EP0021441B1 - Electron accelerator for x-ray therapy - Google Patents

Description

The invention relates to a low-energy electron accelerator for X-ray therapy with an evacuated acceleration tube, with a target exposed to the electron beam made of a material with a high atomic number, with a collimator, with a profiled compensating body arranged centered on the axis of symmetry of the collimator's aperture and with a filter plate.

Through DE-A-2 727 275 and the essay by Dr. Haas in the specialist magazine "Electromedica" Vol. 45, No. 1, 3-4, 1977, pp. 101 to 106 discloses a electron accelerator which is preferably known for use in medical radiation therapy. In this electron accelerator, a target is exposed to the electron beam emerging from the beam exit window of the acceleration tube. An electron absorber, through which the electrons remaining in the X-rays are filtered out, is arranged in the beam direction behind the target. The electron absorber consists of two parts, one of which is made of graphite and the other of aluminum. There is a collimator in the beam direction behind the electron absorber for the suppression of the maximum X-ray field to be used. A profiled compensating body made of iron (relatively low atomic number material), centered on the collimator's blanking opening and projecting into it, is attached to the collimator. It achieves a considerable hardening of the X-rays and a low neutron production. With such an electron accelerator, the undesirable low-energy X-ray component would be relatively high. In order to reduce this low-energy X-ray component, the device on which the above-mentioned DE-A-2 727 275 is based is to use a deflection magnet which deflects it by 270 ° and focuses the electrons of predetermined energy in the electron beam. In this way, the target is only hit by electrons of the respectively set (high) acceleration energy. This significantly improves the radiation quality. However, such a deflection magnet is extremely complex in its construction and also requires a correspondingly large space between the beam exit window of the acceleration tube and the target. This in turn affects the size of the accelerator in an undesirable manner. A deflection magnet will therefore only be provided for electron accelerators that achieve a relatively high energy. A certain inhomogeneity of the energy distribution over the radiation cross-section at different penetration depths can be accepted, since at the high energies under consideration tissue is to be attacked not far in the subcutaneous area, but far below. Such a high-energy linear accelerator with a deflection magnet should not be considered in the following.

The electron accelerator mentioned at the outset is known from the reference “Radiology” 115, pages 475-477, May 1975. This works with an X-ray energy of 4 MeV and does not need a magnet. Here, too, the acceleration tube is followed by a target that generates X-rays when electrons collide. After passing through a primary collimator, this strikes a profiled compensating body which consists of a heavy metal, namely lead. After the throughput of an ionization chamber and a secondary collimator, the X-rays fall on a disk-shaped filter, which is made of a low-order metal, namely brass. This filter is intended to remove an unpleasant property of such a low-energy electron accelerator; namely, it is said to level the so-called "hot spots" or "horns" in the energy distribution of the X-ray beam measured across the cross section. These "hot spots" or "Hömer" can lead to increased doses and thus to burns during therapy in the subcutaneous area. This filter therefore selectively reduces the areas with a high radiation dose at the edges of large radiation fields. Such a solution to the problem of "hot spots" or "horns" cannot be used according to the protective provisions of a number of countries that the dose and dose rate changed by the additional filter are not recorded by the monitor.

DE-A-2 533 348 relates to a target which is composed of three layers. While the first layer consists of a medium atomic number material and is used to generate X-rays, the middle layer consists of a material of low atomic number and serves as an electron absorber. As the last layer, this layer is followed by one made of a material with a high atomic number, which is preferably used to absorb X-ray quanta of lower energy. The use of linear accelerators with low energy is not dealt with in this reference.

DE-B-2441 986 discloses a large aperture x-ray generator that generates a wide, diffuse x-ray cone. In this beam generator, the target is applied to a low atomic number plate, preferably aluminum, and there is an aluminum window behind this support plate. This publication does not show that the support plate or the window have a function other than allowing the X-ray radiation of the target to pass through well.

The invention has for its object an electron accelerator of the beginning ge named type, which does not need a magnet and works with an electron energy in the range of 2 to 10 MeV, so that the hardening of the X-rays is achieved with the simplest possible means and at the same time the most uniform possible energy distribution over the radiation cross-section, whereby a practical solution is found should.

In the case of an electron accelerator of the type mentioned at the outset, this object is achieved according to the invention in that the compensating body is made from a material of a low atomic number, that an electron absorber known per se is connected downstream of the target, and that the filter plate is inserted between the electron absorber and the compensating body and is made of heavy metal with high absorption for low-energy X-rays and with low absorption for higher-energy X-rays, the filter plate having an equivalent lead of at least 1 mm at an electron energy of 2 to 10 MeV.

This takes advantage of the fact that the elements of higher atomic numbers weaken X-ray quanta of lower energy comparatively more strongly than X-ray quanta of higher energy. This means that those X-ray quanta whose energy lies in the absorption maximum of the material of the filter plate are increasingly absorbed over the entire beam cross section. With the heavy metals in question for the filter plate, such as. B. uranium, tungsten, tantalum, gold and preferably lead, X-ray quanta with energies between 1 and 3 MeV are particularly strongly absorbed in this way. This solution has the particular advantage that the compensation body, which is preferably made of aluminum, does not itself harden the radiation. But this would have been the case if the compensating body made of a material with a higher atomic number, such as. B. of copper or even lead. Hardening of the X-rays by the compensating body would then have led to an undesired hardening which decreases radially in the cone of radiation due to the different thickness of the profiled compensating body.

