DE1915883B2 - GAMMA RADIATION SCINTILLATION CAMERA - Google Patents

Description

3 4

a constructive measure to reduce the scintillator diameter of about 27.9 cm and the diameter!

body in which the scintillator body, the light guide of the part of the coUimator penetrated by channels

and the electron multipliers and the shell have a diameter of about 24 cm.

The advantages of this arrangement are shown in FIG. 4 ge

and to ensure that all rays show, including those where a scintillator body was used,

genes that enter through the outermost controller channels, as is the case with the test according to F i ζ. 3 was used,

fall, in any case still enough scintUlator- In the study of F i g. 4 became the

have material in front of you with which you can put in an interchangeable knife of the perforated surface of the KoUimator

can take effect. The overlap of the scintile is reduced to the D ± equal to 24 cm, in which the outer

lators on the outer edge above the collimator openings were removed from the channels 10. How out

The interspersed area of the CoUimator also has the comparison of FIG. 3 and 4 can be seen, eliminated

nothing to do with the marginal problems described. this change in the controller eliminates the undesirable

There is also no information given about the ten peaks in the image intensity curve, which by

how far the overlap area of the not under- superimposition of light points were created,

broken collimator with the crystal, 15 This increases the usable

so that the problem outlined above is not solved knife from 21.6 cm to 24 cm and the exploitable

became. Area by 25 «/ 0.

From »International Journal of Applied Radiation The invention is used in the following description

and Isotopes ”, Volume 17, 1966, No. 4. Pages 225 explained in more detail with reference to the drawing. It shows

to 230, as well as from "Journal of Nuclear Medicine", 20 Fig. 1 a partial section of an inventive

Volume 5, 1964, pages 515 to 531, is a scintilla-trained scintillation camera with numerous

tion camera with a crystal of 29.25 cm through parallel collimator openings,

knife and a parallel hole collimator disclosed, F i g. 2 is a partial sectional view of a known one

whose channels extend over an area of 28 cm. Scintillation camera with numerous parallel collisions

Extend diameter. The combination of a 25 limator openings,

Crystal with the diameter mentioned and a F i g. 3 is a diagram showing the size and location of the

KoUimators, which represents in a surface area with a non-uniformity of the figure, which at

only slightly smaller diameter of channels is generated by the known scintillation camera, and

is set. corresponds approximately to that in connection with FIG. 4 is a diagram showing the size and location

F i g. 3 and leads to the 30 of the irregularities of the figure, which

problems described. by means of a scintillator designed according to the invention

It is the object of the invention to generate with a gammalation camera.

Radiation scintillation camera of the aforementioned F i g. 2 shows a scintillation camera 30 more commonly

th kind a definitive and effective measure to kind, equipped with a collimator 32 with; cahl-

hit, by means of which the parallel openings rich in the edge of the scintillator and with a scintillator

Tillators caused distortion in the recorded body 34. The collimator 30 is ν on einrr

menen planar scintillation frequency distribution large number of parallel feedthroughs, such as

development of a gamma ray field can be avoided. z. B. the holes 35, 36 and 37, pierced.

This task is performed in a scintillation camera. B. holes 35 and 37, solved according to the invention in that the channels 40 lie below the edge parts 38 and 40 of the frame penetrated area of the collimator is only latorkörpers 34. The holes 35 and 37 are the extends so far that the scintillator body enlarge against the effective scintillator area. Because of the Radiation in an "edge cluster" for the respective dimensions reduces their presence each Scintillator body to be determined edge area but the usable area of the scintillator body is shielded to the extent that interactions of the 45 34, as explained above.

Gamma rays with the scintiUator body are available there. 1 shows the same scintillation camera 30, now

be avoided, where the reflections of scintillas equipped with a collimator 32 ', the invention

tion light at the edge of the scintillator body is designed according to. It should be pointed out

substantial errors in the conversion of the scintillates that are located at positions 35 'and 37' below

tillations in corresponding electrical output 50 of the edge parts 38 and 40 of the scintillator body 34

signals would lead. there are no holes. The collimator 32 'prevents

This has the advantage that scintillations in the edge and radiation in the edge areas of the scintillator

area of the scintillator where the scintillator hits and thus prevents a reduction in the

Torrandfläche reflections occur and thus the effective area of the scintillator body 34 in the

Scintillation frequency distribution to be imaged without 55 image overlay.

would desirably distort are prevented. The optimal diameter of the openwork

According to the invention, the collimator surface interspersed with channels must be used for every given scene.

Area of the KoUimator just made so large that tillalor can be determined experimentally. The

which should be shielded when the gamma radiation interacts with the outer area of the scintillator body

the light quanta produced by the scintillation body 60 should be just wide enough to have peaks, as they are in the

just in the outer peripheral surface of the scintillator curve of FIG. 3 occur to suppress. Of the

body no longer occur where at the edge of the shielded area should not be so wide that

The reflected scintillation light to larger by further shielding the effective size of the crystal

Errors in the determination of the coordinate signals of the image itself are reduced,

would lead. 65 The collimators 32 in FIG. 2 and 32 'in FIG. 1

In an advantageous embodiment of the invention, for the sake of clarity, they have been shown in a simplified manner,

where the scintillator body is round. The collimators 32 and 32 'contain only a few

Is disc, the scintillator body has a relatively large diameter hole. A practical

Lisch designed collimator with parallel feedthroughs will have about 1000 holes that are about 0.6 cm in diameter.

