DE102007014815A1 - Scattered beam screen for x-ray computer tomography scanner, has stationary ring detector and circulating x-ray focal spot for reduction scattered beam incident on ring detector - Google Patents

Abstract

The scattered beam screen has stationary ring detector (4') and circulating x-ray focal spot (1'a) for reduction the scattered beam incident on the ring detector. The scattered beam screen is subdivided in the direction of a system axle (8') into lying one behind the other partial scattered beam screens, where the lamella assigned to the individual partial scattered beam screens, have a same angle with respect to the radial direction, also with respect to the direction to the system axle.

Description

X-ray computed tomography (referred to below as CT for short) reconstructs the superimposed X-ray image of an object layer of projections which are recorded by lateral X-ray radiographs of this object layer. This reconstructed radiograph is a computed tomogram. The principle of CT and embodiments for devices to which the invention relates (computed tomography), with which this description will be concerned, can be found, for. B. in the German Patent 1941433 (GN Hounsfield).

The The first CT scanners built each projection as a parallel beam projection by parallel displacement of a fine blanked "pencil beam" on. X-ray source and detector were simultaneously and linearly shifted in the same direction. After taking a projection This parallel shift mechanism became a small angle rotated, and by another shift, usually by backward shift, from X-ray and detector one next Projection of the same length and the same number of measured values (Sampling points) recorded (dual-motion CT devices). In advanced devices were detector systems with several Detector elements used instead of a single, to move with a shift to record several (parallel) projections simultaneously. Thereby The recording times were initially several minutes for a CT image down to the lower two-digit second range be reduced.

For Recordings on the body trunk, z. B. of the lower abdomen, were to avoid or reduce movement artifacts recording times in one-digit seconds range. That led against End of the 70s to replace the above "Dual Motion" Devices by Rotation Only CT Devices, in which a spanned by an X-ray source Fan beam enclosing a patient while doing this rotated.

there There were two principles in competition with each other that differed Set up their X-ray fan beam projections, namely the principle with the rotating emitter-detector system with the patient in the middle and the system in which only the spotlight moved around the patient. In the second mentioned System became the patient's penetrating X-rays picked up by a stationary ring detector.

Both Principles have their specific technical implementation Advantages and disadvantages. From that point of view spoke against the ring detector in particular the high cost of the detectors and the associated Electronics, an effort that was many times what one did for a detector arc moved together with the radiator had to spend when implementing both principles comparable image quality and comparable patient dose sought. Was limited z. B. the ring detector the Number of the ring circumference evenly occupying Detectors on the necessary for the image reconstruction process Number, one was still faced with the election, by a smaller one as a possible width of the detector elements, although a good But to ensure structure resolution not fully utilizing the radiation passing through the patient, and vice versa.

One Another fundamental problem of X-ray imaging was for the ring detector in that compared to a device with rotating emitter detector system the on the detector at the same time as the primary radiation carrying the image information No or only very conditionally eliminating incident stray radiation was, as discussed below. That meant disadvantages for the image both in terms of its representation, z. B. by occurring artifacts, as well as the size the reproduced in the picture signal values, z. B. different Basic signal values or different signal values for Details of identical tissue properties in the recorded object cross section, depending on the type and size of the irradiated patient volume.

enforced finally have the systems with the moving detector arc, So the systems of today's design, where one through spotlights and detector system spanned fan beams around the To be picked object cross-section rotates and thereby takes Fanstrahlprojektionen.

The Problem of insufficient suppression of scattered votes now discussed with a comparison of a CT device with rotating emitter detector system and a CT device with incident on a ring detector beam fan.