Another advantage of this arrangement is that the filter plate is not hit by electrons because of the upstream electron absorber. It cannot therefore appear as a competing target. Under this condition, the choice of filter material can only be based on its suitability for hardening the X-rays. In addition, the compensation body downstream of the filter plate in the beam direction is hit by X-rays, which is largely homogenized by the upstream filter plate.

A particularly simple construction results if the target is attached to the side of the electron absorber facing the acceleration tube. In this case, the electron absorber supports, whose dimensions must be kept much stronger than that of generally only about 3 mm. strong lead foil existing target, this off. This construction therefore results in an improved mechanical protective function.

Further details of the invention will be explained with reference to an embodiment shown in the figure.

The figure shows a sectional view through the last two cavity resonators of an acceleration tube, through the target and through the collimator.

In the figure, the two last, cavity-shaped cavity resonators 1, 2 of an acceleration tube 3 of a linear accelerator are shown cut open along their axis of symmetry 4. The axis of symmetry of the cavity resonators coincides with the electron beam 5. The outlet opening 6 of the last cavity 2 is closed by a metal plate with high thermal conductivity, the electron absorber 7, in the exemplary embodiment a 20 mm thick copper plate. This electron absorber 7 is the last resonant cavity 2 gas-tight up _- soldered. At the location of the electron absorber 7 where the electron beam 5 would strike, it is provided with a disk-shaped depression, into which a target 8 only a few tenths of a millimeter thick is soldered. At the same time, the electron absorber 7 is provided with cooling channels (not shown) which end in hose connections 9, 10 for connection to a cooling system (not shown here for the sake of clarity). The electron absorber 7 carries a filter plate 11 on the side facing away from the target 8. In the beam direction behind the electron absorber 7 and the filter plate screwed onto the electron absorber, the collimator 12 is arranged with a conical opening 13 for the passage of the maximum X-ray field 14 to be used . A compensating body 15 is fastened to the collimator 12, by means of which the intensity profile of the X-ray radiation following a Gaussian distribution curve is compensated for over the entire cross-section of the X-ray field 14 that is maximally used.

When the electron accelerator is in operation, the electrons accelerated by the acceleration tube 3 strike the target 8 which closes the exit opening 6 of the acceleration tube 3. X-ray brake radiation is generated in the target. The waste heat generated in the target is released to the electron absorber via the solder connection between the target 8 and the electron absorber 7 and flows off there to a coolant. The electrons passing through the target are braked and absorbed in the material of the electron absorber 7 located behind them. For this reason, in the beam direction behind the electron absorber 7 ordered filter plate 11 also no further X-rays are generated. A material has therefore been used for the filter plate 11, which has been selected solely on the basis of its absorption properties - the largest possible absorption factor in the range of low-energy X-ray quanta of 1 to 3 MeV and the smallest possible absorption factor in the range of higher-energy X-ray quanta above 3 MeV. The heavy metals lead, tantalum, gold, tungsten and uranium are particularly suitable for this purpose. In the present case, a 2 mm thick filter plate made of lead was used for an electron energy of approx. 4 MeV. Since the filter plate 11 is equally strong over the entire maximum radiation cross section to be used, the hardening effect for the radiation is also uniform over this entire radiation cross section. The compensating body following in the beam direction needs and should therefore no longer show any hardening effect. It can therefore be made of a material with a low atomic number. be made, in which the absorption over the entire occurring X-ray energy spectrum is approximately the same size. Aluminum is particularly well suited for this.

The advantage of this design can be seen in particular in the fact that the disadvantages with regard to the beam quality associated with the omission of the complex and bulky 270 ° deflection and focusing magnet for the electron beam 5 can largely be compensated for by the compensating body 15 made of a material with a low atomic number, e.g. B. aluminum, and a filter plate 11 is used behind the electron absorber 7, the X-ray quanta of lower energy preferably absorbed. The design is not only decidedly cheaper, it also leads to devices that are much smaller and easier to position in medical applications.

Claims (3)

1. A low-energy electron accelerator for X-ray therapy comprising an evacuated acceleration tube, a target which is exposed to the electron beam and consists of a material of high atomic number, a collimator, a profiled compensating body which is arranged centrally with respect to the axis of symmetry of the limiting aperture of the collimator, and a filter plate, characterised in that the compensating body (15) is made of a material of low atomic number; that an electron absorber (7), known per se is connected after the target (8) in the direction of radiation; and that the filter plate (11) is inserted between the electron absorber (7) and the compensating body (15) and is made of a heavy metal with a high absorption for low-energy X-rays and with low absorption for high-energy X-rays, the filter plate (11) having a lead equivalent of at least 1 mm for an electron energy of 2 to 10 MeV.

2. An electron accelerator as claimed in claim 1, characterised in that the filter plate (11) is made of lead.

3. An electron accelerator as claimed in claim 1 or claim 2, characterised in that the compensating body (15) is made of aluminium.

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