UA45696A - DEVICE FOR ACOUSTOELECTRIC THERAPY AND COSMETOLOGY - Google Patents

Abstract

The device for electroacoustic therapy and cosmetology consists of the housing with the power supply, voltage generator feeding the electromagnetic signal generator connected to the electroacoustic applicators-converters, data input unit of the detectors recording the physiological state of the tissue and/or organs of the body. The signals from the detectors are transmitted to the data processing unit controlling the electromagnetic signal generator and the unit of the electroacoustic applicators-converters.

Description

Description of the invention

The invention relates to the field of medicine, in particular, therapy, dermatology and cosmetology. 2 A device for ultrasound therapy and cosmetology is known (Marchenko A.T., Ostrovsky I.V. Device for ultrasound therapy and cosmetology. Russian patent Mo 2058167, registered 04/20/1996. Cl.

Ab1M7/00 and AbI1N23/00, 1992|1)) which contains fixed frequency units, a stochastic signal generator, frequency switching and power supply installed in the case, which are connected via a connecting cable to an ultrasonic emitting unit consisting of an ultrasonic broadband converter and containers with 710 adaptive environment and elastic surface to ensure acoustic contact with the patient's skin.

The disadvantage of the specified device is the complete lack of information and control over the state of the patient's tissues and skin during a medical or cosmetic session, which can lead to both low efficiency of the procedure and negative consequences of the use of physiotherapeutic effects on the patient, for example, ultrasound therapy, electric therapy currents and electromagnetic fields, etc., - in the case of 72 Overdose of exposure time or exceeding the intensity of the above-mentioned active physiotherapeutic signals.

So, for example, under the influence of ultrasound, the phenomenon of cavitation may occur in a biological object, which leads to the so-called lysis, that is, the cells are destroyed (Mogiop K. y)., Teg Naag b. K., Zigatsoga I. 9. apa

NIiYi S. MK. That's how it is, how it's done (it's how it's done, how it's done) M79

You), Sapseg - 1982. - 45. - yr. 147 - 150. I2I). It was to combat cavitation that a stochastic ultrasound device was developed (Marchenko A. T., Ostrovsky I. V. Ultrazvukovoy terapuchetichesky apparat. Russian patent Mo 2066215, registered on September 10, 1996, IZI), but it also does not have the function of monitoring the condition of tissues the patient

The disadvantage is confirmed by the fact that human skin and tissues are very sensitive to the influence of external physical factors, including ultrasound (MU. YII. Murogd apa M. S. 2ivKip. Vioiodisai EPesiv oi OKgavotspa. Mem « mogk, SpigepiiI-G imipudviope. - 1989 , 384 R. |4); D. S. Chernavskyi, V. P. Karp, A. P. Nikitin. The system of analysis of the body's reaction to weak electromagnetic influence in biologically active points. - Radio engineering and electronics, 1996. - vol. 41, Language. - P. 995 - 1000. I51).

It has also been proven that even at low intensity, physical factors can significantly affect biological objects, including humans (A. V. Chaly. External effects of physical fields on biological objects. Ge»)

Ukrainian Journal of Medical Equipment and Technologies. - 1994, Mo. 1 - 2, pp. 11 - 16. IEEI). So, for example, when ultrasound affects tissues and cells, various physiological processes at the cellular level can lead to purely individual sensitivity and susceptibility of patients to ultrasound exposure (Adieg 9U., Zrigpa M. apa oyu

Ngagaya 3. Te epesi oi omu ipiepeyu shygazotspi op o tattaiyap sei! syMiguev I. Oigesi apa ipaigesi 32 epiesiv oi tsygavotspa // shcha. Biorpuz. - 1988. - 128. Mo 1, yr. 13 - 20. GI). And the illumination of the skin M with ultraviolet light leads to the activation of certain chemical processes in it, which has also been shown experimentally (R. I. Kononov, L. G. Koreneva, A. V. Lebedev, A. G. Markov. Processes determining the photoinduced chemiluminescence of human skin ip mimo. - Biomedicinskaya radiozlektronika, 1995. - Mo 2, pp. 82 - 84 " (Radiotechnique, 1995, Mo 9). |8)). - 70 Control over the state of the patient's tissues is necessary in the process of any medical or cosmetic session, which stems from modern ideas about the complex nature of the influence of external physical factors on

From" physiological processes in human tissues, including the state of individual cells and the pericellular environment.

