DE102006014339A1 - Endoscopy capsule and endoscopy system and method for therapy by means of an endoscopy capsule - Google Patents

Abstract

The invention relates to an endoscopy capsule (1) with a housing (2) in which at least one magnetic element (3) for navigation by means of a magnetic field that can be generated by an external magnetic system and at least one radiation source (6) are arranged. The invention also relates to an endoscopy system with an endoscopy capsule (1) and a method for therapy using an endoscopy capsule (1). The invention enables the therapy of malignant tumors to be carried out in a simple manner with a targeted radiation dose delivery with a simultaneous low radiation exposure of the medical staff.

Description

The The invention relates to an endoscopy capsule and an endoscopy system and a method of therapy by means of an endoscopy capsule.

at radiotherapy, e.g. of malignant tumors, become diseases treated by the action of ionizing radiation. It is Make sure that the healthy tissue in the area of the treatment area as far as possible little, ideally receives no radiation dose. Furthermore, the medical Personnel should not be exposed to radiation.

at percutaneous irradiation, e.g. with gamma rays from a linear accelerator, too referred to as teletherapy (radiotherapy with large source-skin distance), can also be careful Align the radiation source damage to healthy tissue can not be excluded in the beam path.

One brachytherapy provides alternative procedure to teletherapy in which a radiation source having a shorter range, e.g. Iridium 192 preparation, in nearby of the target area is placed. Brachytherapy will be especially then applied when the target area near a hollow organ (Lumen), as for example in cervical carcinoma or in prostate cancer is the case.

X-ray brachytherapy is a therapeutic X-ray treatment in which the X-ray source is brought very close to the tissue to be treated, for example, a tumor or vessel wall after performing endovascular dilatation. In order to introduce the X-ray source either without or with the least possible invasive intervention inside a body using a catheter or a probe, a miniaturized X-ray source is required, as for example from the US 6,721,392 B1 is known. This is arranged at the distal end of a probe, which is positioned intraoperatively, for example in a tumor or after its removal in a tumor bed, as for example in the PR information of Carl Zeiss AG, Medical Technology Innovation of Carl Zeiss AG, "Intraoperative radiotherapy with the INTRABEAM system from Carl Zeiss AG, as of September 2004 ".

Out US 2003/0149327 A1 is a miniaturized X-ray source known, which is arranged in a catheter with which they are in the Body cavities (lumens) introduced can be used to irradiate selected tissue zones from close proximity. It contains a shield rotatable about the axis of the catheter, around the x-rays targeted substantially perpendicular to the axis in a selected solid angle radiate. With an optical observation device arranged in the catheter the environment of the catheter can be considered. For this purpose, a light source used, which illuminates only the part of the surface of the cavity, which is also irradiated.

Also in endovascular brachytherapy with a arranged in the top of a catheter beta or gamma emitters (eg for intracoronary irradiation) is for example from the DE 10 2004 008 373 B3 known to arrange an optical observation device in the catheter. For this purpose, a brachytherapy catheter with an OCT catheter based on optical coherence tomography (OCT) is integrated into a unit.

Essential for the Therapeutic success is that of the radiation source in an irradiation area outside of the catheter radiated ionizing radiation largely exclusively on impact the tissue to be treated, for example the tumor, one as possible to ensure low stress on the adjacent healthy tissue. This requires a precise Positioning of the irradiation area, i. a precise positioning and orientation of the radiation source or the solid angle, in the the ionizing rays escape.

Farther it is known to treat tumors or organs from the inside by means of the after-loading method ("reloading"). at The after-loading technique is a local process Radiotherapy, wherein in a first step empty applicators (Cannulas, Plastic hoses) be placed directly in the tumor or in the intracavitary space. In a second step then takes place via a recharging the loading with encapsulated radionuclides (small "needles" from Iridium 192). The radionuclides will be afterwards remotely advanced to the target area. This technique is used the more precise limitation of the irradiated area as well as the more targeted ones Distribution of the beam energy. Compared with radium radiation shortened the duration of treatment by a factor of 3.5. In addition, in this Procedures protect medical personnel from unnecessary radiation exposure.

The problem with this is that the plastic tube can move inadvertently during the treatment procedure, for example, by a movement of the patient. This is especially in a hollow organ of variable width, for example, the rectum, in which the plastic tube only bad fix, possible.

task The present invention is therefore to provide a radiotherapy device, the one easy to do Therapy of malignant tumors with a targeted radiation dose delivery at the same time low radiation exposure of the medical staff allows.