1 shows transmission ratios, as they occur in a rotating emitter-detector system. In 1a emits a spotlight 1 with an x-ray stain 1a a fan of light 2 with the individual beams 2a . 2 B , ... 2i , ... etc. off. The fan of rays 2 passes through the object cross-section 3 , made from the cross section of the patient 3a and the couch 3b through to the detector arc or shortly detector 4 with the detector elements 4a . 4b ... 4i , ... etc. It is found that z. B. on the detector element 4i not just the single beam 2i represented and when passing through the object cross-section 3 according to that Weakening properties weakened primary radiation, but also scattered radiation 6 incident, in other places, such as the places 5a and 5b of the object cross section 3 through the fan of rays passing through it 2 is produced. The detector element 4i converts the unwanted and disturbing stray radiation, which is undesirable for the signal formation, into an electrical signal together with the primary radiation incident on it and intended for signal formation. To obtain the projections to be taken from different directions, this turns out of the radiator 1 and the detector 4 existing system together with the associated fan beam 2 around the system axis 8th and thus also around the object cross section 3 ,

1b shows the same arrangement as 1a , but with a lens hood 7 , their radiopaque fins 7a . 7b , ... 7i , ... etc., on the separation points between the detector elements 4a . 4b , ... 4i , ... etc and attached to the x-ray spot 1a are aligned and so the access of the primary radiation to the detector elements 4a . 4b , ... 4i , ... etc. allow unhindered. In the 1a already shown exemplary scattered radiation 6 is in their access to the detector elements. 4a . 4b , ... 4i , ... but prevented, as in the example of the detector element 4i is shown.

A similar consideration now for CT devices with ring detector based on 2 , In 2a there is again a spotlight 1' with his focal spot 1'a of which a fan of light 2 ' with the individual beams 2 ' . 2 B , ... 2i , ..., etc., after passing through the object cross-section 3 on the ring detector 4 ' with its detector elements 4 'a . 4'b , ... 4'i , ..., etc. As in 1a superimposed here, too, in the places 5 'a and 5 'b generated and unwanted for signal generation scattered radiation 6 ' on the detector element 4'i the one by the single jet 2'i represented primary radiation.

2 B shows the in 2a illustrated arrangement, but now with a stray-iris 7 ' with the slats 7a ' . 7b ' , ... 7'i , ... etc. So that at every point of the ring detector 4 ' same conditions prevail for the incident radiation are the lamellae 7a ' . 7b ' , ... 7'i , ... etc. also similar to install, where for reasons of symmetry their orientation to the system center or the system axis 8th' offering. When using the arrangement in 1b approximately comparable stray beam efficiency with respect to the exemplified stray radiation 6 ' that from the bodies 5 'a and 5 'b goes out, but only the central beam falls 2 ' z of the fan of light 2 ' or the primary beam bundle it represents unattenuated on the associated detector element 4 ' z. The other single beams 2 ' . 2 B , ... 2'i , ... etc. or the primary beams they represent are shaded differently, increasingly from the central beam 2 ' z starting at the edges of the fan beam 2 ' out. At far in the fan-beam 2 ' reaching in lamellas 7a ' . 7b ' , ... 7'i , ... etc. can be single beams 2 ' . 2 B , ... 2'i , ... etc. to the edge of the fan of light 2 ' be completely shaded.

However, the resulting effect on the signal acquisition was obviously so annoying that one has tried in the development of CT devices with ring detector, the fins 7a . 7b ' , ... 7'i , ... etc. of the antiglare screen 7 ' create a mobile and then control so that they always focus on the focal spot during the recording process 1'a of the rotating radiator 1' were aligned.

The Significance of the stray beam suppression for the reconstructed image can also be measured by that one on The company active in the field of computed tomography a device had developed in which the x-ray spot of the radiator in Center of the ring detector was and the spotlight around his Focal spot turned. This was the antiglare with their Ideally, slats aligned with the center of the system are effective. The problem, however, was that the patient in the rotating X-ray fans to keep what is easiest is conceivable that the patient bed while maintaining their horizontal position in the fan beam with this around the x-ray focal spot, so moved around the system center. Such a movement of Patients were naturally impractical, which is why the center of the system and thus the entire system surrounds the patient moved around (without the ring detector turning inside). So it was a CT machine with an ultimately rather complex one and considerable design effort required movement, however after all, with a self-contained ring detector. One such CT device was presented at a congress, but it is, if anything, at best in the clinical Trial operation gone.

enforced As already mentioned, the systems have with the with the spotlight mitbewegten detector arc, so the systems of today's design. This will be recording times for the record of a CT image significantly below one second, z. B. at about half a second.

