RU2155084C1 - Method and device for acting upon biological objects - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves exposing biological objects to extremely high frequency electromagnetic field with at least five oscillators at the same time. Each oscillator creates electromagnetic radiation of the predefined frequency bandwidth. Radiation power intensity at the place the object is positioned, is from 0.3 mcW/cm² to 10 mcW/cm². The action has threshold level when five oscillators are used at the same time for irradiating an object with electromagnetic radiation that results in delay of neoplasm cell growth. The device has at least five oscillators creating electromagnetic field in five basic bandwidth areas. Additional oscillators operating in additionally selected frequency bandwidths are optionally useable. EFFECT: enhanced effectiveness in treating tumors, bacterial and viral infectious diseases. 9 cl, 1 dwg

Description

 The invention relates to biology and medicine and can be used for therapeutic effects on biological objects, in particular in the treatment of neoplasms and viral diseases in humans and animals by irradiating a biological object with an electromagnetic field of high and ultrahigh frequency.

Currently, various types of electromagnetic radiation are widely used in medicine and biology for both treatment and diagnosis. When assessing the effects of interaction with various biological objects, it is customary to separate electromagnetic radiation into ionizing and non-ionizing ones. Typically, such electromagnetic waves, in particular X-ray or gamma radiation, whose energy quantum is so large that intermolecular bond breaks occur up to ionization of atoms, are referred to ionizing radiation. Longer-wave electromagnetic radiation with a small amount of quantum energy is attributed to non-ionizing radiation, which has a different character of influence on a biological object and is used, for example, to heat at least part of the object. Depending on the frequency, power and other parameters of electromagnetic radiation, this effect is divided into physiotherapy (less powerful effect) and hyperthermia (more powerful effect), which raises the temperature to 41 ^o C and above.

 In the treatment of various oncological diseases, ultra-high frequency electromagnetic radiation is used, which, acting on the tumor, leads to local heating of the affected area, which causes inhibition of tumor growth and its resorption.

A known method of conducting hyperthermic electromagnetic therapy of malignant neoplasms, which consists in introducing into the tumor a suspension of ferromagnetic particles with a Curie temperature from 42 ^o C to 45 ^o C, followed by heating with microwave energy of an electromagnetic field (see RU 2082458, A 61 N 5/02, 1997).

 The method involves the use of a generator, the power of which, depending on the size and depth of the heating region, is from 5 W to 100 W. This method can be used to treat not only oncological diseases, but also in the treatment of other diseases, such as post-radiation fibrosis, some inflammatory kidney diseases, etc. The use of ferromagnetic particles having a Curie temperature comparable to the required heating temperature allows for automatic maintenance of the set temperature, since when the fabric is heated above the Curie temperature, the ferromagnetic particles lose their magnetic properties and their interaction with electromagnetic radiation drops sharply.

 There is also known a method of forming microwave radiation during hyperthermic exposure, including the formation of microwave pulses and exposure to an electromagnetic field of ultrahigh frequency on cancer patients (see SU 1804793, A 61 N 5/02, 1993).

 The method consists in preliminarily cooling the irradiation region to a predetermined temperature, then focusing the microwave radiation in the predetermined region and irradiating with a delay relative to the moment the cooling starts. The preliminary cooling of the irradiation area is due to the following. Obviously, the surface tissues of the human body are most susceptible to overheating as a result of exposure to a microwave pulse. Therefore, in order to increase the pulse power, and therefore to increase the hyperthermic effect, preliminary cooling of surface tissues in the zone of exposure to microwave radiation is necessary.

 Installation for implementing the method includes a pulsed microwave generator, a system of directional antenna elements associated with a microwave generator, a control unit for a microwave generator and a temperature sensor system.

 The delay in the start of irradiation is due to the presence of an amplitude-phase converter with an adjustable phase shift connected to a microwave radiation generator and each antenna element. Power in a pulse with a duration of 10 s in this installation is at least 10 kW.

