DE1295709B - Device for recording and visualizing the spatial and temporal distribution of isotopes emitting gamma rays with a gamma scintillation camera - Google Patents

Description

The invention relates to a device for receiving and pictorial representation of the spatial and temporal distribution of gamma rays emitting isotopes with one of individual, arranged in a flat grid Detectors existing gamma scintillation camera, a playback device for areal Recording of the intensity distribution recorded by the individual detectors of the camera and with a storage device switched on between the camera and playback device.

Such devices serve to record the isotope distribution in particular in biological objects.

Besides isotope diagnostics with gamma emitters for localization the distribution of activity in biological objects exists on the part of medicine Need to carry out functional diagnostic examinations with isotopes. From a physical point of view, this means that not only the spatial distribution of activity A = f (x, y, z), but also the spatiotemporal course A = J (x, y, z, t) should be. However, only small ones are available to determine the displacement of isotopes Measurement times are available, since the individual movement phases are generally within expire in fractions of a second. It is known that scanner equipment, how to use scintigraphers or autoradiographs that track the object in time Scan the sequence.

With this elementary image field decomposition, however, there is a loss of sensitivity, which makes a temporal recording of the migrating isotopes practically impossible.

A device for recording and reproducing images is also known of isotopes emitting gamma rays with a single detector Gamma scintillation camera with the detectors in a flat grid are arranged. This known device also includes a playback device for two-dimensional recording of the images recorded by the individual detectors of the camera Intensity distribution. There is a storage device between the camera and playback device switched on ("Nucleonics", Vol. 21, 1963, pp. 52 to 55). With this well-known facility however, it is not possible as is necessary to carry out an accurate diagnosis is, the temporal distribution of isotopes emitting gamma rays in fractions of seconds as a sequence of images. A high temporal resolution is required for this required, at which the respective permissible activity concentration is fully exhausted will.

The object of the invention is therefore to provide a device for recording and depicting the spatial and temporal distribution of gamma rays to create emitting isotopes by changing the isotope distribution in the Object, especially in biological bodies, even in very short periods of time, i. H. in fractions of a second. That should be the case in each case permissible activity concentration spatially and temporally appropriate resolution can be achieved.

This task is performed in a facility for recording and imaging Reproduction of the spatial and temporal distribution of emitting gamma rays Isotopes of the type mentioned at the beginning solved by that according to the invention the memory device as a multi-channel memory with one of the number of detectors in the gamma scintillation camera corresponding number of channels formed and so with the detectors of the camera is interconnected that in each memory channel one of the associated detector The electrical quantity corresponding to the recorded radiation intensity is stored, that the storage capacity of the channels of the memory is divided into individual time groups in which the intensity distributions are separated in their time sequence in groups are stored, and that an interrogator the contents of the time storage groups decreases in time sequence and supplies the playback device.

By means of the device according to the invention it is possible to control the activity distribution as a cinematographic image sequence. It goes without saying that in the If necessary, easily possible, the difference between two consecutive times Form memory contents and map the difference signal. To query the memory, there are various possibilities. For example, it is possible to use the individual memory to query one after the other. In this mode of operation, the one used for television Image decomposition corresponds to a substantial simplification for the required Transmission facility. There is only one between the memory and the playback device Channel is used, in this case all memory channels need the downstream one Electronics to be present only once. Becomes a direct pictorial isotope distribution desired, e.g. B. on the screen of a picture tube, the result is from the collimator system resulting image field decomposition written as a raster. It has proven to be very useful proved, the stored values by means of a digital-to-analog converter known per se into image signals having a number of discrete gray levels and convert these image signals then make it visible on a television screen. The picture impression that obtained in this way is very easy to interpret, since it is a lowering of the statistical Fluctuations due to reduction to a certain number of discrete amplitude levels with the effect that isodose curves are made visible on the fluorescent screen will. This makes the isotope distribution significantly easier to understand.

Since the detectors of the recording device generally have a background effect and have a different basic sensitivity, it is very desirable to to eliminate these interfering components.

This can be done by adding the background values and the values for the sensitivity of the detectors of the recording device in per se known Way can be stored together in a storage group. This achieves that the interfering components are subtracted from the memory content and only the true distribution pattern is imaged by the playback device.

Since all detectors work at the same time with the gamma camera, see above if you use 32 32 = 1024 detectors, for example, this is the opposite the known scanner technology under otherwise identical conditions more than a thousand times greater sensitivity, so that advantageously the recording time or - if desired this will - the activity concentration to less than a thousandth can be reduced.

