RU2266100C2 - Multielectrode - Google Patents

Abstract

FIELD: medical engineering.

SUBSTANCE: device has casing and end piece having micro-electrodes isolated from each other, switchboard mounted in the device casing and connected to each micro-electrode, amplifier and shielded cable wire. Switchboard is covered with metal-backed screen. Current source is available in the device casing having bypass resistor and band switch. The end piece having micro-electrodes is detachable. Each electrode is connected to the switchboard via connector member.

EFFECT: higher accuracy in making diagnosis; wider range of measurement and treatment currents.

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Description

The invention relates to medical equipment, in particular to devices for electropuncture with multi-contact active electrodes, and can be used in diagnostics when measuring electrical resistance and treatment when exposed to electric auricular and corporate biologically active points (BAP) of a person.

A device for electroreflexotherapy according to patent SU 1783983, class. A 61 H 39/00, publ. 12/23/92, comprising a housing with a handle, in which an active multi-electrode is placed, connected to an electronic unit, to which a passive electrode is also connected.

A disadvantage of the known device in the collective connection of the entire group of needles of a multielectrode to a current source, which does not allow using it to search for the exact position of the BAT during diagnostics.

A device for reflexology according to AS SU 1255130, class A 61 H 39/00, publ. 09/07/86, containing a passive electrode and an active multi-electrode connected through an electronic unit, the contact elements of which are made in the form of needles and have the same electrical resistance, and the working parts of the needles are located on the surface of the sphere.

A disadvantage of the known device is also in the collective connection of the entire group of electrodes to the electronic unit, which does not allow to search for the exact position of the BAT during diagnostics.

A device is known for the simultaneous installation of electrodes on a group of acupuncture points as. SU 1803094, class A 61 H 39/00, publ. 03/23/93, containing the base, longitudinal and transverse connections, and the base is made in the form of a rectangle, each side of which is a chain of multiple articulated parallelograms interconnected by hinges and bushings, and is equipped with electrode holders, and longitudinal and transverse connections are longitudinal and transverse guides passed through holes in the bushings and electrode holders, forming a matrix with a variable distance in the longitudinal and transverse directions independently.

The disadvantages of the known device in mechanical and technological complexity, low reliability due to the large number of parts, movably interconnected by articulated and flexible elements. In addition, for the diagnosis of auricular BAT with a resolution of not more than 1 mm, the design is practically not suitable.

The rapid movement of such a design on the surface of the auricle or other areas of the skin is inconvenient due to the lack of a handle or other holder.

The connection of each of a large number of electrodes with a separate wire of a length of about 1.5 m with measuring or acting equipment forms a thick and rigid cable that impedes the movement of the device on the skin surface.

Wires of this length have an electric capacity of about 50 pF, which delays in time (by 5-7 ms) transients when switching diagnostic currents of the order of 0.1-1.0 μA and reduces the noise immunity from industrial electromagnetic interference.

The closest technical solution (prototype) of the inventive multielectrode according to most of its features and technical nature is the multielectrode according to patent UZ No. 2716, class. A 61 H 39/00, publ. 09/30/95, containing a housing with a tip filled with mutually isolated microelectrodes, the working parts of which are located on the surface of the sphere, and a switching device with an amplifier connected to each microelectrode.

The disadvantage of the prototype in the rigid fixation of microelectrodes in the tip at a distance from each other (with a resolution) of the order of 0.3 mm This allows you to effectively conduct auricular diagnostics, but reduces the possibility of its use in the examination of corporal BAT located more than 10 times less often.

The well-known multi-electrode does not have a current range switch, which makes it difficult to use currents of different ranges:

- with auricular diagnosis - 0.01-1 μA;

- for corporate diagnostics - 0.1-10 μA;

- with therapeutic effect - 10-100 μA or more.

