EA007347B1 - Magnetic pulse stimulation apparatus and magnetic field source thereof - Google Patents

Abstract

The present invention relates to medical equipment, and more particularly to an apparatus for pulse magnetic stimulation of various organs and systems of various organs and systems of the systems of the human body.To provide wide application of a method of magnetic stimulation and to design a fairly inexpensive and reliable apparatus for magnetic stimulation, it is necessary first of all to increase the rate of magnetic induction rise up to the value of DELTA B/ DELTA t=10T/sec. The latter will make it possible to considerably reduce energy consumption of an apparatus for magnetic stimulation, to increase pulse repetition up to 1-2 kHz with the duration of an efficient stimulation pulse being increased up to ts= 1 sec and more, i.e. to provide the modulation frequency of about 30 pulse trains per minute.The object of the invention set forth in the apparatus for magnetic stimulation comprised of an oscillatory circuit containing a capacitor and a source of unipolar magnetic field pulses, said source further comprising a winding, a power supply unit and a storage capacitor, said capacitor connected in parallel to a capacitor in the oscillatory circuit, and also first and second controlled switches, and first and second diodes is achieved by providing said magnetic field source with a core made of soft magnetic composite material.

Description

Technical field

The invention relates to medical equipment, in particular equipment for pulsed magnetic stimulation of various organs and systems of a person.

Background of the Related Art

Stimulation by a pulsed magnetic field of the central and peripheral nervous systems and various internal organs consists, first of all, of optimizing the process of creating an induced electric field in a given place, sufficient in magnitude to activate certain processes.

The process of optimizing the impact includes, as a consequence, determining the shape and duration of the magnetic field pulse, pulse repetition rate and magnetic field distribution near the emitter. These questions of magnetic stimulation were investigated in a number of works {A1ehapbeg e! a1. Tgea1shep! OG Ippatu 1psopeypepsy E1es! ys Rekkagu. Run b. OG Itododu (1980), 42.184-190 [1]; Moses ^ at, S1oke-S11ek1 Sagb1as 8! 1ti1iop \ νίΐ1ι Ri1ke Madpeys Ie1b, Mebua1 apb Vu1od1sa1 Eppsheppd apb Sotri! E Mag. (1992), 162-169 [2]; Whipokisy e! a1. Jeue1orsche Moghe Eosa1 Madpeys 8it1a! From. 1. OG Syssha1 No. Igoryukyuodu (1991), 8, 102-111 [3]; Soyep e! a1. EGGes! OG Soi Eek1dp op Ieyuyu OG Eosa1 Madpeys 8iti1ayop. E1es! Goepsery1odgaryu apb Syssa1 №igoryukyu1odu. (1990), 75, 350-357 [4]; MShk e! a1. Madpace Vtash 8i1iop \ νίΐ1ι and fighting in the jay. E1es! Goepsery1odgaryu apb Syshsa1 №igor11ukyu1odu. (1992), 85, 17-21 [5]} and in some of them a number of solutions have been proposed {Saber e! .A1. Me1yob apb Arraga! Ik Gog Madpeysa11u 8it1yop Yeeigopk. Ra! Ep! I8: 4940453 [6]; Kopo! Find e! a1. Madpace 8ti1ayop Eeyu1se. Ra! Ep! I8: 5267938 [7]; C1isk e! a1. Мейоб оГ apb Arraga! Ik Gog Madpeisa11u 8it1iop оГ №иг1 Се11к. Ra! Ep! I8: 5738625 [8]; Agatk e! a1. Mebua1 Madpe! Ou1a1 Tiegaru. Ra! Ep! I8: 5813970 [9]; Fuck you! a1. Me! Yob apb Arraga! Ik Gog Yosikeb Ieigotadpeys 8it1yop apb Ie! Es! Yup. Ra! Ep! I8: 6066084 [10]; Jaueu.ee! a1. Madpace Yehue 8ti1ayop Gog Yehshd Repriega1 Jehovah. Ra! Ep! Ra! Ep! I8: 5725471 [11]; Ea! Op e! a1. Madpace Yehue 8it1a! From. Ra! Ep! I8: 5066272 [12]; Bsh e! a1. Ttea1tep! OG ExGe! Ra! Ep! I8: 6306078 [13]; Agatk e! a1. Rgeuepyop OG 8e1 / ig Apksd Ggot Mebua1 Madpe! Oy1a1 pop-Sopui1k1ue 8it1a! Ju Tyegaru. Ra! Ep! I8: 6117066 [14]; Ро1коп е! a1. Madpeys 8toyaa! From Gog Yeitotiksi1ag Tkkie. Ra! Ep! I8: 5766124 [15]; Erk! Yesh! a1. Ttapskshasha1 Vtash 8ti1ayop. Ra! Ep! I8: 6132361 [16]}. An analysis of the cited works showed all the ambiguity and inconsistency of solutions to the above problems of magnetic stimulation.