 There is also a method of influencing biological objects, which consists in the fact that biological objects are irradiated with an electromagnetic field of ultrahigh frequency with an effective boundary in the form of a single-cavity hyperboloid of revolution (see SU 1156705, A 61 N 5/00, 1985).

 To improve the accuracy of pointing microwave radiation to an object in a known method, an indication of the effect of microwave radiation by collimated light is carried out along the rectilinear generators of a single-cavity hyperboloid, which is carried out by connecting the generator antenna with light sources. Light rays formed by a collimation device permanently or temporarily connected with the antenna are supplied to the irradiated object, for example, in the form of two light spots. Located directly on the effective boundaries of the invisible field of microwave exposure, these light spots determine the exact position of the area exposed to electromagnetic radiation.

 The closest in technical essence to the described device is a device for influencing biological objects, containing a generator of electromagnetic radiation of superhigh frequency coupled to a radiating antenna means (see SU 1736511, A 61 N 5/00, 1992).

 The known device comprises a generator and four emitters of a superdirectional antenna means (array), providing uniform exposure of the tumor with minimal damage to surrounding healthy tissues due to the formation of unidirectional radiation with a rectangular directivity. The radiation power of the known device is about 200 watts.

 The influence of microwave radiation on biological objects of all the above methods using known devices is based on the method of hyperthermia, i.e., the method of locally increasing the temperature of irradiated cells. As a result, there is a death of the irradiated cells.

 However, these methods require a sufficiently significant increase in the temperature of the irradiated cells during the transition of electromagnetic radiation energy to heat and, therefore, a significant amount of power from devices for influencing objects using microwave radiation. At the same time, it is impossible to provide strictly local exposure exposure. For this reason, heat release occurs in healthy cells adjacent to malignant neoplasms, which leads to the destruction of healthy cells. Known methods also do not allow uniformly increasing the temperature of the entire irradiated structure. Therefore, the degree of positive impact of known methods and devices on biological objects is relatively low.

 In addition, the known methods and devices have a strong negative effect on the whole organism as a whole, since the microwave radiation power of the known methods is quite substantial - at a level from several watts continuously to 10 kW per pulse. It is widely known that after a powerful and even more prolonged exposure, patients, in particular cancer, experience general malaise, dizziness, and nausea.

But it is also possible such an effect of electromagnetic radiation on the irradiated organism, in which the temperature increase is insignificant (less than 0.1 ^o C) and it does not turn out to be the main factor in achieving a beneficial effect. Due to a number of features of the interaction of these electromagnetic waves with various objects, their use in biology and medicine is unique.

 The closest in technical essence and the achieved result to the described invention is a method of influencing biological objects, which consists in the fact that biological objects are irradiated with electromagnetic radiation of superhigh frequency (O. V. Betsky, M. B. Golant, N. D. Devyatkov. Millimeter waves in biology. Subscribed popular science series. PHYSICS, Knowledge: M., 6/1988, p. 5, 19-22).

 The known method eliminates the hyperthermic effect on objects, but has a significant impact on the life of various organisms (from microorganisms to mammals) due to the frequency-dependent effect of the interaction of electromagnetic microwave radiation with biological objects. In particular, such radiation is useful in the treatment of cancer, when it not only promotes the resorption of tumors, but also plays a protective role in relation to the hematopoietic system, weakening the toxic effect of chemicals, x-rays used in the treatment of cancer.

 However, along with positive factors, the known method and device do not allow to fully realize their advantages, since the actual degree of damage to malignant neoplasms, transformed cells, and other cellular structures of tumor cells is not large enough, which is due, for example, to the sequential re-reflection of an electromagnetic wave from an irradiated object. In addition, in this case, the specificity of the effect on the tumor cells in comparison with normal cells is not ensured.

 In addition, the effectiveness of electromagnetic radiation on an object depends on the initial state of the object. If in the initial state some function of the object is changed compared to the normal state, then irradiation at some frequency will lead to different results after irradiation, which also reduces the efficiency of the application of the known method and device.

