RADIOTHERAPY CALIBRATION

Abstract

A radiotherapy apparatus is disclosed, with a linear accelerator for producing a beam of electrons, a target aligned with the electron beam, the target being capable of producing photons when electrons are incident thereon, and a material which is capable of producing neutrons when photons of sufficient energy are incident thereon. A neutron detector capable of providing a signal to a controller of the linear accelerator is provided, the controller being capable of varying the energy of the electrons of the electron beam.

Claims

1. A radiotherapy apparatus, comprising: a linear accelerator for producing a beam of electrons; a target aligned with the electron beam, wherein the target produces photons when electrons are incident thereon; and a material which produces neutrons when photons of sufficient energy are incident thereon; and a neutron detector configured to provide a signal to a controller of the linear accelerator, wherein the controller is configured to vary the energy of the electrons of the electron beam.

2. The radiotherapy apparatus according to claim 1, wherein the target comprises the material.

3. The radiotherapy apparatus according to claim 1, wherein the material is tungsten.

4. The radiotherapy apparatus according to claim 1, wherein the material produces neutrons when photons of at least 7.2 MeV are incident thereon.

5. The radiotherapy apparatus according to claim 1, wherein the neutron detector provides a predetermined signal when it detects incident radiation above a predetermined background level.

6. The radiotherapy apparatus according to claim 1, wherein the neutron detector comprises a Helium-3 proportional counter surrounded by a moderator.

7. The radiotherapy apparatus according to claim 6, wherein the moderator is polyethylene.

8. The radiotherapy apparatus according to claim 6, wherein the moderator is substantially spherical.

9. The radiotherapy apparatus according to claim 1, wherein the controller modulates the output of the linear accelerator by varying the strength of a radio-frequency electromagnetic field applied to the linear accelerator.

10. The radiotherapy apparatus according to claim 5, wherein the controller increases the energy of the electrons of the electron beam of the linear accelerator if the predetermined signal is not received from the neutron detector.

11. The radiotherapy apparatus according to claim 10, wherein the controller increases the energy of the electrons by a pre-determined percentage of a maximum output of the linear accelerator.

12. The radiotherapy apparatus according to claim 5, wherein the neutron detector provides a second predetermined signal to the controller if the detected incident radiation rises above a second predetermined level.

13. The radiotherapy apparatus according to claim 12, wherein the controller decreases the energy of the electrons of the electron beam of the linear accelerator if the second predetermined signal is received from the neutron detector.

14. A method of calibrating the output of a radiotherapy apparatus, comprising the steps of: positioning a neutron detector relative to a linear accelerator such that the neutron detector is clear of any electron or photon beam generated by the linear accelerator; providing, with the neutron detector, a signal to a controller of the linear accelerator; and varying energy of electrons generated by the linear accelerator in response to the signal.

15. The method according to claim 14, wherein the calibration occurs continuously during operation of the radiotherapy apparatus.

16. The method according to claim 14, wherein the calibration is effected during a start-up cycle of the radiotherapy apparatus.

17. (canceled)

18. (canceled)

19. (canceled)

20. A tool for providing information to a controller of a radiotherapy apparatus, the tool comprising: a neutron detector; a count measurement device configured to receive incident radiation signals from the neutron detector; and a data logging device configured to receive and store data from the count measurement device, wherein the count measurement device and the data logging device are configured to collect and collate radiation data for adjusting parameters of the controller.

21. The method according to claim 14, wherein varying energy of electrons generated by the linear accelerator comprises increasing the energy of the electrons if the neutron detector detects incident radiation below a predetermined background level.

22. The method according to claim 14, wherein varying energy of electrons generated by the linear accelerator comprises varying the strength of a radio-frequency electromagnetic field applied to the linear accelerator.