One of the main issues of magnetic stimulation is the optimization of the distribution of the magnetic field near the emitter, including the orientation of the magnetic induction vector with respect to the irradiated surface. When considering this issue, two main types of impact can be distinguished, such as bipolar and unipolar.

In the case of bipolar irradiation, the direction of the magnetic induction vector In _p will be parallel to the surface of the exposure. In this case, the circulation of the electric field vector E is normal to the irradiated surface:

go! E = - bV / b!

The induced circular electric field leads to an electric current, the value of which depends on the total (p) resistivity of the inner layers and skin p = pn + pv where pn is the specific resistance of the skin, pv is the specific resistance of the inner layers. Since the specific resistance of the skin is significantly higher than the resistance of the inner layers pn> pv, the magnitude of the induced current in the case of bipolar irradiation will be minimal.

The method of unipolar irradiation is deprived of this drawback, in which the direction of the magnetic induction vector is B ± of the normally irradiated surface. The latter determines the direction of circulation of the electric field vector parallel to the surface directly in soft tissues, characterized by low resistivity. As a result, the magnitude of the induced current during unipolar exposure is significantly higher than under bipolar exposure.

As follows from the foregoing, the efficiency of the unipolar method of exposure to a pulsed magnetic field will be significantly higher than with bipolar irradiation. In this regard, magnetic stimulation with a bipolar irradiation scheme given in [11] and in a number of other works seems to be less effective in comparison with unipolar.

The higher efficiency of the unipolar method of exposure to a pulsed magnetic field determines the design parameters of the pulsed magnetic field source.

Important for magnetic stimulation is the optimization of the magnetic field momentum - its shape, amplitude and duration.

In [12], the most common forms of magnetic field pulses and schemes for their preparation are shown. A magnetic field pulse, similar in shape to a triangular, occurs when the capacitor bank C is discharged when the key 8 is shorted to the inductance b. Front rise momentum magnetically

- 1 007347th field, in this case 1r = 100 μs, is determined by the circuit parameters - inductance b, capacitance C and resistance K. After the discharge of the capacitor C, when the current in the inductance decreases and the field decreases, the energy of the latter is released in the form of heat on the resistance K. the scheme is very inefficient, since all the supplied energy to create a magnetic field is subsequently transformed into thermal energy.

A magnetic field pulse, similar in shape to half a sinusoid, is formed when the capacitor C1 is discharged to the inductance b when the key 81 is closed and the magnetic field energy is then reset to the capacitor C2 when the key is closed 82. The total magnetic field pulse duration for the selected circuit parameters is this can be seen from the drawing, is 1 _and = 350 μs for symmetric rise and fall times of the pulse.

An important difference between the above schemes is the difference in the shapes of the induced electric field voltage pulse. In the first case, due to a significant difference in the rise and fall times of the pulse, the induced pulse is almost unipolar. In contrast, in the second case, the shape of the induced signal is close to sinusoidal.

As follows from the analysis of works on magnetic stimulation, both forms of a magnetic field pulse have approximately the same use.

One of the important issues of the effectiveness of the impact is the duration of the magnetic field pulse - the duration of the rise and fall front. In [12], the duration of a magnetic field pulse is 1 _and = 350 μs. In contrast to this, in one of the latest works [13], the recommended magnetic field pulse duration, similar in shape to a triangular one, is 1 _and = 0.4 s. Approximately the same pulse width of a magnetic field of a half-sinusoidal shape was adopted in [14].

