RU2038101C1 - Method and device for performing electromagnetic massage - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: method involves measuring physiologic properties parameters of patient skin when doing electromagnetic massage before applying nutrient components on the skin. Low frequency pulsating complex modulation electromagnetic field is created. Electromagnetic field parameters are formed corresponding to the physiologic properties of skin, that is, modulation frequency is selected in the range of 0.3 0.8 Hz, pulse succession frequency is in the range of 3 30 Hz, harmonic components spectrum width is 500 Hz 1 kHz. A pause is to be done in the process of doing massage. Then the pulse succession frequency is to be increased up to 80 -120 Hz and the skin is additionally treated in prescribed manner. The time parameters are set corresponding to the physiologic properties of skin of the patient. Skin state sensor has two electrodes mounted on internal side of the casing flexible surface of the massage device. Electrodes are connected to inputs of control unit. Inductance coil is connected to output of the control unit. EFFECT: individually selectable massage treatment procedure parameters; maximum penetration of medicines through skin pores; improved microcirculation in subcutaneous tissular layers. 7 cl, 2 dwg

Description

 The invention relates to medicine, namely to physiotherapy.

 A known method of massage the skin, in which open the pores of the skin, apply to the skin nutritional components for massage, and then act on the skin with vibration, changing the frequency and amplitude of the massage. (Electrical appliance for women "Kharkivyanka-2". Operation manual XII 18.00.000 RE, Kharkov, 1977).

 The disadvantage of this method is that in this case, the skin has only a mechanical effect. At the same time, the amplitude and frequency of the massage are changed without regard to the individual characteristics of the patient’s skin. As a result, the known method of skin massage induces an adaptive reaction of tissue cells of the massaged surface, which causes the pores of the skin cells to close and prevents filling with nutritional components for massage, and reduces microcirculation in the subcutaneous tissue layers.

 Closest to the proposed method is a method of electromagnetic massage, implemented by a device for vibromassage (USSR, N 1342501, 12.25.84. A 61 N 23/00) and including a complex effect on the patient's skin of an electromagnetic field of a sinusoidal shape, vibration and heat with a change in amplitude and massage frequencies.

 A disadvantage of the known method is the use of a sinusoidal electromagnetic field for exposure, which has a smooth increase in the leading edge and uniformity of parameters, which is inadequate for a living organism and almost immediately causes an adaptive reaction. This leads to the closure of cell pores and reduces the permeability of cell membranes, which prevents filling them with nutritional components for massage. In addition, the method does not allow to form the parameters of the massage procedure individually for each patient. This does not create conditions for the development of exposure modes, based on the individual properties of the skin and the composition of the applied nutritional components of the massage.

 Thus, the known methods do not allow to obtain a technical result during their implementation, which consists in the possibility of forming massage parameters taking into account the individual characteristics of the patient’s skin; in reducing the adaptive response of tissues to the massaged surface of the patient’s body; in achieving maximum penetration during massage of nutrients through the pores of the skin and enhancing microcirculation of the subcutaneous tissue layers.

 Known electrical appliance for women "Kharkivyanka-2" containing an AC voltage source, voltage regulator, frequency converter, electromagnetic vibrator, which is anchored with a head for massage (electrical appliance "Kharkivyanka-2" Operation manual XII18.00.000RE, Kharkov, 1977) . The device provides the ability to control the amplitude and frequency of the massage.

 A disadvantage of the known device is that it does not allow forming the parameters of the massage procedure taking into account the individual characteristics of the patient’s skin and only has a mechanical effect on the skin, causing an adaptive reaction to occur in the tissues of the massaged body surface. The latter leads to the closure of the pores of skin cells and prevents the filling of cells with nutrients for massage, reduces microcirculation in the subcutaneous layers of tissues.

 Closest to the proposed device is a device for vibration massage, which contains a housing in which there is a chamber with massage balls of hard magnetic material; an inductor wound around a cup-type magnetic circuit that encloses a chamber with balls. The open surface of the chamber is limited by an elastic membrane. The inductor is connected to the output of the control unit containing an AC voltage source, a voltage regulator and a frequency converter, the outputs of which are the outputs of the control unit (USSR, N 1342501, 25.12.84, A 61 N 23/00).

 A disadvantage of the known device is that the inductor generates a sinusoidal electromagnetic field, which is significantly physiologically less active than pulsed fields, and causes an adaptive reaction of tissues of the massed body surface, prevents the penetration of nutrients through the skin, and does not promote microcirculation of the subcutaneous tissue layers, which adequate for closing pores of the skin. In addition, the device does not allow forming the parameters of the massage procedure individually for each patient, due to the lack of a feedback system, which also contributes to the development of the adaptive response of the body.

 Thus, the known devices for vibration massage do not allow to obtain a technical result during their implementation, consisting in the possibility of forming massage parameters taking into account the individual characteristics of the patient’s skin, in eliminating the adaptive reaction of tissues of the massaged surface of the patient’s body and in achieving maximum penetration of nutrients through the skin pores during massage and increased microcirculation of the subcutaneous tissue layers.