It Another object of the present invention is a radiation therapy system to create a therapy of malignant tumors in a simple way allows and ensures a targeted radiation dose delivery, while simultaneously the radiation exposure of the medical staff kept low becomes.

Finally is It is an object of the present invention, in malignant tumors easy to perform Radiotherapy to create a targeted radiation dose delivery at the same time low radiation exposure of the medical staff allows.

The Task is for a radiotherapy device according to the invention an endoscopy capsule according to claim 1 solved. For a Radiation therapy system is the task through an endoscopy system according to claim 19 solved. For a Radiotherapy method is the object by a method according to claim 37 solved. Advantageous embodiments of the invention are each the subject of further claims.

The Endoscopic capsule according to claim 1 according to the invention comprises a housing, in the at least one magnetic element for navigation by means of one of an external magnetic system can be generated magnetic field and at least a radiation source are arranged.

• • eine Endoskopiekapsel, die ein Gehäuse aufweist, in dem wenigstens ein Magnetelement zur Navigation mittels eines von einem externen Magnetsystem erzeugbaren Magnetfeldes und wenigstens eine Strahlungsquelle angeordnet sind, und
• • ein Magnetsystem zur Erzeugung des für die Navigation der Endoskopiekapsel erforderlichen Magnetfeldes, sowie
• • ein Ortungssystem für die Lokalisierung der Endoskopiekapsel.

The endoscopy system according to claim 19 comprises according to the invention

• An endoscopy capsule which has a housing in which at least one magnetic element for navigation by means of a magnetic field which can be generated by an external magnet system and at least one radiation source are arranged, and
• A magnetic system for generating the magnetic field necessary for the navigation of the endoscopy capsule, and
• • A location system for the localization of the endoscopy capsule.

• • Patientenlagerung in bzw. unter einem Magnetsystem,
• • Zuführung einer Endoskopiekapsel (1), die ein Gehäuse aufweist, in dem wenigstens ein Magnetelement zur Navigation mittels eines von einem externen Magnetsystem erzeugbaren Magnetfeldes und wenigstens eine Strahlungsquelle angeordnet sind,
• • Navigation der Endoskopiekapsel (1) in ein zu untersuchendes Gebiet in einem menschlichen oder tierischen Hohlorgan,
• • Freisetzung einer von der Strahlungsquelle erzeugten ionisierenden Strahlung und
• • Verlassen des Magnetsystems, oder
• • Verlassen des Magnetsystems und
• • Freisetzung einer von der Strahlungsquelle erzeugten ionisierenden Strahlung.

The method according to claim 37 for therapy by means of an endoscopy capsule comprises according to the invention the following steps:

• Patient positioning in or under a magnet system,
• • delivery of an endoscopy capsule ( 1 ), which has a housing in which at least one magnetic element for navigation by means of a magnetic field that can be generated by an external magnet system and at least one radiation source are arranged,
• • Navigation of the endoscopy capsule ( 1 ) in an area to be examined in a human or animal hollow organ,
• Release of ionizing radiation generated by the radiation source and
• • Leaving the magnet system, or
• • Leaving the magnet system and
• Release of ionizing radiation generated by the radiation source.

According to the invention, the radiation source is integrated in a magnetically navigable endoscopy capsule, which is also referred to as a capsule endoscope. Such an endoscopy capsule is for example from the DE 101 42 253 C1 and from the corresponding US 2003/0060702 A1, where it is referred to as "endo-robot" or "endo-robot". The from the DE 101 42 253 C1 Known endorobots can be navigated in a hollow organ of a patient by means of a magnetic field which is generated by an external (ie arranged outside the patient) magnet system (coil system). An integrated system for position control, which includes a position measurement of the endo-robot and an automatic control of the magnetic field or the coil currents, can automatically detect and compensate for changes in the position of the endorobot in the hollow organ of the patient.

at the endoscopy capsule according to the invention it is a miniaturized medical device, preferably provided is for radiation therapies in the gastrointestinal tract, primarily in rectal access, as in Rectoscopy or colonoscopy is common. The use in lumens other than the gastrointestinal tract is in the Frame of the invention also possible. Similarly, access is via a other natural Body orifice, for example about the mouth (oral administration of endoscopy capsule), possible. Also an artificial, So surgically created body opening can as access opening for the Serve endoscopy capsule.