The difficulty lies in the fact that during diagnosis and treatment both constant bipolar current and alternating current are used, the formation of which requires an 8-bit DAC that provides 258 gradations of current (dynamic range D = 256 or 48 dB), and for operation in the full range 0.01-100 μA, a current control signal with a dynamic range of D = 2560000 or 128 dB is required, for which it is necessary to use a 22-bit DAC, where it is problematic to provide an acceptable level of noise, which most of all affect the measured voltage when diagnosing small s.

The known multielectrode does not have a shunt resistor current source, which avoids uncertainty in the absence of current, i.e. with quasi-infinite resistance to breaking the current circuit.

In addition, the absence of a shunt resistor, normalizing the measurement results, complicates the measurement process by the need to first determine the range of skin resistance of each patient, due to the large spread of this parameter, and the subsequent adjustment of the measuring equipment to this range, which consists in linking the beginning of the scale of the meter to the resistance of skin areas outside BAT dislocation.

The objective of the invention is to increase the efficiency of the multielectrode by increasing the accuracy and expanding the range of measurement currents and the impact on biologically active points.

The technical result of using the proposed technical solution is:

- operational transformation (change) of the density of the microelectrodes of the tip of the multielectrode;

- reducing noise due to dividing the dynamic range of the current source into subbands;

- the establishment of predetermined forms and polarity of currents in the diagnostic use of the frequency properties of BAP;

- compression of the scale of normal skin resistances (outside the BAP dislocation), including infinite resistance to rupture of the measurement circuit (when the sensor is separated from the skin) to a 15% section of the skin conductivity display scale.

Since the measurement is performed by applying direct current to the BAP, the measured parameter is the voltage, which is directly proportional to the BAP resistance. This means that the measurement scale displays resistance and extends from "0" (short circuit) to infinity (open circuit).

But for diagnostics, it is more expedient to display BAT conductivity rather than resistance, for example, the absence of BAT activity should be displayed as the initial part of the conductivity scale from zero conductivity of open circuit to normal skin conductivity of most people.

Thus, the scale for measuring BAP activity is the resistance scale, and the scale for displaying BAP activity is the inverse conductivity scale, i.e. an infinite section of the resistance scale from infinite chain breaking resistance to the usual skin resistance of most people should correspond to a small initial section of the conductivity scale, starting from zero circuit breaking conductivity to the usual skin conduction of most people. This contradiction allows eliminating the introduction of nonlinear compression of the measurement scale.

The technical task of the claimed invention is achieved in that a multielectrode for electropuncture diagnostics and electrotherapy, comprising an insulating body with a working tip filled with microelectrodes rigidly insulated therefrom, a shielded cable wire, an electronic switch with an amplifier, closed by a metallized screen connected to an electronic device computer diagnostic system and providing output to a shielded wire cable signal from one of the microelectrics The ode, further comprises a current source located in the housing with a current range switch and a shunt resistor connected to the passive electrode, while the tip with microelectrodes is made removable and filled with microelectrodes with different resolutions, the microelectrodes are equipped with connectors through which they are connected to the electronic switch, which in turn is connected to the output of the current source, a shunt resistor and the input of the amplifier, and the current source and the associated range switch The azones are also connected to the electronic device of the computer diagnostic system by individual cable wires, and the electronic switch communicates with the electronic device of the computer diagnostic system via a signal transmission circuit through an amplifier via a shielded cable wire.

Thus, the multielectrode according to the invention, in contrast to the above closest technical solution (prototype), is characterized in that it contains a current source located in the housing with a range switch and a shunt resistor connected to the passive electrode, and the tip with microelectrodes is removable, and the microelectrodes are connected with electronic switch through connectors. The electronic switch, in turn, is connected to the output of the current source, a shunt resistor and the input of the amplifier. The current source and the associated range switch are also connected to the electronic device of the computer diagnostic system by individual cable wires, and the electronic switch communicates with the electronic device of the computer diagnostic system via a signal transmission circuit through an amplifier through a shielded cable wire.

