RU2107486C1 - Method and device for determining optimum value of therapeutic frequency of patient in performing extremely high frequency acupuncture therapy - Google Patents

Abstract

FIELD: medicine; medical engineering. SUBSTANCE: method involves acting with electromagnetic radiation of variable frequency upon the biologically active point area in invasive way. Frequency is measured that corresponds to maximum absorbed radiation power in the biologically active point by determining the frequency sought for from minimum value of standing voltage wave coefficient. The device has electromagnetic power supply source, discrimination device, wave guide tract, indication member, emitter. The electromagnetic power supply source has extremely high frequency oscillator, power supply source unit, control unit, saw-tooth voltage generator with controllable constant level of voltage. The emitter is wave guide line transformer sending signals into open line having conductor. The external conductor has its open end placed on the epicutaneous projection of the biologically active point. The opposite ends of the external and internal conductors are short circuited on extremely high frequency. The short circuit on extremely high frequency is carried out through structural low frequency filter. EFFECT: enhanced accuracy in determining therapeutic frequency; enhanced effectiveness of treatment. 11 cl, 6 dwg

Description

 The invention relates to medicine, namely to reflexology and can be used in dotted EHF-therapy.

 A known method of treating osteochondrosis and a device for its implementation (see US Pat. USSR N 1807872, A 61 H 39/00, A 61 N 5/06, publ. 1993), including the impact on the corporal acupuncture point of the patient’s da-jui electromagnetic waves of the millimeter range with a frequency of 59-62 GHz, with a power of 1-10 mW for 30 min, while the optimal value of the therapeutic frequency is set according to the initial stage of muscle fibrillation in the pathological zone.

 The determination of the resonant (i.e., therapeutic frequency at which the treatment is carried out in the indicated method) is based on obtaining the patient’s sensory response when exposed to an EHF signal that varies in frequency.

 The disadvantage of this method of determining the therapeutic frequency is the length of the procedure for obtaining a sensory response to the desired frequency, the low accuracy of determining this frequency, and in some cases the impossibility of determining it due to the lack of communication with the patient (for example, children, certain types of patients) and due to the subjectivity of the method .

 A known method for determining the therapeutic frequency for exposure to biological tissues by irradiating them with electromagnetic waves of the millimeter range with the creation of standing waves along the distance between tissue sections with a maximum change in its state (see AS USSR N 1209239, A 61 N 5/02, publ. . 1986).

 The disadvantages of the method are: firstly, the duration; - the measurement result can be determined only after exposure to electromagnetic radiation, and the exposure should be long enough for biological changes to occur in the tissues; secondly, complexity, since it includes not only irradiation with electromagnetic waves, but also subsequent biological, physical or chemical methods of measuring changes in tissues; thirdly, the low accuracy of the method, because to determine the wavelength it is necessary to know the value of the dielectric constant of the investigated tissue; fourthly, the feasibility of this method on complex biological systems, for example, man, is doubtful.

A known method for the treatment of inflammatory diseases of the biliary system by exposure to low-intensity electromagnetic radiation of extremely high frequencies on the projection area of corporal acupuncture points for 10 min with a power density of 1 to 3 mW / cm ² , including the search for the resonant frequency of electromagnetic radiation from the patient’s sensory response in the frequency range 59 5 - 61.5 GHz (see AS USSR N 1697804, A 61 H 39/00, A 61 N 2/00, publ. 1991).

 The disadvantage of this method is the duration of determining the therapeutic frequency from the patient's sensory response, as well as the subjectivity of such a determination.

 There is also a method for the automated search for the optimal value of the therapeutic frequency of a patient according to the reaction of his body by irradiating the skin projection of a biologically active point with millimeter-wave electromagnetic radiation, followed by recording the patient's sensory sensations with an electroencephalograph with an α-Δ filter - rhythm, implemented using an EHF-therapy device (see USSR AS N 1711920, A 61 N 5/02, publ. 1992), in which the output of the encephalograph is connected to the control input of the EHF generator.

 The disadvantage of this method is its complexity due to the need for a combination of electrophysiological and radio engineering measurement methods for an objective, according to the testimony of the encephalograph definition of therapeutic frequency.