The queryable and can be subdivided into separate memory groups The memory can, for example, be designed as a multi-channel magnetic core memory. In the memory groups formed by the method according to the invention are if also with a correspondingly reduced capacity in the channels, one after the other stored separate distribution patterns and reproduced as a sequence of images by query.

If only a few distribution patterns are to be saved, you come with a magnetic core memory whose storage capacity corresponds to the size of the memory of a multichannel pulse height analyzer, which corresponds to 32 32 = 1024, for example Has channels. If a larger sequence of distribution patterns is to be stored, then the memory is divided into a corresponding number of memory groups. Instead of of magnetic cores as storage elements can of course be known per se Also thin-film storage (transfluxors), diode storage or similar elements be used.

But if there are large series of images to be saved, another series is required Embodiment of the device according to the invention as a memory a main memory with high storage capacity and a main memory that can be divided into two storage groups provided, the two storage groups alternating in a manner known per se can be switched to the camera for recording and to the main memory for querying. The advantage of this embodiment is that a simplification and cheaper the required facility is achieved. For storing large series of images, d. H. of a few hundred images, the magnetic core memory is either unsuitable, or it would be too expensive to manufacture. When using a main memory and a working memory, the image content is for reasons the storage capacity recorded in the form of analog signals. It can It may be useful to use a magnetic layer memory as the main memory and a working memory to provide a magnetic core memory.

In order to store a large number of images, according to the invention Instead of a magnetic core memory, a special charge storage tube is also provided be. In this case, the individual channels of the camera are connected to, for example 1024 storage elements connected to the existing storage disk of the tube. That I The charge image based thereon becomes electronic, similar to that of a television tube scanned. By repeatedly scanning the charge storage tube, the distribution patterns are saved as "single images" in the main memory and can be accessed from there using the Playback device are queried.

This simplifies the device according to the invention achieves that the detectors of the scintillation camera dispense with electron multipliers each of a scintillation crystal and one provided with a photocathode Release counter tube exist. Although the known state of the art includes a facility in which a scintillator with a gas-filled one provided with a photocathode Trigger counter tube is connected.

This detector is used to register radioactive radiation (British Patent 855,974).

This counter tube gives a high response probability. at the use of such counter tube scintillation detectors in a scintillation camera in the device according to the invention, the construction cost is low, since photocell and Counter tube form a single component. Another advantage is the small ones Dimensions. This will facilitate the assembly of the detector system and the storage system facilitated, so that cable connections can be saved.

The subject of the invention is based on the following drawings, in which some exemplary embodiments are shown schematically, explained. 1 shows the recording, storage and playback device in perspective Representation, the dashed lines indicating the possibility of a main memory optionally to be switched on, illustrate, F i g. 2 shows a representation similar to FIG. 1, with details of the device parts shown or additional device parts added FIG. 3 is a perspective view of the scintillation camera, FIG. 4th a plan view of part of the camera according to FIG. 3, F i g. 5 shows a longitudinal section by the camera, with collimator system and detector system, as well as the one drawn Radiation characteristics, FIG. 6 a scintillation counter with scintillation crystal.

The scintillation camera 10 (see FIG. 1 and 2) consists of one Collimator part 11 and a detector part 12. The gamma quanta from the to be examined Area 13 form a radiation field, which through the collimator part in individual Radiation bundle is broken down, which can then be measured.

The collimator part can be a pinhole or a cylindrical bore 14 (see. Fig. 3 and 4), through which the image field is divided into picture elements will. It is also possible to use special focusing collimators or a double collimator system to use. In order to obtain a collimator part 11 that is as thin as possible, uses a high atomic number, high density material such as tungsten, the Tungsten block 16 is designed so that it provides a shield for relatively hard Represents radiation. The collimator length can be 10 cm, the collimator wall thickness z. B. 1.3 mm, depending on the dimensions of the detector.

The detector part 12 is connected downstream of the collimator part. Everyone The detector initially has a sodium iodide crystal 17 activated with thallium on (Fig. 5). The crystal absorbs the energy of the gamma quantum and sends you Flash of light off. The quantitative values for a good crystal are one Photon per 50 eV of absorbed energy.