The multielectrode is equipped with a set of removable tips with microelectrodes of different resolution (different distances between the electrodes). In Fig.1 shows a structural diagram of a multi-electrode, a longitudinal section, in Fig.2, "a" and "b" are embodiments of tips with microelectrodes, Fig.3 is an electrical block diagram of a multielectrode, Fig.4 is a graph of display characteristics resistances of the skin with the output voltage of the microelectrode using and without a shunt resistor.

The microelectrode contains placed in the housing 1, for example a cylindrical one, an electronic switch 2 with an amplifier 3, a current source 4 with a shunt resistor 5 and a range switch 6 closed by a metallized screen 7, for example, metallized plastic.

A removable working tip 8 from the microelectrode 9 is fixed at the end of the housing 1. Microelectrodes 9 in the tip 8 are rigidly fixed, their outputs on the working surface are distributed along a given grid of distances between them, and the opposite ends are equipped with a connector 10. Switch 2, amplifier 3, current source 4 The 6 range switch is based on microchips.

Each microelectrode 9 of the tip 8 through the connector 10 is connected to a switch 2, which is connected to the output of the current source 4, a shunt resistor 5 and the input of the amplifier 3.

A current source 4 is connected to a 6 range switch. Amplifier output 3.

A current source 4 is connected to a 6 range switch. The output of amplifier 3 is connected by a shielded wire of cable 11 to an electronic device 12 (not shown) of a computer diagnostic system (CDS) that manages the multi-electrode circuit according to a given program and measures the signals recorded by the multi-electrode.

In addition, the switch 2, the current source 4 and the 6-band switch with individual wires of the cable 11 are also connected to the electronic device 12 of the CDS by the current lead (Fig. 3).

The presence of the connector 10 between the microelectrodes 9 and the switch 2 allows you to quickly change the tips 8 of the multi-electrode with different resolutions for auricular or corporate diagnostics and treatment, which expands the possibilities and efficiency of using the claimed multi-electrode in comparison with the prototype.

The presence of an adjustable source 4 of the exposure current allows you to generate current, the magnitude and polarity of which is proportional to the control voltage coming from the electronic device 12 KDS, which in turn allows you to influence the BAT with a constant current of a given magnitude and polarity or a pulse current of a given amplitude, duty cycle and polarity, and also alternating current of a given amplitude, frequency and shape (sawtooth, sinusoidal, etc.).

The latter allows to increase the efficiency of the diagnostic use of the frequency properties of BAP.

The presence of a switch of 6 current ranges allows with the same relative error - 1/4096 (when using a 12-bit DAC) and equally low noise level to generate exposure currents in the ranges of auricular and corporate diagnostics, as well as currents in the treatment range.

At the same time, the current range required for diagnosis and treatment is 0.01-100 μA, divided into 4 ranges: 0.01-0.1 μA, 0.1-1 μA, 1-10 μA and 10-100 μA, which allows to increase the permissible the relative error from 1/4194304 (when using a 22-bit DAC in the full dynamic range) to 1/4096 (when using a 12-bit DAC and a range switch), i.e. 1000 times. At the same number of times (three orders of magnitude), the noise level of the current source 4 is also reduced.

The multi-electrode operates as follows (see figure 3)

The doctor turns on and sets up the CDS, connects the passive electrode 13 to the patient’s arm or leg, then takes the multielectrode by the housing 1 and applies the working tip 8 to the BAT dislocation area on the human skin. The electronic device 12 of the CDS via cable 11 transfers to the multi-electrode a digital control code of the switch 2 to its address input.

Corresponding to this code, the microelectrode 9 is connected by a switch 2 with the output of the source of current 4 and the input of the amplifier 3. At the same time, the electronic device 12 of the CDS via cable 11 transmits a digital control code to the microelectrode at the input of the 6-band switch.

