EA032247B1 - Device and system for local magnetic therapy - Google Patents

Abstract

The invention is related to the field of therapy, in particular, to devices and apparatus for magnetic therapy, and can be used for treatment of various diseases including oncologic diseases. In a device for local magnetic therapy including a current source connected to an inductor, the inductor comprises a magnetic field concentrator in the form of a rod of a magnetically conductive material elongated towards a targeted object. The device is characterized in that the inductor is made of a set of two or more coils wound in a bifilar manner and disposed along the concentrator axis. Also disclosed is a system for local magnetic therapy comprising a set of inductors with magnetic field concentrators, wherein at least two inductors include coils wound in a bifilar manner, and the coil windings in each inductor are connected to control devices, the inductors being mounted on a positioning device so that the axes of the concentrators intersect in the area subject to therapy.

Description

The invention relates to medicine, in particular to devices and devices for magnetic therapy, and can be used to treat various diseases, including cancer. In a device for local magnetotherapy, including a current source connected to an inductor, the inductor comprises a magnetic field concentrator made in the form of a rod of magnetically conductive material elongated in the direction of the target. The device is characterized in that the inductor is made in the form of a set of two or more coils located along the axis of the hub made by bifilar winding. A system for local magnetotherapy has also been developed, including a set of inductors with magnetic field concentrators, in which at least two inductors are made with bifilar winding coils, and the windings of the coils of each inductor are connected to control devices, and the inductors are fixed to the positioning device so that the axes of the concentrators intersect in the area to be treated.

032247 B1

The invention relates to medicine, in particular to devices and devices for magnetic therapy, and can be used to treat various diseases, including cancer.

Magnetic fields (MP) are used in the treatment of a wide range of diseases and various types of inducers are used to create them. One of the most relevant aspects of the use of magnetotherapy is the creation of high-gradient local magnetic fields.

Known devices for local magnetic effects on biologically active points, for example, by AS USSR No. 1690792, containing an inductor in the form of a coil and a magnetic hub in the form of an extended magnetically conductive core. The working end of the core has a narrowing with a solution angle of 40 to 90 °. This device is designed to affect surface local biological points with an alternating magnetic field and does not allow using it to treat internal organs, to obtain high-gradient values of both constant MP and broadband pulsed fields. In addition, such a device consumes a lot of energy from an external power source.

High-intensity pulsed magnetic correctors are known according to GO2015012672. creating magnetic pulses with a strength of 3-60 T due to the discharge of the storage capacitor through an inductor with various gaps between the turns. The localization of the magnetic field with the help of such an inductor is quite low and the magnetic field of this intensity affects the surrounding tissues and organs. Such an inductor also has high energy consumption and cannot be used to create highly gradient constant fields, for example, to accumulate and retain magnetic nanoconjugates in a critical organ or tumor.

A device for magnetotherapy is known RF patent No. 2224559, in which the concentration of the magnetic field is carried out using a rod of soft magnetic material and a plate mounted on the end of the rod. The inductor also contains four coils with cores, which are located vertically and symmetrically around the rod. The ends of the cores are rigidly fixed to the plate. Thus, for the formation of the field, the induction of four coils is used alternately, with the creation of a rotating pulsed magnetic field in the gap between the concentrator and the core of the coil.

The specified device can be considered as the closest to the claimed by the number of similar features.

However, this design has the following disadvantages:

the coils have a fairly high inductance, which limits the bandwidth of the applied signals;

when using in a mode of a direct current has rather high power consumption;

It has rather large dimensions and weight, which makes it difficult to use in combination with other inductors;

the region of localization of the magnetic field is determined by the distance between the concentrator and the cores of the coils, which also depends on the diameter of the coils;

the functional use of the described device is limited by local effects on biologically active points (BAP).

The objective of the invention is to increase the effectiveness of magnetotherapy, both by improving the localization and depth of exposure, and by expanding the functionality of the use of inductors.

Another objective is to reduce the mass and size characteristics of the inductors.

