RU2727227C1 - Cochlear implant magnet on spherical magnetic elements - Google Patents

Abstract

FIELD: medicine.SUBSTANCE: invention relates to medical equipment, in particular to implanted cochlear devices, which include a spherical magnet located in the center of the receiving coil and intended for holding an external transmitting coil in the required position. Cochlear implant magnet comprises a set of permanent spherical magnetic elements with equal diameters and poles N and S, upper round flat cover of non-magnetic material and lower cover made of nonmagnetic material in the form of cylinder, diameter of which is equal to diameter of top round cover, which is rigidly fixed on lower cover. Cylindrical lower cover includes annular groove coaxial to its cylinder, made with possibility of uniformly filling with set of spherical magnetic elements, for each of which there is possibility of free rotation at complete filling of ferromagnetic liquid with annular groove with spherical magnetic elements.EFFECT: technical result of the claimed invention consists in providing a possibility of examining a patient with a magnetic resonance imaging (MRI) imaging device installed with more simple means than in the known similar devices; besides, additional technical result of claimed invention is its simplification due to absence of possibility to attract metal objects (buttons, nails et cetera) to user's head in absence of speech processor.6 cl, 2 dwg

Description

The technical field to which the invention relates

The invention relates to medical technology, in particular to implantable cochlear devices. Specifically, to devices that include a spherical magnet located in the center of the receiving coil and designed to hold the outer transmitting coil in position.

State of the art

In cochlear devices, permanent magnets must be used to ensure that the position of the cochlear device (implant) being implanted under the patient's skin and the speech processor used to transmit power and command messages to the implant are strictly aligned. At the same time, the presence of an implant with a permanent magnet under the skin of a patient (usually a child) can create certain inconveniences.

When the speech processor is removed, the permanent magnet of the implant can attract buttons, nails, and other similar objects. Parents should ensure that no such objects are worn on the patient's head when the speech processor is returned.

A patient with an implant in place may need to undergo a medical examination with magnetic resonance imaging (MRI). The external magnetic field generated during an MRI scan can create a torque on the implant magnet. When using a solid magnet in the implant, this torque can displace the magnet, resulting in tissue damage to the patient. Manufacturing companies of serial implants require surgery to remove the magnet before MRI and re-surgery to place the magnet under the patient's skin after MRI (https: //advancedbionics.com/us/en/home/professionals/mri-safety.html ).

In order to facilitate such surgical operations, composite cochlear magnets have been developed, an example of which is the Implantable Magnet System according to US patent 2019022380 A1, IPC A61N 1/08, A61N 1/375, A61N 1/378 (published on 01.24.2019).

In a number of publications, prefabricated cochlear magnets have been described, which in some cases completely exclude the possibility of their extraction by surgical operations. Examples of such cochlear magnets, the constituent parts of which include cylindrical magnets capable of limited rotation, are the implants described in US Pat. Nos. 2018369586 IPC A61N 1/08, A61N 1/36, A61N1 / 375, H04R 25/00 (published 27.12. 2018) and US 2018296826 IPC A61N 1/05, H01F 7/02 (published on 18.10.2018). However, the above "case series" is quite limited, which is recognized by the developers of these prefabricated cochlear magnets.

Based on purely geometric considerations, all rotation restrictions should be removed by spherical magnets. The spheres are unlimited in the direction of rotation. The use of spherical magnetic elements made with the possibility of their free rotation prevents a possible change in the position of the receiving coil or its elements and excludes the possibility of damage to the tissues surrounding the implant magnet.

Known Implantable device for electrical stimulation of the auditory nerve according to patent RU 2484801 C2, IPC A61F 11/04, A61N 1/36, F61N 2/10 (published 20.06.2013). The known device contains a single spherical magnet placed in a sealed magnet attachment unit, inside which the spherical implant magnet can freely rotate. In the absence of external magnetic fields, the orientation of the spherical magnet can be arbitrary. However, when the external magnet of the transmitter coil approaches the implant, this external magnet acts on the spherical magnet of the implant. As a result, the spherical implant magnet is rotated so that the magnetic force lines of the spherical implant magnet and the magnet of the external transmitting coil combine, creating an attraction of the external transmitting coil to the spherical implant magnet.

Under the influence of MRI, the rotation of the spherical magnet of the implant suppresses the possibility of unwanted rotation of the receiving coil and eliminates the possibility of tissue damage.

However, the presence of a large magnetic element under the patient's scalp can lead to some distortion of the MRI results. Therefore, in certain situations, a medical operation is required to remove the spherical magnet of the implant from the patient before the MRI scan and, of course, to reinstall it after the end of the MRI.

This drawback was eliminated in the device according to the utility model CN 207980177 U, IPC A61N 1/36, A61N 1/375 (published on October 19, 2018), and in the device according to the patent for invention CN 107308543 A, IPC A61N 1/36, A61N 1 / 375 (published 03.11.2017).

The device according to the patent for invention CN 107308543 A is the closest in technical essence to the claimed one.

