RU2104595C1 - Method for exposition of three-dimensional brain tumors to ionizing radiation and device which implements said method - Google Patents

Abstract

FIELD: medical devices, in particular, oncology and neural surgery. SUBSTANCE: method involves tuning emission center of ionizing radiation source by means of movement of X-ray sighting unit in vertical plane, three-dimensional sighting of emission center to target point and its exposition to radiation using ionizing radiation source which moves around target point using collimated radiation. In addition emission center is located at intersection of optical axes of X-ray sighting unit when it is driven to vertical or horizontal position. Corresponding device has ionizing radiation source, X-ray sighting unit, object table and patient's head clamp which is located on table and is designed as individual mask which is made from rapidly hardening material. Clamp is located for fixing with respect to emission center. In addition device has set of collimators. X-ray sighting unit has X-ray sight which is mounted for movement in vertical plane. EFFECT: possibility to generate required under-surface dozes for increased number of patients. 4 cl, 1 dwg

Description

 The invention relates to medicine, more specifically to radiology, and may find application in radiation therapy of cancer, neurosurgical and endocrine diseases.

 Existing methods of irradiation with ionizing radiation are based on the use of accelerators of heavy charged particles and electrons with maximum protection of healthy brain structures.

 However, the use of the former in medical practice is fraught with significant economic costs, since most of them are focused on solving physical and technical problems.

 As for the methods of irradiation using electronic accelerators, they all differ in the complexity of pointing the ionizing radiation source to the target point and require highly qualified personnel. A known method of irradiation with ionizing radiation by pointing the radiation source to the target point using a stereotactic device [1].

 The method is associated with rigid fixation of the patient’s head, is traumatic and cannot be used in a number of patients (for example, with parkinsonism). A known method of irradiation using for pointing to a target point a stereotactic apparatus fixed on the upper jaw of a patient [2], which is less traumatic in comparison with the described method.

 However, such a pointing of the radiation source to the target point is very uncomfortable and also cannot be used for a large circle of patients.

 Closest to the proposed is the method of irradiation with ionizing radiation, described in [3].

 The method consists in the fact that using the two x-ray centralizers (horizontal and vertical), the target point is set at the isocenter of the proton stereotactic therapy unit. The patient’s target point is irradiated with a stationary radiation source with a horizontal proton beam, rotating the table with the patient around the vertical axis of the installation isocenter and shaking his head relative to the horizontal axis perpendicular to the beam axis.

This method allows irradiation of volumetric formations of the brain up to 0.1 cm ³ in size, while protecting healthy structures. With large sizes of volume formations, repeated irradiation sessions with a focus shift relative to the isocenter are necessary, which increases the radiation load on healthy tissues. In addition, this method of irradiation (with large sizes of pathological formations) is associated with high economic costs: power consumption and the patient’s long hospital stay.

Thus, the prototype method is advisable to use with volumetric formations of not more than 0.1 cm ³ , that is, for a limited number of patients.

 The technical result of the invention consists in expanding the contingent of patients to whom radiation therapy may be recommended.

 This result is achieved by the fact that in the known method, irradiation of volumetric formations of the brain with ionizing radiation, including setting the isocenter of the ionizing radiation source by pointing the x-ray centering block, stereotactically aligning it with the target point and then irradiating it with the ionizing radiation source, according to the invention, the x-ray centering block by moving it in a vertical plane, and the source of ionizing radiation is not emeschayut around the target point, wherein the ionizing radiation is collimated.

 It is advisable to install the isocenter at the intersection of the optical axes of the x-ray centralizer of the x-ray centering unit when it is installed in a vertical and horizontal position.

The guidance of the X-ray centering unit by moving it in the vertical plane allows reducing the patient laying time, increasing the accelerator capacity, and the rotation of the ionizing radiation source around the target point with radiation collimation provides the possibility of a single irradiation of volume formations up to 15 cm ³ in size while maintaining the protection of healthy structures. This significantly expands the contingent of patients to whom radiation therapy may be recommended.

 The installation of the isocenter of the ionizing radiation source at the intersection of the optical axes of the x-ray centralizer of the x-ray centering unit when it is installed in the vertical and horizontal positions ensures the alignment of the target point with the isocenter with high accuracy, not inferior to the known guidance methods, and allows the rotation of the emitter around the target point with simultaneous rotation of the table with the patient.