The next task is to reduce energy consumption and increase the efficiency of conversion of electric energy into MP and, accordingly, increase the efficiency and dynamic characteristics of magnetotherapy devices.

Another objective is the creation of a complex magnetic therapy system for cancer in the brain using nanoconjugates.

The tasks are solved as follows.

In a device for local magnetotherapy, including a current source connected to an inductor, the inductor comprises a magnetic field concentrator made in the form of a rod of magnetically conductive material elongated in the direction of the target. The device is characterized in that the inductor is made in the form of a set of two or more coils located along the axis of the hub made by bifilar winding.

Each of the coils can be connected to a current source directly, or through a control device. Moreover, each of the coils can have its own characteristics and perform its function of generating either a high-gradient constant magnetic field or a local high-amplitude pulsed field with a given shape.

These problems can be solved, both on the basis of an inductor with one concentrator, and include an additional inductor with a concentrator and bifilar coils, with the concentrator rods oriented at an angle to each other so that the axes of the concentrators converge in the area to be treated. In this case, the localization of the magnetic effect can be increased due to the intersection of the field diagrams of two (and possibly more) inductors.

- 1 032247

The invention is based on the unique properties of bifilar winding coils, as are known from electrical engineering, starting with US patent No. 512340, and also according to RF patent No. 2355060. According to this, bifilar coils have non-inductive properties and allow to obtain magnetic fields from turns of a bifilar pair of wires, with equally directed currents that add up and can more efficiently transfer energy to the core (concentrator). Such coils are also energy efficient.

At the same time, the combination of several such coils with the same or different parameters on one magnetically conducting hub-concentrator makes it possible to concentrate significant magnetic field energy in it in a narrow limit near its cross section and to a greater depth compared to known inductors. In addition, the absence of mutual induction in such coils provides broadband and simultaneous and alternately different processes of magnetotherapy, in the local zone and with the help of a single inductor. Even greater opportunities arise when using two or more inductors, the diagrams of which are combined in space. This allows you to go beyond the saturation of one concentrator, as well as improve the localization of the impact due to the intersection of diagrams.

To solve one of the most urgent tasks of the complex therapy of oncological diseases associated with the delivery of drugs (drugs) to the brain. In such cases, nanoconjugates are used to overcome the blood-brain barrier, i.e. Drugs associated with ferromagnetic nanoparticles. Magnetic concentrators can be used here for the accumulation of drugs and their activation in a selected area of the brain, i.e. at the location of the tumor. To this end, a system for local magnetotherapy has been developed, including a set of inductors with magnetic field concentrators, in which at least two inductors are made with bifilar winding coils, and the windings of the coils of each inductor are connected to control devices, and the inductors are fixed to the positioning device so that the axis of the concentrators intersect in the area to be treated. In this case, one inductor can be used to create a high-gradient field and confine magnetic particles with drugs in the tumor area, and the second inductor can receive high-energy magnetic field pulses in this area to release (activate) the drug. In this case, drugs accumulate in the field of action of one inductor and are activated in the region of intersection with the effective diagram of the activating inductor.

For coordination and correct operation of the entire system, the control devices of the inductors and the positioning device are connected to the software device.

In FIG. 1 shows a device for local magnetotherapy.

In FIG. 2 shows a system for local magnetotherapy.

The device for local magnetotherapy of FIG. 1 contains a number of coils 1 made by bifilar winding and placed on an extended rod 2 of soft magnetic material. The rod at the protruding end is pointed or has a replaceable tip, providing a narrower concentration of the magnetic field generated by the coils. The conclusions of the coils 1 are connected through a control device 3, which can be a switch, or a pulse shaper, with a power source 4.

The device operates as follows.

The current from the power source 4 is supplied to the parallel pairs of turns of each coil through the corresponding switching device 3 and excites in the adjacent parallel turns a unidirectional magnetic field. This field is summed up and concentrated in the magnetically conducting rod 2. In this case, the field from different coils is summed up without mutual induction, which allows one to achieve significant values of magnetic induction with a rather low energy consumption. At the same time, the concentration of magnetic flux in an extended magnetically conducting rod increases the induction and creates a good field pattern along the axis of the rod.

