RU2266762C2 - Method and device for applying dynamic electrostimulation - Google Patents

Abstract

FIELD: medicine; medical engineering.

SUBSTANCE: method involves producing pulses of given frequency, modulating the pulse durations, amplifying the pulses and sending them via electrodes to biological object skin surface. Subelectrode skin area impedance capacitive component rate is determined during stimulation. Impedance rate value being close to zero, stimulation time interval is to be hold within 3-5 min and the stimulation is stopped next to it. Device has oscillator connected to pulse duration modulator, stimulus power setter connected to the second modulator input, pulse power amplifier connected to pulse duration modulator output, indication unit connected to the first output of power amplifier and electrodes connected to the second pulse power amplifier output and differentiation unit input. The device also has pulse duration shaper, memory unit, timer and adder. Differentiation unit output is connected to pulse duration shaper input. Shaper output is connected to memory unit input with one of adder inputs. Memory unit output is connected to the other adder input. The adder output is connected to timer. Timer output is connected to indication unit.

EFFECT: enhanced effectiveness and objectiveness in determining procedure duration and dose.

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Description

The present invention relates to medicine and relates to percutaneous electrical stimulation. The invention can be applied in physiotherapy and reflexology for electrical stimulation of biological objects in clinics, hospitals, dispensaries, sports complexes, in veterinary medicine and in everyday life as an auxiliary or main tool in the treatment and prevention of diseases of humans and animals.

In the methods and devices of dynamic electrical stimulation to determine the adequacy of the impact, the dynamics of the frequency of the forced oscillations of the resonant circuit formed by the inductance of the output transformer and the capacitive component of the impedance of the sub-electrode section of the skin surface is taken into account. The active component of the impedance of the subelectrode region of the skin affects the quality factor of the contour and affects the decay rate of forced vibrations. The capacitive component of the impedance, which changes due to perspective in the process of stimulation, affects the frequency of forced oscillations. Sufficiency of exposure or dosage of exposure is determined by the nature of the change in impedance of the sub-electrode area of the skin to optimize the treatment algorithm and achieve sustainable changes in one or more physiological parameters.

A known method of pulsed electrotherapy of a biological object, in which the sufficiency of exposure is determined by stabilizing the dynamics of changes in the amplitude of the signal (patent RU 2118901).

The method is as follows. Electric impulses of a given frequency and a given duration are formed, which amplify and apply to the electrodes for stimulation. As soon as the stabilization of the amplitude of the forced oscillations occurs, the stimulation is stopped.

The determination of the sufficiency of electrical stimulation and its termination by this method has no physiological justification, since the amplitude of the forced oscillations largely depends on the pressure of the electrodes on the skin surface. All this leads to a decrease in dosage accuracy and therapeutic effect due to the uncertainty of the time interval of electrical stimulation.

A known method of regulating the psychosomatic homeostasis of a biological object, according to which the adequacy of the effect is determined by stabilizing the dynamics of changes in the duration of the first half-wave signal (patent RU 2068277).

The method is as follows. Electric impulses of a given frequency and a given duration are formed, which amplify and apply to the electrodes for stimulation. Then, depending on the rate of change of the first half-wave of forced oscillations, the effect of therapeutic stimulation is evaluated, the pulse repetition rate is changed, and stimulation is stopped if there is no dynamics in the change in the duration of the first half-wave.

The determination of the adequacy of stimulation by this method has no physiological justification, since the frequency of forced vibrations depends on the value of the capacitive component of the impedance of the subelectrode region of the skin and is determined by the level of perspiration, which leads to the appearance of a salt solution with a high dielectric constant and a corresponding decrease in the frequency of forced vibrations. The moment of stabilization of the parameter is the phase of the electrodermal reaction, but is not in itself the basis for terminating the electrical stimulation procedure.

All this leads to a decrease in dosage accuracy and therapeutic effect due to premature termination of stimulation.

A known method of stimulation of a biological object, in which the sufficiency of exposure is determined by the level of the derivative of the output signal to change the duration of a series of stimulating pulses (SU 1817335).

