SU578679A1 - Gamma-tomograph detecting device - Google Patents

Description

one

The invention relates to medical technology, namely, to detector devices of gammatomographs, will find application in medical, prophylactic and research institutions for the diagnosis and investigation of internal organs and systems of humans using radioisotopes.

A gammatomograph detector device is known, comprising a housing, oscillating crystals with collimators, photomultipliers, optical fibers, and a protective screen.

However, the known device has a complex structure, and because of the uneven sensitivity of photocathodes of photoelectric multipliers and the spread of their parameters, the accuracy and efficiency of detecting pathological foci is limited.

The purpose of the invention is to increase the efficiency of detection of pathological foci and simplify the design.

This is achieved by the fact that, in the detector device of the gammatomograph, the strong crystals are located around the perimeter of the square, colpi-mized under the UTLA to the scanning plane, and the photocathode of each photomultiplier tube is optically coupled to scintilla cytophores.

FIG. 1 shows the detector device gammatomograf, general view; in fig. 2 - ra cut AA one.

The gammatorotrafa detector device includes a housing 1, eight collimators 2, eight scintilla tiocath crystals 3, four photoelectronic multipliers 4, light guides 5 and a lead protective screen 6.

The collimator .2 is located around the perimeter of the square and is inclined to the plane of movement of the detector device when examining a patient.

Each of the photocathodes of photomultiplier tubes 4 is connected by means of optical fibers 5 with equal areas of scintilles of silicon crystals 3, which form an angle of a square.

The device works as follows.

Through the scanning mechanism of the gammatomograph, the detector device is moved along a rectangular raster over the patient's area under investigation, to which the required amount of the radioactive preparation is injected.

Gamma quanta, the passage through the aperture of one of the collimators 2, fall into a scintillation crystal 3 conjugated with it, where they are converted into light flashes, which by means of S fibers arrive at the photo chip 3 photoelectric multipliers 4. Multipliers convert these The light pulses of an electrical pulse in a laser are the amplitude of which is proportional to the energy of the detected gamma-quanta.

By means of, for example, an amplitude analyzer of a gammashgomograph connected to the outputs of the photo multiplier 4 multipliers, electrical pulses are selected that correspond to the photo-field of the energy spectrum of a given radioisotope.

Depending on the location of the collimator

2 and conjugated with him STsINTILLYaTsIOinogo Crystal 3 through which passed and zaregistrirovals gamma quantum with energney in photopeak znergeticheskogo spectrum of the radioisotope, electrical pulses vyrabattayuts only those photoelectron multipliers 4, which fotokagody optically coupled with these stsiktill the pion cr stalpom 3 by means of light guides 5 .... -

Next, the electrical pulses of the hustle come out to the outputs of the corresponding amplitude analyzers of the gammatomograph and then to the logic solver, which determines exactly the collimator 2 through which the gamma quantum was received. Depending on this, coordinate signals are generated and illuminated on screens, for example, cathode ray tubes, the points whose coordinates on the selected scale correspond to the intersection of the central axis of this collimator 2 with the selected planes in which the radioactive isotope is visualized.

Documentation of research results is done, for example, on photographic film by integrating light flashes from the screens of cathode-ray tubes during a scanning cycle using a camera.

Such a device provides for the use of high-energy emitters, reducing the distortion of the image of the distribution of a radioactive drug, eliminates the need to select photoelectronic smart devices according to the uniformity of the sensitivity of photocathodes, and thus improves the efficiency of detection of pathological foci and simplifies the structure.

Ф о рм ул and; and 3 o. A detector device of a gammatomograph, comprising a housing, scintillation crystals with collimators, photoelectronic multipliers, (zetovod and protective, characterized in that, the perimeter of the square, the colliminda at an angle to the scanning plane, and the photocathode of each photoelectric multiplier of the multiplier is optically coupled to the scintillaries by the crystals.

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