The magnets described in the invention CN 107308543 A are composite magnets, the magnetic elements of which are spherical magnetic balls having N and S poles. The compound magnet has a top cover closest to the patient's skin, below which is an inner grill and a cage with many internal magnetic balls, below which is a bottom cover of the compound magnet. A plurality of internal magnetic balls are evenly spaced along the bottom of the bottom cover and are held from the sides by the walls of the bottom cover and from the top by a cage with a grid.

Thus, the known device uses two layers of magnetic balls, one above the other. All of these balls that enter the receiving coil of the implant can rotate freely. Under the influence of MRI, the magnet balls of the implant rotate, preventing displacement of the receiving coil. On the other hand, the diameter of the magnetic beads that make up the implant magnet is small enough (no more than 7 mm) so as not to distort the MRI results.

To ensure the correct orientation of the transmission coil of the known device, its magnet is also a composite one, including two layers of magnetic balls, the diameter of which must exceed the diameter of the magnetic balls of the receiving coil of the implant. The magnetic fields of the transmitting coil and the receiving coil of the implant are added from the total fields of the magnetic balls, as a result of which the correct mutual position of the external transmitting coil and the receiving implant coil is ensured, completely corresponding to the position that could be caused by solid magnets in the transmitting and receiving coils.

The use of devices according to the utility model CN 207980177 U and the invention CN 107308543 A makes it possible to ensure good compatibility of the external transmitting coil and the internal receiving coil of the implant.

The technical result achieved in the known devices consists in providing the possibility of carrying out MRI to the patient without surgical operations to remove the composite magnet from the patient's head.

The technical result of the claimed invention is to achieve a simpler in comparison with analogues by the possibility of carrying out MRI to the patient without surgical operations to remove the composite magnet from the patient's head.

In addition, an additional technical result of the claimed invention is to simplify use due to the lack of the ability to attract metal objects (buttons, nails, and others) to the user's head in the absence of a speech processor.

Disclosure of the essence of the invention

To achieve the specified technical result, the composition of the claimed magnet for a cochlear implant on spherical magnetic elements includes a set of permanent spherical magnetic elements with equal diameters and poles N and S, an upper round flat cover made of non-magnetic material and a lower cover made of a non-magnetic material in the form of a cylinder, the diameter of which is equal to the diameter of the upper round cover, which is installed and rigidly fixed on the lower cover, and the cylindrical lower cover includes an annular groove coaxial to its cylinder, made with the possibility of uniform filling with a set of spherical magnetic elements, for each of which the possibility of free rotation is provided when fully filled ferromagnetic fluid of an annular groove with spherical magnetic elements.

The set of permanent spherical magnets consists of six, eight or ten neodymium spherical elements. Top and bottom covers are made of titanium and are rigidly connected by laser welding. The ferromagnetic fluid is made in the form of a silicone-based ferrofluid.

Brief Description of Drawings

FIG. 1 shows a top view and frontal view of the inventive magnet for a cochlear implant. In this case, the top view is shown without the ferromagnetic fluid and the top cover. On the right and left in FIG. 1 shows two possible positions of the magnetic elements.

FIG. 2 shows the magnet 1 of the cochlear implant after the cochlear implant is placed under the patient's skin. The location of the magnetic elements inside the annular groove of the bottom cover is shown schematically (dotted line). The position of the external magnet is shown, which may be the magnet of the speech processor.

In the drawings (Fig. 1, Fig. 2), the following designations are used: 1 - magnet of a cochlear implant, 2 - upper lid, 3 - lower lid, 4 - annular groove, 5 - magnetic element, 6 - ferromagnetic fluid, 7 - external magnet , 8 - the patient's skin.

Implementation of the invention

FIG. 1 shows a drawing of the inventive magnet for a cochlear implant on spherical magnetic elements.

The design of the considered magnet 1 of the cochlear implant contains a flat top cover 2 of a round shape, made of a non-magnetic metal, which can be titanium, and a bottom cover 3 of a cylindrical shape, also made of a non-magnetic metal, which can be titanium. After implantation to the patient, the top cover 2 becomes the closest to the patient's skin. The diameter of the base of the lower cover 3 is equal to the diameter of the upper cover 2. The lower cover 3 contains on its upper base an annular groove 4. The depth and width of the annular groove 4 should ensure that a set of permanent magnetic elements 5 of a spherical shape with magnetic poles N and S is located inside it. From which these permanent magnetic elements 5 (neodymium magnets) are formed, is an alloy of the rare earth element neodymium with boron and iron. The crystal structure of a permanent neodymium magnet has a tetragonal shape and is represented by the formula Nd ₂ Fe ₁₄ B. The annular groove 4 contains a ferromagnetic liquid 6 completely covering each of the magnetic elements 5. The level of the ferromagnetic liquid 6 corresponds to the upper base of the lower cover 3. The upper cover 2 is installed on the upper base the bottom cover 3 and rigidly fixed to it using laser welding.