 The proposed method of electromagnetic massage solves the problem of creating a method that, when implemented, provides a technical result, which consists in the possibility of forming the parameters of the massage procedure individually for each patient; in reducing adaptation to the effects of tissues of the massaged surface of the patient’s body; in achieving an increase in the penetration of drugs through the pores of the skin during massage and enhancing microcirculation of the subcutaneous tissue layers.

 The essence of the invention lies in the fact that in the method of electromagnetic massage, including applying the massage components to the patient’s skin, followed by exposure to the patient’s skin of an electromagnetic field, vibration and heat with a change in the frequency and amplitude of the massage, while the effect of vibration and heat is carried out throughout the time massage procedures simultaneously with exposure to an electromagnetic field, before applying the nutritional components of massage to the patient’s skin, determine the physiological properties of the patient’s skin, for it is fixed on the control area of the skin the magnitude of the amplitude of electromagnetic waves induced in the tissue by electromagnetic fields as a result of its bioelectrical activity, then applied to the massaged surface of the patient’s body nutritional components for massage, after which, in accordance with the magnitude of the amplitude of induced electromagnetic waves recorded on the control area of the skin form a low-frequency pulsed complex-modulated electromagnetic field with a modulation frequency in the range from 0.3 to 0.8 Hz, with often pulse repetition in the range from 3 to 30 Hz and with a spectrum width of harmonic components in the range from 500 Hz to 1 kHz, and they affect the patient’s skin, then pause, increase the pulse repetition rate of a complex modulated electromagnetic field, for which they form it in the range from 80 to 120 Hz, and additionally affect the patient’s skin, while the duration of the massage procedure before a pause, the duration of the pause and the duration of the additional exposure to the electromagnetic field are determined on the basis of ziological properties of the skin of the patient.

 The technical result is achieved as follows.

 Due to the fact that the property of living tissue is used to determine the physiological state of the skin, it is used to convert the parameters of electromagnetic waves induced in the tissue by pulsed complex modulated electromagnetic fields, and the parameters of the oscillatory process in the body are known to depend on the functional state of the living tissue (Kholodov Yu.A. "Organism and magnetic fields" // Uspekhi Fiziologicheskikh Nauk. 1982, T13, N 2, pp. 48-64), a fixed value of the amplitude of the oscillatory process induced in the tissue is characteristic terizes not only skin type (dry, normal, oily), but also its morphological and functional state. The use in the proposed method of a low-frequency pulsed complex-modulated electromagnetic field ISMEMP, which is the most appropriate for a living organism (Bankov V.I. “Feedback system in magnetotherapy equipment.” Magnetobiology and magnetotherapy in medicine. (Abstracts of reports of the All-Union Symposium with international participation). Sochi , Kuibyshev; 1991, p. 168), creates a real opportunity to ensure information interaction between the formed ISMEMP and a living organism, on which the field acts (Demetsky A.I. et al. "Artificial magnetic fields in medicine" Experimental studies, Minsk: Belarus, 1981, pp. 5-31; Kratin Yu.G. "The principle of filtration and resonant tuning of cyclic loops in the theory of higher nervous activity" UFN, 1986, vol. 17, N 2, pp. 31-56; Ban'kov V.I. "Bioelectromagnetic diagnosis of ischemia" // Issues of development and implementation of radioelectronics in the diagnosis of cardiovascular diseases, M. Radio and Communications, 1984 , with. 31; Bankov V.I. and others. "The use of bioelectromagnetic reactivity of living tissues in diagnostics" // The use of electronics in biology and medicine. Sverdlovsk, 1981, p. 35).

 Due to the fact that in the proposed method, the parameters of the EMF EMF are formed in accordance with a fixed magnitude of the amplitude of electromagnetic waves induced in the tissue by electromagnetic fields as a result of its bioelectric activity, the integrative component of the generated EMF EMF is strictly individual. In addition, the spectrum of harmonic components of the formed EMF EMF is in the range of 500 Hz 1 kHz, which is the most likely frequency range that allows you to control metabolic processes in the skin (V.I. Bankov et al. "Selective filtering of pulses of a weakly complex electromagnetic field by living skin" // VI Ukrainian Republican Conference on Bionics (abstract), Uzhgorod, 1981, p. 138). As a result, the formed low-frequency ISM EMF provides informational interaction with the body, moreover, individual, which excludes the adaptation of the tissues of the massaged surface of the patient's body to the effect. In this case, the low-frequency ISM EMF initiates, according to the feedback principle, activation of the vital activity of skin cells, which is adequate to the opening of skin pores, enhances microcirculation of the subcutaneous tissue layers and promotes increased penetration of the nutritional components of massage into skin cells. This allows you to exclude from the method the operation of processing the massaged surface to open the pores of the skin, which is usually uncomfortable for the patient and in some cases has a harmful effect on the skin (treatment with alcohol, hot compress, steam). The increased penetration of nutrients into the cells is facilitated by the simultaneous exposure to the generated EMF EMF, vibration and heat. The pulse repetition rate of the low-frequency ISM EMF is formed in the frequency band of 3-30 Hz, which is comfortable for a living organism. Moreover, since the EMF EMF is formed in accordance with the physiological properties of the patient’s skin, the formed sections of this frequency range are strictly individual. As a result, the formed EMF EMF is comfortable. The modulating frequency of the EMF (0.3-0.8 Hz) allows you to pass a soft, pleasant massage mode by forming short pauses in the process of exposure to the electromagnetic field. The specific value of the modulation frequency is also formed on the basis of the physiological properties of the skin, which makes the massage regimen strictly individual.