The method is as follows. A sequence of stimulating pulses is generated, the duration of which is changed using a modulator in proportion to the voltage at its control input. These pulses are amplified and fed to the electrodes for stimulation. The output energy is directly proportional to their duration. In case of pathological changes in the stimulated tissues, the stimuli at the output of the electric stimulator look like short pulses with an exponential decay and an oscillatory establishment process. In this case, the signal at the output of the differentiating element is sufficient to set the duration of a series of pulses close to zero. Thus, a certain threshold value of the signal from the differentiating element determines the moment of completion of stimulation.

The determination of the adequacy of stimulation by this method has no physiological justification, since the value of the capacitive component of the impedance is determined by the level of perspiration, which leads to the appearance and concentration of a brine with high dielectric constant under the electrodes and, accordingly, to an increase in the capacitive component of the impedance of the sub-electrode section, followed by a decrease in the frequency of forced fluctuations. In addition, in the mode with stationary electrodes during electrical stimulation, the process of lowering the frequency is always one-sided in nature within the treatment zone due to the accumulation and delayed evaporation of moisture from the skin surface. At some point, the perspiration process begins to saturate, in which the cessation of stimulation occurs. The saturation moment is a phase of the electrodermal reaction, but is not in itself the basis for the termination of stimulation.

All this leads to a decrease in dosage accuracy and therapeutic effect due to premature termination of stimulation.

The known device for stimulation, taking into account the dynamics of impedance changes, contains a pulse generator, a modulator and an amplifier connected to it (patent RU 2068277).

The rectangular voltage pulse from the output of the pulse generator is supplied to one input of the modulator, to the other input of which pulses from the stimulator energy generator are supplied. At the output of the modulator, a rectangular-shaped pulse-modulated voltage is generated, which is fed to the input of the amplifier, and from its output is fed to a biological object.

In this device, the duration of the first half-wave is determined by the rectifier, which reduces the speed of the circuit. In addition, the circuit disables stimulation as soon as the change in the duration of the first half-wave ceases, which leads to an unreasonable termination of the stimulation procedure.

A device is known that takes into account the dynamics of changes in impedance and contains serially connected control unit, key, amplitude measuring unit (patent RU 2118901).

The control unit generates stimulation pulses, each of which is supplied to the load through the key, and the amplitude measurement unit is used to determine the stabilization of skin conduction parameters.

In this device, the adequacy of stimulation is determined by the amplitude of the first half-wave, which is more determined by the active component of the impedance and depends on the pressure of the electrodes on the skin surface than on the capacitive component. This reduces the reliability of any impedance estimates for the subsequent development of a treatment algorithm. In addition, the circuit disables stimulation as soon as the amplitude of the first half-wave has stopped changing, which leads to an unreasonable termination of the stimulation procedure.

A device is known that implements the method described above, comprising a stimulating pulse generator connected to a pulse width modulator, a stimulus energy adjuster connected to a second input of the modulator, a pulse power amplifier connected to a pulse width modulator, an indicator connected to a power amplifier, electrodes, connected to the input of the differentiating element and to the outputs of the pulse power amplifier and applied to the biological object (SU 1817335).

The generator generates a sequence of stimulating pulses, the duration of which varies with the modulator in proportion to the voltage at its control input. Duration-modulated stimuli are supplied to the electrodes through a power amplifier. The energy at the output of the electric stimulator is directly proportional to their duration and is estimated by the frequency of flashes and the intensity of the indicator glow. In case of pathological changes in the stimulated tissues, the stimuli at the output of the electric stimulator look like short pulses with an exponential decay and an oscillatory establishment process. In this case, the signal at the output of the differentiating element is sufficient to set the duration of a series of pulses close to zero. Thus, a certain threshold value of the signal from the differentiating element determines the moment of completion of stimulation.

The elements included in the circuit cannot provide control over the rate of change of impedance and the duration of stimulation. This leads to an unreasonable termination of the stimulation procedure.

The technical result of the claimed method of electrical stimulation and device for its implementation is to increase the accuracy of ensuring the adequacy of the impact.

The technical result is achieved by the fact that in the method of electrical stimulation generate pulses with a given frequency, modulate them in duration, amplify and feed through the electrodes to the skin surface of a biological object, according to the invention, during electrical stimulation, the rate of change of the capacitive component of the impedance of the sub-electrode section of the skin of the object and when the speed is reached changes in impedance close to zero withstand the time interval of stimulation for 3-5 minutes, after which the stimulation is stopped.

