SU594610A1 - Scanner - Google Patents

Description

I

The invention relates to devices for radioisotope diagnostics, and specifically to scanners, can be used in medical, prophylactic and research institutions for the diagnosis and study of internal organs and systems of humans using radioactive isotopes.

Known scanners are designed to visualize the distribution in the human body of radioactive drugs administered for diagnostic purposes. These devices allow to determine the shape, size and location of internal organs and reveal an abnormal accumulation of radioactive drugs in the areas corresponding to the pathological foci. With the help of radioisotope scanning, a dygnostic treatment of the liver, lungs, brain and other human organs and systems is carried out.

A scanner is known comprising a sensor, a radiometric unit, a scanning mechanism with a control circuit and a recorder.

However, the low speed of electromechanical recorders limits the use of scanners at scanning speeds above 2: 2 mm / s, and the range of reproducible count rates determines the need for using counting devices and the loss of some information, which ultimately reduces the accuracy of recording and the detection of pathological data. fociS.

The purpose of the invention is to improve the accuracy of registration and reliability of detection of pathological foci.

This is achieved by the fact that the scanner is equipped with a pulse distributor, electrically driven with radiometric: fuzzy, and expander pulses, the inputs of which are connected to the outputs of the detector, and the outputs to the inputs of the recorder. Moreover, the pulse extenders are made in the form of standby multivibrators with a common for them p & pulse duration pulse, and the recorder is in the form of an LED screen and a lens enclosed in a light-shielding housing. The drawing shows a structural diagram of the scanner. It contains sensor 1, radiometric unit 2, recorder 3 and scanning mechanism 4 with a control circuit. Sensor 1 is designed to direct & gamma flux from the object under study into electrical pulses and consists of a collimator, a scintillation crystal, a photomultiplier and a preamplifier. Radiometric unit 2 uses c to isolate electrical signals from sensor 1 in a given range of radiation energy and convert them. The recorder 3 is designed to put visually perceptible marks on the scannogram, the scanning mechanism 4 with the control circuit - for automatic synchronous movement of the sensor 1 and the recorder 3 along a predetermined path. : The scanner is also equipped with a 5-pulse dispenser, electrically connected to the radiometric unit 2, with spreader 6-8 pulses, the inputs of which are connected to the outputs of the distributor 5, and the outputs - to the inputs of the recorder 3. The distributor 5 pulses is designed to deliver each pulse, passed through the radiometric unit 2, to the corresponding registrar level 3 and made in the form of a Johnson counter with a decoder. Extenders 6–8 pulses provide normal exposure (obtaining a visually perceived mark for any Recorder format: with electromechanical markers, photo markers, etc.) and made to auxiliary multivibrators with a common pulse width regulator for them. To enable photo recording of the scannogram, register 3 is made in the form of an LED matrix and a lens enclosed. in the light-protective case. In automatic mode, the scanner works as follows. The scanning mechanism 4 (controlled) sensor 1 n of the register 3 torus synchronously moves along the trajectory at a predetermined speed. When moving sensor 1, recording gamma radiation over the examined part of the patient’s body (which requires the required amount of radioactive drug), it enters The flow of gamma quanta, which emit light flashes in a scintillation crystal, which are converted by a photomultiplier tube into electrical pulses, which are output from sensor 1 to the input of radiometric unit 2. In the radiometric unit 2, those pulses are selected and normalized from the total pulse flow; the amplitude of which corresponds to the energy of the isotope used, and the background is subtracted simultaneously. From the output of the radiometric unit 2, the pulses are fed to the input of the distributor 5, which ensures their sequential input (distribution), and the inputs of the extenders 6-8, from the OUTPUTS of which the pulses are fed to the corresponding recorder 3, are arranged in a column across the scan line. The incoming pulse causes the triggering of the first level of the recorder 3 and the appearance of a mark on the scannogram; the next pulse passes through the distributor 5 and the corresponding expander to the second registrar marker 3 and causes the appearance of the second mark, etc. After filling in the distributor 5 (the number of outputs of which corresponds to the number of markers used), the process is repeated (the first marker triggers again, etc.). The image of the distribution of the radioactive drug in the object under study is obtained as a result of the successive horizontal passage by sensor 1 of all areas above the object and is represented as points diffusely distributed on the surface of the scan image. The described device improves the registration accuracy and reliability of detection of pathological foci by increasing the registration speed, as well as expanding the dynamic range of the airborne signal caused by a decrease in the size of the marks applied. In addition, it also avoids the long-term presetting of c & a before the study, since there is no need to perform calculations on the choice of the conversion factor, which reduces the total study time and guarantees

pathological foci in the context of an incorrectly selected recalculation.

Claims (3)

1. A scanner containing a sensor, a ranger unit, a scanning mechanism with a control circuit and a regisgrator, characterized in that, in order to improve the accuracy of recording and nationalizing the pathological foci, it is equipped with a pulse distributor electrically connected with the radiometric unit, and 5 spreads of pulses, the inputs of which are connected to the outputs of the distributor, and the outputs to the inputs of the recorder. 2. A scanner according to claim 1, characterized in that the pulse expanders are made in vice-multiplying multivibrators with a common regulator of pulses of alcoholism. 3. A scanner according to claim 1, characterized in that the recorder is embodied as an LED array and a lens enclosed in a light-shielding housing. Sources of information taken into account in the examination: 1. E. Yu, Elkind et al. GammatopoGraph GT-6O with graphic registration. Proceedings of the Institute of All-Russia Institute of Medical Instruments and Equipment M., 1964, no. 1, s. 18-24. -