 The duration of exposure to low-frequency pulsed complex-modulated electromagnetic fields is set in accordance with the physiological properties of the skin. This contributes to the long-term preservation of turgor (skin elasticity), softness of the skin and the long-term preservation of its condition without wrinkles.

 A pause in the massage procedure is associated with a certain inertness of the body and allows you to prepare the skin for the next stage of the procedure. Moreover, due to the fact that the action of the formed ISM EMF does not cause an adaptive reaction of tissues of the massed body surface, during a pause there is a further filling of the pores of the cells with the nutritional components of the massage due to increased microcirculation of the subcutaneous tissue layers.

 Exposure to the patient’s skin after a pause of ISM EMF with a repetition rate in the range of 80-120 Hz, i.e. A sharp change in the pulse repetition rate to a higher one leads to the effect of amplitude parameters of the EMF EMF on the electrodes, i.e. to energy impact instead of information. This forms the adaptive response of the tissues of the massaged surface of the patient’s body and breaks the information link between the body and the effect, which is adequate to close the cell pores. The latter after filling the cells with nutritious components contributes to their long-term preservation, as well as their gradual assimilation by the body, which leads to a prolongation of the effect of massage.

 Thus, the proposed method of electromagnetic massage ensures the achievement of a technical result, which consists in the possibility of forming massage parameters individually for each patient; in reducing the adaptation of tissues of the massaged surface of the patient’s body to exposure; in achieving an increase in the penetration of drugs into the tissue cells of the massed body surface through the pores of the skin during massage and in enhancing the microcirculation of the subcutaneous tissue layers. In addition, due to the fact that the low-frequency EMF EMF used during massage is strictly individual and is formed not only in accordance with the physiological state of the patient’s skin, but also taking into account the functional and morphological state of the tissues of the massaged surface, the proposed method of electromagnetic massage provides an additional technical result, which consists in that it allows you to combine massage with the simultaneous stimulation of the healing of skin lesions of the patient, initiating oscillatory processes in pain s tissues, and thereby enhancing their livelihoods.

 The proposed invention, a device for implementing the method of electromagnetic massage, solves the problem of creating a device for electromagnetic massage, which provides a technical result, which consists in the possibility of forming the parameters of the massage procedure individually for each patient; in the exclusion of adaptation of the tissue of the massaged surface of the patient to the impact; in achieving maximum penetration of nutrients through the pores of the skin during massage and in enhancing the microcirculation of the subcutaneous tissue layers.

 The essence of the invention lies in the fact that in the device for implementing the method of electromagnetic massage containing a control unit that contains a frequency converter, a massager, in the housing of which an inductor is placed, the surface of the housing above the coil is made elastic, and the inductor is equipped with a magnetic circuit, the magnetic circuit is made in the form of a half-glass of a SB type ferrite core, covered through an elastic strip with a plate of ferromagnetic material; an inductor is placed inside the core, which is connected through a parallel capacitor to the output of the control unit, in addition, a massage mode setting unit, a modulator, and a pulse shaper are introduced into the control unit, and a skin condition sensor is introduced into the massager, containing two electrodes fixed on the inside of the elastic the surface of the housing at a distance from each other, and one of the electrodes is made in the form of an incomplete coil, the output of which is connected to the first input of the unit for setting massage modes, w to the other input of which the output of the second electrode is connected, the output of the massage mode setting unit is connected to the input of the frequency converter, the outputs of which are connected to the inputs of the modulator, the output of which is connected to the input of the driver by a pulse, the output of which is the output of the control unit. In this case, the unit for setting massage modes contains the first and second comparators connected in series, a programmable timer connected by a start input through a resistor to the output of the first comparator and a storage device connected by control inputs to the timer outputs, information inputs to the non-inverting input of the first comparator, and the output to the inverting input of the second comparator, the inverting and non-inverting inputs of the first comparator are respectively the first and second inputs of the mode setting unit, output is the output of the second comparator block further timer connected upravyayuschimi inforatsionnym inputs to outputs of the memory device and the second output to the additional information input of the memory device. In this case, the storage device contains memory cells and an adder, each of the memory cells contains a transistor, the emitter of which is connected to a common bus, the base through the first resistor is connected to the corresponding information input of the storage device, and through the second resistor to the power source, it is included in the collector circuit of the transistor a trigger, the direct and inverse outputs of which are the outputs of the first and second memory cells, the second outputs of the memory cells are connected to the corresponding inputs of the adder, the output of which is the output the house of the storage device, and the control inputs are the control inputs of the storage device, the additional information input of which is connected to the corresponding input of the adder, while the first outputs of the memory cells are information outputs of the storage device. In addition, the pulse shaper contains the first and second transistors, the emitters of which are connected to the common bus, the base of the first transistor is the input of the shaper and is connected through a resistor to a power source, to which are connected, through a parallel RC circuit, the collector of the first transistor and the base of the second transistor and the collector of the second transistor is the output of the pulse shaper.

