, 3 ... Treatment table, 10 ... Neutron beam generation part, 11 ... Cyclotron (accelerator), 16 ... Current monitor, 20 ... Neutron beam irradiation part, 31 ... Collimator, 31a ... Aperture, 40, 90 ... Attitude detection unit, 41... Scintillation detector (first neutron beam detection unit), 41a, 71a, 81a, 101a ... scintillator, 50 ... position correction unit, 71, 81 ... scintillation detector (second neutron beam detection unit) ), 101... Scintillation detector (third neutron beam detector), L... Charged particle beam, N... Neutron beam, S... Patient (irradiated body), T.

Claims (5)

A neutron capture therapy device that irradiates an irradiated object with a neutron beam,
A neutron beam generator for generating the neutron beam;
A neutron beam irradiation unit that irradiates the irradiated object with the neutron beam generated by the neutron beam generation unit;
A posture detection unit that detects a posture of the irradiated body when the irradiated body is irradiating the irradiated body with the neutron beam;
A position correction unit that corrects the position of the irradiated object with respect to the neutron irradiation unit according to the position of the irradiated object detected by the posture detection unit;
The posture detection unit includes a first neutron beam detection unit capable of detecting the neutron beam irradiated by the neutron beam irradiation unit,
The first neutron beam detection unit is affixed to the irradiated object, and the position correction unit is based on a change in the state of the neutron beam detected by the first neutron beam detection unit of the posture detection unit. A neutron capture therapy apparatus that corrects the position of an irradiation body . The irradiated object is placed on a treatment table movable with respect to the neutron beam irradiation unit,
The neutron capture therapy apparatus according to claim 1, wherein the position correction unit corrects the position of the irradiated object by moving the treatment table. The posture detection unit includes a second neutron beam detection unit capable of detecting the neutron beam irradiated by the neutron beam irradiation unit,
The neutron capture therapy apparatus according to claim 1 or 2 , wherein the second neutron beam detector is fixed around the irradiated body. The neutron beam generation unit includes an accelerator that emits a charged particle beam, and a target that generates the neutron beam by being irradiated with the charged particle beam.
The neutron capture therapy apparatus according to any one of claims 1 to 3 , further comprising a current monitor that detects a current of the charged particle beam irradiated to the target. The neutron beam irradiation unit has a collimator having an opening for shaping the irradiation field of the neutron beam,
A third neutron beam detection unit capable of detecting the neutron beam generated by the neutron beam generation unit is provided between the exit of the neutron beam and the neutron beam generation unit in the collimator. The neutron capture therapy apparatus according to any one of claims 1 to 3 .

Images