DE2152647C3 - Scintillation camera for recording the distribution of radioisotopes in an object - Google Patents

Description

3. Scintillation camera according to claim 1, characterized in that the radiation mask (20) between the collimator (30) and radiation detector (40) an- is ordered.

4. Scintillation camera according to one of claims 1 to 3, characterized in that the image recording selection device has a matrix of AND gates (Al 1 to A44) , at the inputs of which on the one hand X pulse height selector [SXi) to SX4), on the other hand V-pulse height selector (5Vl to SY4) are connected, which in turn are connected to the outputs of the X or V signal voltages of the radiation detector (50) and to the output of the scanning drive (90 '), and one with its inputs the outputs of the AND gates (AU to Λ44) connected OR gate ter (oil) and an AND gate (Λ50), the two inputs of which are connected to the output of the OR gate (oil) and the Z output of the radiation detector, and whose output is connected to the picture tube display device, the Change of the transmission ranges of the X and y pulse height selector by the scanning drive (90 ') is controlled in synchronism with the movement of the radiation mask (20).

The invention relates to a scintillation camera for recording the distribution of radioisotopes in one Object, with a stripe detector of a given spatial resolution, which gives the coordinates the interactions of radiation quanta with a scintillator corresponding output signals, with a movable radiation mask from the Shape of a perforated plate with a multiplicity of holes arranged at predetermined intervals Large size collimating device between the object and the detector, a picture tube display device for displaying an image the recorded activity distribution, with a photographic recording device, with a variable image recording selection means arranged between the radiation detector and the recording means, which record the output signals by means of the photographic recording means only within one A large number of limited areas in the vicinity of locations which correspond to the coordinates of the point of intersection of the central axes of the holes in the radiation mask correspond with the scintillator, as well as with a scanning drive connected to the radiation mask and the image recording selector, which the Radiation mask issued a scanning movement and the image recording selection device synchronized with it controls.

Scintillation cameras for the detection, recording and storage of ionizing radiation are used in the Medicine used to record the distribution of radioisotopes in organs and tissues. Here, the radioisotopes should be as precisely as possible within a suitable short examination period can be sampled. The recognizability of details in the the Distribution of the radioisotope-showing images is determined by the resolving power of the collimation device, through which only the ionizing Radiation passes through, affecting a limited part of the radiation detector within a given Solid angle impinges, as well as by the resolution of the radiation detector and the recording device. Such a scintillation camera is z. B. in U.S. Patent 3,011,057. In addition, from the scintillation camera for the measurement, For literature on recording and storing ionizing radiation, see the publication by H. O. Anger, »Radioisotope Cameras, Instrumentation in Nuclear Medicine ”, Vol. I, Chapter 19, Academic Press, New York 1967, edited by G. J. Hine.

In conventional scintillation cameras, ionizing radiation of a given energy is recorded the resolving power of the collimator via the sensitivity and the resolving power of the

Radiation detector, taking into account a uniform sensitivity over the detector surface This optimization of the resolution of the camera arrangement is therefore fundamental limited by the resolution of the radiation detector.

From "Proceedings of the IEEE", Ba 58, Febr. 1970, Kr. 2, pp. 226 and 227, it is basically known that the resolution of a camera with a multi-hole KoIIi'nator can be improved by moving the collimator during a recording; about the required dimensioning of the collimator and a connection to an image recording selector is this Nothing to be found in the publication.

: From the DT-OS 20 11 164 is a scintillation camera of the type mentioned above is known, in which a radiation collimator in front of the scintillator and an optical one Collimator are arranged between a cathode ray tube and the recording film, wherein rotate these two collimators synchronously to obtain an ao tomographic image. Both collimators however, do not result in an improved two-dimensional resolution in the representation plane parallel to the, Szin tillator. but only a depth resolution along an axis perpendicular to the scintillator.

Other scintillation cameras in which collimators are only used to improve the tomography, can be found in German Offenlegungsschrift 20 11 104 and 19 56 377.