The present invention can improve the effective image size of almost any scintillation camera to be used. In particular, it can also be used with other forms of collimator will. The sciintillator body can also be of a different type; B. from cadmium tungstate, Calcium tungstate, thallium-activated cesium iodide, thallium-activated sodium iodide, Anthracene, naphthalene, transtilbene, terphenyl, solutions of terphenyl in a polymer or from consist of some similar scintillator substance. The scintillator does not have to be round, it can be Be designed as desired, if only the shield is adapted to the shape of the edge. Instead of the one described Photo multipliers for proof and for amplification of the resulting more visible The scintillation camera can also use other detectors for image scanning and amplification have such. B. a vidicon, an image intensifier ίο tube or a spark chamber. It can also be used as a scintillation camera without an amplifier arrangement the visible image can be used for the ζ. Β a photographic film to which the scintillator is attached.

1 sheet of drawings

Claims (2)

1 2 an intermediate circuit utilizes signals from these claims: photocells to determine the location of each scintillation and points of light on the screen of a 1. To generate a gamma radiation scintillation camera with an oscilloscope at the appropriate points, a scintillator body with a multi-channel 5 The light points are recorded on a photographic FUm collimator, whose channels interspersed with it. The resulting photograph is a rich one that extends outward only to the extent that the image of the distribution, and the density of the light in the edge area of the scintillator body against points is a measure of the radiation intensity, remains shielded from the gamma radiation, and with the respective points of this distribution,
The quality of the interaction of a scintillation camera with the gamma radiation in the generated image is quite good towards the center, but the scintillations produced by the scintillator body quickly deteriorate towards the edges. The corresponding electrical, the position coordinate F i g. 3 graphically shows the type and size of these edges of the respective interaction reproducing distortions on the basis of experimental measurements. Output signals, characterized in that the graph along the x-axis shows that the points interspersed with channels (3 <T ) are only plotted on an assumed diameter of a region of the collimator (32 ") to the extent that they are mapped , which by a scintillation stretching that the scintillator body (40) was generated against the camera, in which a scintillator body radiation in a for the respective dimensions of about 28 cm in diameter and a collimator gene of the scintillator body to be determined 20 with a perforated surface with a Edge area is shielded so far that alternating diameter D ₂ equal to 27 cm was used, interactions of the gamma rays with the scintil along the y-axis is the density of the light point detector bodies are avoided where those reproduced that lie on this diameter of scintillation light at the edge when the scintillation camera causes a uniformity of the scintillator body to be substantial learn to be exposed to 25 radiation beams. In the ideal case, when converting the scintillations into ent, the curve of FIG. 3 electrical output signals that do not have peaks and valleys carry zen. It can be seen, however, that the image of would. deviates from the ideal line and strongly towards the edges 2. Gamma ray scintillation camera after becoming nonuniform. Since the distorted, pointed to claim 1, the scintillator body of which is a round area provided at the edges of the image disc, characterized in that it cannot be used for measuring purposes, the diameter of the scintillator body (40) is approximately the same as the diameter of the practically usable 27 , 9 cm and that the diameter of the part of the collimator through which the image passes is only about D ₁ equal to 21.6 cm, instead of D ₂ equal to channels (36 ') 27 cm. (32 ') is approximately 24 cm. 35 The distortions at the edges of the image arise due to the edges of the scintillator body. If one of a radioactive substance emitted radiation quantum enters the scintillator body at a point that is close to the edge The invention relates to a gamma radiation 40 some of the emitted photons from the scintillation camera with a scintillator body, with giving scintillation on the edges of the scintillator one Multi-channel collimator whose body reflects from channels. The reflected photons are more penetrated Area is only proven to the extent that it is earthed to the outside by photomultiplier that is used for stretches so that an edge area of the scintillator body lies in the middle of the photomultiplier arrangement, remains shielded from gamma radiation, and with 45 and cause the scintillation reproducing a device for converting the shifted by Wech light spot to the center of the oszülografen interaction with the gamma radiation in the scintillator. The strength of this shift increases in that scintillations arising in correspondence with how the scintillation of the edge of the corresponding electrical, which approximates the position coordinates of the scintillator body. The two tips in the The output curve from FIG. 1 showing the respective interaction. 3 are signaled by overlay. pushed light points over the correctly classified Scintillation cameras are generated for examination, and the indentations in the area and for mapping radiation distributions, e.g. B. Conclusion to these peaks arise due to the the distribution of its radioactive isotope "in vivo", vacancies used by the shifted light points. The camera is to be filled with the collimator 55 th. This appearance that facing the radiation source. The collimator, due to optical discontinuities at the edges of the usually a solid block from which the radiation scintillator body emerges, is called "edge accumulation" radioactive substances shielding material called which is pierced by a multitude of holes, A gamma-ray scintillation camera of the causes the scintillator 60 to be of the type mentioned at the beginning from "nuclear technology" only, meet and cause scintillations that in the 9th year, 1967, issue 12, pages 542 to 545, ins-center line of the collimator openings. Each separate page 542, FIG. 2, is known. With this bezel ne scintillation in the scintillator body, the z. B. known device is a narrow edge a crystal of a thallium activated area of a non-channeled sodium iodide consists, and covered with a flat 65 NEN edge portion of the multi-channel collimator. Side on the collimator and with the other on this edge part does not serve to avoid the common one photoelectric converter is applied, is called edge effects, which lead to a distortion of the several photocells of the converter detected, and lead image, but it is only