RU50392U1 - SENSOR FOR DIAGNOSIS OF ONCOLOGICAL DISEASES - Google Patents

Abstract

The utility model can be used for early detection of malignant oncological diseases, including before the formation of conditions providing the possibility of detecting the fact of the formation of a malignant tumor using currently accepted diagnostic methods. Objective: to increase the reliability of the diagnosis, while making it possible to diagnose, at the initial stage, before the formation of a malignant tumor, simplifying the diagnostic procedure. Essence: A sensor for diagnosing an oncological disease comprising a receiver of its own radiation from organs and / or human tissues and a means for extracting a diagnostic signal from the general spectrum of radiation from the body, characterized in that the receiver contains a single crystal quartz plate, a Z-slice equipped with silver coatings on both sides , a thickness, preferably up to 0.03 mm, electrically connected with the amplifier of electromagnetic signals, while its center is placed on the axis of symmetry of the cavity of the confuser reflector, ext the friction surface of which is coated with silver, wherein the reflector symmetry axis perpendicular to the surface of the quartz plate, which is mounted on elastic suspension.

Description

The utility model relates to the field of medicine and is intended for early detection of cancer, including the formation of conditions providing the possibility of detecting the fact of the formation of a malignant tumor using currently accepted diagnostic methods.

A known sensor for the diagnosis of cancer, made in the form of a highly sensitive receiver of radiation of the human body in the range of ultraviolet frequencies emanating from atoms of polymerized, oncological cell molecules, which is associated with the processing unit and analysis of the measurement results, while the presence of cancer is judged by the excess radiation background level (see US Pat. RF No. 2128337, class A 61 V 1/00, G 01 N 33/483, 1999)

The device is based on the fact established by the inventors that in the presence of a cancer, an increased background of ultraviolet radiation is observed. This phenomenon is indirectly confirmed by the studies of A.A. Gurvich who discovered that during mitogenesis of the cell, i.e. during its division, ultraviolet radiation is observed (see A. A. Gurvich. The problem of mitogenetic radiation as an aspect of molecular biology. - L .: 1968, p. 240. The patent authors claim the possibility of diagnosing cancer, including early, at the initial stage 6-30 years before the formation of the malignant tumor, however, it is clear that the power and intensity of radiation (providing the ability to highlight a diagnostic sign against the general background of a signal of a similar nature generated by the body), ceteris paribus ditions depends on the volume of the object generating the signals, i.e. the number of cells containing polymerized oncological molecule. Therefore diagnosis on the early stages of cancer development is insufficiently reliable.

Currently, in physiology, an information approach to the analysis of various human functions is widely used. Considering only physical and chemical factors, it is not always possible to explain the processes occurring in the human body. From the point of view of the information approach, along with physicochemical processes in the human body, information processes are formed and closely interact, transmitted, stored and analyzed. The theory of functional systems, proposed by the outstanding Russian physiologist P.K. Anokhin, opens up new possibilities for an objective assessment of the information activity of the body. Functional systems according to P.K. Anokhin are dynamic, self-regulating organizations, all the components of which are closely interconnected and interact to achieve various beneficial results for the body. It is the adaptive results that are useful to the body that act as system-forming factors in the organization of functional systems at various levels. The activity of various functional systems determines the levels of various indicators of homeostasis, such as pH, gas composition, osmotic and blood pressure, temperature, nutrient levels, etc. The concept of homeostasis was introduced into physiology by W. Canon, who understood by homeostasis the harmonic interaction in the internal environment of the human body of various physical and chemical factors of vital activity. However, it is the information in living organisms that is closely related to the activities of the various components of its functional systems, which is, as it were, a common denominator for all the physical and chemical processes taking place in the body. Only in self-regulating functional systems during the long evolution of living organisms can an information evaluation apparatus be formed - an acceptor of performance results. The apparatus of an acceptor of results of activities based on mechanisms ahead of actual events allows living organisms to constantly evaluate various parameters of achieved results and to build an adaptive information base

activity. Moreover, the informational assessment in the functional systems of the homeostatic level acts as informational signals that control processes in the human body. Recent studies in microbiology in the field of redox systems: excited molecules and key signal-transmitting proteins of electron acceptors (Journal of Science 1998, N 5, v.280, p.1723), confirmed the leading role of information processes in the regulation of homeostasis. As a rule, living organisms objectively and quantitatively evaluate the results of activities of functional systems that determine various indicators of homeostasis. Thus, information and / or energy-information processes that are organically inherent in any living organism, manifesting themselves in the external environment in the form of radiations of various physical nature, can be used to diagnose the state of the human body and its individual organs.