Studies have shown the effect of magnetic field pulse duration on the process of stimulation of the central and peripheral nervous systems, the effectiveness of the latter increases with increasing pulse duration. In this regard, in separate magnetic stimulation devices, in order to increase the efficiency, the parallel inclusion of several discharge chains is adopted [15].

When developing magnetic stimulation devices, the magnitude of the magnetic field pulse determines the energy consumed. With a pulse duration of 1 _and = 350 μs [12], a pulse current of 1 _and = 3000 A, a voltage across the capacitor and = 1500 V when discharging to an inductor without a core, the amount of energy to create a magnetic field pulse is

E = i-1i-1i = 1.5 kJ

Such a storage high-energy installation has a large weight and high cost performance with a relatively low reliability.

The closest analogue of the claimed apparatus and method are the apparatus and method described in [9]. This magneto-induction therapy apparatus contains an oscillatory circuit, including a capacitor and a unipolar emitter of unipolar magnetic field pulses, having a winding, a power supply unit, a storage capacitor connected in parallel with the circuit capacitor, as well as the first and second controlled keys and the first and second diodes. The method of magneto-induction therapy consists in exposing the apparatus described by placing the end of the emitter winding on the desired portion of the patient’s head and generating unipolar magnetic field pulses. When implementing this method, the emitter is placed in a Dewar vessel to impart superconducting properties to its winding. The complexity of this design is not in doubt.

Some improvement of these indicators can be achieved in the manufacture of magnetic field sources using highly inductive magnetic materials, such as vanadium permendure [16]. However, in this case, the rate of increase of the magnetic field due to eddy current losses cannot be high and amounts to 20-30 T / s. When a capacitor system is discharged to a coil without a magnetic core, this value is significantly higher and amounts to 2000–3000 T / s.

Actually, the rate of increase of magnetic induction determines the effectiveness of magnetic stimulation - the magnitude of the induced potential of the electric field. Naturally, increasing the rate of rise of magnetic induction will allow to achieve the same values of the induced voltage to reduce the maximum achievable induction of the magnetic field, and therefore the energy consumed.

The indicated values of the slew rate of magnetic induction for coils with a magnetic core, and without it, are almost extremely achievable, since an increase in the value of the magnetic field requires a significant increase in the capacitive system - parameters b, C, K of the discharge circuit and, as a consequence, a decrease in the slew rate of magnetic induction .

All this ultimately leads to the fact that, despite the prospects of the magnetic stimulation method, magnetic stimulation devices, due to their high cost, bulkiness and low reliability, have found very limited use.

The closest analogue of the emitter of unipolar magnetic field pulses is described in [10] and has at least two spiral windings, the end of one of which is designed to be placed on the patient’s body.

- 2 007347

SUMMARY OF THE INVENTION

The solution to the problem of the widespread use of magnetic stimulation methods and the creation of a relatively inexpensive highly reliable magnetic stimulation apparatus lies, first of all, in increasing the magnetic induction rise rate to ΔΒ / ΔΙ = 10 ⁵ T / s. The latter will significantly reduce the power consumption of magnetic stimulation devices, increase the pulse repetition rate up to 1-2 kHz with an effective exposure pulse of up to! _and = 1 s and more, i.e. modulation frequency of the order of 30 series of pulses per minute.

The problem is set in a magneto-induction therapy apparatus containing an oscillatory circuit, including a capacitor and a unipolar emitter of unipolar magnetic field pulses, having a winding, a power supply unit, a storage capacitor connected in parallel with the circuit capacitor, as well as the first and second controlled keys and the first and second diodes, it is decided that the specified emitter is equipped with a core, which is made of soft magnetic composite material.

The positive terminal of the circuit capacitor is connected to the first terminal of the emitter winding through the first key and to the second terminal of the radiator through the first diode, and the negative terminal of the capacitor of the circuit is connected to the specified second terminal of the radiator through the second key, with the specified first terminal of the radiator through the second diode, the first and second diodes are turned on in the locking direction.