 In addition, the use of an electroencephalograph significantly reduces the noise immunity of the device for EHF therapy that implements this method, namely: various external stimuli, for example, sound, tactile, light, as well as mental work of the patient, cause a change in the parameters of the α-Δ rhythm, which introduces the method is an element of subjectivity (see V. A. Berezovsky, N. N. Kolotilov. Biophysical characteristics of human tissues (reference). - Kiev: Naukova Dumka, 1990, p. 39).

P_(погл) = 42%, а отраженная мощность соответственно P_(отр) = 58% падающей мощности (см., например, И.В.Лебедев. Техника и приборы СВЧ. Под ред. акад. Н.Д.Девяткова, Москва, Высшая школа, 1970 г., т. 1, стр. 187 и 211);
б) при облучении индифферентного участка поверхности кожи (т.е. не содержащего проекций БАТ) КСВ = 6,35 ± 0,11, что соответствует P_(погл) = 47% и P_(погл) = 53% от падающей мощности;
в) при облучении накожной проекции БАТ КСВ составил 6,1 ± 0,12, что соответствует P_(погл) = 49% и P_(отр) = 51% от падающей мощности.Closest to the proposed method is a method for determining the optimal value of the therapeutic frequency of the patient with punctured EHF-therapy by minimizing the standing wave coefficient (SWR). (The hardware complex "Electronics-EHF" and its use in medicine, under the editorship of Corresponding Member of the USSR Academy of Sciences L. G. Gassanova, M., 1991, pp. 10-17), which is selected as a protopip. The prototype method includes exposure to electromagnetic radiation of a millimeter wavelength range of non-thermal intensity with a varying frequency on the skin projection of a biologically active point (BAP) of the patient. In this case, the desired therapeutic frequency is determined by the minimum value of the standing wave coefficient. When implementing the prototype method, the values of the SWR and the corresponding absorbed power values were:
a) upon irradiation of free airspace, the SWR = 7.45 ± 0.16, which means that the absorbed power is

P _(float) = 42%, and the reflected power, respectively, P _(neg) = 58% of the incident power (see, for example, I.V. Lebedev. Microwave equipment and devices. Edited by academician ND Devyatkova, Moscow Higher School, 1970, vol. 1, p. 187 and 211);
b) upon irradiation of an indifferent part of the skin surface (i.e., which does not contain BAP projections) KSV = 6.35 ± 0.11, which corresponds to P _(damp) = 47% and P _(damp) = 53% of the incident power;
c) during irradiation of the cutaneous projection BAT, the SWR amounted to 6.1 ± 0.12, which corresponds to P _(m) = 49% and P _(neg) = 51% of the incident power.

The disadvantage of the prototype method is that the accuracy of determining the frequency of resonant absorption (i.e., the desired therapeutic frequency) in the BAP is too low, due to insufficient matching of the EHF emitter with the load, which is not used in the BAP itself, but the area of its projection on the skin . The lack of coordination with BAP (with a large SWR of about 6 or more) in the prototype is explained by the strong attenuation of the EHF signal in the skin and muscle tissue. So, for points at a depth of 5 - 10 mm from the skin surface, the attenuation of the EHF signal is of the order of 50 - 100 dB for the incident power and 100 - 200 dB for the reflected power, which greatly complicates the measurement of the power reflected from the BAP at non-thermal levels of the incident power ( less than 10 mW). As follows from the values of the SWR given in the prototype, the difference in the SWR values obtained when exposed to the indifferent section and the BAP projection is very insignificant and in boundary values is 0.02 with a reduced measurement error of 0.12, which indicates a very low accuracy and actually the unreliability of such measurements. In addition, it is known (see, for example, ND Devyatkov, O.V. Betsky, E. A. Gelvich, "The influence of electromagnetic oscillations of the millimeter wavelength range on biological systems", Publishing House of the USSR Academy of Sciences, Radiobiology, t . 21, N2, 1986, pp. 163 - 171) that the interaction of EHF radiation with the BAP has a clearly pronounced resonant character in a narrow frequency band Δf
(Δf ≤ 10 ^-2 -10 ^-4 ) • f _o ,
where f _o is the central resonant frequency, which is the therapeutic frequency in EHF-therapy.

