RU2842446C1 - Device for generating a beam of low-energy neutrons for irradiating a tumour - Google Patents

Abstract

FIELD: medical science.

SUBSTANCE: invention relates to the field of combined methods of irradiating tumours, based on the combined action of proton and neutron radiation, and can be used for irradiating tumours in the flash therapy mode with an average dose of 50-80 Gy, in particular, with introduction of sensitizers (for example, gold or iodine isotope) into irradiated area. Device for forming a beam of low-energy neutrons for irradiating a tumour comprises, arranged in series on one longitudinal axis, a proton accelerator, a proton channel, a target for receiving fast neutrons, and a moderator in the form of a cylinder, surrounded by means designed to absorb radiation and obtain a directed stream of low-energy neutrons. Above target and retarder are shaped and dimensioned to enable simultaneous irradiation of the tumour surface with the proton beam, and the remaining tumour region with the neutron beam in a projection perpendicular to the long axis. Device intended for absorbing radiation and obtaining a directed stream of low-energy neutrons is a hollow cylinder located on the same longitudinal axis and made of a material intended to reflect neutrons, surrounded by a hollow cylinder, which is located close to it and is made of a material intended for slowing down neutrons, and which, in turn, is surrounded by a cylinder made of material intended for absorbing neutron radiation, bottom and upper surface of which are covered by covers made of material intended for absorbing neutron radiation.

EFFECT: invention ensures increased safety of use of the device while simultaneously making it easy to manufacture and use.

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Description

The invention relates to the field of combined methods of irradiating tumors based on the combined action of proton and neutron radiation, and can be used for irradiating tumors in flash therapy mode with an average dose of 50-80 Gy, in particular, with the introduction of sensitizers (for example, gold or an iodine isotope) into the irradiated area.

Theoretically and experimentally, it has been established that the flash beam has a more gentle effect on healthy tissues compared to traditional methods of proton therapy (average dose no more than 7 Gy). This effect is explained by radiochemical oxygen depletion at ultra-high dose rates (at least 40 Gy) and subsequent radioresistance of irradiated healthy tissue (see, in particular, Wilson J.D., Hammond E.M., Higgins G.S., Petersson K. Ultra-High Dose Rate (Flash) Radiotherapy: Silver Bullet or Fool's Gold? Front. Oncol., 2020, Vol. 9, p.1563 [1]; Favaudon V., Caplier L., Monceau V. et al. Ultrahigh Dose-Rate FLASH Irradiation Increases the Differential Response between Normal and Tumor Tissue in Mice, Sci. Transl. Med., 2014, Vol. 6, No. 6 (245) [2]; Diffenderfer E.S., Verginadis 1.1., Kim M.M. et al. Design, Implementation and In Vivo Validation of a Novel Proton FLASH Radiation Therapy System, Intern. J. Radiat. Oncol. Biol. Phys., 2020, Vol.106, No.2, pp. 440-448 [3]). As a result, flash therapy is currently considered as a promising direction of radiation therapy.

There are various variants of implementing proton therapy in flash therapy mode. For example, a method of proton therapy is known in which a directed proton beam and a two-dimensional projection of the tumor are formed in a plane perpendicular to the proton beam, the depth of the tumor is measured, the two-dimensional projection of the tumor is scanned with a proton beam to the depth of the tumor, and the energy of the directed proton beam is selected during scanning in accordance with the depth of the tumor. The directed proton beam is formed as a focused beam, and the focus position is changed during scanning to the depth of the tumor, ensuring consistent movement of the beam along the outer surface of the tumor.

The scanning speed is set at each point on the outer surface of the tumor, taking into account the intensity of the proton beam and the beam diameter at the focus, ensuring the destruction of irradiated tissues on the outer surface of the tumor with a dose of 50-80 Gy (see RU 2695273 C1, published 22.07.2019 [4]).

Devices for generating proton beams for irradiating tumor cells in flash therapy mode are known.

In particular, a device for irradiating tumor samples is known, containing a proton accelerator, a proton channel and an experimental body in which tumor samples are placed, located sequentially on one longitudinal axis (see SV Akulinichev, VN Vasiliev, Yu.K. Gavrilov et al. Possibilities of proton flash therapy at the INR RAS accelerator, Izvestiya RAS. Physical Series, 2020, Vol. 84, No. 11, pp. 1542-1546 [5]).

The disadvantages of the known device are that it is designed only for experimental research and cannot be used to solve problems of radiation therapy.

A device is known for generating a beam of low-energy neutrons for irradiating a tumor, comprising a proton accelerator, a proton channel, a target designed to produce fast neutrons, and a moderator in the form of a cylinder, surrounded by a means designed to absorb radiation and produce a directed flow of low-energy neutrons, located sequentially on one longitudinal axis (see RU 2808930 C1, published 05.12.2023 [6]).