Thus, it seems possible to use the body's own radiation for diagnostic purposes.

There is also a technical solution that implements this idea, which we used as a prototype (see US Pat. RF No. 2144781, class A 61 B 5/00, 2000), while the sensor for diagnosing cancer includes a receiver of its own radiation from organs and / or human tissues and a means for isolating the diagnostic signal from the general spectrum of radiation of the body. The sensor is connected with the processing unit and the analysis of the measurement results, while the presence of cancer is judged by the excess of the radiation intensity of the background level.

In the process of diagnosing cancer, the electromagnetic radiation of human organs and tissues is measured in the millimeter and / or decimeter ranges using a highly sensitive receiver, followed by processing and analysis of the measurement results, moreover, the measurement results are processed by detecting a high-frequency noise signal and isolating a low-frequency modulating

component, then change the orientation of the receiver by 90 ° relative to its longitudinal axis and repeat the measurements, followed by their processing, analysis and the formation of diagnostic signs, for each of which a second set of time series is built by comparing the time series obtained before and after changing the orientation of the receiver, using an additional statistical and / or neural network classifier, cancer is differentiated

The disadvantages of the device stem from the fact that the diagnosed organ itself is used as the signal source and the energy-informational characteristics of the carcinogenesis process that is already occurring in the diagnosed organ are “removed” ie there is no possibility of early diagnosis of the disease (i.e., the initial stage - before the formation of a malignant tumor of certain sizes), which reduces the reliability of the diagnosis. In addition, the disadvantages of the device include the multi-operation of its use, and the complexity of the mathematical processing of the results. Moreover, the need to rotate the radiation receiver 90 °, with respect to the initial orientation of the receiving axis, can be realized only in relation to individual organs of small size, such as breasts, male genitalia, etc. , since in other cases it will not be possible to ensure a constant distance from the signal source to the receiver, which determines the power of the received signal.

The task to which the proposed technical solution is directed is to increase the reliability of the diagnosis, while making it possible to diagnose it, at the initial stage - until the formation of a malignant tumor, simplifying the diagnostic procedure.

The technical result that is achieved when solving the problem is expressed in ensuring high reliability of diagnosis on the earliest steel of the carcinogenesis process, providing the opportunity

diagnosing a wide range of cancers. In the future, with the accumulation of statistical material, accurate differentiation and localization of oncopathology at any stage of its development will be possible.

To solve this problem, a sensor for the diagnosis of cancer containing a receiver of its own radiation from organs and / or human tissues and a means for extracting a diagnostic signal from the total spectrum of radiation of the body, characterized in that the receiver contains a single crystal quartz plate, Z-slice, provided on both sides silver coatings, preferably up to 0.03 mm thick, electrically connected to an amplifier of electromagnetic signals, while its center is placed on the axis of symmetry of the cavity Zorn reflector whose inner surface is coated with silver, wherein the reflector symmetry axis perpendicular to the surface of the quartz plate, which is mounted on elastic suspension.

A comparative analysis of the totality of the features of the proposed solution and the totality of the features of analogues and prototype indicate that the proposed technical solution meets the criterion of "novelty."

At the same time, the distinguishing features of the formula solve functional problems, the complex of which provides an increase in the reliability of the diagnosis, while making it possible to diagnose, at the initial stage, before the formation of a malignant tumor, simplifying the diagnostic procedure.