The confirmation of the above can be the results of a number of works where it is shown that even small doses of ultrasound irradiation (Vigapeu V. 9., Viaskroshgpe R. apa Kigkieu U. Keviviapse oi SNI E patvzvieg seiYiv Yuyu uygavopis gadiaiop oi 1.5 MN: yedcepsu // Vii 9. Kadioi, 45, - 1972. - years 354 - 357 |9); Ovigomekii I. t- SpPidtasom I. OKgazotspa Ipisshepse op Metbgap oi IzoYiaiei Metsygop Ippapsevs oi IGidosaiip Asiop. / UAM, - 1991, 4! M319, Mo 4, R. 1003 - 7. (10); as well as the above-cited |Э, 7|Й) cause a number of changes in isolated cells, cell cultures or in the skin and mimo, including both variations in the intensity of growth and changes in other physiological characteristics. It turned out, for example, that ultrasound-treated cells can change (Te) 20 The speed of their reproduction, the speed of DNA synthesis and the intensity of protein exchange (Aadieg )., Zrigpa M. apa

Ngagaya 3. Te epesi oi omu ipiepeyu shygazotspi op o tattaiyap sei! syMiguev Sh. Biorpuz. - 1988. - 128. Mo 1, yr. 13 - 20. , also |91).

The purpose of the claimed invention is to improve the results of therapeutic and cosmetology procedures, including applications and effects of acoustic, vibration-mechanical, electromagnetic, and pharmacological nature, and to improve the quality of prevention of skin aging due to the current control of the physiological state of tissues. patient with simultaneous reverse correction of signal parameters affecting the patient to optimize the positive therapeutic effect of the signals acting on the patient, as well as the exclusion of possible negative consequences associated with the patient's individual sensitivity to physical factors influencing him.

These signals affecting the patient can be various acoustic and mechanical, electrical and magnetic, 60 pharmacological, or compatible procedures. For example: a) acoustic waves and oscillations of different frequency ranges and with arbitrary dependence on time of their amplitude, frequency and phase, including frequency ranges of ultrasonic, infrasound and audio frequencies that a person can hear; moreover, acoustic waves and oscillations can be mono-frequency, multi-frequency, broadband and stochastic; b) vibrational and mechanical effects on the skin; c) electromagnetic influences, including electric currents and electromagnetic fields, are constant and time-varying; d) effects of pharmacological or cosmetological drugs; e) it is advisable to use signals of the type of combined action

"acoustic waves and electric currents or electromagnetic fields", "acoustic waves and electric currents and pharmacological preparations", as well as "electric currents and electromagnetic fields and fields and pharmacological preparations".

It should be noted that stochastic ultrasound waves best meet the tasks of cosmetology, which is explained by their properties for stimulating metabolic processes and blood supply in the skin area (Marchenko A. T.,

Ostrovsky I. V. Device for ultrasonic therapy and cosmetology. Russian patent No. 2058167, registered on April 20, 1996.).

Current control of the physiological state of the patient's tissues with simultaneous reverse correction of the 7/0 parameters of the above-mentioned signals affecting the patient should ensure the optimization of the positive therapeutic effect of the signals acting on the patient, as well as the exclusion of possible negative consequences associated with the patient's individual sensitivity to physical factors of influence on him.

The specified task is achieved due to the design features of the device, which consists of a case with generator blocks of electrical sinusoidal, and/or stochastic, and/or time-varying and and/or 7/5 impulse voltages connected to an electric signal generator, power supply unit, and processing of information, which controls the operation of the generator of electric signals producing electric voltages for the generation of ultrasonic and electric signals of impact on the patient, and the information block of sensors, which is brought into contact with the skin and tissues of the patient, registers their physiological state according to the biophysical characteristics that are measured and provides the corresponding information signal to the information processing unit, which

Controls the shaper of electrical signals.