By The natural or artificial access opening the endoscopy capsule according to the invention via a Applicator (cannula, rigid or flexible plastic tube) directly into the tumor or in brought the cavity, wherein the patient is preferably already located in the magnet system.

The delivery of the endoscopic capsule according to the invention from the radiation-shielded container through the applicator into the target area is carried out remotely controls by mechanical, pneumatic and / or hydraulic means. After the endoscopy capsule has entered the human or animal hollow organ, the capsule can then be magnetically navigated by means of the external magnet system surrounding the patient.

One direct contact of the medical staff with the radiant Endoscopic capsule is not required because the navigation the endoscopy capsule according to claim 1 remotely controlled, for example via controls outside the treatment room, can be done.

alternative For this purpose, the patient himself the endoscopy capsule according to the invention from a radiation-shielded Remove packaging and administer orally.

By the invention is a targeted placement and alignment of Radiation source possible, so that an optimal local dosage of ionizing radiation can be achieved. The malignant tissue in the target area can thereby be treated optimally, while sparing the adjacent healthy tissue becomes. The placement and orientation of the radiation source can by navigating the endoscopy capsule by means of its capsule internal Magnetic element and the magnetic field generated by the external magnetic system respectively.

With the endoscopy capsule according to the invention can easily areas within a human hollow organ achieved with endovascular brachytherapy (catheter, in the tip of which is a beta or gamma emitter) is not or are very difficult to treat.

by virtue of the possibility of navigation the endoscopy capsule, which is an integrated magnet system, ie a System with a position control and thus a position measurement the endoscopy capsule, in the invention, any displacement of the Radiation source, e.g. by an unintentional movement of the patient or by an involuntary Movement of the hollow organ, automatically detected and compensated.

at the solution according to the invention does not come medical personnel in contact with the radiation source or this dangerous near, as the feeder the endoscopy capsule from the radiation shielded container into the target area either remotely controlled, or the patient himself takes the endoscopy capsule from the radiation-shielded packaging and administered this orally. Even with the actual radiotherapy is the medical Personnel protected from ionizing radiation from the radiation source since the navigation of the endoscopy capsule is remotely controlled.

Opposite the classic after-loading technique, the inventive solution is essential more flexible in the positioning of the radiation source in the target area. By the applicator (cannula, rigid or flexible plastic hose) connection to be made only has to go from the radiation shielded container over the access opening into the body Hollow organ, but not to the target area, rich. The navigation gation the radiation source to the target area with the malignant to be irradiated Tissue is done by remote control of the endoscopy capsule. Thereby can From the radiation source also target areas can be achieved, with the Conventional after-loading technology is difficult or impossible to reach are.

in the Advantageous embodiments of the invention, the radiation source designed as alpha emitters, as beta emitters or as gamma emitters be.

Becomes used as radiation source an alpha emitter or a beta emitter, then suffice for one Preferably provided shield a relatively thin layer a heavy metal (e.g., lead or cadmium).

at A gamma emitter, such as Iridium 192, would have an almost 5 mm thick layer of lead needed around the radiation intensity in half to reduce. Since the useful weight of the endoscopy capsule (total weight the endoscopy capsule minus the weight of the magnetic element) only a few Grams, are in this case the shielding options, which lead to a noticeable reduction in radiation intensity, limits set. If the delivery occurs the endoscopy capsule - like described above - about one Applicator, then the achievable shielding options are sufficient.

According to one advantageous embodiment of the invention, the radiation source a shield on. The preferably when using a shield necessary for alpha emitters and beta emitters radiation exit window is part of the shield surrounding the radiation source and not Part of the preferably made of a biocompatible plastic material housing the endoscopy capsule.

According to a further advantageous embodiment of the endoscopy capsule according to the invention, the shield has a diaphragm, through which the beam exit window can be changed in size. This panel may be formed according to a before ferred embodiment as a rotary shutter. The operation of the diaphragm can, for example, by an internal capsule actuator or by that of the external magnetic system can be actuated magnetic field.

By the beam exit window is the exit of the ionizing Radiation in a preferred direction possible. Together with the invention possible Navigation of the endoscopic capsule makes it possible for the malignant tissue in the Target area targeted with a predetermined radiation dose irradiate. The meterability of the ionizing radiation can here be further improved by a diaphragm.