These controlled keys are made in the form of high-frequency transistors with low output resistance, and the control electrodes of the transistors are inputs of the device for supplying control signals.

These transistors are ΠΒΤ - transistors.

The positive terminals of the storage capacitor and the loop capacitor are connected through a high-frequency choke, and the negative ones directly.

The apparatus is equipped with first and second control elements connected in series with the corresponding diode.

In the method of magneto-induction therapy, which consists in exposing the magneto-induction therapy apparatus to an oscillatory circuit including a capacitor and a unipolar emitter of unipolar magnetic field pulses, having a winding, a power supply unit, a storage capacitor connected in parallel with the circuit capacitor, and also the first and second controlled keys and the first and second diodes, by placing the end of the emitter winding on the desired area of the patient’s body and the formation of unipolar magnetic field pulses , the problem is solved in that the said emitter is performed with a core that is made of soft magnetic composite material.

The pulses of the magnetic field are formed close to triangular.

The duration of the decline of the pulses of the magnetic field is regulated from 5-10 ^-5 to 10 ^-3 s.

Packs of magnetic field pulses are formed.

Bursts of pulses of a magnetic field are formed with a pulse frequency in the burst from 100 to 1000 Hz.

The frequency of the packs of pulses of the magnetic field is formed in the range from 20 to 60 packs per minute.

In an emitter of unipolar magnetic field pulses having at least two spiral windings, the end of one of which is designed to be placed on the patient’s body, the problem is solved by the fact that it is equipped with a core of magnetically soft composite material.

The emitter core is made in the form of a hollow cylinder, the outer surface of which is covered by one of these spiral windings, and the other spiral winding, included in the opposite direction, covers the inner surface of the core.

The height 11 and the outer diameter of the core are selected from the ratio 11/4 <bs <11. moreover, the outer diameter of the core does not exceed its inner diameter 61 by 10-30 mm.

Brief description of the drawings

FIG. 1 is a generalized block diagram of the inventive apparatus;

FIG. 2 is a block diagram of a universal apparatus with two emitters;

FIG. 3 - time diagrams of the magnetic field generated by the claimed device;

FIG. 4 is a timing diagram of an induced potential impulse;

FIG. 5 is a schematic representation of a claimed source of magnetic pulses in a longitudinal section;

FIG. 6 - time diagrams of magnetic field pulses generated by the claimed source (a), a magnetic field source without magnetic material (b) [12] and a magnetic field source with a core on a vanadium permendure (c) [13].

Detailed Description of the Invention and Preferred Examples

A generalized block diagram of the inventive magneto-induction therapy apparatus is shown in FIG. 1. The inventive apparatus comprises an oscillatory circuit, including a capacitor 1 and a unipolar emitter 2 of unipolar magnetic field pulses, a power unit 3, a storage capacitor 4. The positive terminal of the capacitor 1 of the circuit is connected to the first terminal of the emitter 2 through the first key 5 and with the second output of the emitter 2 through the first diode 6. The negative output of the capacitor 1 of the circuit is connected to the specified second output of the emitter 2 through the second key 7 and with the specified first output of the emitter 2 through the second diode 8. The first 6 and second The 8th diodes are turned on in the locking direction. The positive terminals of the capacitors 1 and 4 are connected through a high-frequency inductor 9. The control electrodes of these transistors are the inputs of the device for supplying control signals. In this particular example, they are connected and the same control signals are applied to keys 5 and 7. In series with the diodes 6 and 8, the first 10 and second 11 control elements are included.

The inventive method is implemented as follows.

The emitter 2 of the magnetic field is placed on a portion of the patient's body due to the disease. This may be the head, limb or other part of the body.

From the power supply unit 3, a voltage is applied to the capacitor 1 until it is fully charged.

When a pulse signal is simultaneously supplied to the control electrodes of the transistors, keys 5 and 7, a magnetic field pulse is generated in the emitter 2, shown in FIG. 3.