 The collimation of ionizing radiation in the range of 5-30 mm allows one to obtain certain dose fields depending on the size of the volumetric formations.

 The installation of the isocenter of the ionizing radiation source at the intersection of the optical axes of the x-ray centralizer of the x-ray centering unit when it is installed in the vertical and horizontal positions ensures the alignment of the target point with the isocenter with high accuracy, not inferior to the known guidance methods, and allows the rotation of the emitter around the target point with simultaneous rotation of the table with the patient.

 The limitation of the fields of ionizing radiation by collimators in the range of 5-30 mm in diameter makes it possible to obtain deep dose fields depending on the size of the volume formations.

 The proposed irradiation method is thus suitable for a wide range of patients subject to radiation therapy, it is economical, quite simple and reliable in implementation, provides reliable protection of healthy structures.

 Methods of irradiating with ionizing radiation volumetric formations of the brain are currently implemented using accelerators of heavy charged particles and electron accelerators.

 Accelerators of heavy charged particles make it possible to form optimal depth dose fields, but due to their extremely high cost and small quantity (about 20 in the world) they are usually oriented toward solving physical and technical problems, therefore their use in medical practice is limited.

 In recent years, linear electron accelerators have been used in the world practice to treat volumetric brain formations. When operating in the bremsstrahlung mode, they allow the formation of depth dose fields that are practically adequate to various sizes of volumetric formations of the brain.

 Known streotactic radiosurgical device for irradiating the brain of the company PHILIPS [1]. It includes a radiation source - a linear accelerator, a set of collimators, a centering system, a therapeutic table and a stereotactic fixator for the patient’s head. The device allows you to generate the required deep dose fields, providing high accuracy of field guidance on volumetric formations and minimal impact of ionizing radiation on healthy structures. But this device, in view of the hard (bloody) fastening of the stereotaxic apparatus on the head, is traumatic and therefore cannot be used for a wide range of patients.

 Known stereotactic radiosurgical device company RADIONICS [4], consisting of a linear accelerator, a set of collimators, therapeutic table and stereotactic device. As described, this device allows you to irradiate volumetric formations of the brain with high precision guidance, but also with rigid fixation of the head, which also limits the number of patients to whom radiation therapy may be recommended.

Closest to the proposed is a device for proton stereotactic therapy [3]. This device consists of an ionizing radiation source installed with the possibility of pointing at its isocenter two blocks of X-ray centralizers and a therapeutic table with a patient head lock. Such a device makes it possible to irradiate small volumetric formations of the brain with an accuracy not inferior to the above-described devices, but compares favorably with them by the simplicity of pointing the target point to the source isocenter due to the use of two X-ray centralizers. However, the use of this device for medical purposes is limited due to the possibility of obtaining deep dose fields with a diameter of not more than 6 mm and irradiation of volume formations with a size of only 0.1 cm ³ . Moreover, in this device, to obtain the required deep dose fields, it is necessary both to rotate the therapeutic table and to shake the patient’s head. All this significantly limits the contingent of patients to whom radiation therapy may be recommended.

 The purpose of the invention is to expand the patient population.

 This result is achieved by a device for radiation therapy, containing an ionizing radiation source installed with the possibility of pointing an X-ray centering unit, a therapy table and a patient’s head clamp on it. According to the invention, it additionally has a set of collimators, the X-ray centering unit includes an X-ray centralizer mounted with the possibility of movement in the vertical plane, the patient head retainer is made in the form of an individual mask of quick-hardening material and is mounted with the possibility of fixing relative to the isocenter, and the ionizing radiation source is mounted with the possibility of movement relative to the target point.

 The presence of an X-ray centralizer in the X-ray centering unit, which is mounted with the possibility of moving in a vertical plane, allows high-precision guidance of the target point to the isocenter of the radiation source using one X-ray centering unit, which speeds up patient placement, increasing the overall throughput of this device.

 The fixation of the patient’s head in the form of an individual mask made of quick-hardening material eliminates the traumatic effect on the patient and thereby expands the contingent of patients to whom radiation therapy may be recommended. In addition, the implementation of the latch in the form of an individual mask provides a quick, reliable and accurate combination of the target point with the isocenter of the ionizing radiation source, not only during the initial laying of the patient, but also during repeated irradiation sessions.

 Thus, the presence of an X-ray centralizer of the X-ray centering unit in combination with the indicated head fixator allows you to quickly and accurately target the isocenter of the radiation source, as well as reproduce the patient’s styling with repeated irradiation with high accuracy.

