RU114863U1 - DEVICE FOR IMPACT OF A MAGNETIC FIELD ON BIO-OBJECTS CONTAINING MAGNETIC NANOPARTICLES - Google Patents

Abstract

A device for influencing a magnetic field on biological objects containing magnetic nanoparticles, including a generator and a pair of electromagnetic coils placed on two poles of the magnetic circuit, characterized in that it is equipped with a transformer, a capacitor and an additional pair of electromagnetic coils, the generator is connected to the primary winding of a transformer containing two secondary windings , the first of which is connected to the first pair of electromagnetic coils, and the second through a capacitor is serially connected to an additional pair of electromagnetic coils, an additional pair of poles is installed on the magnetic circuit orthogonally to the first pair of poles, each of which has a corresponding additional electromagnetic coil, and the capacitor capacitance is selected from the condition electrical resonance in a circuit containing an additional pair of electromagnetic coils.

Description

The utility model relates to medical equipment and can be used for the treatment of malignant neoplasms by local selective and non-invasive effects on the tissues of biological objects, for example, animals or humans, in which magnetic particles are preliminarily embedded.

There are many devices in which variable electromagnetic fields are used to process various biological objects, including human in order to treat. Such devices consist of two main blocks: an alternating current source (for example, a generator) and a magnetic field source (emitter) - a solenoid or an electromagnet. Typically, the field strength is not more than a few tens of oersteds, and the area to which the field applies is from individual parts of the body, such as the head [RF Patent No. 100407], to the entire human body [RF Patent No. 2074749]. The effect of such an apparatus is due to the interaction of the emitted magnetic field with electric impulses propagating through the nerve fibers.

Essentially different in nature are devices that use an alternating magnetic field for the treatment of cancer. The effect of magnetic hyperthermia is due to the preliminary delivery of magnetic particles in one way or another to the tumor tissue and the subsequent selective exposure to a magnetic field. In this case, magnetic particles, heating under the influence of a field, destroy cancer cells.

Most known works on magnetic hyperthermia use devices that include a generator and a solenoid connected to its output.

Important parameters that determine the efficiency or degree of heating of magnetic particles are the frequency and amplitude of the magnetic field. The frequency should be one hundred kilohertz or more, and the amplitude should be more than one hundred oersteds.

A device for magnetic hyperthermia, including a generator and a solenoid [N. Kawai, A. Ito, Yoko Nakahara, H. Honda, T. Kobayashi, M. Futakuchi, T. Shirai, K. Tozawa, and K. Kohri // Complete Regression of Experimental Prostate Cancer in Nude Mice by Repeated Hyperthermia Using Magnetite Cationic Liposomes and a Newly Developed Solenoid Containing a Ferrite Core The Prostate 66: p.719 (2006)]. The solenoid creates an axial magnetic field, the biological object is located inside the solenoid

One of the disadvantages of this device is the restriction on the size of the bioobject - it can be cell cultures or small animals (mice, rats), because To create the desired field in large diameter solenoids, too large currents (thousands of amperes) would be required. When placing the processed biological object outside the solenoid, heating of the tumor tissue does not occur, because solenoidal magnetic fields decay rapidly along the axis of the solenoid.

Also known is a device for applying an axial magnetic field to biological objects, including a generator and a solenoid with a core made of soft magnetic material [N. Kawai, A. Ito, Y. Nakahara, H. Honda, T. Kobayashi, M. Futakuchi, T. Shirai, K .Tozawa, and K.Kohri // Complete Regression of Experimental Prostate Cancer in Nude Mice by Repeated Hyperthermia Using Magnetite Cationic Liposomes and a Newly Developed Solenoid Containing a Ferrite Core The Prostate 66: p.721 (2006)].

Using a solenoid with a core made of soft magnetic material, i.e. turning the solenoid into an electromagnet, it is possible to increase the field strength outside the solenoid and somewhat reduce the rate of its attenuation along the axis. As a result, it becomes possible to process larger bioobjects placed close to the end surface of the core. Such a device is suitable for treating pathological lesions located close to (1-2 cm) from the surface of the body. A device containing a generator and one coil with a core is not suitable for treating deeper tumors, because the field attenuation rate along the axis remains significant, therefore, the heat release in the biological object will also be low.

Closest to the claimed is a device for exposure to biological objects with a magnetic field, with pre-embedded magnetic nanoparticles, including a generator, a frame type magnetic circuit with two poles and a pair of electromagnetic coils connected to the generator, each located at its own pole of the magnetic circuit. [A. Jordan, R. Scholz, K. Maier-Hau, M. Johannsen, P. Wust, J. Nadobny, H. Schirra, H. Schmidt, S. Deger, S. Loening, W. Lancksch, R. Felix . Presentation of a new magnetic field therapy system for the treatment of human solid tumors with magnetic fluid hyperthermia // Journal of Magnetism and Magnetic Materials 225 (2001), 121].

Such a device, due to the presence of a magnetic circuit closed on the outer side and two poles, is characterized by moderate field attenuation with distance from the poles, which allows you to process large bioobjects placed between the poles, including, with the appropriate size of the magnetic circuit, the human body (certain parts of it, where pathological foci, and where magnetic nanoparticles were previously delivered).

Since this device (like the ones mentioned above) creates axial fields, their common drawback is the weak interaction of the field with part of the nanoparticles embedded in the bioobject, which leads to insufficient heat release. This is due to the fact that for an arbitrary orientation of the magnetic moments of the particles relative to the field, as is the case in the initial state, part of these moments will be oriented along the field, as a result of which the rotational moment induced by the field will be close to zero, i.e. these particles will not respond to the action of the field, and, therefore, will not create a therapeutic effect.