With a decrease in the magnitude of the magnetic field after the closure of these transistors, a decay of the indicated magnetic pulse is formed. By means of the first 10 and second 11 control elements, the decay time of the indicated magnetic field pulse can be set from 5-10 ^-5 to 10 ^-3 s.

The induced voltage of the opposite sign in the emitter 2 is inverted by means of diodes 6 and 8 and energy is returned to the capacitor 1 of the circuit.

At the same time, active losses in the circuit are replenished by recharging energy through the inductor 9 from the storage capacitor 4.

Thus, during the decay of the magnetic field pulse, the voltage across the capacitor 1 is restored to its nominal value.

The second magnetic field pulse can be formed almost after the end of the first discharge pulse.

The control electrodes of the indicated transistors - keys 5 and 7 are fed with a sequence of pulse signals of a given frequency and in a predetermined quantity and a packet of magnetic field pulses with a frequency from 10 to 1000 Hz in a packet is generated as described, and a frequency of packet of magnetic field pulses is formed in the range from 20 to 60 packs per minute.

Each of the described magnetic field pulses induces a potential electric field pulse, shown in FIG. 4. It is obvious that the shape of this impulse, and, consequently, the particular effects on the patient depend on the generated magnetic field impulse. With a very short decline in the magnetic field pulse (line (a) in Fig. 4), the indicated potential pulse will be bipolar (line (a) in Fig. 4), and with an increased decay time of the magnetic field pulse, the potential pulse becomes unipolar (line (in ) in Fig. 3 and 4, respectively).

A block diagram of a universal apparatus with two emitters (15 and 16, respectively) on two types of composite soft magnetic material with emitter rings diameters be = 100 and 40 mm is shown in FIG. 2. A feature of the proposed circuit apparatus is the fact that the energy of the charged capacitors 17 and 18 circuits is much more than the energy of the magnetic pulse

<< Ei100 C17 and ^2/2 or Ei40 C18 and << ^2/2

In this regard, when opening the transistor switches, for example 19 and 20, and discharging the capacitor 17 to the magnetic field radiator 15, the voltage across the capacitor 17 decreases by no more than 20%. After the transistor switches 19 and 20 are closed, the voltage at the emitter is inverted and after the diodes 21 and 22 are opened, the energy of the magnetic pulse is returned to the capacitor 17. At the same time, active losses in the circuit are replenished by energizing through the high-frequency inductor 23 from the storage capacitors 24 and 25. the decay time of the magnetic field pulse, the voltage across the capacitor 17 is restored to its nominal value. In connection with the foregoing, the second magnetic field pulse can be formed almost after the end of the first discharge pulse.

The operation of the second circuit (magnetic field emitter 16, capacitor 18, transistor switches 19 'and 20', diodes 21 'and 22' and high-frequency inductor 23 ') occurs similarly to the first, but with a shift by the duration of the discharge pulse in the first circuit.

The inventive magnetic field emitter is shown in FIG. 5.

To ensure the circulation of the induced electric current inside the human body in a plane parallel to the surface, the magnetic field emitter 2 has two spiral windings 12 and 13 and a core 14 of soft magnetic composite material.

The core 14 is made in the form of a hollow cylinder, the outer surface of which is covered by one of these spiral windings - winding 12, and the other spiral winding 13 is turned on and is covered by the inner surface of the core 14.

- 4 007347

To increase the magnetic field induction in the pulse to W = 2 Tesla on the surface of the emitter and increase the penetration depth of the magnetic field, the height K of the core 14 is selected from the ratio K / 4 <6e <K, where b e is the outer diameter of the core. The outer diameter of the core without exceeds the inner diameter of 61 by 10 to 30 mm.

A magnetically soft iron-based composite material, where each iron particle is coated with a thin layer of a magnetic dielectric, for example, 8MS-500 from Nodapaz AB (Sweden), unlike metal magnets, does not have eddy current losses. As a result, the frequency response of magnetic permeability, in comparison with metallic magnetic material, shifts toward higher frequencies.