The device consists of a case with a power supply unit (KBZH) 1, which houses units of electric sinusoidal voltage generators (GESN) 2, and/or electric stochastic voltages (GSTN) 3, and/or time-varying voltages (GZChN) 4, and/or impulse and constant electric voltages (GIPN) 5, connected to the electric signal generator (FES) 6, the information and control signal processing unit (BIUS) 7, which controls the operation of the electric signal generator, the connecting cable (ZK) 8, the electroacoustic unit applicator-transducer (BEAP) 9 for generating acoustic and electrical signals of impact on the patient, sensor information unit (IBD) 10, which determines the physiological state of the patient's tissues, connecting loop (ZSh) 11 for implementing feedback. The signals produced by the electro-acoustic unit of the applicator-transducer (BEAP) are injected into the patient's tissues. The characteristics measured by the sensor information unit (IBD) of Gezo are transformed by it into electrical signals and are further submitted to the information and control signal processing unit (BIUS) in order to process the information received from the sensor unit (IBD) about the state of the patient’s tissues, and on this Me on the basis of developing a control command for the electric signal generator (ESG) to correct the active Ge signal introduced into the patient. Fig. 1 is a diagram of the device.

The device works as follows: o

The power supply unit 1 is connected to the network and the generators 2, and/or 3, and/or 4, and/or 5 are put into operation, the electrical signal generator 6, the information and control signal processing unit 7, and the sensor information unit 10. Electric voltages from generators 2, and/or 3, and/or 4, and/or 5 are fed to the input of FES 6, where

The BIUS 7 sets at the output of the unit 6 the amplitudes of electric and electromagnetic signals, which are fed through the connecting cable 8 to the unit of the electro-acoustic applicator - converter 9. The BEAP unit 9 converts "electrical voltages into signals that affect the patient, and introduces the influencing signals into the patient's tissues, for example, acoustic waves of all frequency ranges, including ultrasound, infrasound, and human-hearable sounds. vibration-mechanical pressures for various types of massage; electromagnetic fields and electric currents of various types, and? that is, both constant in time or sinusoidal, as well as variables of a complex form, or certain impulses; or arbitrary combinations of the above signals.

The information unit of the sensors, simultaneously with the impact on the patient, registers the physiological characteristics of the patient's skin and tissues, and changes in these characteristics during the procedure. Such physiological characteristics, for example, can be: temperature; electrical resistance or conductivity in direct or alternating current; about electric potentials in local areas or certain points of the skin, tissues and organs, including

Ge" potential difference; electrical capacity and quality factor; skin color; electromagnetic characteristics of the type of reflection, absorption, and polarization of electromagnetic waves of both optical and high-, ultrahigh-, and microwave ranges; chemical elements and compounds; combinations of the above characteristics; and other

F biophysical parameters. The measured physiological characteristics are transformed in the GBD 10 into an information signal, which is fed through the loop 11 to the BIUS 7 for their processing and subsequent production of the appropriate control signal for its submission to the FESb.

It is important to note that the current monitoring of the condition of the patient's tissues and skin can be carried out both in the areas adjacent to the point of contact of the BEAP applicator unit with the patient's skin, and in other areas distant from the BEAP,

R" regions.

In accordance with the current physiological characteristics of the patient's tissues and skin, BIUS 7 and FES 6 through BEAP 9 produce the optimal signal for the patient for therapy and cosmetology. 60 It has been experimentally and clinically established that there is an effect on the patient's skin and tissues of acoustic and electrical active signals, including monofrequency and stochastic ultrasound, electric currents and fields, pharmacological and thermal procedures. These procedures affect the physiological state of tissues and skin, which leads to a change in their characteristics.

Even at the level of a single muscle, ultrasound modifies neuromuscular transmission (Miiaditigoma I, 7adogodpik 65 M., OvigomeKki |, ZogoKipa 7, SPilltasom I! BpcCsram, Ibcepse oi ShPgazopa op o btooi Mizsie5. /

Meyhorpusioiodu. - 1993. - M.1. Mo. 4, R. 297 - 302. (1111).