 Thus, the radiation power absorbed in the BAP in the narrow frequency band Δf should significantly (at least several times) differ from the absorbed power outside this frequency band and from the absorbed power in the indifferent section. However, in the prototype method, the resonance absorption in the BAP due to the insufficient accuracy of the method was not achieved, which is noted on page 14 of the description of the prototype, and the therapeutic frequency can only be said conditionally, which is not possible when using the therapeutic frequency obtained by the prototype method pronounced therapeutic effect with punctured EHF-therapy.

 A device for the treatment of osteochondrosis of the spine in the cervical region (see US Pat. USSR N 1807872, A 61 H 39/00, A 61 N 5/06, publ. 1993), containing a microwave generator and a microwave unit, consisting of main and control channels. The main channel includes a series-connected directional coupler, a variable attenuator, a waveguide transition and a flexible dielectric waveguide with a horn emitter at the end. The control channel included in the secondary branch of the directional coupler contains serially connected installation attenuator, absorption wave meter, microwave detector and indicator.

 A device for stimulating vital processes in living tissues (see AS USSR N 1426584, A 61 H 39/00, A 61 H 1/42, publ. 1988), containing a high-frequency generator, a transmitting line and a radiator, made in the form of a hollow truncated quadrangular pyramid with an open working end, inside of which a matching dielectric element is located along the entire length, made in the form of a quadrangular pyramid with a base coinciding with the working end and a vertex matching one of the corners of the base of the truncated pyramid.

 Mentioned devices contain emitters of various designs, with the help of which they effect electromagnetic radiation on the skin projection of biologically active points (BAP).

 These devices do not allow to implement a new method for objectively determining the optimal therapeutic frequency for punctured EHF-therapy without using additional information processing methods.

 Closest to the proposed device is a device for microwave therapy, containing a source of electromagnetic energy, consisting of an EHF generator, power supply and control units, an emitter made coaxially in the form of an end part of a flexible line and a shielding metal cup connected through a flexible line to the EHF generator. The control unit of the electromagnetic energy source includes an EHF power meter and an EHF power stabilization system. The emitter is made with a sealed cavity connected to a source of adjustable reduced pressure, and is equipped with an elastic membrane restricting the sealed cavity of the emitter from the side of the working end, and the flexible line is made in the form of a flexible dielectric waveguide (see AS USSR N 1681856, A 61 H 39/00, publ. 1991).

 Due to the special design, the emitter in the said device is in good agreement with the external surface of the biological tissue, that is, the skin projection of the acupuncture point in the working frequency range.

 The disadvantage of this device is the inability to determine the optimal therapeutic frequency of the patient by determining the resonant frequency of absorption of EHF energy directly biologically active point. This is due to the large attenuation of EHF energy in biological tissues (see V. A. Shestiperov. New directions in the use of microwave frequencies in biology and medicine. - Electronic Industry, 1982, issue 8 (114), pp. 56 - 63), which does not allow matching the EHF emitter directly with the BAT.

 In addition, these devices implement a method for determining the therapeutic frequency of a patient, based on irradiation of the cutaneous projection of puncture points with EHF energy, according to which the incident power directly at the biologically active point is uncontrolled, since it strongly depends on the condition of the patient’s skin and from the state of biological tissues.

 Thus, the implementation of the proposed new method for determining the therapeutic frequency with punctured EHF-therapy is impossible in any of the known devices for microwave therapy.

 The aim of the invention is to increase the accuracy of determining the optimal value of the therapeutic frequency of the patient with punctured EHF-therapy by increasing the coordination of the EHF emitter with BAP. The criterion for increasing matching is to reduce the SWR at a biologically active point to values corresponding to the ideal matching of the emitter with a load close to unity.

 The next goal is to increase the efficiency of exposure to EHF radiation on the biologically active points of the patient by choosing the optimal therapeutic frequency for each BAT.

 The essence of the proposed method for determining the optimal value of the therapeutic frequency for punctured EHF-therapy is that it, like the prototype method, includes exposure to non-thermal intensity electromagnetic waves of millimeter wavelengths with a varying frequency on a biologically active point, followed by measurement of the standing voltage wave coefficient while the desired frequency is determined by the minimum value of the standing wave coefficient.

 New in the proposed method is that the impact on the biologically active point is carried out invasively.

 The essence of the proposed device for influencing a biologically active point during punctured EHF-therapy is that it, like the prototype device, contains an electromagnetic radiation source consisting of an EHF generator and power and control units, as well as a decoupling device, a waveguide path , indicator and emitter.

