RU2063218C1 - Ionic epicutaneous stimulator "istina" - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: the ionic epicutaneous stimulator has an active high-voltage and a passive electrodes, connected to a power source, as well as an element of porous dielectric material positioned against the active electrode and featured by the fact that, with the aim of stabilization of the ion flux and provision of electric safety, the source is mate with stabilization of load current, and at least one system of counterelectrodes is additionally introduced, whose corona-forming electrode is connected to the active electrode, and the receiving electrode is connected to the passive electrode. The ionic epicutaneous stimulator is also featured by the fact that, with the aim of enhancing the effectiveness at action on the integument due to forming of an ion flux variable in amplitude and frequency, the additional system of counter-electrodes is made for periodic variation of the interelectrode gap by means of an electromechanical drive. The ionic epicutaneous stimulator is also featured by the fact that the additional system of counter-electrodes is made for periodic variation of the corona-forming surface of the electrode with the aid of the electromechanical drive. The ionic epicutaneous stimulator is also featured by the fact that the electrode of the additional system of counter-electrodes is covered by a porous dielectric element, and the porous dielectric element positioned against the active electrode is coated by a layer of current-conducting material on the side of the electrode. The porous dielectric element is impregnated with medicinal substance. EFFECT: enhanced effectiveness. 6 cl, 3 dwg

Description

 The device relates to medical equipment, namely, devices for electrical stimulation of human reflexogenic zones.

 The closest in technical essence is an iontophoresis device containing an active corona electrode placed in a dielectric housing, and a passive electrode connected to a high-voltage power source. Opposite the corona electrode, a gasket of dielectric material is located on an open surface (French Application N 2616333, A 61 N 1/44, 1988).

 The disadvantage of this device is uncontrolled (non-periodic) sudden changes in the discharge current of the forward and reverse corona, possible during the procedure, which are due to the probabilistic nature of electrical discharges. This leads to instability of the ion flux, which determines the therapeutic effectiveness of physiotherapy.

 The aim of the invention is to stabilize the flow of ions and ensuring electrical safety.

 It is achieved by the fact that in a cutaneous ionic stimulator containing an active high-voltage and passive electrodes connected to a power source, as well as an element of porous dielectric material located opposite the active electrode, according to the invention, the source is made with load current stabilization and at least one additional counter electrode system, the corona electrode of which is connected to the high-voltage output of the source, and the receiving electrode is connected to the passive electrode.

 To ensure variable in amplitude and frequency of the electrofactor according to the invention, an additional system of counter electrodes is made with the possibility of periodically changing the interelectrode distance by means of an electromechanical drive.

 According to the invention, an additional counter electrode system is arranged to periodically change the magnitude of the corona surface of the electrode using an electromechanical drive.

 According to the invention, the receiving electrode of the additional counter-electrode system is coated with a porous dielectric element.

 According to the invention, the porous element opposite the active electrode is coated with a layer of electrically conductive material from the side of the electrode.

 According to the invention, the porous dielectric element is impregnated with a drug substance.

 In FIG. 1 shows a schematic diagram of a device; figure 2 another of its modifications; figure 3 modification of an additional system of counter electrodes.

 The stimulator consists of a high-voltage source 1, to which an active electrode 3 is connected through a ballast resistance 2, mounted opposite the porous dielectric strip 4 in the dielectric housing 5. A passive electrode 6 is provided, which is connected to the low-voltage output of source 1. An additional counter-electrode system (corotron) contains a corona electrode 7, connected to the high-voltage output of the source 1, and a receiving electrode 8, connected to the passive electrode 6 and the low-voltage output of the source 1. Coronier The supply electrode 7 can be equipped with a screen, in this case a tube (electrically conductive), or a dielectric 9 mounted for movement along the corona electrode (in this case, the strings) 7. The drive can be any mechanical or electrical device that provides reciprocating movement of the tube 9. The receiving electrode 8 may be coated with a porous dielectric pad 10. The porous pad (element) 4 and the passive electrode 6 are installed on the skin of a person 11. The gasket 4 can be coated with a layer of electrically conductive material 12. The receiving electrode 8 can be connected to the low-voltage output of the source 1 through a chain containing a neon lamp 13 and a resistor 14 connected in parallel.

 In FIG. 3 separately depicts a modification of an additional system of counter electrodes (a corotron in which one end of the corona string 7 is wound on a pulley (drum) 15 and the other is attached to a dielectric thread (fishing line) 16 wound on a pulley 17. The pulleys are associated with an electromechanical drive (not shown) . To ensure the supply of high voltage to the corona electrode 7, a sliding contact 18 is provided.

