EP2558163A1

EP2558163A1 - Device using x-rays to highlight soft-tissue parts in medical radiotherapy

Info

Publication number: EP2558163A1
Application number: EP11712798A
Authority: EP
Inventors: Oliver Heid; Jürgen HELLER
Original assignee: Siemens AG
Current assignee: Siemens AG
Priority date: 2010-04-16
Filing date: 2011-03-23
Publication date: 2013-02-20
Also published as: BR112012026128A2; JP2013524882A; CA2796233A1; WO2011128189A1; RU2012148712A; CN102844076A; US20130034208A1; DE102010015224A1

Abstract

The invention relates to a device using X-rays to highlight soft-tissue parts in medical imaging. This device and an associated method can be implemented in particular in radiotherapy equipment or used in radiotherapy. One aspect of the invention is a control of the radiation dose needed for the therapy, which control involves phase-contrast imaging using X-rays to highlight soft-tissue parts and can preferably be used in a radiotherapy apparatus. The result of the imaging by highlighting soft-tissue parts can be used for real-time and non-real-time planning of therapy and for adapting the treatment plan or the radiation dose. The radiation dose control here comprises: c) anatomical imaging for locating tumours before, during and after irradiation, d) optionally: real-time adaptation of the treatment plan, on the basis of imaging that highlights soft-tissue parts. The positioning and arrangement of the combination of X-ray sources S and detector D in such a radiotherapy apparatus and of an accelerator T are independent of one another. The accelerator makes it posible to cover the entire body of the patient P with X-rays.

Description

description

Apparatus for X-ray based highlighting of soft tissues in medical radiotherapy

More particularly, the invention relates to a device for X-ray based highlighting of soft tissues in medical imaging. This apparatus and an associated method can be used in particular in a beam Thera ^¬ piegerät or be in radiotherapy ver ^¬ turns.

Background of the invention

Radiation therapy is generally intended to irradiate a target area within the human body to fight disease, especially cancer. In this case, a high radiation dose is deliberately generated in an irradiation center (isocenter) of an irradiation device or radiotherapy device. A radiation therapy machine will contact me ^¬ dizinisch ionizing radiation on humans to cure diseases or to delay its progression, especially in tumors. As ionizing, high-energy beams mainly gamma radiation, X-rays and electrons are used. It is also possible to use systems for treatment with neutrons, protons and heavy ions.

For the treatment of a tumor, for example, a certain desired Dosisvertei ^¬ lung is to be realized in a target volume with a radiation therapy device. Upon irradiation itself, the problem frequently arises that the goal of Be ^¬ radiation in the body is movable. For example, a tumor in the abdominal area shifts during the breathing process. On the other hand, a tumor may also have grown or already shrunk in the period between irradiation planning and actual irradiation. Therefore, it is possible to determine the location of the irradiation target in the body during the irradiation by imaging to control the beam accordingly or if necessary to cancel the irradiation and thus to increase the success of the therapy. One goal in radiotherapy is one with the help of

Real-time guided treatment without having to reposition the patient during treatment. There are either radiation therapy systems with integrated X-ray imaging or separate computed tomography or magnetic resonance imaging that support treatment planning.

Radiation therapy systems with integrated X-ray imaging, however, do not provide high resolution soft tissue contrast images for precise treatment or irradiation, nor do they provide a necessary opportunity to adapt to treatment in real time based on the images produced. That is, an adjustment for respiration or patient movement during treatment is currently not possible. There are Strahlungsthe ^¬ rapiesysteme environment with integrated conventional Röntgenbildge ^¬ advertising with conventional Kontrastbildge- characteristic based on the absorption of photons, wherein the photo Electronic process for imaging the interest ^¬ the target region is used. This insert is dahinge ^¬ starting disadvantageous in that the contrast produced is not suitable to visualize soft tissue, and is limited in precision in the radiation treatment. Furthermore, real-time adaptation of the treatment plan can not be achieved. As an imaging medium for monitoring the treatment or therapy, an ultrasound device is also possible. However, these only provide a limited solution to the problem. Ultrasound imaging lacks the depth of penetration for many applications. Furthermore, various Strahlungsthe ^¬ rapiesysteme with integrated Magnetresonanzbildgebungslösun- gen example from DE 10 2008 007 245 AI known. The high quality of soft tissue enhancement of magnetic resonance imaging is useful for identifying soft tissues to be treated with radiotherapy. These approaches are very complex and complex. It is an object of the invention to provide a method or a Vorrich ^¬ tion in radiation therapy, which allows controlled by real-time images treatment, the imaging should emphasize soft tissues in sufficient accuracy. In ^addition , an adaptation of the treatment plan or the radiation dose in real time is to be made possible.

The object is achieved with the device and the method according to the independent claims. Advantageous embodiments of the device or the method are the subject of the dependent claims or can be taken from the following description and the exemplary embodiments. One aspect of the invention is a control required for the therapy ^¬ The radiation dose which emerges on an X-ray-based soft tissue highlighting phase contrast imaging, which can be preferably used in a radiation therapy device. The result of soft tissue imaging can be used for real-time and non-real-time therapy planning, as well as adjustment of the treatment plan or radiation dose.