 The technical result is achieved as follows. The introduction of a skin condition sensor makes it possible to take into account the physiological state of the patient's skin, i.e., its individual characteristics. Since the sensor is made in the form of two electrodes located at a distance from each other and fixed on the inner side of the elastic surface of the housing located above the inductor, the electrodes are pressed against the skin of the massaged surface of the patient’s body simultaneously with the elastic surface of the massager. The implementation of one of the electrodes in the form of an incomplete turn allows us to fix the magnitude of the amplitude of electromagnetic waves induced in a constant volume of tissue by electromagnetic fields on the control area of the skin as a result of its bioelectric activity, the property of living tissue to convert electromagnetic waves induced in the tissue by external electromagnetic fields. Since the parameters of the oscillatory process depend on the functional state of living tissue, the magnitude of the electromagnetic oscillation amplitude recorded in the sensor characterizes not only the type of skin (dry, normal, oily), but also its functional and morphological state. Due to the introduction of a unit for setting massage modes to the control unit, the inputs of which are connected to the skin condition sensor and the output is connected to the frequency converter, a control signal is generated at the input of the latter, the value of which is determined by the physiological state of the patient’s skin. As a result, two sequences of pulses formed at the converter outputs: modulating, in the frequency range 0.3–0.8 Hz, and modulating, in the frequency range 3–30 Hz, have a repetition rate also determined by the patient’s skin condition. The modulator provides the formation of a sequence of packs of start pulses for the pulse shaper. Due to the fact that the inductor is connected to the output of the control unit through a parallel-connected capacitor, a parallel LC oscillatory circuit is formed. At the same time, for each trigger pulse, a pulse in the form of a periodic damped oscillation is generated in the circuit, the spectrum of which is rich in harmonics and a capacitor selection of the circuit is formed in the range of 500 Hz 1 kHz, which is the most likely frequency range that allows you to regulate metabolic processes in the skin. At the same time, the coil induces an electromagnetic pulse. After passing from the output of the modulator through the pulse shaper a series of pulses of pulses, a low-frequency pulsed complex-modulated electromagnetic field is formed near the coil, which has a strictly individual character, with a pulse repetition rate in the range from 3 to 30 Hz, with a modulation frequency in the range from 0.3 to 0, 8 Hz and with a spectrum width of harmonic components in the range from 500 Hz to 1 kHz. The low-frequency ISM EMF is the most characteristic for a living organism and is able to carry information parameters due to modulation. Therefore, the low-frequency complex-modulated EMF formed by the proposed device, acting on the skin tissue, activates the vital activity of cells, which is adequate to their opening and contributes to an increased digestibility of the nutritional components of massage by cells. In addition, in this case, a special procedure for opening the pores of skin cells before massage is not required by treating it with hot compresses or steam, which allows you to spare the skin and makes the procedure comfortable.

 The implementation of the magnetic circuit in the form of a half-glass of a SB type ferrite core creates a screen around the winding of the inductance coil, thereby eliminating the scattering of the electromagnetic field induced by the coil, which increases the effectiveness of the massage.

 Vibration during massage is provided by the magnetostriction effect, which leads to the movement of a ferromagnetic plate covering the half-glass of the magnetic circuit. The presence of an elastic pad softens the vibration. The vibration of the plate is transmitted to the elastic surface of the massager body located above the inductor. Since the parameters of the formed low-frequency ISM EMF are individual in nature, the amplitude and frequency of the magnetostriction effect are also individual in nature, corresponding to the functional and morphological state of the patient’s massaged tissues. The presence of pauses between packs of electromagnetic pulses, formed with a modulation frequency, allows you to smoothly translate an active massage into a gentle one, which allows the skin to relax.

 The thermal effect on the skin surface in the proposed device is due to the heating of the core of the inductor as a result of eddy currents due to the action of an alternating electromagnetic field.

 The formation at the output of the unit for setting the control signal modes for the frequency converter corresponding to the physiological state of the patient’s skin is carried out by introducing into the unit for setting the modes of the storage device, the inputs of which are connected to the skin condition sensor. The operation of the storage device is controlled by a programmable timer, which generates control signals of the temporary grid operation of the storage device. As a result, the adder of the storage device generates a voltage level at the inverse input of the second comparator, according to which, according to the generated control signal at the output of the mode setting unit, the frequency converter generates at its outputs sequences of modulated and modulating pulses, selecting frequency sections from the corresponding frequency ranges that are strictly individual in nature.

 Due to the fact that the control inputs of the programmable timer are connected to the information outputs of the storage device, on which the voltage level corresponding to the physiological state of the patient’s skin is formed, the timer ensures the duration of the massage procedure until a pause, the duration of the pause and the duration of the additional exposure to the electromagnetic field in accordance with the physiological properties of the patient’s skin . The connection of the second output of the programmable timer with the additional information input of the storage device, which is the information input of the adder, allows after a pause to change the signal at the output of the adder so that the control signal at the input of the frequency converter causes a sharp increase in the values of the repetition rate of the modulated pulses, and hence the frequency following pulses of a complexly modulated electromagnetic field. A quick change in the parameters of the ISM MP leads to an energy effect on the massaged skin tissue instead of the information one, which causes an adaptive reaction and is adequate to close the pores of skin cells. This helps to fill the cells with the nutritional components of massage and contributes to their maximum penetration through the pores of the skin.