 New in the proposed device is that the emitter is made in the form of a transformer of a waveguide transmission line to an open TEM line at one end, the outer conductor of which is open-ended at the skin projection of the biologically active point, and the open end of the inner conductor is invasively installed directly into the biologically active point, and the ends of the outer and inner conductors opposite the biologically active point are short-circuited along the EHF, while the first input yvayuschego device connected to the output of the EHF oscillator, the second input of the decoupling device via the waveguide path is connected to the input transducer and the output of the isolating device is connected to the input of the indicator to determine the ratio of the reflected biologically active point and incident on the biologically active point capacity.

 In one particular case in the device, a short circuit of the ends of the outer and inner conductors opposite from the area of the biologically active point is made in the form of a low-pass filter.

In another particular case, the inner conductor of the emitter is dielectric coated with the exception of the open end not covered by an amount equal to half the radiation wavelength in free space. In the present invention, a good (with SWR <2) matching is achieved, in contrast to the prototype, an EHF emitter with any biologically active point in a wide range of extremely high frequencies f (from 50 GHz to 80 GHz) due to the invasive effect on the BAP, since it is invasive the internal conductor of the TEM line is highly conductive for EHF radiation. This allows the EHF radiation to be transmitted to the BAP and the EHF signal back to the recording equipment when scanning the frequency f through the absorbing tissue with minimal attenuation. In contrast to the prototype, the EHF signal coming back to the indicator in the present invention contains information on the resonant absorption of the biologically active point of EHF radiation in a narrow frequency band Δf [Δf = (10 ^-2 -10 ^-4 ) • f _o ], which allows you to accurately determine the resonant frequency f _o , which is the desired therapeutic frequency. In the developed method, the characteristic value of SWR and BAP at the moment of resonance absorption is 1.1 ± 0.1, which corresponds to the power absorbed in the BAP P _(damp) = 99.75% and the reflected power P _(neg) = 0.25% of the incident . The characteristic value of the SWR in the BAP in the absence of resonance absorption (i.e., when the frequency is tuned off by f _o by Δf) is 10 ± 0.27, which corresponds to P _(deg) ≤ 20% and P _(neg) ≥ 80% of the incident power. Since the SWR measurements are based on the reflected signal, it is clear that the contrast of measurements, i.e. the ratio of P _(neg) out of resonance to P _(neg) at the moment of resonance is very high - about 300. In the prototype, the contrast of measurements, i.e. the ratio of P _(neg) in the area of the projection of BAP to P _(neg) in the indifferent area is very low and leaves 1.02. In the prototype, due to the lack of matching of the emitter directly with the BAP, when determining the therapeutic frequency, the region Δf of frequencies with resonant absorption of radiation energy was not detected at all, and only a slight smooth decrease in SWR in a wide frequency range (about 6 GHz) in the BAP projection region was observed compared to indifferent plot. Thus, the proposed method can significantly improve the accuracy of determining the optimal value of the therapeutic frequency of the patient, this, in turn, provides higher efficiency of therapeutic effects with dashed EHF-therapy.

 In FIG. 1 shows a block diagram of a device; in FIG. 2 - emitter design; in FIG. 3 - a characteristic form of the dependence of the SWR in the BAT when changing the frequency f of the source of EHF radiation.

 A device for determining the value of the therapeutic frequency of the patient contains a source of electromagnetic energy 1, a decoupling device 6, a waveguide path 7, an indicator 8, an emitter 9.

 The electromagnetic energy source 1 consists of an EHF generator 2, a power supply 3, a control unit 4, a sawtooth voltage generator 5 with an adjustable constant voltage level.

 The decoupling device 6 serves to separate the incident on the biologically active point and the power reflected from it.

 The waveguide path 7 is designed to transfer EHF energy from the generator 2 to the emitter 9.

 Indicator 8 is used to measure and display the magnitude of the ratio of incident and reflected power.

 The emitter 9 (see Fig. 2) is a transformer of the waveguide transmission line to the open at one end of the TEM line 10, which has two conductors. The outer conductor 11 with its open end is placed on the cutaneous projection of the BAT. The open end of the inner conductor 12 is invasively mounted directly into the BAP region. The opposite ends of the outer and inner conductors are short-circuited by EHF, and a short-circuit by EHF is carried out through the low-frequency filter 13.