 Establishing a source of ionizing radiation with the ability to move relative to the target point allows one to obtain deep dose fields with a diameter of up to 30 mm, and a set of collimators provides dose fields in full accordance with the individual sizes of the volumetric formations of the brain and reliable protection of healthy structures. All of the above can significantly expand the contingent of patients who may be recommended radiation therapy.

 The drawing shows a block diagram of the proposed device, which contains an ionizing radiation source 1 with an isocenter at point A, mounted to move around the O-O axis, an X-ray centering unit with an X-ray centralizer 2 with an isocenter at point B, mounted to move the X-ray centralizer around the OO axis, therapy table 3, patient head retainer 4, collimators 5. Moreover, the patient head retainer is equipped with radiopaque crosses, the optical axes of which intersect at V.

 The irradiation method using the presented device is as follows. The patient is placed on the therapeutic table 3. A mask that is previously made of quick-hardening material, the patient's head is rigidly attached to the table. Table 3 with the patient is moved in such a way that point B is aligned with point B. By moving the head retainer 4 using the X-ray centering unit 2, the target point is aligned with point B, and therefore with point B. Then therapeutic table 3 is rotated until point B coincides with point A, i.e. until the target point coincides with the isocenter of the ionizing radiation source. Next, a collimator is installed on the ionizing radiation source 1 in accordance with the size of the volumetric brain formation of the patient to be irradiated. After that, irradiation is started by rotating the source of ionizing radiation 1 around point A, and therefore, the target point. If necessary, repeated irradiation of the target point, all repeat in the same way.

 The proposed method and device in comparison with the known have several significant advantages.

1. The method significantly expands the contingent of patients to whom radiation therapy can be recommended, since it makes it possible to irradiate volume formations up to 15 cm ³ . While the prototype method can be used to irradiate only volume formations with a size of not more than 0.1 cm ³ .

 2. Compared with the known methods of irradiation, the proposed one due to the use of X-ray centering allows to simplify and reduce the patient laying time and reduce the invasiveness of the procedure.

 3. The use of one block of x-ray centering in the proposed device instead of two in the prototype without reducing the accuracy of the guidance significantly reduces the cost of the device and the treatment procedure.

 The proposed device is designed, manufactured and manufactured at TsNIRRI with joint participation in the work of specialists of the D.V. NIIEFA Efremova and TsNIRRI. The device is based on the use of a domestic linear electron accelerator of the LUER-20M brand developed by NIIEFA as an ionizing radiation source. To date, the device has passed the stage of physical and technical tests and is prepared for clinical use.

USED BOOKS
1. Radiosurgery System SRS 200 - PHILIPS brochure.

 2. Anichkov A.D., Polonsky Yu.Z., Kambarova D.K. Stereotactic guidance (theory and experience of the clinical application of a computer technique) / Ed. Bekhtereva N.P.-M .: Nauka, 1985, p. 61-65.

 3. Abrosimov N.K. and other Medical radiology, 1987, N 8, p. 10-16.

 4. Stereotactic Radiosudgery System-brochure of the company RADIONICS.

Claims (4)

 1. A method of irradiating ionizing radiation of volumetric brain formations, including setting the isocenter of the ionizing radiation source by pointing the X-ray centering unit, stereotactically aligning it with the target point and then irradiating it with the ionizing radiation source, characterized in that the X-ray centering block is guided by moving it to vertical plane, and the source of ionizing radiation is moved around the target point, and ionizing e radiation collimates.  2. The method according to claim 1, characterized in that the isocenter is installed at the intersection of the optical axes of the x-ray centralizer of the x-ray centering unit when it is installed in a vertical and horizontal position.  3. The method according to claims 1 and 2, characterized in that the collimation of ionizing radiation is carried out by changing the size of the radiation fields in the range of 5 to 30 mm in diameter.  4. Device for irradiating ionizing radiation of volumetric formations of the brain, containing an ionizing radiation source installed with the possibility of pointing to its isocenter of an X-ray centering unit, a therapeutic table and a patient's head retainer placed on it, characterized in that it further comprises a set of collimators, an X-ray unit the centering includes an X-ray centralizer mounted with the ability to move in a vertical plane, the patient head retainer is made in ide individual masks from rapidly material and is installed to be fixed relative to the isocenter, and the source Ionizing radiation movably mounted relative to the target point.