The electrical resistance of human tissues depends on external influences. Thus, Fig. 2, as an example, shows the experimental results obtained by us on the influence of monofrequency ultrasound on the electrical resistance of the tissues of the elbow and the skin of the palm from above in different patients. Two round metal electrodes with a diameter of 16 mm were placed on the hands of the patients (elbow or palm) at a distance of about 20 (twenty) mm from each other in the areas in the middle of the left elbow, and above the index and middle fingers. Water-soaked cotton pads were placed between the metal electrodes and the skin, as recommended during physiotherapeutic procedures (V. M.

Bogolyubov (editor). Techniques and methods of physiotherapeutic procedures. - Moscow, "Medicine", 1983. - 352

S. (121). To ensure the reliability of the measurements, the surface of the electrodes was moistened with water, and 7/0 was pre-exposed for a few minutes so that the measured Ko resistance stabilized before the start of the procedure. After stabilization of Ko, the influence of ultrasound began. The ultrasonic applicator of the UZT-3.04S ultrasound therapy device was placed between the metal electrodes. Ultrasound at a frequency of 2.64 MHz with a therapeutic intensity of 1 W/cm? was injected into the limb (into the soft tissues of the elbow or into the skin of the upper side of the palm) for 150 to 390 seconds for different patients. At the moment of turning on the ultrasound, the measurement of the skin resistance K(Y) began, and measurements of the dependence of K on time E were carried out from the beginning of turning on the ultrasound until it was turned off, and then for some time. Experiments showed that after 10 - 20 minutes after turning off the ultrasound, the resistance could take the value close to the initial Code, which was again kept at the same level of Code. But the main attention was paid to the dynamics of resistance changes during the procedure, because it is these changes that make it possible to monitor the condition of the tissue during the procedure.

Measurements of Ko and time-dependent K() were carried out by an electronic device of the "multimeter" type, or by a device

MA-ZE "Soeg2 Meigazha, the readings coincided. As can be seen from Fig. 2, under the influence of ultrasound, the change in the resistance of the tissues of the elbow reaches 110 kΩ in graph 1 (patient 5) and 120 kΩ in graph 2 (patient 7). The resistance of the skin also changes of the palm, which is 37 kOhm (chart C, patient 5). After turning off the ultrasound, the resistance decreases sharply, by 45 - 50 kOhm on the elbow, and to 10 kOhm on the palm. We note that the after-effect time exceeds the time of the procedure itself. It should be noted that in other studied patients, the nature of changes in resistance K() was similar, i.e., a change in resistance under the influence of ultrasound was observed. The magnitude of the specified change depended on the intensity of ultrasound and the time of application. Moreover, the effect of ultrasound increased with increasing intensity. It is worth noting that in the work of Oippo M. A " at

Change in skin resistance near 5095 under ultrasonic action, but in the skin of a frog.

Stochastic ultrasound strongly affects living objects. A general review proves that signals of a noise nature initiate significant changes in biological objects (V. Horsthemke, R. Lefebvre. Noise-induced transition: theory and application in physics, chemistry, and biology. Trans. from English - M. Mir, 1987. - 400 pp. (141).

It was experimentally and clinically established that stochastic ultrasound stimulates and activates metabolic processes in the skin and tissues, which led to changes in temperature and other biophysical characteristics both in the area of its influence and in the blood of experimental rats (OvigomueKii YII. M., Kagaz A. RG., Mygizvpyspepko M.E. Ipytsepse oi

Ziospaviis OMgavoczpia op Vioepegdeisv apa Egee Cadiz! Ohidanyop ip Ehregitepia! IpPyattaiop. // ЮРоромиай ой Маййопа! Asadetu oi Zsiepsez oi OKgaipe, - 1995, Mo 4, - R. 118 - 120 (15), and in the blood of patients during "clinical studies (OvigomeKi 1. M., Kagaz A. R. MygivpispepkKo M. E., eitspuzakK M. M. Ipytsepse oi