,
где
τ_фр. - длительность фронта импульса электропунктуры.To be able to measure the therapeutic frequency under the combined effects of EHF and electric puncture, an EHF short circuit is carried out through a low-pass filter 13, while the low-pass filter parameters are selected from obvious conditions: the cut-off frequency of the low-pass filter (F) is determined by the ratio

,
Where
τ _fr - the duration of the pulse front of the electric puncture.

 A specific feature of the distribution of EHF energy in the proposed emitter is a rather significant attenuation of ≈ 0.1 dB / mm due to leakage of EHF energy from the internal conductor to the body tissues with high conductivity. This attenuation can be reduced by coating the inner conductor with a dielectric layer, and its dielectric constant should be as small as possible, significantly less than the dielectric constant of the fabric, and the thickness of the dielectric layer as large as possible, while remaining much less than the diameter of the inner conductor, to reduce capacitive currents leaks.

 The open end of the inner conductor of the emitter remains uncovered at half the wavelength in free space. The reduction of the attenuation in the emitter in this way increases the accuracy of determining the therapeutic frequency by increasing the EHF power reflected from the BAP region.

 The method is as follows.

 Invasively, in accordance with the law of classical acupuncture, the open end of the inner conductor 12 of the emitter 9 is installed (see Fig. 2) in the selected BAP, the outer conductor 11 is on the skin projection of the BAP of the patient, the emitter is connected to other blocks of the device shown in FIG. 1. Switch EHF generator 2, selecting the amplitude of the sawtooth voltage such that the frequency f of the EHF generator varies within predetermined limits, for example, 50 - 80 GHz. The indicator 8 measures the dependence of the SWR on the frequency f of the EHF radiation. This dependence is displayed on the indicator screen, the sweep frequency of which is synchronized with the frequency of the sawtooth generator.

On the screen of indicator 8, the moment of resonant absorption of EHF radiation is recorded, which is characterized by a sharp (several-fold) decrease in the SWR in a narrow frequency band Δf ((Δf = (10 ^-2 ± 10 ^-4 ) • f _o ),), where f _o - central resonant frequency), see FIG. 3. The minimum value of the SWR on the resonance curve determines the frequency f _o resonant absorption of BAP, which is the desired optimal therapeutic frequency. In a specific example, for patient C., at the biologically active point RP6, the optimal frequency f _o = 61 GHz was obtained.

 In the developed method for determining the therapeutic frequency, due to the invasive effect of the radiation source 1 on the BAP, good (with SWR <2) matching of the EHF emitter with the BAP is achieved, which makes it possible to observe on the screen of the indicator 8 a resonant response characteristic of the BAP at a frequency specific for each BAP.

Measurement of the central frequency f _{o of the} resonance curve by minimizing the SWR is not difficult, therefore, the developed method allows one to determine the frequency of resonance absorption with high accuracy (≈ 0.1%), i.e. the desired optimal therapeutic frequency. The measurement is carried out quickly, practically during one sweep period and objectively, since it does not depend on either the doctor or the patient.

 The accuracy of determining the optimal value of the therapeutic frequency of the patient by the proposed method is determined by purely hardware measurement error, which does not exceed 0.1%.

 The device operates as follows.

 The electromagnetic radiation source 1 generates EHF oscillations, the frequency of which varies linearly using a sawtooth voltage generator 5.

 The EHF signal through the decoupling device 6, the waveguide path 7 and the emitter 9 acts directly on the BAT. Part of the incident power through the first output of the decoupling device 6 is fed to the input of the indicator 8. The power reflected from the BAP through the emitter 9, the waveguide path 7 is fed to the second input of the decoupling device 6, which is also the output for the radiated power. Indicator 8 measures the ratio of reflected and incident power.

 Due to the location of the open end of the inner conductor 12 directly in the BAP, and the open end of the outer conductor 11 on its skin projection, the emitter 9 is consistent with the BAP itself, and not with its skin projection, as in the prototype method and other known methods. Therefore, when the emitter frequency f changes at frequencies Δf corresponding to the resonant absorption of the BAP, the main part of the EHF power is absorbed by the BAP, and the reflected power is minimal. At other frequencies beyond Δf, the reflected power increases and the absorbed power decreases.