By the following further advantageous embodiments, the radiation therapy options be extended or improved again.

are for example, in the endoscopy capsule at least one storage unit and / or at least one communication unit arranged, then advantageously one to be emitted by the radiation source Radiation dose as a function of time from the beginning of therapy in the storage unit can be stored and / or transmitted by the communication unit.

Farther may advantageously be emitted from the radiation source Radiation dose depending of measured values that can be determined by a sensor device, according to a default value be determined, wherein at least one default value in at least an in-memory storage unit and / or at least one external storage unit is stored.

At least a default value may be e.g. a control algorithm and / or be a control algorithm and / or a table value.

According to one further embodiment at least one default value after delivery (administration or insertion) of the endoscopy capsule is available.

following is based on an embodiment schematically illustrated in the drawing the invention closer explains however, without the invention to the illustrated embodiment to restrict:

1 an embodiment of an endoscopy capsule according to the invention,

2 a flow chart for a with the endoscopy capsule according to 1 possible therapy procedure.

In 1 is with 1 a possible embodiment of an embodiment of an endoscopy capsule referred to. The endoscopy capsule 1 has a housing 2 made of a biocompatible material which is resistant to gastrointestinal digestive secretions.

The endoscopy capsule 1 further comprises a magnetic element 3 , which is arranged in the housing and is designed in the illustrated embodiment as a permanent magnet. The magnetic element 3 (Permanent magnet) is at the in 1 shown embodiment perpendicular to the longitudinal axis 4 the endoscopy capsule 1 magnetized. The magnetization is by an arrow 22 characterized. In the context of the invention, however, is also a magnetization parallel to the longitudinal axis 4 the endoscopy capsule 1 possible.

By designed as a permanent magnet magnetic element 3 can the endoscopy capsule 1 from the outside by a magnetic field in a hollow organ 5 (eg small intestine) to be navigated. In this magnetic field, that of an in 1 Not shown external magnet system (navigation magnet) is generated, it is usually a generated in an examination area 6D ground and gradient field.

Via an integrated position control system, which measures the position of the endorobot 1 and an automatic control of the magnetic field or the coil currents, can automatically changes the position of Endoroboters 1 in the hollow organ 5 be recognized and compensated by the patient.

The endoscopy capsule 1 comprises according to the invention a radiation source 6 , the ionizing radiation 10 emitted (for example, alpha or beta radiation). The radiation source 6 is advantageously a shield 7 with a beam exit window 8th assigned. The beam exit window 8th is parallel to the longitudinal axis in the illustrated embodiment 4 the endoscopy capsule 1 arranged.

The beam exit window 8th is part of the radiation source 6 surrounding shielding 7 and not part of the case 2 , which is transparent to the ionizing radiation and preferably consists of a biocompatible plastic material.

The beam exit window 8th is through a panel 9 - In the illustrated embodiment by a rotary shutter - changeable in size, wherein the beam exit window 8th can also be fully opened or closed. The aperture 9 This can be actuated either by the magnetic field generated by the external magnet system or by an integrated actuator.

At the in 1 variant shown is the actuator of the rotary shutter 9 as a combination of a miniature electric motor 13 and a wave 14 and a gear 15 executed. The miniature electric motor 13 gets out of one in the case 2 the endoscopy capsule 1 arranged energy storage (in 1 not shown) fed. Instead of an energy storage, the miniature electric motor 13 also with an induction coil (in 1 also not shown) can be coupled, in which can be coupled by the external magnet system electrical energy.

The of the radiation source 6 emitted ionizing radiation 10 (Radiation direction indicated by an arrow) can in the illustrated embodiment perpendicular to the longitudinal axis 4 the endoscopy capsule 1 , ie radially in through the shape of the beam exit window 8th defined, for example, cone-shaped irradiation area 11 , exit. That of the ionizing radiation 10 covered irradiation area 11 (Target area with malignant tissue) is in 1 through boundary lines 12 indicated.

The beam exit window 8th not necessarily at the in 1 be arranged. In the context of the invention, it is also possible, the beam exit window 8th to arrange in a different location, so that of the radiation source 6 emitted ionizing radiation 10 obliquely to the longitudinal axis 4 the endoscopy capsule 1 radiates. If necessary, the arrangement of the radiation source 6 inside the endoscopy capsule 1 be adjusted accordingly.

