DE693374C - Process for the production of cross-sectional images by means of X-rays - Google Patents

Description

Method for producing cross-sectional images of the body by means of X-rays As is known, fluoroscopy or photography is based on being inside of the -silluminated body, some parts more and others less the X-rays absorb. As a result, one obtains the shadow image of those inside the body absorbent parts. But it is also possible; that little "details in the The shadowy part in front of or behind them opens up, i.e. invisible will. The X-ray image is a multitude of shadow images layered one on top of the other, on which orientation is often very difficult, even for expert observers. Therefore it is an old endeavor to produce more exact X-ray images in such a way that that you only have the image of the desired cross-section of the body to be examined preserved without affecting the purity of the image. .by the shadows in front of or behind the same parts located would be affected.

Various methods have been proposed up to now, but all are flawed. In one of these known methods, a X-ray tube and the photosensitive plate around an axis that is in the plane of the desired cut, moved in opposite directions so that the focus of the tube, the axis of rotation and a certain point of the photosensitive screen lie in a straight line. This makes it possible to get closer to the axis standing parts appear sharper, while the more distant parts become blurred.

With this known method, only recordings of cutting planes, which are transverse to the X-ray direction, "made". If it is are elongated objects, recordings of. transverse body layers do not manufacture this way. In addition, the washed-out shadows of the parts lying in front of and behind the cutting plane to be mapped the image.

The invention aims to overcome these drawbacks. It is based on the knowledge that the totality of the body emerging Rays originating from a focus located in the plane of the cross-section and illuminate the body from an infinite number of sides, determine the cross-section.

The invention relates to a method for recording body cross-sectional images. However, these images are not suitable for direct perception. The invention therefore also relates to a method for the optical reproduction of the recordings. In which Method for the production of body sectional images by means of X-rays according to According to the invention, a device for generating a narrow X-ray beam is provided used. This is directed towards the body to be recorded in such a way that its plane coincides with the cutting plane to be mapped. It will be with the help of this band of rays in different directions, but with the same from a certain point of the Section plane, which is called the pivot point in the following, line-shaped partial images recorded. These partial images are transverse in one direction on an image carrier lying next to each other to the cutting plane, fixed. So the image carrier contains one Series of parallel lines. The movement during the recording can also be continuous so that one does not distinguish between individual lines on the image carrier, but rather the partial images flow continuously into one another and create an uninterrupted image arises.

The method for the optical reproduction of the recordings is carried out by an optical analogue of the X-rays the partial images one after the other Thrown projection screen. A lens system is used to create the image in a Direction transverse to the radiation plane greatly broadened. At the same time, the projection screen after the projection of each partial image or continuously in the case of uninterrupted images rotated relative to the bundle of rays, namely by the one through the image point of the fulcrum going beam of light. The greatly broadened partial images overlap, but through the angular twist they merge in such a way that the desired cross-sectional image arises.

The invention is explained in more detail with reference to the drawing.

Figures i through 7 relate to the theory of the invention.

8 shows, for example, an embodiment of the X-ray system according to the invention.

The parallel X-rays pass through (large foil spacing) the body to be examined i (Fig. i). A narrow bundle is made through the slit the aperture 5 let through. The position of the focus of the X-ray tube and the position the diaphragm 5 determine the plane of the cross-section to be examined. Because the individual Parts of the illuminated body (in the present case a cylinder 3 from semi-permeable. like fabric with a core 4 made of impervious fabric) from different absorptivity will be on the photosensitive plate 7 the partial image visible in the strip 8 appear, which corresponds to the different beam absorption capacities of part 3 or of the difficult-to-pass part 4 corresponds. Will this streak of light perpendicular to the plane of the cross-section by some optical method lengthened and folded into the plane of the cross-section, this would be shown in Fig. 2 visible image 9 can be obtained.