When determining the rate of change, the well-known principles of converting parameters to time intervals with memory elements are used to compare the previous value with the subsequent one. The difference in time intervals per unit of time determines the rate of change of the parameter.

It is known that the rhythmic activity of the heart is a universal operational response of the body to any environmental impact and there is a method of variational cardiointervalometry, which allows you to determine the level of inclusion of heart rhythm control processes and reflects the voltage of regulatory mechanisms in the form of a voltage index. The method is designed to register significant and stable shifts in the functional state.

Using the method of variational cardiointervalometry, it was found that in the interval from 3 to 5 minutes after the rate of change of the capacitive component of the impedance decreases to a value close to zero, there is a significant and steady decrease in the voltage index of regulatory systems at the segmental level of vegetative regulation, up to its stabilization. The achievement of these physiological changes can be interpreted as the minimum effective dose of electrical stimulation to obtain significant and stable shifts in the functional state under local or segmental exposure.

The problem is also solved by the fact that in a device containing a generator connected to one of the inputs of the pulse modulator in duration, the other input of which is connected to a stimulator of energy stimuli, a power amplifier of pulses connected to a pulse modulator in duration, an indicator connected to one of the outputs power amplifier, and electrodes connected to other outputs of the pulse power amplifier and applied to the biological object and to the input of the differentiating element, according to the invention additionally, a pulse former for duration, a memory element, a timer, an adder are provided, the output of the differentiating element being connected to the input of the pulse former, and the output of the pulse former for duration connected to the input of the memory element and one of the inputs of the adder, to the other input of which the output of the memory element is connected , and the output of the adder is connected to a timer, the output of which is connected to the indicator.

Using a memory element and an adder allows you to determine the rate of change of the impedance and the moment of stabilization of its value.

Using a timer allows you to set the time interval after stabilization of the impedance value during electrical stimulation.

Further, the invention is illustrated by a description of a specific example of its implementation with reference to the accompanying drawings, in which:

figure 1 depicts a timing diagram of signals;

figure 2 is a structural diagram of a device.

The method of electrical stimulation of a biological object, in which the sufficiency of the impact is determined by the rate of change of the impedance and the time interval to establish the duration of a series of stimulating pulses, is as follows.

Pulses are generated with a given frequency, which are modulated in duration and amplified, after which they are fed through electrodes to the skin surface of a biological object. Sufficiency of stimulation is determined by the rate of change of the capacitive component of the impedance and the stimulation is stopped after a time interval after the speed decreases to a value close to zero. The indicator displays the rate of change of the specified parameter during stimulation and time intervals.

On the presented diagram “a” (Fig. 1) the time interval of stimulation is shown, on the diagram “b” - the nature of the change in the capacitive component of the impedance of the subelectrode region of the skin, on the diagram “c” - the time interval after stabilization of the value of the capacitive component of the impedance, on the diagram “d "- a typical graph of changes in the voltage index.

At time t ₁ on plot “a” after the start of electrical stimulation, the impedance of the sub-electrode skin area decreases to moment t ₂ on plot “b”, in which the rate of change is close to zero, an audio signal is turned on, and the countdown starts, then at the end of the time interval of 5 minutes, i.e. at time t ₃ , a signal is sent about the end of the time interval of stimulation sufficient to decrease with stabilization of the voltage index, and the procedure can be stopped.

At the moment t _{2 of} stabilization of the impedance on the diagram "d", the change of such a physiological indicator as the stress index continues, which depending on the characteristics of the nervous system in the time interval from t ₁ to t ₂ may decrease, or may increase. After two to three minutes from the moment of stabilization of the rate of change of t _{2 of the} capacitive component, a steady decrease in the index begins with a gradual exit to the plateau, which lasts a long time. Thus, the minimum effective dosage can be determined. Further stimulation does not affect the value of the voltage index of regulatory systems, and it can be stopped.