In addition to the devices with the mechanically moving emitter-detector-systems but still a special kind of computed tomography was realized, namely systems without mechanically moving parts, as D. Boyd z. B. proposed in 1979 and later produced in the company "Imatron" would have. A whole series of such devices also went into clinical operation until about the mid-90s and are still to be found there sporadically. Such a system consists of an annular anode on which an X-ray focal spot circulates by means of a magnetically deflected electron beam, the beam fan generated by it passes through the patient and strikes the detectors of a stationary ring detector. The device makes use of the fact that the ring detector and corresponding to the rotation of the focal spot on the ring anode, both must not close to a full circle; according to the rules of computer tomographic image reconstruction, a segment could be missing from the full circle that corresponds approximately to the fan angle of the projection. After all, recording times of up to 50 ms are achieved with such devices. Thus, such devices were capable of taking sharp CT images of beating hearts with one shot. To achieve this goal, however, were significant limitations in the image quality to accept, which had their cause, inter alia, in the relatively low radiation power of the ring anode, further in a time for the concept not yet sufficient data technology, as well as in the already mentioned not or only limited solvable problem of a sufficient reduction of the scattered radiation portion of the incident on the X-ray detector X-ray radiation. The further development of these devices has lagged behind the rapid development of the devices with rotating emitter-detector systems and came to an end after a few years.

With Devices with rotating emitter-detector systems are recording times below half a second possible, but with this type of equipment for the Recording time seems to have reached a lower limit For reasons of mechanics not significantly undercut can be.

It would therefore make sense again to the concept of a CT system without moving mechanically moving parts, especially a whole series of technical difficulties has been resolved in the meantime, with which the devices with the encircling on a ring anode Focal spot in their latest state of technology around 1990 to deal with had.

The already described Streustrahlenproblem, which is also a disadvantage of early ring detector devices with rotating emitter was to look at, but is a fundamental. The problem when using a scattered radiation aperture in the ring detector as already described, that with increasing shaft ratio, d. H. increasing height of the slats and / or their decreasing distance from each other, the scattered radiation striking the detector elements Although decreases, but at the edge of the fan beam oriented detector elements of the primary radiation make access to the detector elements difficult if not impossible can.

The object of the invention is to provide an antiscustoscopic X-ray tomography scanner with a ring detector, which allows for effective anti-scattering radiation for all detected by the beam fan detector elements of the primary radiation access to these at the same or sufficiently equal and acceptable attenuation. This object is achieved by the specified in claim 1 embodiment. The invention is described below with reference to 3 to 7 explained in more detail.

3 like 2 B a computed tomography with ring detector, wherein 3 in specifying details is limited and different from 2 B also differs in that the spotlight 1 with the x-ray stain 1a in 3 on a circumferential X-ray spot 10 is reduced, with the type of focal spot production is not further discussed.

3 shows such a ring detector 9 with an X-ray focal spot circulating inside or beside the ring 10 , which is the center of the projections to be taken for the CT image, does not naturally coincide with the center of the ring detector 9 with the detector elements 9a . 9b , ... 9i , ..., etc., which center in the axis of rotation of the focal spot 10 that is the system axis 11 lies in 3 as a trace represents. From the focal spot 10 goes the X-ray fan 12 from, of which only the central ray 12z perpendicular and the rays immediately adjacent to it from the number of all rays 12a . 12b , ... 12i ... etc. almost perpendicular to that of the X-ray fan 12 met segment of the ring detector 9 fall. Now you put the ring detector 9 with a stray-iris 13 , so for their design is already for reasons of symmetry, an arrangement with to the interior of the ring detector 9 and thus on the system axis 11 directed slats 13a . 13b , ... 13i , ... etc., whose surfaces are parallel to the system axis 11 lie, and which are in 3 as traces or as lines.