The scintillation crystal is usually an electron multiplier downstream. One can have a miniature multiplier that is a commercially available device with dimensions of 6.5 mm diameter, 13 mm length is, use. But only there a pure pulse counting is required, the use of a special, in Fig. 6 shown scintillation counter tube proposed that in principle represents a combination of a photocell and a trigger counter tube. Rule here for example the following Ratios: If gamma quanta 18 in the Incident crystal 17, since the walls of the crystal are designed as a reflector 19 are, about 5000 light quanta hit the photocathode20 at the same time and here about 600 photoelectrons, of which only one photo is electron 21 plus its path is shown in an electron optics 2, generate.

Since each photoelectron is accelerated, it is almost complete Reliability in the downstream trigger counter tube 23 can be expected.

In the counter tube is in the usual way between the cathode 24 and the Anode 25 applied a voltage.

The resulting counter tube pulses 26 in the output of the detector preferably directly or optionally also via a pulse shaper, the memory 27 (see. F i g. 1 and 2) supplied, the detector and the memory part a can form a structural unit. Depending on the individual case, however, a multi-channel line can also be used 28 (Fig. 1) can be used.

For each detector 12 a of the detector part 12 there is in each case a single one Kana128a (memory channel) available. The memory 27 has (see. Fig. 2) a separate input part 27 a and a separate output part 27 b, also a number of storage groups 27c, 27d, etc. as well as a storage group 29 for the background value and a further memory group 30 for the basic sensitivity value. About a Ring counter, the content of the groups is queried channel by channel. About a single one Channel 31 is the playback z. B. on the screen of a picture tube, the corresponding intensities measured in the individual spatial elements of the object the geometric arrangement of the detectors are put together like a mosaic, so that the distribution pattern as an isotope distribution image on the screen of the as Playback device serving television tube 32 is made visible.

The contents of the memory 27 can also be transferred to one for all one after the other Channels common digital-to-analog converter 33 are fed. It becomes a downstream Contrast enhancers34 of adjustable amplitude characteristics are used so that the interesting contrast areas are stretched, others are compressed again can. The result of the collimator part is displayed on the screen itself Field decomposition written as a raster. When using the intensity control are the discrete amplitude steps generated in the digital-to-analog converter 33 written on the screen as grayscale, so that isodose curves are quite clear the activity distribution. But what matters is the information to evaluate numerically or to record for documentation purposes, the signal a digital printer 35 or a suitable writer 36, such as. B. a typewriter, are fed. The connection of a punched tape or magnetic tape device is also possible possible. In addition to digital writing, you can also use the digital-to-analog signal converter also the analog representation of the memory contents by a coordinate recorder carry out.

Instead of the magnetic core store 27, a charge storage tube can also be used (Scanning tube) 37 use, but then without digital storage of the information. Part 38 illustrates a magnetic layer or a magnetic drum storage device, which can serve as an analog memory.

Claims (7)

Claims: 1. Device for recording and visual reproduction the spatial and temporal distribution of isotopes emitting gamma rays with one consisting of individual detectors arranged in a flat grid Gamma scintillation camera, a playback device for flat recording the intensity distribution recorded by the individual detectors of the camera and with a storage device connected between the camera and playback device, d a d u r c h g e indicates that the memory device (27) is a multi-channel memory with a number of corresponding to the number of detectors of the gamma camera (10) Channels formed and interconnected with the detectors (12 a, 17) of the camera (10) is that in each memory channel one of the recorded by the associated detector Radiation intensity corresponding electrical quantity is stored that the storage capacity the channels of the memory (27) is divided into individual time groups (27c, 27d), in which the intensity distributions are separated in their chronological order in groups are stored, and that an interrogator the contents of the time storage groups (27c, 27d) decreases in time sequence and supplies the playback device (32). 2. Device according to claim 1, characterized in that the memory is designed as a thin-film memory or diode memory. 3. Device according to claim 1 or 2, characterized in that as a memory, a main memory (38) with high storage capacity and one in two Memory groups of subdivided main memories are provided, the two memory groups in a manner known per se alternately -zur; -recording to the camera (10) and to Query can be switched to the main memory. 4. Device according to claim 3, characterized in that the main memory a magnetic layer memory and a magnetic core memory is provided as a working memory are. 5. Device according to claims 3 and 4, characterized in that that a charge storage tube (37) is provided as a working memory. 6. Device according to one of claims 1 to 5, characterized in that that between memory (27) and playback device (32) for converting the stored Signals are switched to a digital-to-analog converter (33) in discrete amplitude levels is. 7. Device according to one of claims 1 to 6, characterized in that that the detectors (12 a) of the scintillation camera (10) each consist of a scintillation crystal (17) and a release counter tube (23) provided with a photocathode (20).