By the navigation (rotational and / or translational movements) of the endoscopy capsule 1 in connection with the variation of the aperture of the aperture 9 leaves the target area 11 containing the malignant tissue, specifically with a fixed dose of the ionizing radiation 10 to treat.

In the illustrated embodiment of the invention, the endoscopy capsule 1 at closed aperture 9 to the irradiation area 11 (Destination) navigates and only in the target area 11 becomes the aperture 9 opened and thereby irradiated the malignant tissue. After completion of the irradiation, the aperture 9 closed and thereby protects the patient from further ionizing radiation 10 that is not required therapeutically. The endoscopy capsule 1 then leaves with the shutter closed 9 the target area 11 in the human or animal hollow organ 5 and is either excreted by natural intestinal peristalsis or by means or measures similar to those used to deliver the endoscopy capsule 1 are active from the hollow organ 5 away.

In the 1 illustrated endoscopy capsule 1 also contains a communication unit, which is not shown for reasons of clarity. Through the communication unit (transceiver) can also be in a 1 not shown antenna measurement data are sent to the outside and control signals, for example, for the control of the miniature electric motor 13 to operate the panel 9 to be received. In addition, data exchange within the endoscopy capsule 1 be made.

In the 1 illustrated endoscopy capsule 1 further comprises a sensor device 16 for the detection of medically relevant data. The sensor device 16 is executed in the illustrated embodiment as an optical sensor device and includes in the illustrated embodiment, a camera window 17 that at least partially as a lens 21 (Lens) is executed. Furthermore, the optical sensor device comprises 16 one behind the camera window 17 and the lens 21 lying CCD chip 18 (Video camera) as well as two behind the camera window 17 lying light emitting diodes 19 and 20 , Through the CCD chip 18 Images of the environment, so from the inner wall of the human or animal hollow organ 5 added. Within the scope of the invention may be used as a video camera instead of the CCD chip 18 Also, a CMOS device can be used. The one from the video camera 18 maximum detectable observation area 23 extends to the boundary lines 24 and is essentially the size and construction of the camera window 17 and the design of the lens 21 dependent.

The of the sensor device 16 detected medically relevant data are stored in an in-capsule memory unit (not shown), optionally processed in an on-chip processor unit (also not shown) and, if necessary, given to an external image processing unit via the communication device and the antenna. This may correct the alignment of the endoscopy capsule 1 optically controlled. In this case, the irradiation area 11 the radiation source 6 be displayed in the video image, for example, as a colored frame to help the operator with the navigation of Endoroboters 1 to give. This visualization can be advantageously provided with a method of imaging the malignant tissue in the target area 11 be combined, for example, by special dyeings.

The navigation of the endoscopy capsule 1 can be done on a control panel by a person manually, for example via a so-called "joystick". The operator manually specifies a desired direction of movement and a desired speed.

In the context of the invention, the navigation of the endoscopy capsule can also be automatic, ie along a predetermined trajectory and / or with an automatic recognition of the further course of the hollow organ 5 , respectively. In this case, first of all, the ideal dose distribution of the ionizing radiation is determined on a 3D model, which was created using an imaging method (eg computed tomography). Starting from this 3D model will be the trajectory of the endorobot 1 and / or the dwell time of the endorobot 1 in the target area 11 calculated such that an optimal dose distribution of the ionizing radiation 10 is achieved. The navigation (trajectory and residence time) is thus automated, ie software-controlled, performed, manual intervention by an operator should be possible.

To the position of the endoscopy capsule 1 In a simple way to be able to control and facilitate automatic navigation, suitable markers (markers, signalers) in the target area 11 be introduced. For this purpose, both optical and chemical markers come into question, via the built-in video camera 18 (CCD chip) and / or other optical or chemical sensors can be detected.

Other markers, for example, via external imaging techniques, such as X-ray imaging, or by the position detection system of the endoscopy capsule 1 can be detected, are possible in the context of the present invention.

Setting the markers in the target area 11 can be done both by classical procedures (eg catheter endoscopy) as well as by another endoscopy capsule with which the target area 11 of the hollow organ 5 was examined in advance.