Such an arrangement has the advantage that the recording situation with respect to the X-ray focal spot 10 , the ring detector 9 and the antiglare screen 13 for every position of the X-ray focal spot 10 the same is. The system in the in 3 However, the form shown is already with the basis of 2 B described problem of either insufficient stray beam reduction or to the edges of the fan beam 12 increase the shading of the primary radiation afflicted.

4a as a detail of 3 shows once again that the requirement of the anti-scatter lens 13 after the least possible attenuation of the primary radiation with the largest possible anti-scattering for the central beam 12z and its immediate neighboring rays are good to fulfill, but no longer for the marginal rays of the fan of light 12 , That's how the focal spot gets 10 outgoing beam part fans 14a in the central part of the fan-beam 12 from the lamella 13z the antiglare screen 13 and the lamella adjacent to it 13 (z + 1) practically without any shading to the detector 9 z pass through. On the other hand, one from the focal spot 10 outgoing and out of the parts 15a ' and 15a '' composing beam part fans 15a , which is in the left part of the fan of light 12 located and without the anti-scatter lens 13 with its two parts 15a and 15a '' the detector element 9b full hit by the two at the edges of the detector element 9b located slats partially shaded, leaving only its part 15a ' the detector element 9b reached. A similar consideration applies, so to speak, reversed for the right part of the fan of light 12 ,

4b is the detail view of an arrangement like in 3 , however, with a stray-iris 16 equipped, whose fins 16a . 16b , ..., 16i , ... etc. not like the slats 13a . 13b , ..., 13i , ... etc. of the antiglare screen 13 on the system axis 11 are aligned, but at an angle 17 opposite to the respective radial directions. 4b shows that this arrangement with a suitable choice of the angle 17 in view of little weakening of the primary rays from the number of rays 12a . 12b , ... 12i , ... etc., the rays in the right sector of the fan beam 12 prefers. Because of the focal spot 10 outgoing beam part fans 14b in the right part of the fan of light 12 may due to the slat position of the anti-scatter lens 16 the detector element 9i reach virtually without shading.

On the other hand, one from the focal spot 10 outgoing and out of the parts 15b ' and 15b '' composing beam part fans 15b which is located in the central part of the fan of light 12 located, and the without anti-glare 13 with its two parts 15b ' and 15b '' the detector element 9 z full hit by the two at the edges of the detector element 9 z located slats 17z and 17 (z + 1) partially shaded, leaving only part 15b ' the detector element 9 z reached.

In 4c are the slats 18a . 18b , ... 18i , ... etc. of a screen 18 at an angle 17 ' aligned with respect to the respective radial directions, the opposite to the angle 17 is such that, in view of the transmittance to the detector elements, the primary rays are from the number of rays 12a . 12b , ... 12i , ... etc. in the left sector of the fan of light 12 to be favoured. In the central part of the fan of light 12 obtained from the part fan 15c only the part 15c ' the detector element 9 z but not the part 15c '' , The so far based on 4 discussed effect of primary ray attenuation by the stray beam apertures 13 . 16 and 18 should 5 With 5a to 5c on the basis of selected primary beam fan sections, so to speak in the overview. clarify.

If one now assigns three such scattered radiation apertures as partial scattered radiation apertures 13 ' . 16 ' and 18 ' with the associated slats 13'a . 13'b , ... 13'i , ... etc., 16'a . 16'b , ... 16i , ... etc. and 18'a . 18'b , ... 18'i , ... etc. via the ring detector 9 as in 6 shown one after the other, ie in the direction of the system axis 11 that are in 3 . 4 and 5 As a trace, we obtain a compound antiscatter aperture that will match the primary ray attenuation for the fringes of the fan beam of the primary ray attenuation in its central part, even if the course of the primary ray attenuation over the whole of the ray fan 12 formed angle still has residual fluctuations.