So, for example, for one bifilar spiral coil made of 13 turns of a double wire, magnetic induction was obtained along the axis of the coil 0.56 mT at a consumption current of 0.02-0.04 A. When the coil was placed on a metal hub, the induction increased to 3 , 3 mT at the same current consumption. When using the standard multi-turn coil of the Μ-ΤΚΑΝ-AC charger module and obtaining similar values of induction, the current consumption increased to 0.12 A.

A significant increase in the magnetic field parameters can be obtained with the aid of a stacked inductor from several bifilar coils, as well as using their resonance characteristics. In this configuration, it was possible to obtain induction up to 400 mT, and up to 60% of the magnetic field energy was concentrated in a distributed diagram in space up to 0.7 radius from the axis of the extended magnetic core of the concentrator. Depending on the task and the specific size and material of the concentrator, it is possible to obtain induction up to 1 T. The specific values and parameters of the inductors are selected experimentally and depending on the problem being solved.

An even greater value of induction can be achieved by using several inductors.

With the help of several inducers it is also possible to build a system for the implementation of therapy

- 2,032,247 defined points or areas of the brain, as shown, for example, in FIG. 2.

In this example, a tumor 5 located in the brain 6 is affected by a constant field inductor 7, the bifilar windings of which are connected to the control device 8, and a pulse inductor 9 connected to the control device 10. Moreover, the inductors 7 and 9 are fixed to the positioning device 12, connected to the control device 13. The general algorithm of the system is set by the software device 11 through the corresponding control devices 8, 10 and 13.

The system operates as follows.

For complex therapy of oncological diseases of the brain 6, nanoconjugates are used to overcome the blood-brain barrier, i.e. Drugs associated with ferromagnetic nanoparticles.

As a rule, solutions of nanoconjugates are introduced into vessels supplying the tumor 5 gradually or in small doses. Retention and accumulation of drugs in the tumor is carried out using an inductor 7, which creates a high-gradient constant magnetic field in the therapy zone 5 according to the algorithm established by the software device 11 through the control device 8 of the inductor 7. As the drugs accumulate and according to the algorithm of the software device 11, the control device 10 generates pulses current to the inductor 9, which generates in the treatment zone 5 a pulsed magnetic field sufficient to activate or release the drug in this zone. Mutual alignment of the axes of the inductors is preliminarily carried out by the positioning device 12 using the control device 13 operating according to the control algorithm of the program unit 11.

Specific values, dependences, and distribution of magnetic fields can be obtained by preliminary scanning with a magnetic field sensor, or by using a special phantom, stored in the memory of a software device 11, which is a computer and can be set if necessary to solve a specific problem.

When using such a system of inductors with bifilar windings, energy costs are significantly reduced, overall dimensions are reduced, the functionality of magnetotherapy is expanded, the quality is improved and it becomes possible to create affordable clinical facilities.

Claims (5)

CLAIM 1. A device for local magnetotherapy, comprising a current source connected to an inductor, wherein the inductor comprises a magnetic field concentrator made in the form of a rod of magnetically conductive material elongated in the direction of the object of influence, characterized in that the inductor is made in the form of at least two coils located along the axis of the concentrator of the magnetic field, and the coils are made bifilar winding. 2. The device according to claim 1, characterized in that the coils are connected to a current source through a control device. 3. The device according to claim 1, characterized in that it includes an additional inductor with a hub with bifilar coils, the rods of the concentrators mounted at an angle to each other so that the axis of the concentrators converge in the area to be treated. 4. The system for local magnetotherapy, comprising a set of inductors with magnetic field concentrators according to claim 1, characterized in that at least two inductors are made with bifilar winding coils and coil windings of each inductor are connected to control devices, and the inductors are fixed to the positioning device so that the axis of the concentrators intersect in the area to be treated. 5. The system according to claim 4, characterized in that the control devices of the inductors and the positioning device are connected to the software device. - 3 032247