Ziospavis Pgavopis Tregaru op Vioi Spagasiegivisv oi Rayepiv -myy Kesigepi Topviyiv. / ОЮОоромиди -d s oi Mayopai! Asadetu oi Zsiepsez oi OKgaipe, - 1995, Mo 10. - R. 144 - 147 (161). As an example, Fig. 3 shows the dependence of the amount of light, i.e., the intensity during the measurement time, of the chemiluminescence of the blood plasma of patients with chronic tonsillitis, on the number of ultrasound therapy procedures. Graph 1 was obtained using stochastic ultrasound in the frequency range from 0.88 up to 2.64 MHz, and graph 2 - monofrequency ultrasound at a frequency of 2.64 MHz, ultrasound intensity up to 1 W/cm?. Graphs 1 and 2 in Fig. 3 are based on experimental and clinical results obtained by us in cooperation with by doctors, and published in the above-cited work (16), the details of these experiments are also given there.

Thus, it can be considered that one of the parameters of the physiological state of the patient and his tissues can (e)) be certain chemical indicators. Note that 2905% of the total gas exchange of the body passes through the human skin, with 50% gases are released and oxygen is absorbed (Yu. Drybnokhod. Introduction to cosmetology. - Moscow, ed. Peter,

St. Petersburg, 2001. - See 3, pp. 22 - 32 |17)Y); these indicators can also be used to monitor the condition of the patient's skin and 4) tissues.

Electromagnetic fields also significantly affect a person (I. A. Ivanchenko, B. F. Rudko, Yu. V. Chovniuk, L.

V. Sveshnikova, V. M. Kryilov, I. G. Kolosovsky. Experimental study of biophysical processes during the effects of electromagnetic waves on human skin. - Physics of the living, 1997. - vol. 5, Mo. 1. - p. 110 - 114 z" (181; I. A. Imapspepko, E. A. Apageem, I igody M. b., |. M. bmevzppikoma. Zrase-yte aivighirshiop oi pogtai! apa raiaiodisaii pitap z5Kip aiieiIesigis rgorepiev ip (ye MMUM hapde. Eiesigo - apia tadpeifobrioiodu. - 1994, m. 13, - Mo 1, R. 15 - 25. (19); I. A. ImapspepKo, Gigodiv M. 0., 1. M. Zmezppikoma, My. M. SpoopishkK Nytap 5Kip tiypte (seg mame hapde gePesioteigu arriisayop yog aiadpoviz oi vzote dezease5z. RPuvisv oi Ame. - 1994, 60 m.2, - Mo 1, R. 81 - 90 20); I. A. Ivanchekno, Yu. V. Chovnyuk, B.F. Rudko, A. V. Ivanovskaya, T. V. Zavalskaya,

I. H. Kolosovymy. Application of the method of differential microwave reflectometry for the study of polarization properties of acupuncture points. - Physics of the living. v. 8, - Mo2. - P. 52 - 62211.

We experimentally established on 6b-ty patients that an electric field and direct current applied to human tissues cause characteristic changes in skin resistance, which are easily recorded by standard equipment. These changes are slow, the resistance increases and reaches a certain, subsequently constant, value.

Light, we note, also refers to electromagnetic field factors of influence, especially on human skin. It is the spectra of reflection from the skin in the visible region that depend on the condition of the skin and change during diseases and external influences, as shown in special studies (Y. P. Sinychkin, S. R. Uts, E. A.

Pylypenko. Spectroscopy of human skin. - Optics and spectroscopy, 1996, vol. 80, - Mo 2, pp. 260 - 267. (221).

The electrical capacity (C) of the skin and tissues also depends on external influences. In our experiments, we observed a change in the electrical capacity (C) between two metal electrodes applied to the limb in the areas above the index and middle fingers, under the influence of ultrasound and light. Note that water-soaked cotton pads were placed between the metal electrodes and the skin, as recommended during physical therapy procedures. It turned out that under the action of ultrasound of 2.64 MHz of therapeutic 70 intensity of the order of one W/cm 2, the specified change is 1695 - 2095 with the area of the measuring electrode 15 x 1Bmm?, and the time of ultrasound application is 1.5 - 2 minutes. Even with a short-term action of 25 seconds, the capacity changes to 4,690.

