SU408638A1 - HAMMATOPOGRAPH FOR REGISTRATION OF DISTRIBUTION OF LOW ENERGY RADIOACTIVE ISOTOPES - Google Patents

Description

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The invention relates to gammatographs and can be used in medical, prophylactic and research institutions for the diagnosis and study of human internal organs using radioisotopes.

Known gammatographs are used to visualize the distribution in the human body of radioisotopes introduced for diagnostic purposes. These devices make it possible to determine the shape, size, and location of the internal organs, and to detect anomalous accumulation of radioisotopes in areas corresponding to pathological foci. Using the Gammography method, a diagnostic study of the liver, kidney, thyroid, lung, brain, spleen, and other organs is performed.

The well-known gammatograph relies on the use of medium-energy radioisotopes and contains a detector system consisting of ten non-decoupled scintillation sensors with focusing collimators, a ten-channel radiometric unit, a system for recording information on a magnetic mite and a device for acquiring an image on the screen of a cathode-ray tube followed by photographing.

Allowing to reduce the total time of the patient's examination, this device has limited accuracy and efficiency in detecting pathological foci. In addition, due to the use of a cathode-ray tube in the recording system, the resulting image has a high opacity, a small number of luminance gradations, a smaller scale, which makes it difficult to interpret the gammaterograms and identify paeses of small pathological foci.

The detector system, designed for the use of sredneenergetic radio isotones, is heavy, and the use of an amplitude analyzer in each radiometric unit makes the gammayunograph more expensive and expensive, leads to instability in its operation, and makes it difficult for the clinical use of the device.

In recent years, but a number of radiopharmacological preparations based on low-energy y-emitters (1, Xe, et al.) With an emission energy of less than 150 keV. The use of these radioisotopes makes it possible to implement practically all known gammatopographic methods. In this case, without increasing the radiation load of the pan I1nta, it is possible to significantly increase the amount of radioactivity introduced into the body, which increases the statistical accuracy of the radiation and improves the quality and information content of the image. In addition, if the skepier is designed to use only low-energy isotopes, the weight of the sensors and the entire prioor is drastically reduced, the design of the skeleton mechanism and the radiometric unit is simplified and cheapened, and the collimators work drastically (due to the sharp decrease in edge effects). The purpose of the invention is to improve the accuracy and efficiency of detection of pathological foci at the same time reducing the time of a patient's study. The goal is achieved by the fact that, in the proposed gammatopograph, each sensor and marker holder is equipped with tools for manually changing the mutual positioning and grouping of sensors and markers, made in the form of two slats that are movable relative to each other but horizontal, with removable sensors and gauges, and At least one of the slats for fastening the sensors is mounted on a vertical guide, which ensures that the strap does not move vertically. FIG. 1 in two projections depicts the proposed gammatograph; pas figs. 2 shows the disposition of the sensors and gauges of the gammopograf when researching large areas of the patient's body (in two projects); pas figs. 3 - location of sensors and markers in the study of paired organs (in two projects); pas figs. 4 and 5 show the sensor holder, respectively, a front view and a top view; in fig. 6 and 7 - marker holder, respectively, front view and top view. The proposed gammatograph contains a system of sensors 1, placed on rams 2 of the holder 3 of the system of sensors; system markers 4, placed on strips 5 holders 6 marker systems; a scanning mechanism 7 with an automatic control circuit, on the movable guide 8 of which the holder 3 of the sensor system and the holder 6 of the marker system are strengthened; a multi-channel electronic radiometric unit 9, the channel of which is electrically connected to the corresponding sensor and marker; a table 10 for securing a paper on which a map of the radioactivity distribution under study is obtained. The sensor system holder 3 is provided with two devices for manually changing the mutual position and grouping of sensors (Figs. 4, 5), consisting of a fixed 11 and a movable 12 slats, moving one relative to the other along the horizontal guide 13. On each of the slats 11, 12, slots 14 are provided for mounting removable sensors and screw stonors 15 for manually fixing the rake in the desired position. At the same time, at least one of these devices is mounted on the vertical guide 16 of the holder 3 of the sensor system. The marker system holder b is also provided with a similar device for manually changing the relative position and grouping of the markers (Fig. 6, 7), consisting of a fixed 17 and a movable 18 flanges, moving one relative to the other along the horizontal rail IV. On each of the bars G /, 18 there are sockets 20 for installing removable markers 4 and screw stoppers 21 for manually fixing the strip in the desired position. Investigating large areas of the patient's body, sensors and markers are arranged in a single row (Fig. 2). When scanning such paired organs as lungs and kidneys, the sensors and markers are located respectively in two parallel rows in the horizontal plane (Fig. 3). When examining such massive organs as the liver and brain, the sensors are placed in two parallel rows in a vertical plane on opposite sides of the patient (Fig. 1); in this case, the gauges are placed on one bar (one row). Manual change of location and grouping of sensors and markers provides the optimal conditions for recording the radiation of an object in various clinical methods, which improves the accuracy and efficiency of detection of pathological foci and reduces the time of research of the patient. The gammatograpograph works as follows. When moving a system of sensors registering 7 Radiation above a given part of the patient’s body, to which the required amount of the radioactive drug is injected, electrical pulses from the output of sensors 1 go to the corresponding channels of the electronic radiometric unit 9, where amplification is performed, amplitude analysis and pulse counting, as well as background subtraction . The output pulses of the radiometric unit 9 control the operation of the system of markers 4, which ensure a 1: 1 scale of dash-and-white gammatopogram of the test organ on a plain paper fixed on the table 10, the scanning mechanism 7 with the automatic control circuit. 8 moves the holders 3 of the sensor system and 6 of the marker system (along with the reinforcement bars of 2 and 5 and the systems of sensors and markers) along a raster path at a given speed. An experimental sample of the proposed gammatopograph contains eight sensors and eight markers, electrically connected with an eight-channel radiometric one. by block. Since the device is designed to use uradioactive isotopes with an emission energy of less than 150 keV, the toli:, lead sensors were less than 4 mm, which drastically reduced the weight of the group of sensors and the entire device and made it possible to easily change the location of the sensors (and markers) manually, simplified design and increased reliability nribor, as well as reduced its cost.

Subject invention

A gammatograph for registering the distribution of low-energy radioactive isotopes in the human body, containing a scanning mechanism that holds the holders of the sensor system and the system of markers interconnected through

The first radiometric unit is designed so that, in order to increase the accuracy and efficiency of detection of pathological foci while reducing the time of patient examination, each sensor and marker holder is equipped with a device for manually changing the relative position and grouping of sensors and markers, made in the form of two slats being moved one relative to the other along horizontal guides with sockets for installing removable sensors and markers, and at least one of the slats for the sensor mount, it is mounted on a vertical guide, ensuring that the pad is not shrunk vertically,

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