DE102011086120A1 - X-ray source for use in radiation therapy device, comprises electron gun unit, which generates electron beam, and corresponds to target generating x-ray beam - Google Patents

Abstract

The x-ray source comprises an electron gun unit, which generates an electron beam (3), and corresponds to target (4) generating an x-ray beam (5). A deflection unit (6) is provided, which deflects the electron beam in a predetermined direction. The target of the x-ray beam is delivered in the predetermined direction. Independent claims are also included for the following: (1) a radiation therapy device comprises a x-ray source; and (2) a method for irradiation of a moving target volume with a radiation therapy device.

Description

The invention relates to an X-ray source with an electron beam generating unit, a radiotherapy device with an X-ray source and an associated method.

Radiation therapy is an established method using ionizing radiation to treat pathological tissue, such as tissue. As tumor tissue to treat. The aim of radiotherapy is to irradiate the tissue to be treated with a sufficient therapeutic dose while at the same time sparing healthy, surrounding tissue. Among other things, the therapeutic effect is based on the fact that ionizing radiation has different effects on healthy tissue and pathological tissue.

1 shows a perspective view of the main components of a known radiotherapy device, as shown for example in the Scriptures DE 199 27 743 B4 to be discribed. About an arranged in a radiotherapy device electron beam generating unit, which is a ray gun 1 and a linear accelerator (LINAC) 2 includes, becomes an electron beam 3 generated. This hits after leaving the linear accelerator 2 on a target 4 , causing an x-ray beam 5 generated and from the target 4 is passed on. The direction of the X-ray 5 agrees with the direction of the electron beam 3 match. The reason for this is the high energy of the electron beam 3 and the high speed of its electrons. The x-ray 5 has a club-shaped distribution.

Radiation therapy of moving target volumes, such. A lung tumor presents a challenge as the anatomy to be irradiated moves. It is important to apply the therapeutic radiation as specifically as possible in the tumor and to protect the surrounding tissue as well as possible. The movement can reduce the accuracy of the irradiation. One way to counteract this uncertainty is to use a larger safety margin, which, however, may lead to a higher dose burden on healthy tissue.

One method used in the irradiation of moving tumors is the so-called gating procedure. In the gating method, the movement cycle of the target volume is monitored and irradiation only takes place when the target volume is within a certain phase of the movement cycle suitable for the irradiation.

Another method used in the irradiation of moving tumors is motion-compensated irradiation with active tracking (motion tracking). Here, the beam position is continuously harmonized with the movement of the target volume by the beam position are adjusted laterally to the beam direction continuously to the tumor movement.

It is the object of the invention to specify a further X-ray source with an electron beam generating unit, a further radiotherapy device with an X-ray source and a further associated method for irradiating a moving target volume, which provide rapid irradiation with low radiation exposure and at the same time precise irradiation of the target volume with simultaneous protection of the surrounding tissue.

The object of the invention is solved by the subject matter of the independent claims. Advantageous developments of the invention can be found in the features of the dependent claims.

The invention claims an X-ray source comprising an electron beam generating unit which generates and directs an electron beam to a target in which Bremsstrahlung is generated. The X-ray source comprises a deflection unit, which deflects the electron beam in at least one predeterminable direction, before the electron beam strikes the target, where an X-ray is generated which is propagated by the target in the predeterminable direction. The direction of the X-ray coincides with the direction of the deflected electron beam. The reason for this is the high energy of the electron beam and the high velocity of its electrons. Also, the club-shaped distribution of the X-ray beam does not change upon deflection of the electron beam. This makes it possible in an advantageous manner, in a moving target volume to be irradiated, such as a lung tumor to achieve a tracking of the X-ray beam via the deflection of the electron beam and thereby the dose distribution of the X-ray beam on the moving target volume despite its movement unchanged and according to the previously in a Radiation planning assumed to maintain distribution. Also eliminates a previously required tilting of the entire electron beam generating unit for tracking the X-ray beam at a moving target volume. Furthermore, the deflection of the electron beam also allows improvements in the treatment planning and plan application. By rapidly scanning the direction of the electron beam and thus the intensity maximum of the X-ray beam on rotationally symmetrical trajectories, it is possible to achieve a largely homogeneous dose distribution in the time average via the application of an irradiation segment. This makes it possible, even with inhomogeneous beam profiles without compensation filter simple Irradiation plans, which so far usually required a homogeneous beam profile to apply. Furthermore, with an open multi-leaf collimator, it is possible to emit treatment plans with a low dose gradient only by scanning the electron beam without using multi-leaf collimator lamellae. Finally, in the most general application, the possibility of electronic control of the beam profile can be included as a further degree of freedom in the treatment plan optimization. This makes it possible to reduce the number of segments required per gantry angle. Because of the very fast in comparison to the lamellar adjustment of the collimator electromagnetic controllability of the electron beam thus an acceleration of the Planabstrahlung compared to previously known methods can be realized.

In one embodiment of the invention, the electron beam can impinge on the target from different angles.

In a further embodiment of the invention, the deflection unit may comprise at least one electromagnetic coil unit. By using electromagnetic coil units, the electron beam can be controlled very quickly.

Advantageously, the electromagnetic coil unit may comprise at least two crossed electromagnets. By using crossed electromagnetic coils transverse fields can be generated to the electron beam.