In addition, for variable axial magnetic fields, the field modulus passes through a zero value twice per period, which also reduces the degree of heating of biological objects.

The utility model is based on the task of increasing heat generation when a device’s magnetic field acts on biological objects with previously embedded magnetic nanoparticles by creating a rotating magnetic field.

The problem is solved in that the device for exposure to biological objects with a magnetic field, with embedded magnetic nanoparticles, including a generator and a pair of electromagnetic coils located respectively on two poles of the magnetic circuit, according to a utility model is equipped with a transformer, capacitor and an additional pair of electromagnetic coils, the generator is connected to the primary winding of a transformer containing two secondary windings, the first of which is connected to the first pair of electromagnetic coils, and the second Without a capacitor, it is connected in series to an additional pair of electromagnetic coils; an additional pair of poles is installed on the magnetic circuit orthogonally to the first pair of poles, each of which contains a corresponding additional electromagnetic coil.

The capacitance of the capacitor is selected from the condition of electric resonance in a circuit containing an additional pair of electromagnetic coils according to the formula:

C = L ^-1 (2πf) ^-2 , where:

C is the capacitance of the capacitor,

L is the total inductance of an additional pair of coils and a second secondary winding of the transformer,

f is the frequency at which the generator is tuned

The inventive device uses a capacitor with a capacitance that provides electrical resonance in a circuit containing an additional pair of coils. Connecting an additional pair of coils through a capacitor under the condition of resonance provides a phase shift of the current in it by 90 degrees with respect to the first pair of coils. This current creates an additional magnetic field in the gap between the additional poles, which is also phase shifted 90 degrees with respect to the field created by the first pair of coils. The superposition of two phase-shifted magnetic fields in the gap between the poles is described as a rotating field.

Such a field, unlike an axial field, never vanishes modulo, and the energy of its interaction with the magnetic moment of any particle twice per rotation cycle will reach the maximum possible value for a given field strength regardless of the initial orientation of the moment in space, while the axial field does not create a torque for particles whose magnetic moment is oriented in the direction of the field, which is determined by the orientation of the existing one pair of poles and therefore does not change. This provides a higher heat release in tissues containing magnetic particles, compared with the axial field at the same field in amplitude and frequency.

Figure 1 presents the electrical circuit of the inventive device;

figure 2 - structural design of the magnetic circuit with coils placed on its poles.

A device for applying a magnetic field to magnetic nanoparticles previously embedded in the tissue of bioorganisms (Fig. 1) contains a generator 1 (type BAR) and a transformer 2 with a core made of soft magnetic ferrite 3. The generator is connected to the primary winding 4 of the transformer 2. The first secondary winding 5 of the transformer 2 is connected in series to the first pair of coils 7 and 8, and the second secondary winding 6 through the capacitor 11 is connected in series to an additional pair of coils 9 and 10. The capacitance of the capacitor 11 is selected so that the chain of electric resonance occurred. To do this, measure the total inductance L of the second secondary winding 6 of the transformer 2 and an additional pair of electromagnetic coils 9 and 10 and calculate the required capacitance of the capacitor 11 based on the measured inductance and the operating frequency of the generator 1 f according to the formula C = L ^-1 (2π · f) ^{- 2} . Coils 7, 8, 9 and 10 are placed respectively at the poles 12, 13, 14 and 15 of the magnetic circuit 16 (Fig.2), and the poles 12 and 13 are orthogonal to the poles 14 and 15.

The device operates as follows. The generator 1 connected to the transformer 2 generates currents in the coils 7, 8, 9 and 10, and, due to the presence of the capacitor 11 in the circuit of an additional pair of coils 9 and 10, the current in it, under the condition of resonance, is phase-shifted 90 degrees from the first pair coils 7 and 8. These currents create magnetic fields in the gap between the poles 12, 13, 14 and 15, the sum of which is described as a rotating magnetic field. Bioobject 17, the pathological tissues of which contain magnetic nanoparticles, are placed in the gap between the poles 12, 13, 14 and 15 of the magnetic circuit, while a rotating magnetic field causes the particles to heat, which leads to heating of the pathological tissues. In this case, the field acts equally on all nanoparticles, regardless of the orientation of their magnetic moments before the field, which provides higher heat generation than for an axial field that does not rotate particles oriented along the field.

The experiments carried out in the Laboratory of Applied Magnetism at the Institute of Applied Mathematics, Ural Branch of the Russian Academy of Sciences, in an experimental setup that measures the temperature and heat release rate of heated model suspensions with magnetic particles of iron or cobalt coated with carbon, showed that heat generation in a rotating field is 2-5 times higher than in axial field of the same magnitude and frequency.

Claims (1)

A device for applying a magnetic field to biological objects containing magnetic nanoparticles, including a generator and a pair of electromagnetic coils placed on two poles of the magnetic circuit, characterized in that it is equipped with a transformer, capacitor and an additional pair of electromagnetic coils, the generator is connected to the primary winding of the transformer containing two secondary windings the first of which is connected to the first pair of electromagnetic coils, and the second through a capacitor is connected in series to an additional pa e electromagnetic coils corresponding additional electromagnetic coil, wherein the capacitor is chosen from the condition of the electric resonance circuit, comprising an additional pair of electromagnetic coils mounted an additional pair of poles, each of which is located orthogonally on the yoke of the first pole pair.