WO2007036460A2

WO2007036460A2 - X-ray dosimeter

Info

Publication number: WO2007036460A2
Application number: PCT/EP2006/066500
Authority: WO
Inventors: Ronald Dittrich; Detlef Mattern; Peter Schardt
Original assignee: Siemens Aktiengesellschaft
Priority date: 2005-09-26
Filing date: 2006-09-19
Publication date: 2007-04-05
Also published as: DE102005045972A1; WO2007036460A3

Abstract

The invention relates to an x-ray dosimeter comprising a first capacitor plate (1) and a second capacitor plate (2) which are arranged in a chamber or form parts of a chamber (4), said chamber (4) being filled with a gaseous medium. The first capacitor plate (1) comprises an active measuring field (5) on the side thereof facing the second capacitor plate (2), and the second capacitor plate (2) comprises an electron-emitting x-ray absorption layer (6) on the side thereof facing the first capacitor plate (1).

Description

description

X-ray dose measurement device

The invention relates to a Röntgendosismessvorrichtung.

X-ray dosimetry devices are used in radiography and mammography, on the one hand to reduce the proportion of false exposures in X-ray images and, on the other hand, to avoid radiation exposure.

DE 37 41 760 C2 discloses an X-ray diagnostic device which can be used in radiography and which works with an automatic X-ray exposure. In the known X-ray diagnostic device, an X-ray dosing device is arranged between a patient irradiated by X-ray beams and an X-ray image detector (film-film system).

Such Röntgengendosismessvorrichtung is designed as a thin, planar ionization chamber (Iontomat chamber) in the size of the X-ray image detector. The measuring fields consist of 2 μm to 3 μm thick lead layers and can be identified in the X-ray image. Due to the structural design of the ionization chamber, the X-ray images taken by the X-ray image detector are not completely shadow-free.

In mammography with respect to the radiography wei Cheren ^¬ X-ray shadowing in the X-ray image is too strong by the highly absorbent lead layers of the ionization chamber. In mammography the Röntgendo ^¬ sismessvorrichtung is therefore not - arranged between the patient and the X-ray image detector, but behind the X-ray image detector - such as in radiography. The X-ray dose measuring device must thus evaluate the X-radiation, which has not been absorbed by the X-ray image detector. The automatic X-ray exposure is thus dependent on the absorption capacity of the X-ray image detector. When using Film-film systems must be calibrated separately for different film-film systems. Since digital Festkörperde ^¬ detectors have a higher absorption as film-screen systems, the X-ray dose measurement apparatus thus receives only a correspondingly smaller X-ray dose for the evaluation of the X-ray dose. Due to the variability of the objects to be imaged, a plurality of relatively large measuring fields (in each case a few 10 cm ² ) designed as silicon PIN diodes must be present. The cost of Röntgendosismessvorrichtung are thus dependent on the number of measurement channels.

Object of the present invention is therefore to provide a structurally simple design x-ray dosing device that distorts a recorded X-ray as little as possible.

The object is achieved by a Röntgendosismess ^¬ device according to claim 1. Advantageous Ausgestal ^¬ obligations of the invention are the subject matter of further claims sayings.

The X-ray ^dose measuring ^{device according to the} invention comprises a first capacitor plate and a second capacitor plate, which are arranged in a chamber or form parts of a chamber, wherein the chamber is filled with a gaseous medium, and wherein the first capacitor plate on its the second capacitor plate side facing an active Mess ^¬ and the second capacitor plate has an electron-emitting X-ray absorption layer on its side facing the first capacitor plate.

In the X-ray dose measuring device according to claim 1, the electrical function of the active measuring field is separated from the absorption of the X-rays (quantum absorption) and the associated electron release by the arrangement of the active measuring field on the first condenser ^¬ torplatte and the electron-emitting Röntgenabsorpti- onsschicht on the second capacitor plate , The indispensable for measurement of the X-ray dose Quantenab ^¬ sorption takes place in the inventive device Röntgendosismess- place in two layers that behave homogeneously with respect to the X-ray image to be recorded: first, in the gaseous medium and the active in the other measuring field.

The chamber of the x-ray dose measuring device is arranged for the measurement of the x-ray dose in a patient between the x-ray-irradiated patient and the x-ray image detector. Since the chamber absorbs only a small fraction of the x-radiation (less than 10%) and converted into a measurement signal, the aforementioned disadvantages are avoided ^¬ ver. This results in a significantly smaller number of incorrect exposure in mammography, the slightly hö here ^¬ X-ray dose than offset (to compensate for the absorption of X-rays in the chamber) more.

Due to the arrangement of the chamber in front of the X-ray image detector, the measurement signal is independent of the nature of the X-ray image detector. Furthermore, the measuring field geometry in the entire X-ray image field can be arranged arbitrarily and is thus largely freely selectable.