23. The method according to claim 14, wherein varying energy of electrons generated by the linear accelerator comprises varying a beam current injected into the linear accelerator.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0025] An embodiment of the present invention will now be described by way of example, with reference to the accompanying figures in which;

[0026] FIG. 1 is a block diagram showing the interaction of different parts of a radiotherapy apparatus according to the present invention;

[0027] FIG. 2 is a block diagram showing the interaction of different parts of an alternative radiotherapy apparatus according to the present invention; and

[0028] FIG. 3 is a block diagram showing an arrangement in which a radiotherapy apparatus according to the present invention may be embodied in a retro-fitted arrangement.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0029] FIG. 1 shows a radiotherapy apparatus in which a linear accelerator 10 is provided with electrons by an electron gun 12. The gun 12 is provided with electrical current and controlled by a gun current controller 14. The accelerator 10 itself can be controlled by signals from a radio frequency controller 16 and/or an automatic frequency controller (AFC) 18. The gun current controller 14, the radio frequency controller 16 and the AFC 18 may all be provided with signals by a control means 20. An N-gamma material 22 is provided which may act as a flattening filter. The N-gamma material 22 may be tungsten. There is further provided an x-ray shield 24 and a neutron detector 26 within a moderator sphere 28. The neutron detector 26 is in turn connected to a comparator means 30 which is further connected to the control means 20.

[0030] The comparator means 30 is shown with its usual circuit-diagram symbol. However, it should be noted that the comparator itself may be implemented digitally within another electronic circuit or in software. The control means 20 may be substantially implemented in software, and the comparator means 30 may be integrated within the control means 20.

[0031] In use, x-rays generated by the linear accelerator 10 may strike the N-gamma material 22, incident x-rays may in turn liberate neutrons from the N-gamma material 22. If neutrons are liberated in the direction of the neutron detector 26, they may be slowed down by the moderator sphere 28. The neutron detector 26 is shielded from x-ray by an x-ray shield 24. An incident neutron may cause the neutron detector 26 to record that incidence by generating a signal which is in turn transmitted to the comparator means 30. The comparator means 30 compares the signal from the neutron detector with a pre-determined reference level and in turn passes a signal to the control means 20. The control means 20 is pre-programmed so that, by taking the signal from the comparator means 30 or directly from the neutron detector 26, and providing a signal to the gun current controller 14, the radio frequency controller 16 and/or the AFC 18, it can vary the output of x-rays from the linear accelerator 10.

[0032] Turning to FIG. 2, a radiotherapy apparatus in which a linear accelerator 10 is provided with electrons by an electron gun 12. The gun 12 is provided with electrical current and controlled by a gun current controller 14. The accelerator 10 itself can be controlled by signals from a radio frequency controller 16 and/or an automatic frequency controller (AFC) 18. The gun current controller 14, the radio frequency controller 16 and the AFC 18 may all be provided with signals by a control means 20. An N-gamma material 22 is provided which may act as a flattening filter. The N-gamma material 22 may be tungsten. There is further provided an x-ray shield 24 and a neutron detector 26 within a moderator sphere 28.

[0033] The neutron detector 26 is in turn connected to a count measurement means 32 which is further connected to a data logging means 34. The information collected and collated by the count measurement means 32 and data logging means 34 may be provided to a local technician to assist with adjusting the parameters of the control means 20, or to the manufacturer for provision of adjusted parameters of the control means 20. This arrangement may be more suitable for longer-term calibration and control of energy levels.

[0034] FIG. 3 shows a similar arrangement to that shown in FIG. 2. However, in the arrangement of FIG. 3 it is envisaged that the neutron detector 26, moderator sphere 28, count measurement means 32 and data logging means 34 are provided as a discrete unit 36. Such a discrete unit could be provided as a quality assurance tool for temporary neutron detection and measurement. This could provide for regular or occasional calibration and control of energy levels of a radiotherapy apparatus. Such a tool could be arranged to provide information to a local technician or the manufacturer, or could be fed directly into the control apparatus 20.

[0035] It will of course be understood that many variations may be made to the above-described embodiment without departing from the scope of the present invention.