DE1284528B - Device for the elimination of biological tissue by inductively heated bodies with temperature stabilizing properties - Google Patents

Description

The invention relates to a device for switching off of biological tissue in the depth of a living body according to the principle of Induction heating, consisting of a device for generating alternating electromagnetic fields and to be implanted at the locations to be switched off, by means of the electromagnetic Alternating fields of inductively heated, electrically conductive parts.

T. Smell t was the first time a procedure for surgical use in 1958 Elimination of biological tissue by means of inductive heating of metal implants suggested. According to R i e c h e r t this is a small metal part, z. Am Shape of a short cylinder with a diameter of about 1 mm, attached to tissue necrosis Brought to be switched off and from the outside by an electromagnetic alternating field corresponding frequency and amplitude inductively heated for a certain period of time.

The achieved with this inductive heating of the metal implant The temperature and heat output must be finely adjusted so that only the one to be switched off Tissue area is necrotized by heating.

With this therapeutic procedure, as already reported by T. R i e c h e r t was particularly desirable to be found in the metal implant to measure the temperature achieved by inductive heating outside the body, since only in a relatively small temperature range of the metal implant optimal results can be expected.

The inductive heating of the metal implant is generally generated by a ring-shaped field coil through which alternating current flows, which in is located near the metal implant to be heated.

The thermal energy generated by the inductive heating and thus the maximum temperature reached by the metal implant depends on the following parameters from: 1. Electromagnetic field strength.

2. Frequency of the electromagnetic alternating field.

3. Heat dissipation through the fabric.

4. Position of the longitudinal axis of the implant in relation to the field vector at the location of the Implant.

5. Electrical conductivity of the implant.

6. Magnetic permeability of the implant.

7. Geometric dimensions (diameter and length) of the implant.

The electromagnetic field strength of a ring coil, as it is for the inductive heating of such metal implants in the living body is possible, is by no means constant over the cross section of the coil, but grows in the vicinity the coil turns strongly. At a distance of 75% from the center of the coil Coil radius is the field strength of a ring coil already to double the value of Field strength increased in the coil center.

In addition, the heat energy generated inductively in the metal implant depends on the square of the field strength. If the field strength is doubled, the four times the thermal energy in the metal implant with otherwise constant influence parameters generated.

Furthermore, the heat generated in the metal implant is not only from the field strength, but also from the angle of the longitudinal axis of the implant to the field direction addicted. If the field direction is perpendicular to the longitudinal axis of the implant, only a fraction of the thermal energy as in the parallel case with otherwise identical Conditions created.

As is known, a strong one occurs near the turns of the toroidal coil Change in direction of the field strength, so that in this area the direction of the Field vector is usually not exactly known.

Finally, that is in the metal implant by inductive heating reached maximum temperature to a large extent from the extraction of heat by the surrounding Medium dependent. This can be done by pure heat conduction or additionally by convection occur in the presence of fluids in the vicinity of the implant. The removal of heat from the inductively heated metal implant through pure thermal conduction and thus its maximum temperature reached depends, in turn, according to T. R i ech ert not only on the thermal conductivity coefficient of the fabric, but also on the level of blood flow to the surrounding tissue.

The therapeutic success of this method of coagulation and thus to turn off certain tissue parts depends, among other things, on the possibility starting to achieve a certain temperature of the metal implant inside the body.

The effect of the influencing factors discussed above, such as field strength, Angle between field direction and longitudinal axis of the implant as well as heat dissipation through the environment represents a certain uncertainty factor in this process Coagulation of certain tissue parts by inductively heated metal implants.

If it were possible to change the temperature of the metal implant e.g. B. to measure by thermocouples, that would be for the exact dosage of the coagulation necessary thermal energy advantageous. However, it is precisely this one advantage Method that the metal implants are implanted in the body without a there must be a direct connection between the metal implant and the body surface.

Therefore, here is another way of achieving a desired one Temperature of the inductively heated implant in the depth of the living body suggested.

The thermal energy generated by induction in a metal implant can be calculated using Bessel functions. As an argument for these Bessel functions the product f a a, u occurs with d2. Here f means the frequency of the inducing electromagnetic field, o the electrical conductivity of the implant material, measured in m / ohm mm2,, u its relative magnetic permeability and d the diameter of the implant, measured in centimeters.

The exact magnetic analysis of the heat energy generation by a inducing alternating field results in two frequency ranges with completely different behavior with regard to the thermal energy generated in the implant. Is the value of the product f. j. for d2 less than 30,000, the thermal energy generated in the implant increases with the square of this product. If the value of the product f a, u d2 is greater than 30,000, that's how it grows Thermal energy generated with the implant the square of the inducing magnetic field strength.

According to the invention it is now proposed that as a material for the parts to be implanted a ferromagnetic alloy is used, whose magnetic Curie point is chosen so that the inductive heating is in one specific field strength and frequency range, regardless of the field strength or frequency and the thermal dissipation through the environment and from the axis of the part to the direction of the alternating magnetic field to a stable one, through the Curie point sets a certain temperature value. The basic idea of the invention is thus based on the use of a material that can grow in a narrow temperature range Temperature its permeability of high values, e.g. B. set = 100, to the value according to = 1 drops.

Substances have become known in which by alloy composition and / or heat treatment of the Curie point, d. H. the temperature of disappearance of ferromagnetism over a wide temperature range to defined temperature values, z. B. 50, 60, 70 or 800 C, is adjustable.

An implant made from such a material is an automatic one Control system, which is independent of the field strength, the frequency and the energy dissipation to a certain temperature value.