 Thus, when changing the frequency f of electromagnetic EHF energy, indicator 8 shows the frequency dependence of the SWR and allows you to determine the frequency f of the resonant absorption of EHF radiation with high accuracy, that is, the optimal therapeutic frequency necessary for an effective therapeutic effect.

 To date, the optimal therapeutic frequency has been considered the frequency corresponding to the occurrence of the patient's sensory response.

 It was experimentally established by examining 294 patients that the frequency of resonance absorption coincides with the frequency of sensory sensations. With a change in frequency and a constant power level, sensory sensations disappeared in all cases. According to patients, the strength of sensory sensations also changed smoothly with a change in the power level at the resonant frequency.

 Examples of the implementation of the proposed method for determining the optimal value of the therapeutic frequency for punctured EHF-therapy are given on the basis of extracts from the patient history of patients of the endocrinological and nephrological departments of the regional hospital named after Semashko, Nizhny Novgorod.

Example 1. Patient A., 54 years old. Case history N 9403651. Clinical diagnosis: diabetes mellitus, type II, secondary insulin dependence, subcompensated, complicated by diabetic polyneuropathy, angioritinopathy, nephropathy. Concomitant diagnosis: chronic stoneless cholecystitis. Patient A. was determined according to the proposed method the optimal value of the therapeutic frequency for each of the 5 dashed symmetrical points TR5, RP4, F3, R3 and E36, known from classical reflexology and chronorhythmology, taking into account the time of activity of the channels and specific symptoms of the patient. To implement the method sequential from point to point in each of the ten above-mentioned biologically active points, the open end of the inner conductor 12 of the emitter 9 is invasively installed (see Fig. 2), and the outer conductor 11 is installed on the cutaneous projection of the selected point. Then they act with the aid of an EHF generator 2 on the selected BAT by electromagnetic radiation of the millimeter wavelength range with a frequency f varying from 50 GHz to 80 GHz. When you change the frequency f on the screen of the indicator 8 observe the curve of the SWR in the selected BAT from frequency. This dependence has a pronounced resonance character. When observing the value of the SWR, the frequency value f = f _{o is} recorded at which the value of the SWR is minimal. This value of the frequency f _{o is} taken as the optimal value of the therapeutic frequency of the patient for this BAT. For example, for the RP4 point of patient A., a value of f _o = 74.5 GHz is obtained with a minimum value of SWR = 1.5. For bioactive symmetric points TR5, F3 and R3 patient A. values optimal therapeutic frequencies coincide m amounted f _o = 53,5 GHz. For the symmetric point E36, the value of the optimal therapeutic frequency f _o = 74.5 GHz was obtained. In each of these ten BAPs, after determining the optimal value of the therapeutic frequency f _o immediately (i.e., without removing the invasively installed inner conductor 12), therapeutic exposure to EHF radiation with a measured frequency f _o was performed for 2 - 5 min at each point. The full course of therapeutic effect for patient A. consisted of 5 sessions. The influence of the optimal therapeutic frequency by EHF radiation on biologically active points in patient A. was accompanied by sensory sensations. So, when exposed to the RP4 point by radiation with a frequency f ₀ = 74.5 GHz, patient A. noted the propagation of heat waves through the lower extremities. Changes in the radiation frequency f within ± 2 • 10 ^-3 f _o (ie, the frequency f disappears from the resonance region) led to a gradual decrease in sensory sensations until they completely disappear. After a course of punctured EHF-therapy, patient A. noted improvement in well-being: pain in the legs, anemia in the feet and hands disappeared. Biochemical analysis showed stabilization of glucose in the urine to 4.5 mmol / L with an initial glycemic level of 13.8 mmol / L. The indications of glomerular filtration and reabsorption were normalized. In neurological status, areas of gipestensia on the arms and legs decreased. The therapeutic effect obtained from this patient in the form of subjective data (improvement in well-being noted by patient A.) and objective data (biochemical analysis data) shows that the frequencies of EHF radiation found by the proposed method are the optimal therapeutic frequencies for punctured EHF therapy for this patient.