In the present invention, it is possible that the first capacitor plate and second capacitor plates are arranged either in a chamber, or alternatively, parts form ei ^¬ ner chamber. In the second case, for example, the first capacitor plate and the second capacitor plate each form a wall of the chamber and the other walls of the chamber are formed by a frame. Such a structural design ensures a particularly simple assembly technology production.

The disposed on the first capacitor plate ^¬ active measuring field is formed for example of an aluminum layer and / or, according to a further advantageous embodiment tion a layer thickness between about 50 nm and about 200 nm, preferably of 100 nm.

The electron-emitting X-ray absorption layer is preferably made of lead and / or according to a preferred embodiment has a layer thickness of between about 0.1 μm and about 3.0 μm, preferably of 0.3 μm.

A compact, in particular flat construction with good detection properties is achieved according to a particularly advantageous embodiment of the X-ray dose measuring device according to the invention, when the distance between the first capacitor plate and the second capacitor plate between about 1 mm and about 6 mm, preferably 2 mm ,

By the execution of the first capacitor plate and second capacitor plate in a sandwich construction the mechanical ^¬ African stability of the two capacitor plates, and thus the mechanical stability of the whole chamber of the Röntgendosis- measuring device is increased and thus combated in a simple manner the so-called microphonics.

In the case of such a sandwich construction, for example, the first capacitor plate can be made of a carrier plate made of foamed polystyrene (PS, polystyrene) with glued-on sides on both sides

Plastic films are made, wherein the active measuring field is applied to the plastic film, which faces the second capacitor ^¬ plate.

Is composed with both sides glued plastic foils, wherein the electron-emitting X-ray absorption ^¬ layer deposited on the plastic film that faces the ERS th capacitor plate (polystyrene PS) Alternatively or additionally, the second capacitor plate of a carrier plate of foamed polystyrene can.

The glued-on plastic films have, for example, a layer thickness between about 5 μm and about 100 μm, preferably of 15 microns, wherein the plastic films of polyethylene terephthalate (PET, PETP), polyimide (PI, Kapton) or similar materials may exist.

A compact, in particular flat construction with simultaneously good stability is achieved according to a particularly advantageous embodiment of the X-ray dosing device according to the invention in that the carrier plate of the first capacitor plate and / or the carrier plate of the second capacitor plate each have a thickness between about 1 mm and approx 3 mm, preferably 2 mm. If a foamed polystyrene with a density between about 20 mg / cm ³ and about 50 mg / cm ^{3 is} used for the support plate, then the chamber is also still correspondingly light.

If an external electrical shielding is required for the chamber and the two capacitor plates form parts of the chamber, then it is advantageous if this shield is formed by two shielding layers which are applied to the plastic films arranged on the opposite sides of the two carrier plates are. The shielding layers are preferably made of aluminum and have e.g. a layer thickness of about 100 nm.

In the sole figure an embodiment is an X-ray gendosismessvorrichtung according to the invention in a schematic sectional illustration shown, without thereby that occurs to limit the invention to the illustrated Ausführungsbei ^¬ game.

The illustrated x-ray dose measuring device according to the invention comprises a first capacitor plate 1 and a second capacitor plate 2, which are arranged in a chamber or form parts of a chamber 4.

In the illustrated embodiment, the first capacitor plate 1 and the second capacitor plate 2 each form a wall of the chamber 4. The other walls of the chamber 4 are of a frame formed, which is not shown for reasons of clarity.

According to the invention, the chamber 4 is filled with a gaseous medium, eg air. In the context of the invention, however, other gaseous media, such as noble gases or Kohlenwas ^¬ serstoffVerbindungen possible.

According to the invention, on its side facing the second capacitor plate 2, the first capacitor plate 1 has an active measuring field 5 which, according to the illustrated embodiment, is formed by an aluminum layer of 100 nm and segmented into three measuring field segments 5a, 5b, 5c.

Furthermore, the second capacitor plate 2 on its side facing the first capacitor plate 1 side according to the invention an electron-emitting X-ray absorption layer 6, which consists in the embodiment of unstructured lead (homoge ^¬ ner layer structure) and has a layer thickness of about 0.3 microns.

The X-ray absorption layer 6 absorbs because of its high

Density and atomic number of incident X-rays

(X-ray photons, X-ray quanta) very effective and thereby generates electrons. Since mammography only low Quan ^¬ tenenergien used by about 18 keV, the Rönt ^¬ must genabsorptionsschicht 6 very thin, about 0.3 microns be to absorb only a small part of the total already weakened by the patient X-rays , Due to the small thickness of the X-ray absorption layer 6, many electrons can escape from the X-ray absorption layer 6 and form further electron-ion pairs in the intermediate space between the two capacitor plates 1, 2, in which the gaseous medium (air) is located the total kinetic energy of the electrons and the ions has been used up. The measurement signal is due to the electron-emitting X-ray absorption ^¬ layer 6 is about three times as high as that of ionization of the air solely by the X-ray radiation. In the illustrated embodiment, the first capacitor ^¬ plate 1 is grounded via an operational amplifier 7, wherein the operational amplifier 7 as a current-voltage converter with a very high conversion constant of, for example, 10 ⁹ V / A, is connected.