The radiation dose control here comprises: a) anatomical imaging for tumor localization before, during and after the irradiation

b) optional: real-time adjustment of the treatment plan, ba ^¬ sierend highlighting on a soft tissue imaging.

A development of the invention provides a high-quality soft tissue imaging highlighting such to implemen ^¬ animals that a monochromatic X-ray source is used. A monochromatic X-ray source typically produces protons with a narrow wavelength window to allow phase contrast imaging for the imaging of soft tissues. Preferably, an improved soft-tissue contrast can be generated by applying a K-absorption band.

A further embodiment of the invention provides to implement a high-resolution soft-tissue imaging by an energy-suppressing X-ray detector. Preferably, stray radiation due to a narrow photon energy range is suppressed. Further, an increased contrast are generated by a dependent by wavelength ex absorption (especially color) or spektoskopische Informati ^¬ on.

A further embodiment of the invention provides that the high quality soft tissue imaging is implemented by highlighting a coherent X-ray source, which generates photons with a kon ^¬ stant relative phase. An X-ray interpherometer can be used for phase-sensitive imaging. Another embodiment of the invention contemplates implementing high quality soft tissue imaging as follows. Incoherent x-ray sources producing photons with a random phase distribution are preferably used together with an interpherometer. In order to implement a phase-contrast imaging, in this case a so-called "grating" is applied, whereby a regular spatial accumulation of essentiel ^¬ len, identical, parallel and elongated elements will be produced.

A further aspect of the invention provides a method for position control of X-ray based imaging means (S, D) for highlighting soft tissue of a target area provided within a radiotherapy apparatus for phase contrast imaging, wherein with respect to the Target area regardless of the device means (T) to be positioned for radiotherapy. A further embodiment of the invention provides that control signals output by a control device cause avoidance of a collision between the imaging means (S, D) and the device means (T) for radiotherapy.

The invention has the following advantages: There is provided a radiation therapy system having integrated high quality soft-tissue highlighting imaging, similar to magnetic resonance imaging, to enable high-precision radiation treatment. The high-precision radiation therapy of the invention has economically similar expenses on as already Exists ^¬ Ionizing Radiation therapy approaches.

Description of one or more embodiments:

Further advantages, details and developments of the invention will become apparent from the following description of exemplary embodiments in conjunction with the figure. The figure shows an example of a radiation therapy device in which a positioning of the X-ray source S and the X-ray detector D makes possible a radiation coverage of the entire patient's body P from every possible angle. This is indicated by the illustrated arrows and circles.

The accelerator shown (accelerator) or Betrah- radiation source for the T Thearapie makes it possible to cover the whole Pati ^¬ ducks body with rays from every possible angle. This is indicated by the illustrated arrows and circles.

The positioning or arrangement of the x - ray sources and detector combination, wherein x - ray sources and - detector in Reference statically to one another - for example, both may be attached to the "ends" of a C-arm, and the accelerator An unillustrated hardware ^¬ or software control that is integrated into the radiation therapy device or deducted from the radiation therapy machine are independently Steue ^¬ approximately signals. leads to this, prevents a collision of the components S, D and T in their positioning.

Claims

claims

Radiation therapy device comprising X-ray-based imaging means (S, D) for Her ^¬ highlighting of soft parts of a target area, which are designed so that the imaging means are formed for a phase contrast imaging.

Device according to the preceding claim, characterized in that the imaging means are positionable relative to the target area independently of the device means (T) for radiotherapy.

A device according to the preceding claim, characterized in that the imaging means comprise at least one X-ray source (S) and at least one detector (D) which are statically arranged relative to each other but together freely movable and / or positionable with respect to the device means (T) are for radiotherapy.

4. Device according to one of the preceding claims, characterized in that the device has a STEU ^¬ tion device or a receiving device of control signals to avoid a collision between the imaging means (S, D) and the device means (T) for radiotherapy.

5. Device according to one of the preceding claims, characterized in that the imaging means for ^¬ least have a monochromatic X-ray source.

6. Device according to one of the preceding claims 1 to 4, characterized in that the Bildgebungsmit ^¬ tel have at least one coherent X-ray source.

7. Device according to one of the preceding claims 1 to 4, characterized in that the imaging means comprise at least one incoherent X-ray source.

8. Device according to one of the preceding claims, characterized in that the imaging means to ^{¬ at} least one energy-suppressing detector aufwei ^¬ sen.

9. A method for position control of X-ray based imaging means (S, D) for highlighting soft tissue of a target area provided within a radiotherapy apparatus for phase contrast imaging, wherein, with respect to the target area, it is independent of the device means (Figs. T) are positioned for radiotherapy.

10. The method according to the preceding claim, characterized in that emitted by a control device control signals cause avoidance of Kol ^¬ lision between the imaging means (S, D) and the device means (T) for radiation therapy.