Under the influence of light, mainly ultraviolet, from a mercury lamp of the DRSH type, installed at a distance of 10 cm from the limb, a change in capacity was also observed. Lighting time - one minute. The value of this change was 75 less than that from ultrasound and was 395 from the initial value before the procedure.

We also conducted experiments to observe the change in electrical capacity (C) between two metal electrodes applied to the limb in the areas above the index and middle fingers, under the influence of temperature changes. Water-soaked cotton pads were placed between the metal electrodes and the skin, as recommended for physical therapy procedures. Warm air was directed to the limb, and the skin temperature was measured with a thermocouple and the capacitance between the applied electrodes. Experiments have shown that an increase in temperature by 0.9"C degree causes a corresponding change in capacity by 395, and a change in capacity by 11905 when the skin is heated to 27C. Such changes are easily and accurately recorded by the equipment.

Below, the table presents the results of our experimental studies on the influence of physical factors on the electrical capacity of human tissues on the example of two patients, healthy men aged 55 years (patient Ж,) and 33 years old (patient 6). "

Table The effect of external physical factors on the electrical capacity of patient tissues between two metal electrodes placed on the skin. (Se)

Fo

Me | Initial | Impact on the patient The final patient, the change of capacity to the capacity of the area of influence of the capacity of the procedure after 96 o

So, pkF procedures "

Sk, pcF 1 118800 Ultrasound, 22600 Patient 3, 20.25 2.64 MHz, IW/cm", left palm "90 sec. above o) s 2 122500 Ultrasound, 26200 Patient 3, 16.55 hz" 2.64 MHz, IW/cm", right palm 120 sec. beast 13 | 30400 Ultrasound, 29000 Patient 6, 4.695 te 2.64 MHz, IW/smu, left palm at 25 sec, animal at 4 132000 Light from mercury | 31000 Patient 6, 395 s of DRSH-type lamps left palm (ultraviolet) from above St. At a distance of 10 cm, 60 sec. vv 15 | 36000 Temperature, 37200 Patient 3, 3.395 » Heating by 0.9C of the right palm from above 36000 Temperature, 32000 Patient 6, Pe vo Heating by 2'C of the left palm from above

Thus, it was experimentally established that electric capacity, as a characteristic of human tissues in terms of alternating electric current and voltage, can be one of the measurable parameters for registering changes in the physiological state of human tissues under the external influence of physical factors. because biologically active points (BAT) and zones (BAZ) of a person are actively used for therapeutic, i.e. healing, influence with the help of reflexology, which is well known. Here it is necessary to take into account the fact that recently it is ultrasonic stimulation of BAT - points and active zones that has been spreading (V.V. Sobetsky.

Clinical reflexology. - Kyiv, "Health", 1995. - 255 p. 231).

Thus, biologically active points (BAT) and biologically active zones (BAZ) of a person can be exposed to the above-described device for acoustic-electrical information therapy and cosmetology. The latter means that in the case of reflexology, it is necessary to have current information about the condition of the patient's tissues and especially the skin.

Claims (41)