The disadvantages of the known device are its limited capabilities due to the possibility of irradiating the tumor with only neutron beams and using proton slots emitted by the accelerator only for bombarding the target, without their therapeutic effect. In particular, the known device cannot be used to solve flash therapy problems.

The device known from [6] is the closest analogue to the claimed device.

The technical problem solved by the claimed invention consists in creating a device for the simultaneous formation of a scanning beam of protons and a beam of low-energy neutrons for irradiating a tumor in flash therapy mode, which, as a result, has expanded application possibilities.

This achieves a technical result consisting of increased safety of use of the device while simultaneously making it easy to manufacture and use.

The technical problem is solved and the specified technical result is achieved as a result of creating a device for forming a beam of low-energy neutrons for irradiating a tumor, comprising a proton accelerator, a proton channel, a target intended for producing fast neutrons, and a moderator in the form of a cylinder, located sequentially on one longitudinal axis, surrounded by a means intended for absorbing radiation and producing a directed flow of low-energy neutrons, in which the said target and moderator have a shape and dimensions that make it possible to simultaneously irradiate with a beam of protons in a projection perpendicular to the longitudinal axis, the superficial region of the tumor with a beam of protons, and the remaining region of the tumor with a beam of neutrons, and the means intended for absorbing radiation and producing a directed flow of low-energy neutrons is a hollow cylinder located on the same longitudinal axis made of a material intended for reflecting neutrons, surrounded by a hollow cylinder located close to it made of a material intended for slowing down neutrons, which, in in turn, is surrounded by a cylinder made of a material designed to absorb neutron radiation, the bottom and top surface of which are covered with lids made of a material designed to absorb neutron radiation.

In a particular embodiment, the device is equipped with a diaphragm installed at the device outlet made of a material intended to absorb neutron radiation, and two pad chambers on "warm liquids" intended, respectively, to measure the dose profiles of a beam of protons and low-energy neutrons, wherein the device is designed with the possibility of irradiating a tumor with beams of protons sequentially and is designed with the possibility of switching off the accelerator when a total dose of 50-80 Gy is reached in the pad chamber for measuring the dose profile of proton beams.

Fig. 1 shows a general diagram of the claimed device, according to one of the particular embodiments.

Fig. 2 shows a general diagram of the claimed device, according to another particular embodiment.

Fig. 3 shows an example of using the claimed device.

The device shown in Fig. 1 and Fig. 2 contains a proton accelerator (1), for example, a synchrotron, quadrupole lenses (2), scanning magnets (3) arranged sequentially on one longitudinal axis z, designed to direct proton spots (a fraction of the proton beam per accelerator pulse) emitted by the accelerator (1) toward the tumor (10), a target (4) designed to obtain fast neutrons, and a moderator (5) designed to slow down fast neutrons to low-energy neutrons.

The target (4) can be, for example, made of NaI, as well as any other material that meets the task of obtaining fast neutrons. For example, a water phantom can be used as the moderator (5), as well as any other moderator that meets the task of obtaining low-energy neutrons (in particular, made of AlF ₃ , CaF ₂ , MgF ₂ or Al ₂ O ₃ ).

The target (4) and the moderator (5) have a shape and dimensions that allow simultaneous irradiation in a projection perpendicular to the z axis of the superficial region of the tumor (10) with a proton beam (similar to the proton therapy method described in [4]), and the remaining region of the tumor (10) with a neutron beam. In particular, in the embodiment shown in Fig. 1, the target (4) and the moderator (5) are made in the form of cylinders. The diameter of the target (4) is 3 cm, the length is 5 cm. The diameter of the moderator (5) is not less than 3 cm, the length is 26 cm. In the embodiment shown in Fig. 2, the target (4) and the moderator (5) are made in the form of shells. The outer diameter of the target is 17 cm, the length is 5 cm. The outer diameter of the moderator is 17 cm, the length is 26 cm. The difference between the outer and inner diameters of the target (4) and the moderator (5) is 6 cm.

The moderator (5) is surrounded by a hollow cylinder (A) located on the same z-axis made of a material designed to reflect (in the direction of the z-axis) neutrons emitted from the moderator (5), surrounded by a hollow cylinder (B) located close to it made of a material designed to slow down neutrons, which, in turn, is surrounded by a cylinder (C) made of a material designed to absorb neutron radiation, the bottom and upper surface of which are closed by lids made of a material (D), also designed to absorb neutron radiation.

The material of the cylinder (A) may be, for example, tungsten, nickel or lead, as well as any other material that meets the task of reflecting neutrons. The material of the cylinder (B) may be, for example, spheroplastic with the addition of boron carbide at a rate of 20 vol. % boron, as well as any other material that meets the task of slowing down neutron radiation. The material of the cylinder (C) and covers (D) may be, for example, ultra-high molecular weight polyethylene with the addition of amorphous boron in an amount of 5-7 vol. %, as well as any other material that meets the task of absorbing neutron radiation.