The device for electrical stimulation (figure 2) contains a generator 1 connected to the input 2 of the pulse modulator 3 in duration, the input 4 of which is connected to the stimulator 5 stimulus energy. An amplifier 6 of pulse power is connected to the output of the modulator 3, an indicator 8 is connected to the output 7 of which is connected to the outputs 9 of the electrodes 10, also connected to the input of the differentiating element 11, in addition, the device contains a pulse shaper 12 for duration, which is connected to the output differentiating element 11, memory element 13, timer 14, adder 15, and the output of the shaper 12 is connected to the input of the memory element 13 and to the input 16 of the adder 15, with the other input 17 of which the output of the memory element 13 is connected. The output of the adder 15 is connected to a timer 14 connected to the indicator 8.

The second output of the timer 14 can be connected to the input of the stimulator 5.

The generator 1, modulator 3, master 5, amplifier 6, differentiating element 11, pulse shaper 12, memory element 13, adder 15, timer 14 are made according to well-known schemes described in the Art of Circuit Engineering P. Horowitz, W. Hill. In two volumes. Mir (Moscow) 1984, and can be performed on the basis of the K561, 1561 series or Intel, Atmel microcontrollers.

The electrical stimulation device operates as follows.

Rectangular pulses of the generator 1 are fed to the input 2 of the modulator 3, to the input of which 4 is connected the energy adjuster 5, the output signal of which is supplied to the modulator 3 pulses in duration. From the output of modulator 3, the signals are fed to the input of amplifier 6, amplified pulses are fed to the electrodes 10 and to the input of the differentiating element 11. From output 7 of amplifier 6, the signal is fed to indicator 8, which displays the current state of stimulation parameters, for example, frequency, energy, time intervals, speed impedance changes. From the output of the differentiating element 11 to the input of the pulse shaper 12 in duration, signals are received with an interval equal to half the first period of forced oscillations. Thus, the lower the frequency of the forced oscillations, the longer the output of the shaper 12 is longer. The output pulses of the shaper 12 are fed to the memory element 13 and to the input 16 of the adder 15, the input 17 of which receives the output pulses of the memory element 13. The current pulse width is compared with the previous one. As soon as the difference in the duration of these periods becomes close to zero, which corresponds to a decrease in the rate of change of the capacitive component of the impedance to a value close to zero, an output will appear at the output of the adder 15, starting the timer 14 to count the time interval of the stimulation, during which the reduction and stabilization voltage index, with its display on the indicator 8.

The second output of the timer 14 can be connected to the input of the stimulator energy setter 5 to automatically stop stimulation at the end of the time interval to reduce and stabilize the voltage index.

The treatment of patients with various pathologies was observed: osteochondrosis of the spine with neurological phenomena, bruises of the lower leg and ankle joints, neurocirculatory dystonia, headaches against the background of cervical osteochondrosis.

The course of treatment consisted of 5-10 sessions of daily single procedures, the duration of which ranged from 5 to 10 minutes. The current was supplied until a sensation of painless vibration, tingling. The time to reach the impedance plateau ranged from 15 seconds to several minutes.

Using the ability to control the dynamics of changes in impedance with time interval exposure allowed us to reasonably determine the time of the procedures and dosage. All patients tolerated electrical effects well, adverse adverse reactions were not observed.

Claims (2)

1. The method of electrical stimulation, which consists in the fact that they generate pulses with a given frequency, modulate them in duration, amplify and feed through the electrodes to the skin surface of a biological object, characterized in that during electrical stimulation they determine the rate of change of the capacitive component of the impedance of the sub-electrode portion of the skin of the object and reaching a value of the rate of change of the impedance close to zero, maintain the time interval of stimulation for 3-5 minutes, after which the stimulation is stopped. 2. Device for electrical stimulation, containing a generator connected to one of the inputs of the pulse modulator in duration, the other input of which is connected to a stimulator of energy stimuli, a pulse power amplifier connected to a pulse modulator in duration, an indicator connected to one of the outputs of the power amplifier, and electrodes connected to other outputs of a pulse power amplifier applied to a biological object and connected to the input of a differentiating element, characterized in that in it the pulse shaper in duration, a memory element, a timer, an adder have been introduced, the output of the differentiating element being connected to the input of a pulse shaper in duration, the output of which is connected to the input of the memory element and to one of the inputs of the adder, to the other input of which the output of the memory element is connected, and the output of the adder is connected to a timer, the output of which is connected to the indicator.

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