The claimed technical solution is illustrated by drawings: in Fig.2 shows a longitudinal section of the sensor, Fig.1 shows a functional diagram of the installation, providing the implementation of the method; figure 3 schematically shows the location of the radiation receiver during operation, figure 4 shows a fragment of a patient examination with a diagnosis of gastric cancer (the upper graph is the impulse characteristic of a cancer patient, below is the same impulse, increased and extended in time); figure 5 shows a fragment of the survey

a patient with a diagnosis of prostate adenocarcinoma (the upper graph shows the groups of impulses characteristic of a cancer patient, below the same groups of impulses that are enlarged and extended in time); figure 6 shows a fragment of an examination of a patient with a diagnosis of breast adenocarcinoma obtained from the affected organ (the upper graph is the group of impulses characteristic of the cancer patient, below is one of these impulses, enlarged and extended in time); 7 shows a fragment of the examination of a healthy patient (the upper graph is a record of only the noise track, below is the same record, enlarged and extended in time); on Fig shows a diagnostic complex.

The sensor’s operation is based on the effect established by the authors, namely, that single-crystal quartz Z-slice plates placed in the radiation field of a living organism having a malignant disease (confirmed by known diagnostic methods) are able to detect specific signals induced by the patient’s brain in a certain frequency range, whereas in the patients examined by us who do not have a diagnosis of malignant neoplasm, these signals are absent.

The drawings show a single-crystal quartz Z-slice plate 1, which is a thin round plate, on both sides 2 of which a thin coating 3 of silver is applied (actually - no more than 0.1 mm thick). The plate is installed in the cavity of the confuser reflector 4, the axis of symmetry 5 of which passes through the center 6 of the quartz plate 1 and is perpendicular to its surface 2. Moreover, the confuser reflector 4 or its inner surface 7 is made of silver (in the second case, the reflector case is made of non-magnetic material coated silver inside). In addition, the coating of the quartz plate 1 is electrically connected to the input of the signal amplifier 8, wires 9. In this case, the wire in contact with the coating 3 placed on the side of the quartz plate 1 facing the open edge 10 of the confuser reflector 4 is omitted

through the hole 11, made in its center 6. The elastic suspension 12 is made of an elastic material, such as rubber, and ensures the horizontal position of the quartz plate 1 in the process of fixing radiation, and, accordingly, its vibrational movements (due to springing of the plate relative to the end face of the sleeve 13 through channel 14 of which wires 9) are passed. The outer surface of the sleeve 13 is threaded, while the sleeve is placed in a hole provided with the same thread coaxially with the liner 15. One end of the liner 15 is provided with a shoulder 16, the edge of which is congruent with the inner surface of the confuser reflector 4, and the second is provided with a thread on which the nut is placed 17. The sleeve 13, the liner 15 and the nut 17 are made of non-magnetic, preferably synthetic material. The output of the signal amplifier 8, through an analog-to-digital converter 18, is connected to a computer 19.

Known means are used as elements 8, 18-19 of the device, the operating characteristics of which correspond to the operating parameters of the device, while the signal amplifier 8 is made according to the known scheme, a 12-bit ADC is used as an analog-to-digital converter 18, to ensure an acceptable processing speed of the measurement results it is desirable that the computer processor be at least Pentium-4.

The sensor is assembled as follows - through the smaller hole of the confuser reflector 4, the insert 15 is passed until the edges of the collar 16 abut against its inner surface, after which the insert is fixed with a nut 17, then a sleeve 13 is placed in the threaded hole of the insert 15, at the end of which there is an elastic suspension 12 (e.g. rubber washer). Then, wires 9 are passed through channel 14 of sleeve 13, fixing them on the free end of sleeve 13. After connecting wires 9 to the terminals of signal amplifier 8 (connected via ADC 18) with computer 19, the device is ready for operation.

The device is used as follows: it is positioned so that the wide base of the cone of the reflector 1 is in direct

proximity to the studied area of the human body or biological tissue (not shown in the drawing). In this case, the potential difference is constantly removed from the silver-plated surfaces of the 2 quartz round plate 1. With a malignant oncological process, a potential difference arises from the silver coatings 3 of the quartz round plate 2, in the presence of which it is concluded that there is a malignant oncological disease. Examination Procedure:

1. The patient needs to remove all metal parts from the head and neck (earrings, chains, hairpins). The patient is located on the examination couch, lying on his back in the most comfortable position. The head is thrown back a little through the soft cushion-pillow.