 The device operates as follows. Passive electrode 6 is placed on the body of a patient undergoing ion therapy. Then, a housing 5 is applied to the skin 11 in the region of the reflexogenic zone so that the porous element 4 is in contact with the skin, and a high voltage, for example, of negative polarity, is supplied from the source 1. With a certain voltage value on the active electrode 3, a corona discharge will occur. Negative ions rush to the skin surface and settle on the dielectric element, charging it and increasing the electric field strength in the pores. Upon reaching the tension in the pores sufficient for secondary ionization, a microdischarge will occur in each of them, leading to the additional formation of ions of both polarities. Positive ions rush from the pores to the active electrode 3, and negative ions to the skin 11. In an additional corotron, consisting of counter electrodes 7, 8, a discharge also occurs. However, the radius of curvature of the corona electrode 7 and its distance to the receiving electrode 8 are set such that the corona current in the corotron is much less (about an order of magnitude) than the current of the ion flow to the patient. Since the source 1 is made with stabilization of the load current, the ion flow in the housing 5 and the discharge current in the additional corotron are stable. In the case when the active electrode 3 is removed from the patient (or a wire breakage occurs to the electrode 3), there will not be a sharp increase in voltage at the output of source 1 (which necessarily occurs in the absence of an additional system of counter electrodes 7.8, because the power source is stabilization of the load current can not idle, it automatically increases the voltage to the limit, which is dangerous, and fails). In our case, the current in the corotron will increase by the amount of the procedure current, and the output voltage of source 1 will increase slightly. At the same time, the neon lamp 13 will illuminate, signaling an emergency mode. When returning the electrode 3 with gasket 4 to patient 11, the previously established ion flow will resume, the current in the corotron will drop to its original value, neonka 13 will go out.

 In FIG. 1, 2 shows additional corotrons implemented in the form of coaxial cylinders: a thin wire (string) is tensioned inside the tube 8. However, the corotron can also be made in the form of needle-plane, wire-plane, etc. The receiving electrode 8 of the corotron can be it is also covered with a layer of porous dielectric 10. In this case, when the active electrode 3 is removed from the patient, a reverse crown will appear in the pores of the gasket 10 and the current will be set to the same value as from the electrode 3 before it is removed from the patient. The output voltage of the source 1 will increase by an amount even lower than in the case of a clean receiving electrode (figure 1). When the electrode 3 with element 4 is returned to the patient, ionization will reappear in the gasket 4 and the current will be restored, and in the corotron it will fall to the previous minimum value.

 Often in medical practice, it becomes necessary to expose the patient to a stream of ions (electro-factor), which varies according to a periodic law. In the proposed device, this can be achieved by several options devices. If the corotron is represented by coaxial cylinders (see Fig. 2), then on the string 7 put on a tube 9 (electrically conductive or dielectric). Sliding and pushing it inside the cylinder 8, we shield (overlap) part of the corona surface of the electrode 7, changing the magnitude of the corona current. Since source 1 stabilizes the total load current, when the current in the corotron decreases by the same amount, the ion current per patient increases, and, conversely, when the current of the corotron increases, the current of the procedure decreases. The reciprocating movement of the tube 7 is easy to provide any electromechanical drive (not shown). Changing the frequency of movement of the tube 9 and the depth of entry into the cylinder 8, we can adjust the frequency and amplitude of the electrofactor. The magnitude of the corona surface of the electrode can be changed using shielding curtains installed instead of the tube, which are installed in the interelectrode gap with the possibility of their movement. If the corotron is made in the form of a “needle-plane” or “wire-plane” system, then a variable electro-factor can be realized by changing the interelectrode distance by imparting a reciprocating plane using an appropriate electromechanical drive. The value of the corona surface of the electrode 7 can be changed as follows (see figure 3). With the help of the drive pulleys 17 and 15 are driven in a rotational motion, first in one, then in the other direction. At the same time, wire 7 and fishing line 16 are unwound and unwound. The length of the corona piece of wire 7, located in the cylinder 8, then decreases, then increases. In accordance with this, the current of the corotron decreases and increases simultaneously, and, conversely, increases and then decreases the ion current to the patient.

 The counter electrode system 7.8 can be connected as shown in FIG. 1 or in FIG. 2. The latter option is preferable, since when the string 7 breaks (its thickness is about 100 μm), the active electrode 3 is also turned off.

 The porous pad 4 can be coated with a layer of electrically conductive material 12. This leads to an increase in capacitance and, consequently, to a decrease in the frequency of the discharge in the pores of element 4, but an increase in their power.

 The porous element 4 may be pre-impregnated with a drug substance. Then during the procedure there will be electrophoresis. The porous element can be fed with medicine during the procedure (using a dropper, for example).

 An additional corotron (with and without a drive) in combination with a stabilizing source gives new functionality and increases the efficiency of the device both with a static acting electrode (described above) and with a dynamic rotating electrode. YYY2

Claims (6)

 1. Cutaneous ionic stimulator containing an active high-voltage and passive electrodes connected to a power source, as well as an element of porous dielectric material located opposite the active electrode, characterized in that the source is made with stabilization of the load current and at least one counter-electrode system is introduced, the corona electrode of which is connected to the active electrode, and the receiving electrode with a passive electrode.  2. The stimulator according to claim 1, characterized in that the counter electrode system is configured to periodically change the interelectrode distance by means of an electromechanical drive.  3. The stimulator according to claims 1 and 2, characterized in that the counter electrode system is configured to periodically change the surface value of the corona electrode using an electromechanical drive.  4. The stimulator according to claim 1, characterized in that the receiving electrode of the counter electrode system is coated with a porous dielectric element.  5. The stimulator according to claim 1, characterized in that the porous dielectric element located opposite the active electrode is coated with a layer of electrically conductive material from the side of the active electrode.  6. Stimulator according to claims 1 to 5, characterized in that the dielectric porous element is impregnated with a drug substance.

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