 The objective of the invention is to provide a method and device for influencing biological objects with electromagnetic radiation of ultrahigh frequency, with increased effectiveness, especially in the treatment of neoplasms, bacterial and viral infections, including both malignant and benign tumors of any nature.

 As a result of solving this problem, new results can be obtained, consisting in the fact that the degree of damage to neoplasm cells is significantly increased, and the impact stability is increased regardless of the initial state of the object.

These technical results are achieved in that the method of influencing biological objects consists in the fact that biological objects are irradiated with ultrahigh frequency electromagnetic radiation simultaneously by five generators connected to radiating antenna means, the frequency of the first generator being chosen from 1058 MHz to 1194 MHz, the second from 901 MHz to 1017 MHz, the third from 515 MHz to 581 MHz, the fourth from 400 MHz to 451 MHz, the fifth from 109 MHz to 124 MHz, and the intensity of the electromagnetic radiation generated by the generators at the location of the facility, is from 0.3 μW / cm ² to 10 μW / cm ² .

The device for influencing biological objects, containing a generator of electromagnetic radiation of superhigh frequency connected to a radiating antenna means, further comprises at least four generators of electromagnetic radiation of superhigh frequency connected to a radiating antenna means, and the frequency of the first generator is selected from 1058 MHz to 1194 MHz the second from 901 MHz to 1017 MHz, the third from 515 MHz to 581 MHz, the fourth from 400 MHz to 451 MHz, the fifth from 109 MHz to 124 MHz, and the electromagnetic power intensity th radiation generated by the generators at the site of location of the object is 0.3 mW / cm ² to 10 mW / cm ^2.

A distinctive feature of the described invention is that obtaining a qualitatively new level of exposure to electromagnetic radiation of ultrahigh frequency is provided when using at least five generators operating simultaneously with different frequency ranges. Moreover, it unexpectedly turned out that the above results will be realized only if the frequency of the first oscillator is 1058 MHz to 1194 MHz, the second from 901 MHz to 1017 MHz, the third from 515 MHz to 581 MHz, and the fourth from 400 MHz to 451 MHz, the fifth - from 109 MHz to 124 MHz, and the intensity of the electromagnetic radiation generated by the generators at the location of the object is from 0.3 μW / cm ² to 10 μW / cm ² .

 The above five frequency ranges of electromagnetic radiation characterize the threshold level of exposure to electromagnetic radiation on a biological object, providing suppression of the multiplication of tumor cells, including malignant ones. Moreover, the choice of a specific frequency from any range does not depend on the choice of specific frequencies in other ranges, and in each of the frequency ranges several generators can be used.

When the intensity of the radiation power of electromagnetic radiation of ultrahigh frequency at the location of the object is less than 0.3 μW / cm ² , the impact efficiency drops sharply due to the insignificant energy effect of electromagnetic radiation on the biological object.

If the intensity of the radiation power of electromagnetic radiation of ultrahigh frequency at the location of the object is more than 10 μW / cm ² , then the initial effects of hyperthermia begin to appear, suggesting heating of the irradiated structure. As a result, the physical properties (dielectric constant, electrical conductivity, etc.) of a biological object change as a medium in which an electromagnetic wave propagates, and, therefore, the nature of the described effect on a biological object changes.

 It is also advisable to increase the efficiency of the influence of ultra-high frequency electromagnetic radiation on a biological object, along with the five main sources of electromagnetic radiation, use additional generators that generate electromagnetic radiation with frequency ranges: from 1419 MHz to 1682 MHz and / or from 1201 MHz to 1347, and / or from 660 MHz to 764 MHz, and / or from 583 MHz to 638 MHz, and / or from 453 MHz to 509 MHz, and / or from 263 MHz to 327 MHz, and / or from 201 MHz to 227 MHz, and / or from 84 MHz to 96 MHz, and / or from 42 MHz to 48 MHz, and / or from 34 MHz to 40 MHz, and / or from 15 M Hz to 17 MHz.

 Moreover, additional generators of electromagnetic radiation can be used in any combination with five main generators. It is possible, for example, the combined use of five main generators and any one additional, or five main generators and any part of additional generators, or five main and all additional generators.