 Thus, the proposed device for implementing the method of electromagnetic massage provides a technical result, which consists in the possibility of forming the parameters of the massage procedure individually for each patient; in the exclusion of adaptation of the tissue of the massaged surface of the patient’s body to the effect; in achieving maximum penetration of drugs through the pores of the skin during massage and increased microcirculation of the subcutaneous tissue layers. In addition, since the proposed device forms the parameters of the pulsed low-frequency SM EMF taking into account the functional and morphological state of the tissues of the massaged surface of the patient’s body, an additional technical result is provided, consisting in the possibility of combining massage with simultaneous stimulation of healing of the damaged skin of the patient, initiating oscillatory processes in diseased tissues and activating thereby, their vital activity, by enhancing the microcirculation of the subcutaneous tissue layers.

 In FIG. 1 shows a functional diagram of a device for implementing the proposed method of electromagnetic massage; in FIG. 2 voltage plots explaining the operation of the device.

 A device for implementing the proposed method of electromagnetic massage contains a massager 1, in the housing 2 of which an inductor 3 is placed. The surface 4 of the housing 2 above the inductor 3 is made elastic. The coil 3 is equipped with a magnetic circuit 5, made in the form of a half-glass of a ferrite core type SB. In this case, the coil 3 is placed inside the core 5. On the inner side of the elastic surface 4, a skin condition sensor is fixed, containing two electrodes 6 and 7. Moreover, the electrode 6 is made in the form of an incomplete turn and in the example of the device is placed in the center of the elastic surface 4. The second electrode 7 made in the form of a plate located in the center of the coil 6. The electrodes 6 and 7 are located at a distance from each other. The core 5 is covered through an elastic gasket 8 with a plate 9 of ferromagnetic material.

 In addition, the device includes a control unit 10, including a unit for setting massage modes 11, a frequency converter 12, a modulator 13 and a pulse shaper 14. Moreover, the output of the partial turn 6 is connected to the first 15 input of the block 11 for setting the massage modes, and the output of the second electrode 7 is connected to the second input 16 of block 11. The output of block 10 is connected to the input of the frequency converter 12, the outputs 17, 18 of which are connected to the inputs of the modulator 13, the output of which is connected to the input of the pulse shaper 14, the output of which 20, 21 is the output of the control unit Nia 10. Conclusions inductor 3 are connected in parallel across the capacitor 19 included in a yield of 20, 21 of control unit 10.

 Block 11 sets the massage modes contains the first 22 and second 23 comparators connected in series. The inverting and non-inverting inputs of the first comparator are respectively the first 15 and second 16 inputs of block 11. In addition, block 11 contains a programmable timer 24 and memory 25. Programmable timer 24 is connected to the start input via a resistor 26 with the output of the first comparator 22, and the first and second outputs with the first and second control inputs of the storage device 25, the information inputs of which are connected to the non-inverting input of the first comparator 22, and the output to the inverting input of the second comparator 23. Crom Moreover, the second output of the timer 24 is connected to the additional information input 27 of the storage device 25, and the control inputs of the timer 24 are connected to the information outputs of the storage device 25.

 The storage device 25 contains, for example, three memory cells 28, each of which contains a transistor 29 and a trigger 30. The base of the transistor 29 is connected through a resistor 31 to the corresponding information input of the storage device 25, and through the resistor 32 to the plus of the power source. The emitter of the transistor 29 is connected to the common bus, and the collector is connected to the input of the trigger 30, the direct and inverse outputs of which are the corresponding first and second outputs of the memory cell 28. The inverse outputs of the memory cells 28 are connected to the inputs of the adder 33, the control inputs of which are the control inputs of the storage device 25, and the output is the output of the storage device. The collector power circuit of transistor 29 and trigger power 30 are not shown. The value of the resistors 29 and 30 in each memory cell is selected so that the threshold of the memory cells increases, for example, from the first to the third cell.

 The first outputs of the memory cells 28 are information outputs of the storage device 25, the additional information input 27 of which is connected to the corresponding input of the adder 33.

 Frequency converter 10 contains the first 34 and second 35 tunable generators and the HE 36 element. The input of the HE 36 element is the input of the frequency converter 12. The HE 36 element is connected by an input to the input of the first tunable generator 34, and an output with the input of the second tunable generator 35. The outputs of the generators 35 and 34 are outputs 17 and 18 of the frequency converter 12. Tunable generators 34 and 35 can be made in the form of RC generators, in which a field-effect transistor is used as a resistor.

 The pulse generator 14 contains the first 37 and second 38 transistors, the emitters of which are connected to a common bus. The base of the first transistor 37 is the input of the pulse shaper 14 and is connected to a power source through a resistor 39. The collector of the first transistor 37 through a parallel RC circuit 40, 41 is connected to a power source and, in addition, is connected to the base of the second transistor 38. The collector of the transistor 38 is the output 20, 21 of the pulse shaper 14. The role of the modulator 13 in the example embodiment of the device can perform an element AND NOT.