If one follows this weakening course from the central ray 12z starting to the right side of the fan of light 12 , the primary ray attenuation decreases through the first partial scattered radiation aperture 13 ' and the third 18 ' to, but the second part of the beam 16 ' what the increase in the attenuation of the first partial scattered radiation aperture 13 ' and the third 18 ' counteracts. The transitions can be adjusted in terms of the lowest possible fluctuations by the lamella angle 17 the second partial scattered aperture 16 ' and the slat angle 17 ' the third partial scattered radiation aperture 18 ' changes. A corresponding consideration applies to the area of the fan beam 12 here to the left of the central jet 12z , wherein the third partial scatter blends 18 ' the increasing primary ray attenuation by the partial scattered radiation apertures 13 ' and 16 ' counteracts.

It is obvious that in the arrangement of the three mentioned partial scattered radiation apertures 13 ' . 16 ' and 18 ' their order for the effectiveness of the thus composed antiglare does not matter. If you put the partial scattered radiation aperture 13 ' with the aligned on the center of the ring detector slats between the other two partial scattered radiation apertures 16 ' and 18 ' , Thus, one obtains a fin arrangement, in accordance with 7 three consecutive individual lamellae of the partial scattered radiation apertures 13 ' . 16 ' and 18 ' as a single lamella sheet 19 processing technology in cheaper Let's sum up the way.

If you increase the number of three in 6 shown partial scattered radiation apertures 13 ' . 16 ' and 18 ' by interposing each a partial scattered beam aperture at half angle 17 respectively. 17 ' out 4b and c on five partial scattered radiation apertures or, depending on employed calculations, on the desired distribution of the sectors with primary beam preference in the individual partial scattered radiation apertures also deviating angle of the lamellar adjustment, the course of the primary radiation attenuation over the fan angle can be further uniformed. If the number of partial scattered radiation apertures is further increased, one can say, in the border crossing, successive fins of the partial scattered radiation apertures according to FIG 8th through a continuously shaped lamella plate 20 , so a sheet without kinks, summarize.

With such a scattered radiation panel with laminations 20 can for one on the ring detector 9 incident beam fan 12 a uniform primary radiation attenuation can be achieved over the entire area, regardless of the position of the fan beam 12 generating focal spot 10 , However, such a stray-iris diaphragm has a finite fundamental attenuation for the primary radiation, in contrast to a stray-beam shutter in a rotating radiator-detector system whose straight sheets can be aligned with the incident primary beams.

The Level of primary ray attenuation on receipt or increase the debilitating effect on the scattered rays depends mainly on the property the lamellae of a stray beam used, so after the Height of the slats and their distance from each other, as well according to the recording geometry, according to the energy spectra of the primary and scattered rays. It is Z. Also, no condition that before everyone Detector element has its own formed by two lamellae anti-scattering diaphragm section must lie, but on a stray beam aperture section can also several adjacent detector elements omitted.

For Computed tomography with several in the direction of the system axis in a row arranged ring detectors can slats of the anti-scatter blast juxtaposed ring detectors are strung together so that they can be made as one piece. If you keep track of the continuously changing Adjustment of a lamella across the width of a detector element a ring detector from one edge to another, so changes the angle of attack of the lamella starting from the first edge the angle zero to the opposite angle at the second edge, which Angle then the angle of attack at the first edge of the following ring detector is, which is about the angle zero to the opposite angle at the second edge of this ring detector changes, the same the angle of attack at the first edge of the first considered ring detector is, etc.

In With regard to the illustrated detector elements of a ring detector It should be mentioned that these are not physical have to be separate entities. It is also a ring detector conceivable, in which at its inner circumference instead of a consequence from detector elements one continuously over the whole Circle or running over longer segment sections Layer enters the incident radiation into electrical signals converted, which are then queried location-selective. In one In such a case, the sites that are polled would be considered Detector elements in the sense of the employee considerations to watch.