Example 2. Patient S., 16 years old. The medical history N 9408785. Was admitted to the hospital with complaints of: lower back pain on both sides, rare stitching pains in the heart, swelling of the face, rising to 38 ^o C body temperature. From the anamnesis - lower back pain on both sides, intensifying after physical exertion, is disturbed for 4 months. ; blood pressure 180/100 mmHg In the analysis of urine, white blood cells, red blood cells. Moderate protenonuria - detected during examination at school. Clinical diagnosis: chronic glomerulonephritis with isolated urinary syndrome. Concomitant diagnosis: chronic pharyngolaryngitis. Patient S. by the proposed method determined the optimal value of the therapeutic frequency for symmetrical puncture points R3 and RP6. To implement the method, the open end of the inner conductor 12 is invasively installed from point to point in each of the four BAPs (see FIG. 2), and the outer conductor 11 is installed on the cutaneous projection of the selected point. Then, using the EHF generator 2, they act on the selected BAT by electromagnetic radiation with a frequency f varying from 50 GHz to 80 GHz. On the screen of indicator 8, a curve of changes in the SWR in the selected BAP is observed when the frequency changes. This SWR change curve has the form of a resonance curve (see Fig. 3). When observing the value of the SWR, the value of the frequency f is noted at which the value of the SWR is minimal. This value of the frequency f = f _{o is} taken as the optimal value of the therapeutic frequency of the patient for this BAHT. For patient C., at the symmetrical points R3 and RP6, a value of f _o = 61 GHz was obtained with an optimal value of SWR = 1.8 (see Fig. 3). In each of these four BAP after determining the optimum value of frequency f _o therapeutic immediately performed therapeutic effect EHF radiation with a frequency f _o for 2 - 5 min. The full course of therapeutic effect for patient S. consisted of 5 sessions. The influence of the optimal therapeutic frequency by EHF radiation on biologically active points in patient S. was accompanied by sensory sensations. After a course of punctured EHF-therapy, patient S. noted a significant improvement in well-being: lower back pain disappeared, facial stiffness disappeared, body temperature returned to normal, blood pressure dropped to 110/70 mm Hg. Urinalysis is normal, while the temperature of the kidneys has increased by 1.5 ^o C, which is confirmed by the data of radiometry. The therapeutic effect obtained from this patient in the form of subjective and objective data confirms that the frequencies found by the proposed method are optimal therapeutic frequencies for punctured EHF-therapy for patient C.

 Similarly, the optimal values of therapeutic frequencies for punctured EHF-therapy were determined in another 292 patients of the regional clinical hospital named after Semashko. At the optimal therapeutic frequencies selected for each patient according to the proposed method, each of them using the proposed device conducted a course of punctured EHF-therapy, which gave a pronounced lasting therapeutic effect (subjective and objective data were recorded in case histories).

Claims (4)

 1. The method of determining the optimal value of the therapeutic frequency of the patient during puncture EHF-therapy, including exposure to electromagnetic radiation of a millimeter wavelength range of non-thermal intensity with a varying frequency on a biologically active point, followed by measurement of the standing voltage wave coefficient, while the desired frequency is determined by the minimum value of the standing coefficient waves, characterized in that the impact on the biologically active point is carried out invasively.  2. A device for influencing a biologically active point during punctured EHF-therapy, comprising an electromagnetic radiation source consisting of an EHF generator and power and control units, as well as an isolation device, a waveguide path, an indicator and an emitter, characterized in that the emitter is made in the form of a transformer for a waveguide transmission line into a TEM line open at one end, the outer conductor of which is placed on the skin projection of a biologically active point with its open end, and the open end is inside an early conductor is invasively installed directly in the region of the biologically active point, the ends of the outer and inner conductors opposite to the biologically active point are short-circuited in EHF, while the first input of the decoupling device is connected to the output of the EHF generator, the second input of the decoupling device is connected to the input through the waveguide path emitter, and the output of the decoupling device is connected to the input of the indicator to determine the relationship reflected from the biologically active point and falling her to a biologically active power point.  3. The device according to claim 2, characterized in that the short circuit of the ends of the outer and inner conductors opposite from the area of the biologically active point is made in the form of a low-pass filter.  4. The device according to claim 2 or 3, characterized in that the inner conductor of the emitter is coated with a dielectric with the exception of the open end, not covered by an amount equal to half the radiation wavelength in free space.

Images