It is therefore the object of the invention to eliminate those caused by the detector and collimator design itself Limits of the spatial resolution of the radiation detector in that parallel to the scintillator Bypass level and thus further improve the resolution of a scintillation camera.

This object is achieved according to the invention in a scintillation camera of the type mentioned at the beginning solved that between the object and the radiation detector in addition to the radiation mask a collimator it is provided that the sum of the transverse dimensions of the opening of each hole of the radiation mask and of each limited area of the photographic Recording device is smaller than the half width of the radiation detector and that the distance between adjacent holes of the radiation mask and between adjacent ones of the image recording selector certain limited areas is greater than this half width.

According to advantageous refinements of the invention, the radiation mask is between the collimator and the radiation detector or arranged between the collimator and the object.

In a further advantageous embodiment of the invention, the image recording selection device has a matrix of AND gates, to whose inputs, on the one hand, X pulse height selectors and, on the other hand, y pulse height selectors, which in turn are connected to the outputs of the X and K respectively Signal voltages of the radiation detector and the output of the scanning drive are connected, furthermore an OR gate connected with its inputs to the outputs of the AND gates and an AND gate whose two inputs are connected to the output of the OR gate and the Z output of the radiation detector, and the output of which is connected to the picture tube display device, the change in the transmission ranges of the X and Y pulse height selectors being controlled by the scanning drive in synchronism with the movement of the radiation mask.

In the case of the camera formed according to the invention the recording of a determinable part of the detected collimated ionizing radiation (or Radiation quanta) that has passed through the radiation mask in the embodiment of the invention in which an optical BiW recording selector is used as a signal filter, the part of the radiation to be recorded is passed through the In the embodiment in which an electronic Image recording selector is used as the signal filter, becomes the one to be recorded Part of the radiation determined by adjusting electronic components. The geometry of the optical picture recorder selector or the setting of the electronic components are essentially determined so that in one case the radiation-absorbing Parts of the optical image recording selection device or, in the other case, a corresponding one electrical circuit the recording of such radiation quanta prevents such Assume coordinate position in the output signal that they would not be signaled at this point, when the resolution of the detector is closer to the theoretical maximum.

The radiation mask points depending on the material from which it is made and the energy of the to be measured ionizing radiation has some expansion in the direction of movement of the collimated radiation in Direction of the radiation detector. This allows the radiation mask to collimate itself too measuring ionizing radiation, and "thus form an integral part of a collimator system. As already mentioned, the radiation mask can be used together with the most commonly used multi-channel collimator between collimator and radiation detector or between collimator and examination object be arranged. In the case of measurement using a single-hole collimator, the collimator effect is the Radiation mask is of minor importance if a suitable material is used.

The invention is explained in more detail below with reference to the drawings shown embodiments. It shows

F i g. 1 shows the principle of operation of a camera system for recording ionization rendered radiation particles,

F i g. 2 is a distribution function of the number of times measured in a narrow beam perpendicular to the detector ionizing particles,

3a to 3c schematic representations a! Radiation detector, a registration and a recording device,

F i g. 4 is a schematic diagram showing the influence the distribution function on the probability of recording an incorrect signal,

F i g. 5 is a schematic block diagram of an embodiment according to the invention,

F i g. 6 partially in the form of a block diagram eir a schematic circuit diagram of a further embodiment form according to the invention, and

F i g. 7a and 7b representations to explain the mode of operation of the invention.