The control mechanism comes into force when a certain Field strength excess is worked at which the temperature is relatively high Values would assume if not in a narrow temperature range the value of the magnetic Permeability drops from high values to the value 1.

Because of this steep drop in permeability with increasing temperature but if the energy production decreases, which depends on the product f fcsud "lt d2, suddenly, so that the further increase in temperature is interrupted. Shows but z. B. the tendency to drop due to stronger heat extraction, so the magnetic permeability increases again steeply, whereby the heat generation is strongly fanned in the implant.

So by choosing the alloy and / or the heat treatment of the magnetic Curie point placed so that it is at the desired temperature of the metal implant this temperature will be independent of the variation of the parameters Field strength, frequency, heat dissipation and angle between implant axis and field direction to adjust.

This stable temperature of the implanted body in the inductive Warming is caused by the strongly increasing heat generation already at slight cooling below the target value to which the Curie point of the implant corresponds, and due to the strong decrease in heat generation even when the implant is only slightly heated above the setpoint.

Induction heating of the implant can be a side effect the impermissible inductive heating of dental bridges, crowns and seals as well as occur from better conductive tissue parts. True, the value corresponds to the magnetic Permeability of the metal parts used as dentures as non-ferromagnetic to the Values 1. In the product f. lt d2, which is decisive for inductive heat generation is, both the square dimension and the electrical conductivity occur on. Both values, as crowns, bridges, etc., can be considerably higher than the corresponding values of the implant.

In general, it is a low Curie point ferromagnetic for alloying reasons with a relatively small value of the electrical conductivity coupled. So that the product, which is decisive for heat generation, f lt. D2 is sufficient assumes large values, the frequency of the inducing field becomes correspondingly high chosen. At the same time, this means a considerable amount for dental crowns and bridges Heat generation. Therefore it is proposed in a continuation of the invention that the implant is composed of two substances. Inside the full cylinder or tube is the ferromagnetic material, its Curie point in the range of the desired maximum temperature of the inductively heated implant lies. This material can be a metallic alloy or a non-conductive one be ceramic ferrite.

A thin-walled tube encloses this ferromagnetic core made of highly conductive, non-ferromagnetic metal. For this comes z. B.

Gold, silver or another tissue-compatible metal of high electrical power Conductivity in question.

Such an implant is made of two different materials the ferromagnetic core is the carrier of magnetic permeability, the thin-walled one Sheath the carrier of electrical conductivity in the product f a 1X-, lt d2, which is decisive for inductive heat generation.

The theory of eddy currents shows that such a splitting of the physical properties in the core and the shell of the implant is permissible.

With such a material combination with high electrical conductivity on the outer surface and high magnetic permeability inside the implant can use a significantly lower frequency for inductive heating of the implant are used than with a homogeneous ferromagnetic material with its low electrical conductivity as it only affects the product f. j. . d2 of the implant arrives.

Such a reduction in the frequency of the inducing fields causes a sharp drop in unwanted heat generation in tooth crowns, bridges or -seal because with the frequency so reduced the product f a z d2 for the dental prosthesis falls below the value of 30,000. Here, however, as explained above, the generation of heat with the square of the named product.

The proposed division of the implant into an inner support of magnetic permeability and an external carrier of electrical conductivity allows such a low induction frequency to be used for implant heating, that undesirable side effects, such as. B. Tissue warming or warming of metallic tooth replacement parts are not required.

When dividing the implant into a ferromagnetic core and an electrically conductive jacket is used to generate heat in the conductive sheath in no way affects the thermal contact between core and sheath at.

The ferromagnetic core generates below the Curie point in the electromagnetic induction field an alternating magnetization. This creates According to the law of induction, a ring-shaped electrical alternating voltage around the core.

This ring-shaped alternating voltage is generated in the ring-shaped outer conductor the heat-generating eddy currents. As it is not due to the thermal contact between core and jacket arrives, it can be made in a slightly fluted or wavy shape to prevent the implant from migrating in the body.

Claims (6)

Claims: 1. Device for the elimination of biological Tissue in the depth of a living body using the principle of induction heating, consisting of a device for generating alternating electromagnetic fields and on to be implanted in the locations to be switched off, by the electromagnetic alternating fields inductively heated, electrically conductive parts, characterized in that as A ferromagnetic alloy is used as the material for these parts to be implanted whose magnetic Curie point is chosen so that the inductive heating within a certain field strength and frequency range, regardless of the field strength, the frequency and the thermal dissipation through the environment as well as the orientation the axis of the part to the direction of the alternating magnetic field on a stable, through the Curie point sets a certain temperature value. 2. Device according to claim 1, characterized in that the to implantable, inductively heated parts with a tissue-compatible coating be provided. 3. Device according to claim 1, characterized in that the to implanting, inductively heated parts body of circular cylindrical or are hollow cylindrical shape. 4. Device for the elimination of biological tissue in depth of a living body on the principle of induction heating, consisting of a Device for generating electromagnetic alternating fields and on the ones to be switched off Locations to be implanted, inductively heated by the alternating electromagnetic fields, electrically conductive parts, characterized in that the to be implanted, Body to be inductively heated made of a ferromagnetic metallic or non-metallic Core with a Curie point chosen according to the teaching of claim 1, the carries a sheath made of a material that conducts electricity well. 5. Device according to claim 4, characterized in that as well conductive sheathing material a tissue-compatible material is used. 6. Device according to claim 4 and 5, characterized in that the electrically conductive sheath in corrugated or corrugated form to prevent the migration of the implanted body in the tissue is carried out.