SU736958A1 - Apparatus for radio-isotope diagnosing of esophageal tumors - Google Patents

Description

The invention relates to medicine, namely to the field of clinical isotope diagnostic diagnostics, and may find application for the diagnosis of malignant tumors of the esophagus and other neoplasms localized on the mucosa of various cavities of the patient’s body.

A device for the radioisotope diagnosis of tumors of the esophagus, containing an intracavitary probe, semiconductor detectors and an associated electronic recording unit [1].

The main disadvantage of the known device is the isotopic spatial sensitivity of the probe, as a result of which it measures the total flow of beta particles from all sides of the esophageal mucosa. Such a probe design does not allow determining the axial distribution of radioactive phosphorus-32 along the walls of the esophagus (i.e., along its perimeter), making it possible to obtain diagnostic information on the distribution of the indicator only along the length of the esophagus.

The aim of the invention is to clarify the location and extent of the tumor along the perimeter of the esophagus.

The goal is achieved in that the detectors are arranged in pairs on opposite sides of the side surface of the probe, one pair is offset relative to the detectors from the probe 90 °, wherein the distal end of the probe element comprises a radiological orientation relative ste ⁵ nok esophagus.

In FIG. 1 shows an intracavitary probe, a general view; in FIG. 2 - same, left view; in FIG. 3 - block diagram of the electrical part of the device.

A device for radiotopic diagnostics of esophageal tumors contains semiconductor detectors 1 located in pairs on opposite sides 15 of the lateral surface of the intracavitary probe 2, the distal end of which has elements 3 of the radiological orientation of the walls of the esophagus. Moreover, one pair of detectors is offset from the axis of the probe by 20 90 °. Each of the four probe detectors is connected through a high-frequency microcable 4 to a corresponding measuring channel. In addition, the device comprises an electronic registration unit, including a 25 shield amplifier-discriminator 5, a normalizer 6, an optical analog indicator 7, and a pulse storage circuit 8 with an optical digital indicator 9.

The device operates as follows.

.3

The output pulses of detector 1, the average frequency of which is proportional to the flux density of beta particles falling into the sensitive volume of the detector, after amplification and discrimination / noise pulses by amplifier-discriminator 5, is fed through the cascade of normalizer 6 in parallel to the corresponding cell of the optical analog indicator '7 and to the circuit 8 accumulation of pulses with an optical digital indicator 9.

The normalization of pulses in amplitude and duration ensures the proportionality of the conversion of the average frequency of the pulses into the intensity of illumination of the indicator cell. The distribution of the illumination intensity of the cells of the analog indicator displays a planar scan of the spatial distribution of the radioactive indicator over the mucosa of the studied segment of the esophagus, since fluoroscopy of the orientation elements of the probe allows the optical image on the analog display to be linked to the probed section of the esophagus.

The simultaneous presentation of measurement information from each of the four detectors on a digital indicator panel allows you to get quantitative information about the localization, the prevalence of areas with abnormal accumulation of the indicator, as well as the levels of accumulation of radioactive phosphorus in these areas of the esophagus mucosa.

Claims (1)

Claim A device for the radioisotope diagnosis of esophageal tumors, containing an intracavitary probe, semiconductor detectors and an associated electronic registration unit, characterized in that 15, in order to clarify the location and extent of the tumor along the esophagus, the detectors are located in pairs on opposite sides of the lateral surface of the probe, one a pair of detectors20 is offset 90 ° relative to the axis of the probe, while the distal end of the probe contains elements of x-ray orientation relative to the walls of the food water. 25 Source of information taken into account during the examination: 1. Prospectus of the company Nucleotron, Germany "Datenblat" No. 66009, 1974. Fig.Z