Furthermore, the deflection unit may comprise a deflection control unit, by means of which the deflection unit can be controlled. This creates the prerequisite for a targeted deflection of the electron beam.

Furthermore, the invention claims a radiation therapy device with an X-ray source according to the invention.

In a further embodiment, the radiation therapy device may comprise a movement tracking unit which determines a movement of a target volume to be irradiated.

Furthermore, the movement tracking unit can control the deflection control unit in such a way that the electron beam and thus the intensity maximum of the x-ray beam follow the target volume. Thus, the electromagnetically controllable deflection of the electron beam can be used in conjunction with known motion tracking methods.

Furthermore, the invention claims a method for irradiating a moving target volume with a radiotherapy device. In this case, an electron beam which generates an X-ray beam is deflected at predeterminable angles, whereby the direction of the X-ray beam is changeable.

In a further embodiment, the deflection of the electron beam may be performed such that the X-ray beam follows the target volume.

In one embodiment of the invention, the deflection of the electron beam can be carried out in an electromagnetic manner. As a result, the electron beam can be controlled very quickly in an advantageous manner.

Further advantages, features and details of the invention will become apparent from the embodiments described below with reference to schematic drawings.

Show it:

1 FIG. 2: a perspective view of the most important components of a radiotherapy device according to the prior art, FIG.

2 : A perspective view of the main components of a radiotherapy device with a deflection unit, and

3 : A flowchart of a method for irradiating a moving target volume with a radiotherapy device.

2 shows a perspective view of the main components of a radiotherapy device with a deflection unit. About an arranged in a radiotherapy device electron beam generating unit, which is a ray gun 1 and a linear accelerator (LINAC) 2 includes, becomes an electron beam 3 generated. In the radiotherapy device is a deflection unit 6 arranged, the a deflection control unit, not shown, for controlling the deflection unit 6 includes. About the deflection unit 6 becomes the electron beam 3 deflects in at least one predeterminable direction before the electron beam 3 on the target 4 there is an X-ray there 5 is generated by the target 4 is passed in the predeterminable direction. The direction of the X-ray 5 agrees with the direction of the deflected electron beam 3 match. Also, the club-shaped distribution of the X-ray beam changes 5 at deflection of the electron beam 3 Not. The deflection unit 6 is crossed by magnetic coils for generation to the electron beam 3 realized transversal fields similar to the construction of deflection in cathode ray tubes. Alternative to the linear accelerator shown here 2 , at the electron beam 3 after leaving the linear accelerator 2 without changing direction in the deflection unit 6 is guided, can also be a linear accelerator with deflection magnets for 270 ° deflection of the electron beam 3 Find application.

In 3 FIG. 2 is a flowchart of a method for irradiating a moving target volume with a radiotherapy device. In step 100 An electron beam is generated by the radiotherapy device. Subsequently, in the step 110 determined by a disposed in the radiotherapy device movement tracking unit, the position data of the target volume to be irradiated. In the following step 120 By means of a deflection control unit arranged in the radiation therapy device, which controls a deflection unit arranged in the radiation therapy device, the position data are evaluated and a deflection angle for the deflection of the electron beam is calculated and transmitted to the deflection unit. In step 130 In the deflection unit, the electron beam is deflected at the calculated deflection angle. Subsequently, the return to step 110 ,

LIST OF REFERENCE NUMBERS

1

electron gun

2

Linear accelerator (LINAC)

3

electron beam

4

target

5

X-ray

6

Deflector

100

Generating electron beam

110

Determination of position data Target volume

120

Determination of deflection angle

130

Deflection electron beam

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19927743 B4 [0003]

Claims (11)

X-ray source with - an electron beam generating unit, the electron beam ( 3 ) and an X-ray beam ( 5 ) generating target ( 4 ), characterized by: - a deflection unit ( 6 ), which the electron beam ( 3 ) deflects in at least one predeterminable direction, the target ( 4 ) the x-ray beam ( 5 ) in the predeterminable direction. X-ray source according to claim 1, characterized in that by deflecting the electron beam ( 3 ) from different angles to the target ( 4 ). X-ray source according to claim 1 or 2, characterized in that the deflection unit ( 6 ) comprises at least one electromagnetic coil unit. X-ray source according to claim 3, characterized in that the electromagnetic coil unit comprises at least two crossed electromagnets. X-ray source according to one of the preceding claims, characterized in that the deflection unit ( 6 ) comprises a deflection control unit, by which the deflection unit ( 6 ) is controllable. Radiotherapy device with an X-ray source according to one of the preceding claims. Radiotherapy device according to claim 6, marked by: - A motion tracking unit that determines a movement of a target volume to be irradiated. Radiotherapy device according to claim 6 or 7, characterized in that the movement tracking unit controls the deflection control unit such that the electron beam ( 3 ) follows the target volume. A method for irradiating a moving target volume with a radiotherapy device, wherein an X-ray beam ( 5 ) generating electron beam ( 3 ) is deflected at predeterminable angles, whereby the direction of the x-ray beam ( 5 ) is changeable. Method according to claim 9, characterized in that the deflection of the electron beam ( 3 ) is performed such that the x-ray beam ( 5 ) follows the target volume. Method according to claim 9 or 10, characterized in that the deflection of the electron beam ( 3 ) takes place in an electromagnetic manner.

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