In Fig. 1 a camera system for recording ionizing radiation is shown schematically. Whom

a beam 1 of ionizing radiation falls on the radiation detector 2 within a predetermined, very small solid angle on a small circular spot O , the surface of which is known, a part of the radiation quanta that are detected is measured in a zone that extends from the known area of the Radiation detector deviates. The dimensions of the radiation detector are determined by the external dimensions and the structure of the detector system. A criterion for the distribution of radiation quanta that impinge on the detector in the zone around the spot O and are measured and recorded is the resolution value, which is defined as the half- width and is abbreviated as FWHM, as in FIG. 2, where M is the maximum and Mh is half the maximum of the number of radiation quanta detected around the spot O. In a camera system for detecting and recording ionizing radiation quanta, the half- width FWHM is limited by the dimensions of a spatially limited detector of a certain embodiment and by the arrangement and effect of the electronics of the detector.

In a camera system, as shown schematically in FIG. 3a, a point P in the recording device b downstream of a detector a corresponds to a point ρ in the storage device α optical absorption filter, which is arranged between the recording system b and the storage system c , prevents the storage of the signals corresponding to the ionizing quanta.

It is now assumed that, as shown in FIG. 3b, a narrow bundle 1 of ionizing quanta hits the detector a. The bundle has a cross-section that is much smaller than the entire diameter D of the radiation mask Λ, which is arranged in front of the detector a -Axis moves, the ionizing radiation quanta are recorded when the hole Λ1 with the diameter D crosses the bundle 1 in which the ionizing quanta hit the detector. The recorded quanta are stored with a distribution F1 which has a certain resolution value FWHMX at a point around the beam 1 along which the ionizing quanta impinge on the detector a.

As in Fig. 3c, in one embodiment according to the invention, an optical selection device ti is used in conjunction with the radiation mask Λ in such a way that an optical recording signal generated by the measured ionizing radiation quanta passed through the non-absorbing passages A1 in the radiation mask / 1 hm are, pass through a non-absorbent part Λ2 in the optical selection device ti and can also be stored in the area e of the storage device c. Furthermore, the optical selection device ti is arranged so that it moves synchronously with the radiation mask Λ in such a way that both devices interact and allow the recording and storage of all such ionizing quanta that are to be measured, recorded and stored

Since the optical selector ti and the beam mask Λ are arranged to move synchronously in the X-axis direction, as in FIG F i g. 3c, the storage of optical recording signals is started through the opening hl in the optical selection device when the edge ArI of the non-absorbing part of the radiation mask Λ passes the beam 1 of the ionizing radiation. The recording and storage are ended when the opposite edge k2 passes the bundle 1. The storage takes place in an area which has the extension of the diameter D of the passage in the radiation mask plus the diameter rf of the opening in the optical selection device. The stored ionizing quanta have a distribution Fl about the axis of the bundle 1, along which they impinge on the detector a, and the resolution value FWHM1 can be kept smaller than the resolution value FWHM1 by a suitable choice of the size of the holes in the two masks ti and ti (Fig. 3d), which results without the use of optical masks.

As in Fig. 4, the distance between two adjacent holes in the radiation mask Λ, designated there by s, should be large enough so that the probability is low that a radiation quantum pl measured through the opening B generates a registration signal which, because of its coordinate position on the recording medium, the property of a radiation quantum has pi which is measured by another hole a is the distance s between two neighboring apertures in the beam mask for a certain probability of the recording and storage of an erroneous signal by a wrong hole in the optical selection means on the basis of known distribution function of the detector and the sizes of the holes in both masks are determined

F i g. 4 shows the radiation mask fl, the detector a, the recording system b, the optical selection device ti and the storage device c. Both distribution functions Fi and FA shown have the same half-width FWHM, but there are possible interferences from an adjacent hole at a distance s between the holes as shown in FIG. 4 shows, when measuring with a specific detector with a distribution function F \, is significantly smaller than the disturbances that occur when measuring with another detector whose distribution function is Fi. If the distribution function of the detector is FH , the distance 5 between the holes can therefore be reduced, so that the same probability of recording false signals occurs as in measurements with a detector of the distribution function Fi.