At the exit of the device, a diaphragm (F) is installed, made of a material also designed to absorb neutron radiation, regulating the diameter of the neutron beam.

In front of the tumor (10), tied to the xyz coordinates, there are two pad chambers on "warm liquid" (8) and (9), which measure the dose profiles of the proton and low-energy neutron beams during irradiation. As a result, in case of deviation of the dose profile from the specified parameters, the corresponding beam is switched off. The proton beam is also switched off when the total dose in the pad chamber (8) reaches 50-80 Gy.

The claimed device is used, for example, as follows (see Fig. 3).

Before the flash therapy session, the full contour of the tumor and its projection perpendicular to the direction of the proton beam (z axis) are determined using MRI or computed tomography.

From the proton accelerator (1) through the scanning magnets (3) scanning spots of the "pencil" beam of protons (6), for example, with an energy of 200 MeV, are emitted. When bombarding the target (4), predominantly forward-directed high-energy neutrons are formed, most of which enter the moderator (5) and lose energy, which leads to the formation of low-energy (epithermal and supra-epithermal) neutrons. During one pulse of the accelerator (1) (100-300 ms), the scanning spots of the proton beam (6) freely pass in the direction of the tumor (10) and irradiate successively the superficial ("external") area of the tumor (10), and the slowed down, low-energy neutrons (7) fly out of the moderator (5) mainly forward at different angles to the direction of the proton beam (z axis) and irradiate the remaining area of the tumor (10). During the next pulse of the accelerator (1), similar irradiation occurs until the entire superficial area of the tumor is irradiated and the specified total dose is reached, which is 50-80 Gy in the flash therapy mode. If it is not possible to irradiate the entire superficial area of the tumor with a scanning proton beam (with the patient in the chair in one position), the patient's chair is rotated according to a specified program in the xyz coordinate system and irradiation with a scanning proton beam of the area that has not yet been irradiated is continued.

By scanning the superficial ("external") area of the tumor with a proton beam, successively changing the scanning depth, the blood vessels in it are destroyed, after which the supply of oxygen to the tumor is stopped. At the same time, in one session of flash therapy, the entire remaining ("internal") area of the tumor is irradiated with a beam of slow low-energy neutrons, thereby providing combined irradiation of the tumor.

The scanning speed of the superficial area of the tumor is selected with the expectation of obtaining a total dose of about 50-80 Gy. By changing the accelerator energy, it is possible to qualitatively scan the entire "external" area of the tumor to the desired depth (at least 3 mm) from the surface, from the minimum energy layer to the maximum (see E.A. Gritskova, G.V. Mitsyn et al. Flash method of proton beam therapy, Letters to E.Ch.A., 2022, Vol. 19, No. 6 (245), pp. 682-699 [7]).

The claimed device, which has expanded application capabilities, is safe to use both for the patient (due to irradiation of the tumor with a beam of low-energy neutrons, practically devoid of fast neutron admixture) and for the personnel servicing the device.

In addition, the claimed device, as a result of its layout, is easy to manufacture and use (in particular, it can be quickly assembled and disassembled after a radiation therapy session).

Claims (2)

1. A device for generating a beam of low-energy neutrons for irradiating a tumor, comprising a proton accelerator, a proton channel, a target intended to produce fast neutrons, and a moderator in the form of a cylinder, all arranged sequentially on one longitudinal axis, surrounded by a means intended to absorb radiation and produce a directed flow of low-energy neutrons, characterized in that the said target and moderator have a shape and dimensions that allow for the simultaneous irradiation in a projection perpendicular to the longitudinal axis of the superficial region of the tumor with a beam of protons, and the remaining region of the tumor with a beam of neutrons, and the means intended to absorb radiation and produce a directed flow of low-energy neutrons is a hollow cylinder located on the same longitudinal axis made of a material intended to reflect neutrons, surrounded by a hollow cylinder located close to it made of a material intended to slow down neutrons, which, in turn, is surrounded by a cylinder made of a material intended to absorb neutron radiation, the bottom and upper surface of which are covered with lids made of a material designed to absorb neutron radiation. 2. The device according to item 1, characterized in that it is equipped with a diaphragm installed at the outlet of the device made of a material intended to absorb neutron radiation, and two pad chambers on "warm liquids" intended, respectively, to measure the dose profiles of proton beams and low-energy neutrons during tumor irradiation, wherein the device is designed with the possibility of irradiating the tumor with proton beams sequentially and is designed with the possibility of turning off the accelerator when a total dose of 50-80 Gy is reached in the pad chamber for measuring the dose profile of proton beams.