 The electromagnetic massage method is as follows. Before applying the nutritional components of the massage to the patient’s skin, the physiological properties of the patient’s skin are determined, for which the magnitude of the electromagnetic waves induced in the tissue by electromagnetic fields as a result of its bioelectric activity is recorded on the control area of the skin. Nutrient massage components are then applied to the massaged surface of the patient's body. Then, in accordance with the magnitude of the amplitude of the induced electromagnetic oscillations recorded on the control area of the skin, a low-frequency pulsed complex-modulated electromagnetic field is formed with a modulation frequency in the range from 0.3 to 0.8 Hz, with a pulse repetition rate in the range from 3 to 30 Hz and with a spectrum width of harmonic components in the range from 500 Hz to 1 kHz, and they affect the patient’s skin. The duration of exposure is determined based on the physiological properties of the patient’s skin. Then a pause is made, the duration of which is also set based on the physiological properties of the patient’s skin. After a pause, the pulse repetition rate of the complex modulated EMF is increased, for which they are formed in the range from 80 to 120 Hz. After that, an additional ISM EMF is additionally applied to the patient’s skin. The duration of the additional exposure is also determined based on the physiological properties of the patient’s skin.

 Determination of the physiological properties of the patient’s skin by fixing the magnitude of the amplitude of electromagnetic waves induced in the tissue by magnetic fields as a result of its bioelectric activity, is carried out within one to two seconds. To reduce the dispersion of indications in determining the physiological properties of the skin (for example, dry, normal, oily), receptive (control) zones that have a certain structure are used. For example, the most reliable results in determining the physiological properties of the skin of the face are obtained when using the middle area of the cheek as an information (control) zone. This is because the cheek contains almost all the components of the complex of tissues present in the body: mucous, submucous, muscles, subcutaneous tissue, fat, and has strictly individual characteristics.

 Since the proposed method uses a low-frequency pulsed complex-modulated electromagnetic field to act on the skin, which is formed in accordance with the physiological state of the patient’s skin, the spectrum of harmonic components of the EMF EMF is formed from 500 Hz to 1 kHz in width, which is the most likely frequency range that allows you to adjust metabolic processes in the skin, this eliminates adaptation to the effects of tissues of the massaged surface of the patient’s body and activates the vital activity of skin cells. The latter is adequate for opening the pores of the skin. Therefore, in the proposed method there is no separate operation for preparing the skin for applying the nutritional components of massage, opening the pores of the skin, and the nutritional components are applied to the skin immediately after determining the physiological properties of the skin. After this, a massager is applied to the prepared massaged surface, a low-frequency ISM EMF is formed with the parameters: modulation frequency 0.3-0.8 Hz, pulse repetition rate 3-30 Hz, harmonic component width 500 Hz 1 kHz, and they affect the patient’s skin . The duration of this effect is usually 20-30 minutes and depends on the rate of opening of the pores of skin cells, i.e. from the functional state of the patient’s skin. After this, the massage process is interrupted for 3-5 minutes. Moreover, the specific pause time is also determined based on the physiological properties of the patient’s skin. At the same time, for dry skin this time is shorter, for oily skin more.

 At the end of the pause, the pores of the skin cells are closed. To do this, increase the pulse repetition rate, framing it in the range of 80-120 Hz, and additionally affect the skin of the patient. A quick change in the parameters of the EMF EMF leads to an energy effect on the massed tissues, instead of information, which causes their adaptation reaction to the effect and adequately closes the pores of skin cells. The time of additional exposure also depends on the functional state of the skin and usually does not exceed 5 minutes. The massage session is ending. Rapid closure of the pores of skin cells helps to preserve the maximum amount of nutritional components of massage in them and gradually assimilate them by the body. This effect increases the duration of the massage.

A device for implementing the method works as follows. After turning on the supply voltage at the outputs 17.18 of the frequency converter 12, the voltage is practically zero; the first transistor 37 of the pulse former 14 is ajar, and the second transistor 38 is closed; programmable timer 24 of the block 11 setting the massage modes is in standby mode. Before massage, determine the physical condition of the skin. For this, the massager 1 is pressed against the patient’s skin with an elastic surface 4. At the same time, the electrodes 6, 7 of the skin condition sensor are pressed against the skin. In this case, in the incomplete turn of the electrode 6, an EMF is induced due to electromagnetic oscillations (Fig. 2a, t ₁ ) induced by electromagnetic fields in a living tissue, for example, a solar electromagnetic field, as well as due to the property of a living organism to generate a response signal to the influence of external electromagnetic fields, having the character of a low-frequency pulsed complex-modulated electromagnetic field. Using the second electrode 7, the voltage corresponding to the induced EMF is set at the inputs 15, 16 of the first comparator 22 and at the information inputs of the storage device 25 of the block 11 for setting the massage modes. At the same time, in the memory device 25, the memory cells 28 are triggered along the leading edge of the positive half-cycle of the input pulse and the voltage levels corresponding to the value of the emf recorded by the skin condition sensor (for dry skin) formed on the inverse outputs of the memory cells 28 are set at the inputs of the adder 33 (Fig. 2c). At the same time, the signals from the direct outputs of the memory cells 28 through the information outputs of the memory device 25 are installed on the control inputs of the programmable timer 24. The presence of signals on all control inputs of the programmable timer 24 determines its output to the program for providing a temporary exposure mode of the EMF EMF for dry skin. At the same time, the input signal of block 11, amplified by comparator 22, starts a programmable timer 24, which counts 1-2 s and returns to its initial zeroed state. The massager is removed from the skin of the patient. The inputs of block 11 are reset to zero, and the state of the memory cells 28 is saved.