If the X-ray source together with the slit diaphragm 5 and the image carrier 7 relative to the body i about an axis of rotation ii perpendicular to the observed Section plane rotated, e.g. B. at an angle o: (Fig. 2 a), you can use a second Generate drawing file. Think the same about the plane of the cross-section extended vertically and folded down into the cutting plane. Together with the in The image shown in FIG. 2 then results in the image 99 in FIG. 2a.

In this way you can produce several partial images and the extended one and rotate the image folded down into the cutting plane so that the partial images with always remain parallel to their original position.

When the continuous twist equals i8o °, merge the intersecting rays of light, and the image of the cross-section is created. Part 4, from whichever side it is lit, lets the X-rays only a little through. The middle part of the photosensitive image 9 thus only receives very low levels of radiation and stays bright.

3 and 4 show the creation of the image of various idealized Cross sections (e.g. skull and articular bone). Cross-sections visible, determined the image after one revolution of iSo ° the cross-section completely.

There are in Fig. 3 with 12 the cross section to be recorded, with 13 a extended and. Folded down partial image and with 14 (read through the overlay of all partial images 13 indicated result.

In Fig. 4, 15 is the cross section to be recorded, 16 is an overlay two partial images and 17 the result of the superposition of all partial images.

Because it is only related to the relative movement of the X-ray source depends on the body, the same result is obtained, If not the X-ray source and aperture or the light-sensitive plate, but the body to be x-rayed rotates. In such cases, it goes without saying the .extended and folded image 9 coincides with the angular rotation of the Body can be rotated.

FIG. 5 illustrates a method of fixing the individual partial images of the body layer to be displayed, recorded from different sides. The body 1 9, so together with the same also 'the cross-section 18, rotates around a supplied between the X-ray source and the diaphragm 21 and which appears on your cross section i8 imDrehpunkt 2o perpendicular axis 23rd

The one behind rotates at exactly the same angular speed the slit diaphragm 21 located roller 22, on the shell of a photosensitive Film is attached. As a result of the continuous rotation, everyone gets that Side illuminated partial image of the cross section on, the image carrier. So it is that whole image of the cross section on the photosensitive film implicitly given. In FIG. 5, 20 ′ is the image point of the pivot point 20.

The production of the real cross-sectional image can be done accordingly Fig. 6 happen. The developed film is on the mantle of the roller 222, its dimensions match with those of the roller 22, set and brought into continuous rotation. In parallel with the generating of the. Roller 22z is the gap of the aperture 21 same aperture 24. The point-shaped light source is located in the center line of the roller 25, of which the aperture 24 .through the film strips passing in front of the same is illuminated. The narrow bundle of light coming through the diaphragm forms the optical analogue of the X-ray beam exiting through the diaphragm 2i. This narrow bundle of rays is made perpendicular by means of the cylindrical lenses 26 and 27 widened to the plane laid by the gap in the diaphragm 24 and the central jet a9, so that the widened image 9 of FIG. 2 appears on your projection screen 28. The screen 28 is a photographic plate that rotates at an equal angular velocity like the roller 222 about the axis passing through the image point 2o 'of the pivot point 2o 29 turns. The effect of the rotation is geometrically the same as that illustrated in FIGS. 1, 2, 3 Identical effect; the elongated image merges again and one obtains the cross-sectional image.

It is clear that the ratio between the radius of the roller 222 and the distance from the screen must not be too great to allow for excessive magnification to avoid. That is why it is useful to # ban the image carrier as a continuous film execute, so that the point-like light source in any large 'distance from Image carrier can_be arranged.

The photosensitive film 28 can be saved if the one shown in Fig. 7 is applied. This is done by means of what is known in and of itself Mirror or lens system 35 through the lens system 33, 34 according to Embodiment according to Figure 6 perpendicular to a through the gap of the diaphragm 32 and The plane placed on the central ray 37 widened the image 36 by the central ray 37 rotated, -with the same angular velocity as the roller 31. The number of revolutions is increased so high that the stripes are in different directions in the eye of the observer and create the impression of the cross-sectional image.

