WO2006027320A1

WO2006027320A1 - X-ray diagnostic device, especially for mammography

Info

Publication number: WO2006027320A1
Application number: PCT/EP2005/054234
Authority: WO
Inventors: Martin Hoheisel; Thomas Mertelmeier; Marcus Pfister
Original assignee: Siemens Aktiengesellschaft
Priority date: 2004-09-06
Filing date: 2005-08-29
Publication date: 2006-03-16
Also published as: DE102004043032A1

Abstract

The invention relates to an X-ray diagnostic device which comprises a control device (14) for optimally adapting the radiation emitted by the X-ray source (2) to the respective patient. The diagnostic device also comprises a measuring arrangement, coupled to the control device, for determining the tissue composition of the body part (4) to be examined. The control device is adapted to optimally adapt the radiation of the X-ray source to the respective patient based on the measured tissue composition.

Description

description

X-ray diagnostic device, in particular for mammography

The invention relates to an X-ray diagnostic device with a control device for optimum adjustment of the radiation of the X-ray source for the respective patient, in particular for mammography.

The difficulty of determining the optimal exposure, even in mammography, is that the female breast is a very variable organ. Apart from the size, that is, in the compressed case of the thickness, the composition also varies from very high-fat to glandular tissue. This requires a precise adaptation of the exposure ^parameters .

Whereas film-film systems have been used in conventional mammography, digital systems with solid-state detectors have been gaining increasing acceptance in recent years.

In the case of film-based systems, precise exposure is unavoidable, since even slight over or underexposure leads to significant losses in the contrast-detectability of interesting details. Therefore, a measuring cell is arranged in the beam path behind the film cassette, which measures the radiation not absorbed by the amplifier film and uses it to control the exposure time. However, the beam hardening influences the measured values in such a way that, depending on the thickness of the breast, incorrect exposures may occur. This can in turn be solved with the help of a double detector.

Digital solid-state detectors are linear over wide dose ranges and thus much more tolerant to different exposures. At high dose, overdriven by limiting and at low dose electronic noise plays a disturbing role. A novel concept for Control of mammography with such a detector was described in DE 100 19 242 A1.

Both mammography techniques, both the film-film system and the solid-state detector system have in common that for the adjustment of the beam quality, that is to say for the selection of the high voltage of the x-ray tube, only the thickness of the compressed breast is decisive. The variable to ^¬ composition of the breast is not considered. Therefore, the set voltage is not always optimal.

No. 6,157,697 discloses a device with which both X-ray images and 3D distributions of the electrical impedance can be recorded. The measuring arrangement provided there serves to accommodate a three-dimensional

Distribution of impedance values. A control unit is provided which serves to correctly control the multiplicity of existing electrodes according to a specific pattern or to select parameter sets stored in the control unit for the operating parameters mentioned by means of a keyboard 14. Alternatively it is possible that Be ^¬ operating parameters of the x-ray emitter input directly from the keyboard.

The invention is therefore based on the object, an X-ray diagnostic device in such a way that especially in mammography, the different consistency and Zusammenset ^¬ tion of the body part to be X-ray detected and used for optimal adjustment of the radiation of the X-ray source.

To achieve this object, such an X-ray diagnostic device is characterized by a measuring arrangement coupled to the control device for determining the tissue composition of the body part to be examined, preferably in the form of an electrode for attachment to the body part to be examined, which is coupled to the control device Körperfettanalyseeinrich- tion, wherein the control device is ausge¬ for optimal adjustment of the radiation of the X-ray source for each patient on the basis of the measured tissue composition.

By taking into account the tissue composition, in particular the fat content of the breast to be examined, an optimized radiation examination can be carried out after the system has been pre-adjusted accordingly. For this purpose, in a development of the invention, for example, it is provided that optimum values for the anode and filter material, the filter thickness and the tube voltage are determined by simulation or phantom measurement for each combination of breast thickness and fat content and stored in, preferably in the control device. Tables are stored.

The body fat analysis device may further Ausgestal¬ tung the invention is very simple as Elektroimpedanzmessein- direction be formed in the via two impedance-danzelektrodenpaare the skin resistance and the tissue was ^counter-¬ the examination region is determined.

In addition to the possibility of arranging the electrodes on mutually opposite sides of the compressed breast in order to carry out the body fat analysis, according to a ^further feature of the present invention it can also be provided that the electrodes and their electrical leads are formed of material permeable to X-rays and into which Compression plates are integrated.

For example, the electrodes and the electrical leads may consist of aluminum, an aluminum-magnesium alloy or an organic conductive polymer such as, for example, polyaniline or PEDOT (polyethylene thioxythiophene). Especially the arrangement with integrated into the compression plates electrodes has the advantage that these ^¬ additionally also can be used to to to the chest rieh- tiger position (incorrect positioning is one of the most frequent reasons for a required Wiederholaufnahme).

With the two liegen- respectively on the same side of the chest electrodes will then measure the individual's skin resistance ge ^¬, with the respective opposite electrodes of the Ge webewiderstand. Both measurements are used to determine the tissue composition of the breast, in particular the fat content. This makes it possible to make a statement about the proportions of glandular tissue and adipose tissue, which together with the breast thickness and other known influencing variables can then be used to determine the optimum x-ray parameter for the respective patient.

It is also within the scope of the invention that in the control device additional patient-specific data, such as the thickness of the body part to be determined, ie especially the thickness of compressed breast plates, the compression force, the hormone and therapy status and the age of the patient and / or the presence of implants can be processed as parameters for optimizing the radiator setting.