After applying the nutrient components to the skin, the massager is again applied to the skin. The skin condition sensor again captures the emf induced in the electrode 6 and sets the voltage level at the inputs of the mode setting block 11 corresponding to it (Fig. 2a, b, t ₂ ). Since the complex resistance of the skin with the nutritional components applied to it is less than that of clean skin, the amplitude of the voltage established in this case at the input of unit 11 does not cause the memory device 25 to react again and the voltage level remains at the inputs of the adder 31. Amplified by the comparator 22, the input signal of block 11 starts the programmable timer 24.

 The timer 24 generates at the first output a control signal for the adder 33, which records the voltage level from the second outputs of the memory cells 28. In this case, the voltage level corresponding to the functional state of the patient’s skin is set on the inverting input of the second comparator 23 (Fig. 2d).

 At the same time, the timer 24 begins to count the time of the procedure, for example, for dry skin. In addition, the input signal amplified by the comparator 22 is supplied to the non-inverting input of the comparator 23, the output of which is the difference signal between this signal and the voltage level established at its inverting input (fig.2d). The voltage level generated at the output of the comparator 23 is the control for the frequency converter 12. The frequency converter 12 is designed so that in this case it generates two sequentially modulated and modulating pulses in its outputs 17.18 in the form of a meander with frequencies of 3-30 Hz and 0.3-0.8 Hz, respectively. The control voltage at the input of the Converter from the frequency range generated by the Converter, selects the frequency range, adequate to the frequencies of the oscillatory processes induced in the body by external electromagnetic fields (Fig.2.zh).

 The pulse sequences generated by the converter 12 are fed to the inputs of the modulator 13, which generates a sequence of bursts of pulses at its output (Fig. 2i, k). In this case, the pulse repetition rate in the packet is in the range of 3-30 Hz, and the pulse repetition rate is in the range of 0.3-0.8 Hz.

 The first transistor 37 of the pulse shaper 14 is activated for each pulse in the packet, forming an amplified signal based on the second transistor 38. The second transistor 38 opens, thereby initiating the beginning of the charge from the power source of the capacitor 19 in the collector circuit through the inductor 3 of the massage device. In this case, electric vibrations arise in the resulting LC oscillatory circuit, which have the character of periodic damped oscillations. At the same time, an electromagnetic field is formed around the inductor 3, which also has the character of periodic damped oscillations. The pulse duration in the pack is selected taking into account the attenuation time of electrical oscillations in the resulting LC circuit and slightly exceeds it. On the trailing edge of the pulse, the second transistor 38 is closed. The pulse shaper 14 is set to the standby mode of arrival of the next pulse of the packet. Further, the whole process is repeated. As a result, in the oscillatory circuit formed by the inductance coil 3 of the massage device and the capacitor 19 in the collector of the second transistor 38 of the pulse shaper 12, a sequence of electrical pulses is formed, each of which has the form of damped periodic electrical oscillations. Therefore, the electromagnetic field induced by coil 3 also represents a sequence of electromagnetic pulses having the form of damped electromagnetic oscillations (Fig. 2l). The number of electromagnetic pulses is equal to the number of high-frequency pulses in the packet. Upon receipt of the next packet of pulses from the output of the modulator 11 similarly formed the next packet of electromagnetic pulses. As a result, after passing a series of bursts of pulses to the input of the pulse shaper 14, the electromagnetic field induced by the coil 3 is a pulsed complex modulated electromagnetic field, which is a low-frequency sequence of bursts of electromagnetic pulses, each of which, in turn, has the form of periodic damped electromagnetic waves. Due to the fact that damped periodic electric oscillations are rich in harmonics, the electromagnetic field induced by them is also polyharmonic.

 The spectral composition of the electromagnetic field 500 Hz 1 kHz form the restructuring of the LC-circuit by selecting a capacitor 19. Tuning is performed in the factory using a spectrum analyzer.

 Thus, as a result, the inductor 3 of the massager 1 generates a low-frequency pulsed complex-modulated polyharmonic electromagnetic field that is adequate to the electromagnetic waves induced in the patient’s massaged tissue by external electromagnetic fields. This contributes to the opening of pores of cells and good absorption of nutrients. Moreover, due to the fact that the inductor 3 is placed inside the magnetic circuit 5, the scattering of the formed EMF is excluded and the massage efficiency is increased.

 Vibro massage by the proposed device is carried out due to the magnetostriction effect, which causes the vibration of the ferromagnetic plate 9. The vibration of the plate 9 is transmitted to the elastic surface 4 of the body 2 of the massager located above the inductor 3. In this case, the choice of the repetition frequency of electromagnetic pulses in the range of 3-30 Hz provides comfortable sound vibrations accompanying the effect of magnetostriction.

 After the time of the main massage, the timer 24 forms a pause and removes the signal from the first control input of the storage device 25. The moment of the beginning and end of the pause can be fixed, for example, at the moment of switching on and off the indicator light. At the time of the pause, the massager is removed from the skin. The pause duration is determined by the physiological state of the patient’s skin, since the time mode generated by the timer sets the signals from the information outputs of the storage device corresponding to the physiological state of the patient’s skin.