2. Position the sensor on the front of the head (orienting its longitudinal axis to the central region of the brain) at a distance of 3-9 mm from the skin.

3. Start recording signals from the receiving sensor to the computer.

4. After registration, recording stops for 20-30 minutes.

Deciphering the results:

1. The process resembles the interpretation of the results of a standard ECG or EEG. All fragments of the record are viewed page by page. Currently, decoding one study takes up to 20-30 minutes.

2. In the absence of impulses exceeding the level of the amplitude of the noise track, a conclusion is drawn that the patient does not have a diagnosis of malignant neoplasm.

3. With the repeated appearance of impulses and (or) their sequences, they conclude that there is a diagnosis of a malignant neoplasm, or a stage preceding a malignant form of cancer, and it is recommended that the patient undergo a detailed additional examination with other available diagnostic tools.

Recorded Signals:

Recorded "oncosignals" look like relatively short burst sequences of various configurations (Figs. 4-5). The duration of these packets can be from tens of microseconds to milliseconds. As the experience of examining patients shows, during its conduct (20-30 minutes), these signal packets appear repeatedly (up to 10 or more), although there have been cases when only one impulse was recorded for the indicated time. In this connection, to increase the reliability of the diagnosis, the duration of the examination is set within the above limits.

Example 1. Patient M., a woman, 53 years old. Complaints of pain in the stomach. When examining our method, repeated impulse packets were recorded from the brain, indicating the presence of a malignant cancer. The given fragments of the study indicate the orderliness and repeatability of individual amplitude-frequency characteristics of the signals corresponding to a malignant disease with a diagnosis of gastric cancer. Further examinations through fibrogastroscopy, surgery confirmed the presence of a malignant disease - cricoid cancer of the body of the stomach.

Example 2. Patient D., male, 77 years old. When examining our method, repeated impulse packets were recorded from the brain, indicating the presence of a malignant cancer. The given fragments of the study indicate the orderliness and repeatability of individual amplitude-frequency characteristics of the signals corresponding to a malignant disease with a diagnosis of prostate adenocarcinoma. Further examinations confirmed this diagnosis.

Example 3. Patient S., woman, 51 years old. During examination by our method, repeated pulse packets were recorded from the affected organ, indicating the presence of a malignant cancer. The above fragments of the study indicate the orderliness and repeatability of individual amplitude-frequency characteristics

signals corresponding to a malignant disease with a diagnosis of breast adenocarcinoma. Examined on an outpatient basis for breast infiltrate. The diagnosis was made on the basis of puncture of an infiltrate - breast adenocarcinoma

In healthy patients, these impulse groups are absent (Fig.6). The result of their examination looks like a solid line due to the noise of the equipment.

To date, over 300 patients have been examined, of which about 90 people with a diagnosis of malignant cancer have been identified (the rest are either healthy or have a non-cancerous pathology). The reliability of the diagnosis is currently about 87%, and this figure has a tendency to increase, since our diagnosis (initially attributed by us to negative statistics) over time (from one month to years) is still confirmed.

The use of this invention allows you to register changes that occur in biological tissues with malignant diseases in the early and subsequent stages.

Claims (1)

A sensor for diagnosing an oncological disease, comprising a receiver of intrinsic radiation of organs and / or human tissues and a means for isolating a diagnostic signal from the general spectrum of radiation of an organism, characterized in that the receiver comprises a single crystal Z-slice quartz plate provided with silver coatings on both sides with a thickness , preferably up to 0.03 mm, electrically connected to the amplifier of electromagnetic signals, while its center is placed on the axis of symmetry of the cavity of the confuser reflector, internal the surface of which is coated with silver, while the axis of symmetry of the reflector is perpendicular to the surface of the quartz plate, which is mounted on an elastic suspension.