The switch 6 ranges in accordance with this code sets the current source 4 to the desired range of current values. At the same time, the electronic device 12 KDS through cable 11 transmits to the input of the current source 4 the current control signal of the exposure current.

The current source 4 generates an exposure current directly proportional to the voltage and shape of the incoming control signal. The exposure current generated by the current source 4 passes through the switch 2, the selected microelectrode 9, the point of skin that the microelectrode 9 is in contact with, the patient’s body and goes through the grounded passive electrode 13 to the ground.

The skin point through which the exposure current flows has an electrical resistance, measured for diagnostic purposes, at which a voltage drop is allocated that is directly proportional to its resistance. This voltage drop through the microelectrode 9 and the switch 2 is fed to the input of the amplifier 3, which amplifies the signal and transfers it to the electronic device 12 of the CDS through the shielded wire 14 of the cable 11.

Next, the control code of the switch 2 is changed in accordance with the program so that the next microelectrode 9 is connected through the switch 2 to the output of the current source 4 and the input of the amplifier 3. After this, the process of measuring the voltage drop at the corresponding point on the skin is repeated.

After scanning the entire skin area under microelectrodes 9, the process is cyclically repeated several times in accordance with a given program and the doctor can search for BAP by moving the multielectrode over the skin surface.

The shunt resistor 5 selects a portion of the measuring current, which introduces a nonlinearity in the graph 15 (see figure 4) of the dependence of the output voltage on the measured skin resistance. There, for comparison, graph 16 of the same dependence is shown, but without a shunt resistor. The voltage U _{o of the} graph 15 with increasing skin resistance R of the _skin asymptotically tends to the value (line 17 on the graph) of the voltage drop across the shunt resistor 5, which allows you to compress the display scale of the infinitely long section of high resistances to a small (about 15% of the whole scale) initial section skin conduction scales.

By selecting the resistance value of the shunt resistor 5 (optimally about 3 mOhm), one can tie the whole variety of dry skin resistances of patients outside the BAP dislocation to the initial 15% portion of the measurement scale.

In an optimal embodiment, the multi-electrode is made by the applicant as follows.

The housing 1 and the tips 8 are cylindrical in shape and made of plastic, for example hard rubber or polystyrene.

Microelectrodes 9 in the amount of 64 pieces are made of stainless steel. Switch 2 is made in the form of a package of 9 rectangular printed circuit boards with planar cases soldered to them by 8 microchips 590 KN 6 and one 564 ID 1.

The current source 4 is made according to the Howland circuit on an operational amplifier 140 UD 1208 and discrete resistors planarly soldered to one side of a round printed circuit board.

The 6 range switch is made on a 590 KN 3 chip and discrete resistors planarly soldered on the other side of a round printed circuit board.

The amplifier 3 is made according to the repeater circuit on the chip 140 UD 1208 and is planar soldered on the location side of the current source 4 of the round printed circuit board.

The claimed multi-electrode was tested and showed a significant advantage, efficiency and reliability in comparison with the devices known to the applicant for diagnosis and treatment using human BAT.

Claims (1)

A multielectrode for electropuncture diagnostics and electrotherapy, comprising an insulating body with a working tip filled with microelectrodes rigidly insulated from it, a shielded cable wire, a switch covered by a metallized screen connected to an electronic device of a computer diagnostic system and configured to output to a shielded wire signal cable from one of the microelectrodes, and an amplifier, characterized in that it further comprises case, a current source with a switch of current value ranges and a shunt resistor connected to a passive electrode, while the tip with microelectrodes is made removable, and the microelectrodes in it are made so that their outputs to the working surface are distributed along a given grid of distances between them, and the opposite ends are provided connectors, through which they are connected to an electronic switch that is connected to the output of the current source, a shunt resistor and the input of the amplifier, and the current source and the associated switch the range selector is connected to the electronic device of the computer diagnostic system by separate cable wires, the switch being connected to the electronic device of the computer diagnostic system via an amplifier through a shielded cable wire.

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