 After a pause, the massager is applied to the massaged surface of the skin.

After a pause, the timer 24 at the second output generates a control signal for the adder 33 of the storage device 25. At the same time, the same signal is supplied to the additional information input 27 of the storage device 25, which is connected to the corresponding input of the adder 33. As a result, the output signal level of the adder 33, and therefore and the signal level at the inverted input of the comparator 23 increases. This leads to a change in the level of the control signal at the input of the frequency converter, which in turn sharply increases the repetition rate of modulated pulses at the output 17 of the frequency converter 34: in the frequency range from 80 to 120 Hz (Fig. 2a-i, t ₃ ). As a result, the pulse repetition rate of the complex-modulated EMF generated by the inductor 3 also increases sharply, which leads to an energy effect on the massed tissues, instead of an information one, and causes an adaptation reaction to the effect. The latter is adequate to close cell pores. The required duration of additional massage provides a timer 24 in accordance with the functional state of the skin of the patient.

 At the end of the additional massage time, the timer is reset and removes the control signal from the adder 33. The end of the procedure can be fixed with an indicator light (on) or a sound signal. The massager is removed from the skin of the patient.

Claims (6)

1. The method of electromagnetic massage, which includes a complex effect on the patient’s skin with heat, an alternating magnetic field and vibration with a varying frequency and amplitude of oscillations, characterized in that the physiological properties of the patient’s skin are preliminarily determined, for which the magnitude of the amplitude of electromagnetic oscillations induced on the control site of the skin is fixed in tissue with electromagnetic fields as a result of its bioelectric activity, then nutrient components are applied to the massed surface of the patient’s body, after which, in accordance with the magnitude of the induced electromagnetic oscillations recorded on the control area of the skin, a low-frequency pulsed complex-modulated electromagnetic field is formed with a modulation frequency in the range from 0.3 to 0.8 Hz, with a pulse repetition rate in the range from 3 to 30 Hz and with a width the spectrum of hormonal components in the range from 500 to 1 kHz and they affect the patient’s skin, then pause, and then increase the pulse repetition rate of the complex modulated electromagnetic field, why they form it in the range from 80 to 120 Hz and additionally affect the patient’s skin,
2. Device for electromagnetic massage, comprising a massager, in the housing of which an inductor is placed, and a control unit including a frequency converter, the surface of the housing above the coil is made elastic, and the inductor is equipped with a magnetic circuit, characterized in that the magnetic circuit is made in the form of a half-glass ferrite SB type core, covered with a plate of ferromagnetic material, inside of which there is an inductor, which is connected via a parallel capacitor it is not with the output of the control unit, in addition, a massage mode setting unit is introduced into the control unit, the inputs of which are the inputs of the control unit, a modulator and a pulse shaper, and a skin condition sensor is introduced into the massager, made in the form of a miniature antenna mounted on the inside of an elastic surface the massager body, the conclusions of which are connected to the first and second inputs of the unit for setting massage modes, the output of which is connected to the input of the frequency converter, the outputs of which are connected to the inputs of the modulator, d is connected to the input of the pulse shaper whose output is an output of the control unit.  3. The device according to claim 2, characterized in that between the magnetic circuit and the ferrite plate there is an elastic gasket.  4. The device according to claim 2, characterized in that the unit for setting massage modes comprises first and second comparators connected in series, a programmable timer and a storage device, the timer being connected by control inputs to the information outputs of the storage device, the first and second outputs to the first and the second control inputs of the storage device, in addition, the second output of the timer is connected to the additional information input of the storage device, and the start input is connected through a resistor to the output of the th comparator non-inverting input of which is connected to the data inputs of the memory device, the output of which is connected to the inverting input of the second comparator, the inverting and non-inverting inputs of the first comparator are respectively first and second inputs of mode setting unit, and the output of the second comparator being the output of the mode setting unit.  5. The device according to p. 2, characterized in that the storage device contains memory cells and an adder, each of the memory cells contains a transistor, the emitter of which is connected to a common bus, the base through the first resistor is connected to the corresponding information input of the storage device, and through the second resistor to the power source, a trigger is included in the collector circuit of the transistor, the direct and inverse outputs of which are the first and second outputs of the memory cell, the second outputs of the memory cells are connected to the corresponding inputs an adder whose output is the output of the memory, the control inputs of the control inputs of the memory devices, the additional information input coupled to a corresponding input of the adder, wherein first outputs of the memory cells are data outputs of the memory device.  6. The device according to claim 2, characterized in that the frequency converter contains an NOT circuit, two controlled frequency generators, a modulator and a pulse shaper, while one of the controlled generators is connected directly to the input of the converter, and the other is connected via the NOT circuit, the outputs of the generators are connected to the corresponding inputs of the modulator, while the pulse shaper contains the first and second transistors, the emitters of which are connected to a common bus, the base of the first transistor is the input of the shaper and is connected through a resistor to Power supply to which are connected further through a parallel RC-circuit the collector of the first transistor and the base of the second transistor, the collector of which is the output of the pulse shaper.  7. The device according to claim 2, characterized in that the skin condition sensor contains two electrodes, one of the electrodes being made in the form of an incomplete coil, and the other in the form of a plate located in the center of the coil, while the electrode leads are the sensor leads.

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