The endoscopy capsule 1 may additionally be equipped with at least one fixation device through which the endoscopy capsule 1 in the target area 11 can be fixed. Such a fixation further improves the effectiveness of the irradiation, since automatic or manual interventions for position correction during irradiation are reduced.

A Such fixation device for an endoscopy capsule can be designed for example as an anchor, clip or gripper. A formed as a clip or gripper fixing device, the in German Patent Application 10 2005 026 891.9 is described, dissolves after a few days and the endoscopy capsule is opened by the intestinal peristalsis natural Way out.

For certain applications, it may be useful to use a separate radiation detector, which measures the integral radiation dose or current ionizing radiation to the endoscopy capsule 1 or an additional control unit. Upon reaching a predetermined dose of radiation then the beam exit window 8th by adjusting the aperture 9 closed. The radiation detector can be fastened, for example, outside the patient's body, for example on a belt. Alternatively, the radiation detector can also be arranged in a further endoscopy capsule which temporarily in the target area 11 or near the target area 11 can be anchored.

In 2 is a flowchart for one with the endoscopy capsule 1 according to 1 possible radiotherapy procedure shown. The therapy begins after the diagnosis is complete (for example, malignant tissue in the small intestine) and includes the following steps:

Process step I:

• Patient positioning in or under a magnet system,

Process step II:

• Delivery (oral administration, insertion) of an endoscopy capsule 1 that a housing 2 in which at least one magnetic element 3 for navigation by means of a magnetic field which can be generated by an external magnet system and at least one radiation source 6 arranged for radiotherapy,

Process step III:

• Navigation of the endoscopy capsule 1 into an irradiation area 11 in a human or animal hollow organ 5 .

Process step IV:

• Release one of the radiation source 6 generated ionizing radiation 10 and

Process step V:

• Leaving the magnet system,

Process step VI:

• Withdrawal or excretion of the endoscopy capsule 1 or

Process step V:

• Leaving the magnet system and

Process step IV:

• Release one of the radiation source 6 generated ionizing radiation 10 .

Process step VI:

• Withdrawal or excretion of the endoscopy capsule 1 ,

Claims (39)