Furthermore, the second capacitor plate 2 is connected to a ^DC voltage U ₌ of preferably 300 V.

In the illustrated x-ray dose measuring apparatus, the distance between the first capacitor plate 1 and the second capacitor plate 2 is only 2 mm. The total thickness of the chamber 4 is thus only 6.05 mm.

The ge in the embodiment according to the single figure ^¬ selected structure in the first capacitor plate 1 and the second capacitor plate 2 is in each case a sandwich construction ^¬ as is. Thus, the mechanical stability of the two capacitor plates 1 and 2 and thus the mechanical Stabili ^¬ ty of increased total chamber 4 of the X-ray dosemeter and thus easily combats the so-called microphony. Microphones are referred to in the chamber 4 by acoustic ^¬ generated influences generated noise.

The sandwich construction shown is sator plate in the first condensate ^¬ 1 realized in that it consists of a 2 mm thick carrier plate 10 of expanded polystyrene (PS; por styrofoam) with both sides glued plastic film 11, is sawn 12, wherein the active measurement field 5 on the plastic film 11 is applied, which is the second capacitor plate 2 is supplied ^¬ . The glued-on plastic films 11, 12 are made of polyethylene terephthalate (PET, PETP) and have a layer thickness of 15 μm.

The plastic films 11, 12; 21, 22 are adhered homogeneously on both sides of the carrier plates 10, 20 with spray adhesive over a large area and increase the mechanical stability considerably. borrowed. Both support plates 10, 20 together with a 2mm thick Plexiglas frame, which defines the air-filled gap, the chamber 4th

The measuring field 5 (made of aluminum) or the measuring field segments 5a, 5b, 5c on the one hand and the electron-emitting X-ray absorption layer 6 (made of lead) on the other hand must be vapor-deposited on the plastic films 11, 12, 21, 22 prior to bonding in a vacuum process. The measuring field segments 5a, 5b, 5c are defined as small contact surfaces via a vapor deposition mask including conductor tracks to the edge. The contacting to the outside takes place via soldered connections glued into the frame. These are pressed when gluing the support plates 10, 20 with the frame via applied as a drop of conductive silver (electrically conductive pasty material containing silver) to small contact surfaces.

In the second capacitor plate 2, the sandwich construction is formed by a 2 mm thick mounting plate 20 made of foamed polyvinyl lystyrol (PS; polystyrene) material films on both sides glued art ^¬ 21, realized 22, wherein the electron emittie ^¬ Rende X-ray absorption layer is applied to the plastic film 21 6 which faces the first capacitor plate 1. The glued-on plastic films 21, 22 are made of polyethylene terephthalate (PET, PETP) and have a layer ^¬ thickness of 15 .mu.m.

Is required an outside electrical shielding for the chamber 4 and forming the two capacitor plates 1, 2 parts of the chamber 4, it is advantageous if these Ab ^¬ shielding of two shielding layers 13, 23 is formed, which, on the plastic films 12 22 are applied, which are arranged on the opposite sides of the two support plates 10, 20. The shielding layers 13, 23 are preferably made of aluminum and have, for example, a layer thickness of about 100 nm. The illustrated x-ray dosemeter operates on the principle of an air-filled ionization chamber. When ionizing radiation enters the space between the two capacitor plates 1, 2, the air atoms are ionized. The electrons and the ions in the electric field is, the first between the capacitor to ground plate 1 and located on the second capacitor plate 300 V 2 before ^¬ hands, separately and a measurable current flows.

In contrast to the iontomat chamber for radiography, no material may be introduced between the capacitor plates 1, 2 outside the measuring field 5 or the measuring field segments 5a, 5b, 5c into the chamber 4 suitable for mammography for mammography. In the iontomat chamber used in radiography, this material is bonded to the capacitor plates 1, 2 in order to increase the stability against microphone disturbances. Even with foamed polystyrene (trade name "Styrofoam"), one of the lightest known materials (density 20-50 mg / cm ³ ), the edges of the excised measuring fields under mammography conditions remain visible in the iontomat chamber used in the radiography.

The total absorption of the chamber 4 is about 6% to 7% at an X-ray tube voltage of about 27 kV, an anode of molybdenum (Mo) and 30 microns Mo filter. This absorption, however, is homogeneous over the entire image field and thus not troublefree ^¬ rend radiographically visible field. The only structures of the chamber 4 in the X-ray field, the vapor-deposited measuring field ^¬ segments 5a, 5b, 5c nm of aluminum with a layer thickness of 100. However, these remain phiestrahlung invisible even when the soft Mammogra-.