 In addition, it is advisable to irradiate biological objects with electromagnetic radiation for 1 to 6 hours, and choose the location of biological objects at a distance of 2 m to 8 m from the radiating antenna means, which can be located around the biological object.

 The drawing shows a General structural diagram of a device for influencing biological objects.

 The described method and device are implemented as follows. The device 1 for influencing biological objects contains at least five main generators 2, which create electromagnetic radiation in the corresponding emitting antenna means 3 with ranges from 1058 MHz to 1194 MHz, from 901 MHz to 1017 MHz, from 515 MHz to 581 MHz, from 400 MHz up to 451 MHz and from 109 MHz to 124 MHz, respectively. The device 1 may contain additional generators 4 connected to additional radiating antenna means 5. The number of additional generators, as well as additional radiating means 5 must be at least eleven, which corresponds to the number of additional frequency ranges of electromagnetic radiation. But within any frequency range, several generators of electromagnetic radiation can be involved. Each generator 2 and generators 4 are connected to control units 6, which are connected to a common control panel 7.

Before exposure to the biological object begins, the radiating antenna means 3 connected to the main generators 2 and, if necessary, the radiating antenna means 5 connected to the additional generators 4 are placed in the direction of the biological object, preferably around the location of the object. Using control units 6, each generator 2 is tuned to one of the frequencies of one of the five main frequency ranges of electromagnetic radiation, and the power generated by the generators is also selected so that the intensity of the electromagnetic radiation power at the site of the object is at least 0.3 μW / cm ² and not more than 10 μW / cm ² .

 Monitoring the process of exposure and adjusting the modes of electromagnetic radiation can be done using a common remote control 7, as well as directly by the control units 6.

 Similarly, the installation and configuration of additional generators 4.

 As generators 2 and generators 4, you can use any known device with the necessary characteristics that provide the above modes of their operation, for example, G4-176 generators with a frequency range from 0.1 MHz to 1020 MHz, as well as G4-193 generators with a working frequency range from 1 GHz to 4 GHz or HEWLETT-PACKARD generators HP 8643, HPESG. As radiating antenna means 3, it is advisable to use symmetric half-wave vibrators tuned to the selected frequency of exposure to electromagnetic radiation. The control panel 7 and control units 6, as a rule, are component parts and are used in conjunction with electromagnetic radiation generators, and their creation is an obvious task for a specialist.

 The choice of frequencies of electromagnetic radiation of the main generators 2, as well as the number and frequencies of additional generators 4, exposure time and intensity of the electromagnetic radiation power at the location of the object is based on simple experiments.

 Below are examples illustrating the implementation of the described method using the proposed device.

Example 1. Patient S., 54 years old. With a diagnosis of cancer of the upper ampulla of the rectum, stage IV, sick 1 year, had not previously been treated. Histologically - an adenocarcinoma, in the lungs on the radiograph - solitary metastasis in the right lung with a diameter of 1.3 cm, ultrasound (ultrasound) revealed the germination of the primary tumor in the bladder. In connection with several diseases, surgery is not possible. A course of gamma-therapy with a total dose of 32 Gy per primary tumor and a course of exposure to electromagnetic radiation for 3 days for four hours was prescribed. Irradiation was carried out at the following frequencies, selected from the ranges of the five main frequencies: 1058 MHz, 901 MHz, 547 MHz, 451 MHz and 124 MHz, as well as at additional frequencies: 1419 MHz, 1347 MHz, 509 MHz and 17 MHz. Moreover, the intensity of the electromagnetic radiation power at the patient’s location (medical couch) was: from the first generator - 0.3 μW / cm ² , from the second generator - 10 μW / cm ² , from the third generator - 1.5 μW / cm ² , the fourth generator - 6 μW / cm ² and from the fifth generator - 8.3 μW / cm ² . The average intensity of the electromagnetic radiation power of the additional generators 4 was 3.2 μW / cm ² .