The absolute size of the resolution distance in a system for the detection, recording and storage of ionizing radiation according to the invention is determined by the distribution and size of the not absorbent zones, which do not necessarily have to be round, in the mask for absorption the ionizing radiation and the optically measured signals together with the choice of the distribution function determines the resolving power of the Describes ionizing radiation detector

In Fig. 5 is a schematic block diagram of an embodiment of a scintillation camera according to FIG Invention shown gamma rays (or other ionizing radiation) of an object 10 that contains a distribution of radioisotopes pass through a Radiation mask 20 and a collimator 30 and with a radiation-sensitive transmitter 41 in the

Radiation detector 40 in interaction. The radiation mask 20 can be made of radio-opaque material, such as. B. lead, be made of such a thickness that essentially all gamma rays of the object 10 are absorbed, with the exception of the rays that pass through the openings in the radiation mask (such openings are designated in Figure 7a with 211, 221, etc.; in Fig. 4 with A and B; in Fig. 3c with Λ1). The collimator 30 is a multi-channel collimator, which is also made of a radio-opaque material, such as. B. lead, may exist. The radiation mask 20 can be arranged between the collimator 30 and the transmitter 41. When a pinhole collimator is mounted on the radiation detector 40, the radiation mask 20 must be arranged between this collimator and the transmitter 41.

The radiation detector 40 can be a detector of the type known from US Pat. No. 3,011,057. The transmitter 41 consists of a thin disk-shaped crystal made of tallium-activated sodium iodide, that scintillates when a gamma ray from object 10 interacts with it. A group of photomultiplier tubes in radiation detector 40 receives light from scintillation in the sodium iodide crystal and, together with detector electronics 50, generates two electrical signals that represent the coordinates of the Indicate scintillation in the crystal. In the detector electronics 50 there is also a pulse height selection performed, and the scintillations that meet the pulse height selection criteria satisfy, generate a trigger signal. The electrical coordinate signals and that Trigger signals are fed to a cathode ray tube 60, which a point of light on its screen 61 at a location corresponding to the coordinates of the scintillation in the crystal.

An image recording optical selector 70 is between the screen 61 and one in a camera 80 contained film 81 is arranged, the camera serving as a recording device. A synchronous one Scanning drive 90 generates a scanning movement between the beam mask 20 and the object 10 and reproduces this scanning movement in the optical image recording selector 70.

The F i g. 7a and 7b show examples of an arrangement of openings (e.g. 211, 221, 231 etc.) in one Radiation mask 20 which, together with the collimator 30, forms a mask system which has a plurality of mutually spaced passages to the transmitter 41 for gamma rays (radiation quanta) which are emitted by the object 10. In a practical embodiment according to According to the invention, an opening scheme may have more than the 16 openings shown in a 4x4 pattern be used. The invention is of course not limited to a radiation mask with square openings in a square arrangement. F i g. Figure 7b shows one form of scanning movement for a ray mask 20 and correspondingly for an optical imaging selector 70, the like Has geometric dimensions. The openings 711, 721, 712 and 722 in the optical image recording selector 70 are in dotted lines within the corresponding openings 211, 221, 212,222 of the radiation mask 20 shown to the similar Optical Imaging Selector Geometry 70 to illustrate. In an actual embodiment, scale factors were included, when the transmitter 41 is larger than the screen 61 of the oscilloscope.

It can be seen that instead of scanning the beam mask 20 and the optical imaging select means independently of the ray detector 40 and the oscilloscope 60, the ray mask and the image recording selector can also be mechanically attached to the radiation detector 40 and the oscilloscope 60 and that then either the radiation detector and the oscilloscope together with the radiation mask and the image recorder selector can be scanned with respect to object 10 and film 81, or object 10 and film 81 can be scanned with respect to on the radiation detector 40 and the oscilloscope 60 are scanned. Various other combinations of scanning can also be used.