1, 1'

spotlight

1a, 1'a

X-ray stain, focal spot

2

ray fan

2a, 2b, ... 2i, ... etc.

individual jets

2 '

ray fan

2'a, 2'b, ... 2'i, ... etc.

individual jets

2z

central beam

3

Object cross-section

3a

cross-section of the patient

3b

cross-section the couch

4

Detector arc, detector

4 '

ring detector

4a, 4b, ... 4i, ... etc.

detector elements

4 'a, 4'b, ... 4'i, ... etc.

detector elements

5a, 5b

Put of the object cross section

5 'a, 5 'b

Put of the object cross section

6 6 '

scattered radiation

7

Scattered radiation diaphragm

7a, 7b, ... 7i, ... etc.

slats (the anti-scatter screen)

7 '

Scattered radiation diaphragm

7a ', 7'b, ... 7'i, ... etc.

slats (the anti-scatter screen)

8th, 8th'

system axis

9

ring detector

9 'a, 9b, ... 9i, ... etc.

detector elements

10

X-ray stain, focal spot

11

system axis

12

X-ray fans, fan beams

12a, 12b, ... 12i ... etc.

radiate

12z

central beam

13

Scattered radiation diaphragm

13a, 13b, ... 13i ... etc.

slats (the anti-scatter screen)

13 '

Part scattering beam diaphragm

13'a, 13 'b, ... 13'i ... etc.

slats (the partial scattered beam aperture)

14a, 14b

Part ray fan

15a, 15b, 15c

Part ray fan

15a, 15a ', 15b, 15b, 15c', 15c ''

part of the sub-beam fan

16

Scattered radiation diaphragm

16a, 16b, ... 16i, ... etc.

slats (the anti-scatter screen)

16

Part scattering beam diaphragm

16'a, 16'b, ... 16'i ... etc.

slats (the partial scattered beam aperture)

17 17 '

angle

18

Scattered radiation diaphragm

18a, 18b, ... 18i ... etc.

slats (the anti-scatter screen)

18 '

Part scattering beam diaphragm

18'a, 18 'b, ... 18'i, ... etc.

slats (the partial scattered beam aperture)

19 20

lamination plate

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 1941433 [0001]

Claims (2)

Scattering lens for an X-ray computer tomograph with stationary ring detector ( 4 ' . 9 ) and circumferential X-ray focal spot ( 1'a . 10 ) for reducing the on the ring detector ( 4 ' . 9 ) impinging scattered radiation, the passage of the X-ray focal spot ( 1'a . 10 ) outgoing fan beam ( 2 ' . 12 ) through the object cross section to be displayed as a computer tomogram ( 3 ), characterized in that the antiscatter aperture in the direction of the system axis ( 8th' . 11 ) in successive partial scattered radiation apertures ( 13 ' . 16 ' . 18 ' ), whereby the individual partial scattered radiation apertures ( 13 ' . 16 ' . 18 ' ) each to be assigned lamellae ( 13'a . 13'b , ... 13'i , ... etc., 16'a . 16'b , ... 16'i , ... etc. and 18'a . 18'b , ... 18'i , etc.) in each of the partial scattered radiation apertures ( 13 ' . 16 ' . 18 ' ) an equal angle with respect to the radial direction, ie with respect to the direction to the system axis ( 8th' . 11 ), but this angle (zero, 17 . 17 ' ) at each partial scattered radiation aperture ( 13 ' . 16 ' . 18 ' ) is another, so that they are the ones with the ray fan ( 2 ' . 11 ) given primary radiation for geometric reasons only in each case a part of the fan beam ( 2 ' . 12 ) can favor this primary radiation in different parts with the aim that the primary radiation attenuation over the whole on the ring detector ( 4 ' . 9 ) incident fan beams ( 2 ' . 12 ) is as equal as possible. Scattering beam for an X-ray computer tomograph according to claim 1, wherein instead of the consecutive slats ( 13'a . 13'b , ... 13'i , ... etc., 16'a . 16'b , ... 16'i , ... etc. and 18'a . 18'b , ... 18'i , ... etc.) of the partial scattered radiation apertures ( 13 ' . 16 ' . 18 ' ) individual slats ( 20 ), each individual lamella ( 20 ) is a continuously deformed sheet having at one end a certain angle of attack to the radial direction, ie in the direction of the system axis ( 8th' . 11 ) which, as it progresses to the other end of the lamella ( 20 ) gradually decreases, goes through zero, continues to change in the same direction and at the other end of the blade ( 20 ) assumes the opposite value.