The required speed of movement depends on the intensity or the hardness of the X-rays and the sensitivity of the film and your any intensifying screen used. The rotation speed around the The axis at the pivot point i i and the speed of the image carrier are related to choose with each other. Appropriately, they are necessarily coupled. Even with the The movement device of the image carrier can be used to reproduce the recordings necessarily coupled with the rotating device of the projection screen or the image be.

In the embodiment of the receiving system shown in FIG. 8 mandatory coupling is provided.

The X-ray tube 38 is on the stand 39 in the vertical direction adjustable. Simultaneously with the height adjustment of the tube move. the the Slit diaphragm 40, which determines the plane of the cross-section, and the roller 4i up and down. The body to be examined is attached to the turntable 42. The turntable is rotated by the motor 44, as well as the roller 41 by means of a positive clutch.

When recording, the engine is started with switch 45. At the shaft of the roller 41 has a helical-shaped contact attached, which after a predetermined period of time, the contactor of the X-ray apparatus 47 switches so that the X-ray tube begins to shine. After a turn around 36o ° or an integral multiple, the X-ray apparatus or the motor is automatic switched off.

In some examinations it would be desirable for the doctor to be able to see many cross-sections layered one below the other in rapid succession, e.g. B. to determine the location of a tumor. For this. In this case, the arrangement shown in FIG. 8 can be used with some modifications. In this case, a film ring in the shape of a cylinder jacket is not used to record the X-rays, but rather a continuous strip of film. The patient placed on the turntable is now turned over several times while the turntable moves steadily up or down; The straps 43 serve to hold the object in place. The X-rays describe a very slowly rising screw surface. The film tape moves in front of the diaphragm at a constant speed. , When such x-ray film placed in a viewing device of FIG. 7 and as quickly rotated the optics that one rotation thereof corresponds to the one-time rotation of the turntable, the observer sees the 0 uerschnittsbild continuously decrease or increase.

The rotation of the turntable must of course be slow. One revolution must be at least d. take up to 5 seconds.

The invention has not only applied to radiological, medical Practice, but also for the field of material investigation importance.

Claims (8)

PATENT CLAIMS: i. Process for producing body sectional images by means of X-rays, characterized in that by a narrow, in the X-ray bundle lying on the plane of the section to be imaged, in different directions and with the same focus distance from a certain point of the cutting plane (pivot point) recorded line-shaped partial images, lying next to one another in a direction transverse to the cutting plane, can be generated on an image carrier. 2. The method according to claim i, characterized in that that by continuous, preferably uniform movement, continuously into one another Transitional partial images are generated: 3. Method according to claim i or 2, characterized characterized in that the X-ray source and image carrier as a whole relative to Body rotated about an axis that is perpendicular to the cutting plane in the fulcrum and with this rotary movement a movement of the image carrier in its plane, is therefore necessarily coupled transversely to the cutting plane. q .. Method according to claim i, 2 or 3, characterized in that a continuous film tape is used as the image carrier is used. 5. The method according to any one of claims i to .q., Characterized in that that the X-ray source moves on a helical line relative to the body will. 6. A method for the optical reproduction of by means of a method according to a of the preceding claims recorded body cross-sectional images, characterized in that .that the line-shaped partial images are successively replaced by an optical analog of the narrow X-ray beam thrown onto a projection screen while using a lens device is greatly broadened in a direction transverse to the beam plane while rotating the expanded image relative to the projection screen takes place around the light beam passing through the image point (2o ') of the pivot point (2o). 7. The method according to claim 6, characterized in that the projection screen held still with respect to the viewer and the image through an optical device is rotated and the projection of the individual partial images so quickly one after the other occurs that the eye of the beholder is jumping the images or moving of the partial image does not perceive. 8. Establishment to carry out the procedure according to Claim 6 or 7, characterized in that the moving device of the image carrier necessarily coupled with the rotating device of the projection screen or the image is.