In Fig. Figure 6 is an electrical analog to the optical imaging select device of Figure 6. 5 shown. Each electrical output for the X and Y coordinates from the detector electronics 50 is fed to pulse height selectors. The X pulse height selector 5X1 to 5X4 and the Y pulse height selector 5Vl to SY4 have outputs that are connected to the input terminals of a matrix of AND gates All, / 421, / 431, etc. The X and V pulse height selectors are set so that each pulse height selector is set, in view of the range of coordinate output pulse sizes, to respond to an output signal when the X or Y signals are within a certain bandwidth. The bandwidth is determined by the width of the pulse height selector windows. A set of X, Y coordinate signals , which trigger SYi and 5X1 at the same time, generate an output signal from the AND gate All. Each individual output of the AND gate in the matrix is connected to an OR gate OI, so that when an output signal occurs at an AND gate, the OR gate OX also emits an output signal. When an output signal of the OR gate O1 coincides with a light keying pulse Z from the detector electronics 50, an AND gate / 450 is triggered in order to trigger a light keying of the oscilloscope 60. Therefore, if a set of X, Y signals simultaneously triggers 5X1 and 5Yl and a light pulse Z is generated, the oscilloscope generates a point of light at the X, Y coordinate. It can be seen that the circuit arrangement according to FIG. 6 can be set to produce the same result on a photographic image of the oscilloscope screen 61 as the optical image recording selector 70 of FIG. A synchronous scan drive 90 'outputs signals to the X and Y pulse height selectors to scan the positions of the windows of the pulse height selectors in a manner similar to the scanning of the apertures of the optical imaging selector 70.

In the embodiment of the invention according to FIG. f is the output of the radiation detector as light point visible, which is shown spatially on the screen 61 of the oscillograph 60, and the optically « Image recording selector 70 is a signal selector to which the output de! Radiation detector is fed and the visible storage of part of the radiation quanta, di ( interact with the transducer 41, producing the film 81 on limited areas in places) which the coordinates of the intersections of the central egg

509640/180

axes of the radiation mask 20 and the collator 30 formed passages with the transformer 41 it talk.

In the embodiment of the invention according to FIG. 6, the output of the radiation detector shows electrical, y-coordinate signals and the electrical circuit arrangement consisting of the X and K pulse height selectors, the matrix of AND gates, the OR gate oil, the AND gate A50 and the oscilloscope 60 is an electrical image recording selector analogous to the optical image recording selector.

In addition 5 sheets of drawings

Claims (2)

Patent claims: 1. Scintillation camera for recording the distribution of radioisotopes in an object, with S a radiation detector of predetermined spatial resolution, which supplies the coordinates of the interactions of radiation quanta with a scintillator corresponding output signals, with a movable radiation mask in the form of a perforated plate with a large number of A collimation device with holes of a certain size arranged at predetermined intervals between the object and the detector, a picture tube display device for displaying an image of the recorded activity distribution, with a photographic recording device, with a variable image recording device arranged between the radiation detector and the recording device Selection means which record the output signals by means of the photographic recording means only within a plurality of limited areas in the vicinity of the site n allowed, which correspond to the coordinates of the intersection point of the central axes of the holes of the radiation mask with the scintillator, as well as with a scanning drive which is connected to the radiation mask and the image recording selection device, which gives the radiation mask a scanning movement and the Image recording selection device controls synchronously, characterized in that a collimator (30) is provided between the object (10) and the radiation detector (40) in addition to the radiation mask (20) so that the sum of the transverse opening dimensions of each hole (211 to 244) of the radiation mask (20) and each of the image recording selector (Fig. 5, 70; F i g. 6, SXi to SX4, SYi to SY4, AU to A44, Ot, Λ50) certain limited area of the photographic recording device (80, 81) is smaller than the half width (F i g. 3b) of the radiation detector (40) and that the distance between neighboring. Holes of the radiation mask (20) and between adjacent limited areas determined by the image recording selection device is greater than this half-width (FIG. 3b). 2. Scintillation camera according to claim 1, characterized in that the radiation mask (20) is arranged between the collimator (30) and the object (10)