The field dependences of magnetic induction for a metallic magnetic material and a composite material differ significantly in the initial part of the curves. At values of the magnetizing field strength above 10 kA / m, the behavior of the magnetization curves is almost identical. A composite magnetically soft material is characterized by an almost linear change in magnetic induction with the field. The main parameters of the soft magnetic composite material are as follows:

The average value of magnetic permeability - μ = 200

The value of the saturation magnetic induction is W = 2.2 T

The value of the inductance B of the emitter 2 of the magnetic field in the latter case practically retains its value, as for the emitter without a magnetic core due to the reduction in the number of turns:

B = μ0 · μ · η ² · ν = 20-10 ^bH

The capacitance of the capacitor 1 circuit is reduced in comparison with previous cases to C = 10 μF. As a result, the duration of the front of magnetic induction rise is determined by:

T / 4 = 0.5tgL.-C = 20-10 ' ⁶ sec

Accordingly, the slew rate of magnetic induction will be

AB / A1 = 10 ⁵ T / s

Claims (15)

CLAIM 1. Magnetic induction therapy apparatus containing an oscillating circuit, which includes a capacitor and a radiator of unipolar magnetic field pulses, having a winding, a power unit, a storage capacitor connected in parallel with the circuit capacitor, and the first and second controlled switches and the first and second diodes, distinguished by that the emitter is provided with a core, which is made of a soft magnetic composite material, which provides a slew rate of magnetic induction of at least 10 ⁵ T / s. 2. The apparatus according to claim 1, characterized in that the positive terminal of the circuit capacitor is connected to the first terminal of the radiator winding via the first switch and the second terminal of the radiator through the first diode, and the negative terminal of the loop capacitor is connected to the specified second output terminal of the radiator through the second switch, with the specified first output of the radiator through the second diode, and the specified first and second diodes are included in the blocking direction. 3. The device according to PP.1, 2, characterized in that said controlled keys are made in the form of high-frequency transistors with a low output impedance, and the control electrodes of the transistors are inputs to the device for supplying control signals. 4. The apparatus according to claim 3, characterized in that said transistors are HTI transistors. 5. The apparatus according to claim 1, characterized in that the positive terminals of the storage capacitor and the circuit capacitor are connected via a high-frequency choke, and the negative terminals are directly connected. 6. The apparatus according to claims 1-5, characterized in that it is provided with first and second regulatory elements connected in series with the corresponding diode. 7. Method of magnetic induction therapy, consisting in the influence of magnetic induction therapy apparatus, containing an oscillating circuit, which includes a capacitor and a unipolar emitter of a unipolar magnetic field pulse, having a winding, a power supply unit, a storage capacitor connected in parallel with a loop capacitor, and the first and second controlled keys and the first and second diodes, by placing the end of the radiator winding on the required part of the patient's body and the formation of unipolar magnetic field pulses, characterized in that said radiator is performed with a core that is made of a soft magnetic composite material, which provides a slew rate of magnetic induction of at least 10 ⁵ T / s. 8. The method according to claim 7, characterized in that they form magnetic field pulses with a shape close to triangular. 9. The method according to claim 7, characterized in that regulate the duration of the decline of the magnetic field pulses from 5-10 ^-5 to 10 ^{-3 C.} 10. The method according to claims 7-9, characterized in that they form a bundle of magnetic field pulses. 11. The method according to claim 10, characterized in that the pulses of the magnetic field in the pack are formed with a frequency of from 10 to 1000 Hz. - 5 007347 12. The method according to claim 10, characterized in that the frequency of the packs of pulses of the magnetic field is formed in the range from 20 to 60 packs per minute. 13. Emitter of unipolar magnetic field pulses, having at least two spiral windings, one of which end is designed to be placed on the patient's body, characterized in that it is equipped with a core of soft-magnetic composite material that provides a rate of increase of magnetic induction of at least 10 ⁵ T /with. 14. The emitter according to item 13, characterized in that the core is made in the form of a hollow cylinder, the outer surface of which covers one of these spiral windings, and the other spiral winding, included opposite, covers the inner surface of the core. 15. The emitter according to claim 14, characterized in that the height And and the external diameter of the core are selected from the relation I / 4 <Ye <I, and the external diameter of the core does not exceed its inner diameter 11 by 10-30 mm.