Ferromagnetic fluid 4 and top cover 2 in FIG. 1 (top view) are not shown. FIG. 1 also shows a sectional view of the frontal image of the magnet 1 of the cochlear implant. The magnetic elements 5 inside the annular groove 4 in FIG. Figure 1 shows eight, but there may also be six or ten. The number of magnetic elements 5 located in the annular groove 4 depends on the ratio of the diameter of the magnetic element 5 and the annular groove 4.

The functioning of the claimed magnet for a cochlear implant is as follows.

In the absence of an external magnetic field, each magnetic element 5 is affected by a force caused by the magnetic fields of other magnetic elements 5 (first of all, the nearest ones), which are part of the magnet 1 of the cochlear implant. Under the action of this force, the magnetic elements 5 are rotated so that the N pole of each magnetic element 5 is turned towards the S pole of the adjacent magnetic element 5. Since the total number of magnetic elements 5 in the claimed magnet 1 of the cochlear implant must be even (six, eight or ten ), there are two possible options for their location inside the annular groove 4 of the lower cover of the magnet 1 of the cochlear implant. Both of these arrangement options (for eight magnetic elements 5 with the top cover 2 removed and without ferromagnetic fluid 6) are shown in FIG. 1.

The magnetic field lines are closed between adjacent magnetic elements 5, and the magnetic field of the magnet 1 of the cochlear implant as a whole will be practically zero (in any case, significantly weaker than the magnetic field of one magnetic element 5).

When the external magnet 7 (in particular, the speech processor magnet) approaches the claimed magnet 1 of the cochlear implant, the magnetic elements 5 of the magnet 1 of the cochlear implant will begin to rotate towards the external magnet 7. The force lines of the magnetic elements 5 will add up, and the total magnetic field of the magnet 1 of the cochlear implant the implant will attract it to the external magnet 7. The external magnet 7 (not fixed) will automatically move so that the maximum magnetic field is provided, that is, symmetrically to the center of the magnet 1 of the cochlear implant.

The rotation of the spherical magnetic elements 5 of the implant in the desired direction is facilitated by the presence of ferromagnetic fluid 6 inside the composite magnet 1 of the cochlear implant. The patient should not feel such a rotation.

FIG. 2 shows the magnet 1 of the cochlear implant after the cochlear implant is placed under the patient's skin. The skin of the patient 8 is indicated purely symbolically. Above the patient's skin 8, a permanent external magnet 7 (speech processor) is shown. Its design is not the subject of the present invention. FIG. 2 shows the lines of force of the total magnetic field of the external magnet 7 (speech processor) and the magnetic elements 5 of the magnet 1 of the cochlear implant after turning the magnetic elements 5 and, if necessary, after shifting the external magnet 7 along the patient's skin 8.

When the external magnet 7 is removed from the magnet 1 of the cochlear implant, the magnetic elements 5 in the magnet 1 of the cochlear implant under the influence of the magnetic fields of these magnetic elements 5 will rotate up to one of the positions indicated in FIG. 1. The magnetic field of the magnet 1 of the cochlear implant will decrease almost completely. In any case, after removing the speech processor, the patient will not be threatened with knives, forks or other iron objects sticking to the patient's skin 8 (on his head).

If an MRI scan is required for a patient with a cochlear implant magnet installed, then the external magnet must first be removed from the magnetic field of the cochlear implant magnet. In this case, the magnetic elements of the cochlear implant will come to the position shown in FIG. 1.

Exposure to MRI will cause an undefined requirement for rotation of each magnetic element 5 in magnet 1 of the cochlear implant. In this case, the magnetic elements 5 will freely rotate following the change in the direction of the external magnetic field of the MRI. Such turns will not cause any power loads, especially taking into account the presence of a turn in the ferromagnetic fluid 7.

The strength of the applied magnetic field (for example, with MRI), as shown by the research carried out by the applicant company, can reach 3 T (when using eight neodymium spherical magnetic elements 5 with a diameter of 7 mm).

Claims (6)

1. A magnet for a cochlear implant on spherical magnetic elements, which includes a set of permanent spherical magnetic elements with equal diameters and poles N and S, an upper round flat cover made of non-magnetic material and a bottom cover made of a non-magnetic material in the form of a cylinder, the diameter of which is is equal to the diameter of the upper round cover, which is installed and rigidly fixed on the lower cover, characterized in that the cylindrical lower cover includes an annular groove coaxial to its cylinder, made with the possibility of uniform filling with a set of spherical magnetic elements, for each of which the possibility of free rotation is provided with full filling an annular groove with spherical magnetic elements with a ferromagnetic liquid. 2. The magnet of claim 1, wherein the set of permanent spherical magnets consists of six neodymium spherical elements. 3. The magnet of claim. 1, wherein the set of permanent spherical magnets consists of eight neodymium spherical elements. 4. The magnet of claim. 1, wherein the set of permanent spherical magnets consists of ten neodymium spherical elements. 5. The magnet according to claim 1, wherein the upper and lower covers are made of titanium and are rigidly connected by laser welding. 6. The magnet of claim 1, wherein a ferromagnetic fluid is used in the form of a silicone-based ferrofluid.

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