 One week after the start of irradiation, when the effect of gamma therapy could not yet manifest, the patient disappeared pain in the sacrum and rectum. According to ultrasound data, after completing a course of gamma therapy in combination with irradiation with electromagnetic radiation simultaneously at the above five frequencies of the primary tumor and metastasis (which was not exposed to gamma therapy) - "stabilization of the process." This made it possible to successfully conduct more radical operations for patient Sh.

Example 2. Patient G, 45. Upon admission, the diagnosis is breast cancer, stage IV, multiple metastases in the liver, ovaries, peripheral lymph nodes, ascites. The patient has severe cachexia, pain, prescribing drugs is required. A course of exposure to electromagnetic radiation was prescribed for 5 days for two hours daily. Irradiation was carried out using the main generators 2 at frequencies: 1194 MHz, 940 MHz, 515 MHz, 400 MHz and 118 MHz and the intensity of electromagnetic radiation at the patient’s location - 4 μW / cm ² , 9.3 μW / cm ² , 5 μW / cm ² , 2.5 μW / cm ² and 0.4 μW / cm ^2, respectively, as well as using one additional generator 4 with a frequency of 89 MHz with an electromagnetic radiation power intensity of 9.5 μW / cm ² . The course of exposure, taking into account the severity of the disease, was five days, 6.5 hours a day. Then, after a two-week break, a second course of exposure was carried out according to the original scheme, but with the addition of another generator with an irradiation frequency of 44 MHz and an intensity of electromagnetic radiation power of 0.75 μW / cm ² . After the first course, stabilization of the process, the cessation of pain, the absence of ascites growth were noted. The patient practically does not need narcotic drugs. Repeated observation after the second course of exposure to electromagnetic radiation, conducted after 2 and 5 months, confirmed the stabilization of the tumor process without progression of the underlying disease. Symptomatic treatment is carried out without the use of drugs.

Example 3. Patient K., 80 years old. Diagnosis: laryngeal pharynx cancer, stage III, histologically low-grade squamous cell carcinoma. Upon admission, the tumor was found to be inoperable; radical treatment was not performed. A course of exposure to electromagnetic radiation for three days for 3 hours. Irradiation was carried out by five generators 2 at frequencies of 1128 MHz, 960 MHz, 581 MHz, 423 MHz and 109 MHz with an intensity of electromagnetic radiation power: 10 μW / cm ² , 7 μW / cm ² , 0.45 μW / cm ² , 5.5 μW / cm ² and 0.3 μW / cm ² respectively, as well as eight additional 4 generators at frequencies: 1682 MHz, 1201 MHz, 638 MHz, 456 MHz, 327 MHz, 213 MHz, 48 MHz and 15 MHz, respectively electromagnetic radiation power - 4.5 μW / cm ² . A follow-up examination after 5 months showed that the tumor decreased in size, regional lymph nodes were not enlarged. The patient was offered a radical operation, from which he refused. The patient left the clinic with positive results after exposure to electromagnetic radiation and was sent under the supervision of an oncologist.

Example 4. Patient G., 60 years old. He was admitted with a diagnosis of a condition after resection of the rectum and sigmoid colon 3 years earlier, with colostomy for stage III rectal cancer, and liver metastases. A course of exposure to electromagnetic radiation by six main generators 2 was carried out at frequencies: 1017 MHz, 901 MHz, 547 MHz, 425 MHz, 109 MHz and 117 MHz, respectively, with an average radiation power intensity of 6.5 μW / cm ² , as well as electromagnetic radiation generated by four 4 additional generators at frequencies: 660 MHz, 583 MHz, 263 MHz and 40 MHz with an average radiation power intensity at the patient's location of 9.2 μW / cm ² for five days for 6 hours daily. After a course of exposure to ultra-high frequency electromagnetic radiation, the patient's condition is satisfactory, with ultrasound, the formation in the liver is not determined.