Endoscopy capsule ( 1 ) with a housing ( 2 ), in which at least one magnetic element ( 3 ) for navigation by means of a magnetic field generated by an external magnetic system and at least one radiation source ( 6 ) are arranged. Endoscopy capsule ( 1 ) according to claim 1, wherein the radiation source ( 6 ) a shield ( 7 ) with at least one radiation exit window ( 8th ) having. Endoscopy capsule ( 1 ) according to claim 2, wherein the beam exit window ( 8th ) an aperture ( 9 ), through which the radiation exit window ( 8th ) is variable in size. Endoscopy capsule ( 1 ) according to claim 3, wherein the diaphragm ( 9 ) is designed as a rotary shutter. Endoscopy capsule ( 1 ) according to claim 3 or 4, wherein the diaphragm ( 9 ) by an internal capsule actuator ( 13 . 14 . 15 ) is operable. Endoscopy capsule ( 1 ) according to claim 3 or 4, wherein the diaphragm ( 9 ) Is actuated by the magnetic field generated by the external magnetic system. Endorobot ( 1 ) according to one of the preceding claims, in which in the housing ( 2 ) at least one memory unit and / or at least one communication unit are arranged. Endoscopy capsule ( 1 ) according to claim 7, wherein one of the radiation source ( 6 ) to be emitted radiation dose as a function of time from the beginning of therapy in the memory unit can be stored and / or transmitted by the communication unit. Endoscopy capsule ( 1 ) according to one of the preceding claims, wherein one of the radiation source ( 6 ) to be emitted radiation dose as a function of measured values, by a sensor device ( 16 ) can be determined according to a default value can be determined. Endoscopy capsule ( 1 ) according to claim 9, wherein at least one default value is stored in at least one in-capsule memory unit and / or in at least one external memory unit. Endoscopy capsule ( 1 ) according to claim 10, wherein at least one default value is a control algorithm and / or a control algorithm and / or a table value. Endoscopy capsule ( 1 ) according to one of the preceding claims, wherein at least one default value after delivery (administration or insertion) of the endoscopy capsule ( 1 ) is available. Endoscopy capsule ( 1 ) according to claim 1, wherein the radiation source ( 6 ) is designed as an alpha emitter. Endoscopy capsule ( 1 ) according to claim 1, wherein the radiation source ( 6 ) is designed as a beta emitter. Endoscopy capsule ( 1 ) according to claim 1, wherein the radiation source ( 6 ) is designed as a gamma emitter. Endoscopy capsule ( 1 ) according to claim 1, which comprises at least one fixation device for anchoring in the tissue of a human or animal hollow organ ( 5 ) having. Endoscopy capsule ( 1 ) according to claim 16, wherein the anchoring of the fixing device is mechanically detachable after a predetermined time. Endoscopy capsule ( 1 ) according to claim 16, wherein the anchoring of the fixation device is automatically biocompatible resolvable. Endoscopy system with • an endoscopy capsule ( 1 ), which is a housing ( 2 ), in which at least one magnetic element ( 3 ) for navigation by means of a magnetic field generated by an external magnetic system and at least one radiation source ( 6 ) and a magnet system for generating the endoscopy capsule ( 1 ) required magnetic field, and • a locating system for the localization of the endoscopy capsule ( 1 ). Endoscopy system according to claim 19, in which the radiation source ( 6 ) a shield ( 7 ) with at least one radiation exit window ( 8th ) having. Endoscopy system according to claim 20, in which the radiation exit window ( 8th ) an aperture ( 9 ), through which the radiation exit window ( 8th ) in its size is changeable. Endoscopic system according to claim 21, in which the diaphragm ( 9 ) is designed as a rotary shutter. Endoscopy system according to claim 21 or 22, in which the diaphragm ( 9 ) by an internal capsule actuator ( 13 . 14 . 15 ) is operable. Endoscopy system according to claim 21 or 22, in which the diaphragm ( 9 ) Is actuated by the magnetic field generated by the external magnetic system. Endoscopy system according to one of the preceding claims, in which in the housing ( 2 ) at least one memory unit and / or at least one communication unit are arranged. Endoscopy system according to claim 25, wherein one of the radiation source ( 6 ) to be emitted radiation dose as a function of time from the beginning of therapy in the memory unit can be stored and / or transmitted by the communication unit. Endoscopy system according to one of the preceding claims, in which one of the radiation source ( 6 ) to be emitted radiation dose as a function of measured values, by a sensor device ( 16 ) can be determined according to a default value can be determined. The endoscopy system of claim 27, wherein at least a default value in at least one capsule-internal memory unit and / or stored in at least one external storage unit is. The endoscopy system of claim 28, wherein at least a default value is a control algorithm and / or a control algorithm and / or a table value. Endoscopy system according to one of the preceding claims, wherein at least one default value after delivery (administration or insertion) of the endoscopy capsule ( 1 ) is available. Endoscopy system according to claim 19, in which the radiation source ( 6 ) is designed as an alpha emitter. Endoscopy system according to claim 19, in which the radiation source ( 6 ) is designed as a beta emitter. Endoscopy system according to claim 19, in which the radiation source ( 6 ) is designed as a gamma emitter. Endoscopy system according to claim 19, comprising at least one fixation device for anchoring in the tissue of a human or animal hollow organ ( 5 ) having. Endoscopy system according to claim 34, wherein the Anchoring the fixation device after a predetermined time mechanically detachable is. Endoscopy system according to claim 34, wherein the Anchoring the fixation device is automatically biocompatible resolvable. Method for therapy by means of an endoscopy capsule, comprising the following steps: patient positioning in or under a magnet system, delivery of an endoscopy capsule 1 ), which is a housing ( 2 ), in which at least one magnetic element ( 3 ) for navigation by means of a magnetic field generated by an external magnetic system and at least one radiation source ( 6 ) are arranged for radiotherapy, • navigation of the endoscopy capsule ( 1 ) in an irradiation area ( 11 ) in a human or animal hollow organ ( 5 ), • release one of the radiation source ( 6 ) generated ionizing radiation ( 10 ) and • leaving the magnet system, • removing or excreting the endoscopy capsule ( 1 ), or • leaving the magnet system and • releasing one from the radiation source ( 6 ) generated ionizing radiation ( 10 ), • removal or excretion of the endoscopy capsule ( 1 ). Method according to claim 37, comprising the following steps: • acquisition of medically relevant data by means of a sensor device ( 16 ) The method of claim 37 or 38, comprising the following steps: • fixation of the endoscopy capsule ( 1 ) in the tissue of the human or animal hollow organ ( 5 ).