The formula of the invention 1. A device for acoustoelectric therapy and cosmetology, consisting of a case with a power supply unit, generators of electric constant and/or variable, and/or sinusoidal, and/or stochastic voltages, supplied to the generator of electromagnetic signals, connected to the unit of electroacoustic applicators-transducers, which is distinguished by the fact that it additionally has an information unit of sensors for registering the physiological state of the patient's tissues and/or organs, signals from which are sent to the information processing unit that controls the operation of the electromagnetic signal generator and unit of electroacoustic applicators-transducers. 2. The device according to claim 1, which is characterized by the fact that it has a unit of electroacoustic transducer applicators that emits ultrasound. 3. The device according to claim 2, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 4. The device according to claim 2, which is characterized by the fact that it has a block of electroacoustic transducer applicators that emits stochastic ultrasound. 5. The device according to claim 4, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which "additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 6. The device according to claim 2, which differs in that it has a block of electroacoustic applicators-transducers, which emits monofrequency ultrasound. 7. The device according to claim 6, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which (9) additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 8. The device according to claim 2, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which i) emits multi-frequency ultrasound. " 9. The device according to claim 8, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 10. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers " 20 which generates a vibration-mechanical impact signal. w-in the village 11. The device according to claim 10, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 12. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which generates vibrations of variable frequencies. driving 13. The device according to claim 12, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. FO 14. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic transducer applicators that generates variable pressures. is) 15. The device according to claim 14, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, Ф which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 16. The device according to claim 10, which differs from the one used in massage procedures. 17. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which emits electromagnetic signals of influence. » 18. The device according to claim 17, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. in 19. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which emits constant and/or time-varying electromagnetic fields. 20. The device according to claim 19, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 65 21. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which generates constant and/or time-varying electric currents. 22. The device according to claim 21, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of one or more arbitrary pharmaceutical and/or cosmetic preparations. 23. The device according to claim 1, which is characterized by the fact that it has a block of electroacoustic applicators-transducers, which additionally ensures the effect on the patient of arbitrary pharmaceutical preparations along with the simultaneous application of one or more of any physiotherapeutic signals and means. 24. The device according to claim 1, characterized in that it has a block of electroacoustic applicators-transducers, which creates composite signals that are the sum of physical factors in an arbitrary set for further action on the patient. 25. The device according to any one of claims 1-24, which is characterized in that it has a unit of transducer applicators that affects one or more biologically active points and/or areas of the patient. 26. The device according to any one of claims 1-25, which is characterized by the fact that it has a sensor information unit that registers the current electrical characteristics of the patient's tissues and/or organs. 27. The device according to claim 26, which is characterized by the fact that it has an information unit of sensors that registers the resistance of the patient's tissues and/or organs. 28. The device according to claim 26, which is characterized by the fact that it has an information unit of sensors that registers the conductivity of the patient's tissues and/or organs. 29. The device according to claim 26, which is characterized by the fact that it has an information unit of sensors that registers the electric 2o potentials of the patient's tissues and/or organs or their differences. 30. The device according to claim 26, which is characterized by the fact that it has a sensor information unit that registers the electrical capacity of the patient's tissues and/or organs. 31. The device according to claim 26, which is characterized by the fact that it has an information unit of sensors that registers the electrical and/or acoustic quality factor of the patient's tissues and/or organs. 32. The device according to any one of claims 1-25, which is characterized by the fact that it has a sensor information unit that registers current electromagnetic characteristics of the patient's tissues and/or organs. " 33. The device according to claim 32, which is characterized by the fact that it has an information unit of sensors that registers the absorption of electromagnetic waves by the patient's tissues and/or organs, both ultraviolet, visible, infrared, and high-, ultrahigh-, and microwave frequency ranges. Ge zo 34. The device according to claim 32, which is characterized by the fact that it has an information unit of sensors that registers the reflection of electromagnetic waves by tissues and/or organs of the patient, both ultraviolet, visible, infrared, ME, and high-, ultrahigh-, and microwave frequency ranges. Ge 35. The device according to claim 32, which is characterized by the fact that it has an information unit of sensors that registers the polarization of electromagnetic waves reflected by the tissues and/or organs of the patient as ultraviolet, VISIBLE, infrared, as well as high-, ultrahigh-, and microwave frequency ranges . "IS 36. The device according to any one of claims 1-25, which is characterized in that it has a sensor information unit that registers the current temperature of the patient's tissues and/or organs. 37. The device according to any one of claims 1-25, characterized in that it has a sensor information unit that registers the current color of the patient's tissues and/or organs. " 38. The device according to any one of claims 1-25, which is characterized by the fact that it has an information unit of sensors that registers the current blood pressure. AND 39. The device according to any of claims 1-25, which is characterized by the fact that it has an information unit of sensors, which registers a change in the composition of the chemical elements of the patient's tissues and/or organs. 40. The device according to any of claims 1-25, which differs in that it has an information block of sensors that registers a change in the composition of substances related to the vital activity of the human body, tissues and/or organs of the patient. 41. The device according to any one of claims 26-40, which is characterized by the fact that it has an information unit of sensors, which registers in an arbitrary set the composite characteristics of the patient's tissues and/or organs. (22) o 50 42) P 60 b5