Example 5. Patient K., 15 years old. The diagnosis is osteogenic sarcoma of the lower third of the right femur, the diagnosis is histologically confirmed. A course of exposure to electromagnetic radiation for seven days for 4 hours. Irradiation was carried out at five frequencies selected from the main frequency ranges: 1145 MHz, 995 MHz, 565 MHz, 451 MHz and 118 MHz with an average radiation power intensity of 0.35 μW / cm ² and simultaneously using eleven generators 4 at the following frequencies: 1580 MHz, 1165 MHz, 764 MHz, 453 MHz, 263 MHz, 201 MHz, 96 MHz, 42 MHz, 46 MHz, 34 MHz and 16 MHz with an average radiation power intensity at the patient's location of 3.5 μW / cm ² .

 After a course of exposure, the patient's condition improved significantly, the effect of anesthesia and stabilization of tumor growth was observed. The effect of electromagnetic radiation was considered as positive and adjuvant for subsequent chemotherapy.

Industrial applicability
Thus, the described method and device for influencing biological objects can be practically implemented and used to inhibit the growth of neoplastic cells and to resorb necrotic tissue cells, which increases the effectiveness of the treatment of diseases.

Claims (9)

1. The method of exposure to biological objects, which consists in the fact that biological objects are irradiated with electromagnetic radiation of superhigh frequency, characterized in that biological objects are irradiated with electromagnetic radiation of superhigh frequency simultaneously by five generators connected to radiating antenna means, and the frequencies of the first generator are chosen equal to 1058 - 1194 MHz, the second - 901 - 1017 MHz, the third - 515 - 581 MHz, the fourth - 400 - 451 MHz, the fifth - 109 - 124 MHz, and the electromagnetic radiation power intensity Produced by the generators at the site of location of the object, is 0.3 - 10 mW / cm ^2.  2. The method according to claim 1, characterized in that biological objects are additionally irradiated with at least one generator of electromagnetic radiation of superhigh frequency coupled to radiating antenna means, the frequency of additional generators being chosen equal to 1419 - 1682 MHz, and / or 1201 - 1347 MHz, and / or 660 - 764 MHz, and / or 583 - 638 MHz, and / or 453 - 509 MHz, and / or 263 - 327 MHz, and / or 201 - 227 MHz, and / or 84 - 96 MHz, and / or 42 to 48 MHz, and / or 34 to 40 MHz, and / or 15 to 17 MHz.  3. The method according to claim 1 or 2, characterized in that biological objects are irradiated with electromagnetic radiation of ultra-high frequency for 1 to 6 hours  4. The method according to claims 1, 2, or 3, characterized in that the location of biological objects is selected at a distance of 2 to 8 m from the radiating antenna means.  5. The method according to PP.1, or 2, or 3, or 4, characterized in that the radiating antenna means are placed around the biological object. 6. The device for influencing biological objects, containing a generator of electromagnetic radiation of superhigh frequency connected to a radiating antenna means, characterized in that it further comprises at least four generators of electromagnetic radiation of superhigh frequency connected to a radiating antenna means, the frequency of the first generator selected equal to 1058 - 1194 MHz, the second - 901 - 1017 MHz, the third - 515 - 581 MHz, the fourth - 400 - 451 MHz, the fifth - 109 - 124 MHz, and the electromagnetic radiation power intensity Nia generated generators at the location of the object, is 0.3 - 10 mW / cm ^2.  7. The device according to claim 6, characterized in that it further comprises at least one microwave generator of electromagnetic radiation connected to the radiating antenna means, the frequency of the additional generators being chosen equal to 1419 - 1682 MHz, and / or 1201 - 1347 MHz, and / or 660 - 764 MHz, and / or 583 - 638 MHz, and / or 453 - 509 MHz, and / or 263 - 327 MHz, and / or 201 - 227 MHz, and / or 84 - 96 MHz, and / or 42 to 48 MHz, and / or 34 to 40 MHz, and / or 15 to 17 MHz.  8. The device according to claim 6, or 7, characterized in that the radiating antenna means are installed at a distance of 2 to 8 m from the location of biological objects.  9. The device according to claims 6, 7, or 8, characterized in that the radiating antenna means are located around the biological object.