Further advantages, features and details of the invention will become apparent from the following description of some Ausfüh¬ insurance examples of the invention with reference to the drawing. Here zei ^¬ gen:

1 is a schematic representation of an X-ray diagnostic device for mammography and

Fig. 2 and 3 partial views of the compression plates such as the arrangement of the so¬ for determining the overall webezusammensetzung serving electrodes, it being possible for these electrodes once from the compres sion ^¬ plates are separated and once tegriert in this in ^¬. In the figure, an inventive mammography Röntgen¬ is apparatus with a powered from a high voltage generator 1 with high and heating voltage X-ray tube 2 is shown which produces a cone-shaped X-rays 3, which penetrates to un ^¬ tersuchende Mamma 4 of a patient and on an X-ray 3 sensitive digital Festkörper¬ image converter 5 beam images generated. The Festkörperbildwand ^¬ ler 5 contains, for example, switching elements of amorphous silicon (a-Si: H) and has arranged in a matrix Bild¬ points.

In the X-rays 3 are arranged from ^¬ replaceable filter 6 near the X-ray tube. 2 The output signal of the solid-state image converter 5 is fed to an image processing system 7, which may have converters, image memories and processing circuitry. It is connected to a monitor 8 for reproducing the recorded X-ray images. The user interface 9 is connected via a system control and communication 10 with the other components of the X-ray diagnostic device.

The mamma to be examined 4 is pressed by a compression ^¬ plate 11 against a cover plate 12 at the inlet side of the solid state image converter 5. A feeler 13 measures the

Of the compressed breast thickness 4. The measured thickness is transmitted ei ^¬ ner control device 14, which also may be part of the Hoch¬ voltage generator 1 or the image processing system. 7 The X-radiation 3 penetrates partly the Mamma 4 and falls weakened on a region 16 of the solid-state image converter 5. Side of the Mamma 4 part of the X-radiation 3 strikes unattenuated, ie directly on a region 15 of the solid-state transducer fifth

In addition, the X-ray diagnostic device shown schematically in FIG. 1 also contains two pairs of electrodes 17 and 18 which are compressed on opposite sides of the compression plates 11 and 12, respectively Mamma are to be arranged. About each arranged on the same side of the chest electrodes 17, 17 and 18, 18, the measurement of skin resistance, and via one of the Elect ^¬ clear 17 and 18, with transversely verlaufendem current through the chest, the measurement path of the fat content. In addition to the arrangement of the electrodes shown in FIGS. 1 and 2 as separate components which are arranged on the opposite free sides of the breast, the variant shown in FIG. 3 can also be used with preference in which the electrodes 17 and 18 in the compression plates 11 and 12 are integrated, which of course makes it necessary that these electrodes and their leads from X-rays durchläs¬ sigem material. The arrows 19 and 20 show the type of interconnection of the electrodes for measuring once the skin resistance (19) and in the case of the interconnection 20 of the Fettge ^¬ haltes. In the control device 14, the optimum values for anode material, filter 6, tube voltage, tube current and duration of the x-ray pulse associated with the thickness and the known geometry-the distance x-ray focus solid-state image converter in one of a table memory

20 taken from the table. Here, for each Kombina ^¬ tion of breast thickness and fat content of the optimum value for the anode and filter material, the filter thickness and the tubes ^¬ voltage determined in advance by simulation or measurement and phantom been determined in form of a table in the table memory, and

21, so that the measured values of the electrodes 17 and 18, which of course are still processed by an electronic system, are automatically taken into account in the optimization of the radiator setting.

The invention is not limited to the illustrated Ausführungsbei ^¬ games. Thus, it is of course completely indifferent as to whether the mammary between perpendicular Kom ^¬ pressionsplatten or compressed between th horizontal Kompressionsplat- and Berücksichti ^¬ invention account the tissue composition of the examined body part for adjustment of the X-ray source can of course also be used when a film-film system is used instead of a Festkör¬ perbildwandlers.

Claims

claims

1. X-ray diagnostic device with a Steuerungvorrich¬ device for optimal adjustment of the radiation of the X-ray emitter for each patient gekenn ¬ characterized by a coupled with the Steuerungsvor¬ direction measuring arrangement for determining the Geweb¬ composition of the body part to be examined, wherein the control device for optimal adjustment the radiation of the X-ray source is designed for the respective patient on the basis of the measured tissue composition.

2. X-ray diagnostic device according to claim 1, characterized ge ¬ by an electrode (17, 18) for attachment to the body part to be examined um¬ comprehensive coupled to the control device body fat ^¬ analysis device.

3. X-ray diagnostic device according to claim 2, since - by in that the Kör ^¬ perfettanalyseeinrichtung an electrical impedance measuring device, it is determined in each case via two impedance electrode pairs (17, 18) of the skin resistance and tissue resistivity of the investi ^¬ monitoring region.

4. X-ray diagnostic device according to claim 2 or 3, for the mammography, dadurchgekenn ^¬ characterized in that the electrodes (17, 18) and their electrical leads formed of X-ray transmissive material formed in the compression plates are integrated.

5. X-ray diagnostic device according to one of claims 1 to 4, characterized in that in the control device additional patientenspezi¬ fische data such as the thickness of the body part, especially the zwi ^¬'s compressed compression plates mom, the compression force, the hormone and therapy status, age of the patient and / or the presence of implants can be processed as parameters for optimizing the radiator setting.

6. X-ray diagnostic device according to one of claims 1 to 5, characterized in that for each combination of breast thickness and fat content opti ^¬ male values for the anode and filter material, the Filterdi ^¬ cke and the tube voltage determined by simulation or phantom- sung and in, preferably stored in the Steuerungsvorrich¬ device, tables are stored.