Claims

claims

An X-ray dose measuring device comprising a first capacitor plate (1) and a second capacitor plate (2) arranged in a chamber or forming parts of a chamber (4), the chamber (4) being filled with a gaseous medium, and wherein

The first capacitor plate (1) has an active measuring field (5) on its side facing the second capacitor plate (2), and

The second capacitor plate (2) has an electron-emitting X-ray absorption layer (6) on its side facing the first capacitor plate (1).

2. X-ray measuring device according to claim 1, wherein the active measuring field (5) is segmented into at least two measuring field segments (5a, 5b, 5c).

3. Röntgendosismessvorrichtung according to claim 1, wherein the first capacitor plate (1) via an operational amplifier

(7) is grounded.

4. Röntgendosismessvorrichtung according to claim 1 or 2, wherein the second capacitor plate (2) to a DC voltage (U ₌ ) of 300 V is placed.

5. Röntgendosismessvorrichtung according to claim 1, ^wherein the chamber (4) has an external electrical shield on ^¬ .

6. Röntgendosismessvorrichtung according to claim 3, wherein the operational amplifier (7) as a current-voltage converter with a defined conversion constant, for example of 10 ⁹ V / A, beschal ^¬ tet.

7. Röntgendosismessvorrichtung according to claim 1, wherein the first capacitor plate (1) and the second capacitor plate (2) each form a wall of the chamber (4) and the other walls of the chamber (4) are formed by a frame.

8. Röntgendosismessvorrichtung according to claim 1 or 2, wherein the active measuring field (5) is gebil ^¬ det of an aluminum layer.

9. Röntgengendosismessvorrichtung according to claim 1, 2 or 8, wherein the active measuring field (5) has a layer thickness between about 50 nm and about 200 nm, preferably of 100 nm.

The X-ray dose measuring apparatus according to claim 1, wherein said electron-emitting X-ray absorbing layer (6) is lead.

11. Röntgendosismessvorrichtung according to claim 1 or 10, wherein the electron-emitting X-ray absorption layer (6) has a layer thickness between about 0.1 microns and about 3.0 microns, preferably ^¬ before 0.3.

12. Röntgendosismessvorrichtung according to claim 1, wherein the distance between the first capacitor plate (1) and the second capacitor plate (2) between about 1 mm and about 6 mm, preferably 2 mm.

13. Röntgendosismessvorrichtung according to claim 1 or 7, wherein the first capacitor plate (1) and the second capacitor ^¬ torplatte (2) are each designed in a sandwich construction.

14. X-ray dose measurement device of claim 13, wherein the first capacitor plate (1) polymer films of a carrier plate (10) made of foamed polystyrene having bonded to both sides Art ^¬ (11, 12), wherein the active measurement field (5) on the plastic film (11) is applied, which faces the second capacitor plate (2).

15. Röntgendosismessvorrichtung according to claim 13 or 14, wherein the second capacitor plate (2) consists of a carrier plate

(20) consists of foamed polystyrene with plastic films (21, 22) glued on both sides, wherein the electron-emitting X-ray absorption layer (6) is applied to the plastic film (21) which faces the first capacitor plate (1).

Is 16. X-ray dose measuring device according to claims 5 and 13 or 5 and 14, wherein the outer-side electric Abschir ^¬ mung the chamber (4) of two shielding layers (13, 23) are formed, which are applied to the plastic films (12, 22), which are arranged on the opposite sides of the two support plates (10, 20).

17. The x-ray dose measuring device according to claim 16, wherein the shielding layers are made of aluminum.

18. Röntgengendosismessvorrichtung according to claim 17, wherein the shielding layer has a layer thickness of about 100 nm.

19. Röntgengendosismessvorrichtung according to claim 13 or 14, wherein the support plate (10) of the first capacitor plate (1) and / or the support plate (20) of the second capacitor plate (2) each have a thickness between about 1 mm and about 3 mm, mm before ^¬ preferably 2, comprising.

20. Röntgendosismessvorrichtung according to claim 13 or 14, wherein the adhered plastic films (11, 12, 21, 22) have a layer thickness between about 5 microns and about 100 microns, preferably of 15 microns.

The X-ray dose measuring device according to claim 13 or 14, wherein the foamed polystyrene support plate (10, 20) has a density between about 20 mg / cm ³ and about 50 mg / cm ³ .

22. Röntgendosismessvorrichtung according to claim 1, wherein the gaseous medium is provided air.

23. Röntgengendosismessvorrichtung according to claim 1, wherein the noble gas is provided as the gaseous medium.

24. Röntgendosismessvorrichtung according to claim 1, wherein the gaseous medium is a hydrocarbon compound vorgese ^¬ hen.