DE2109515A1 - Methods and probes for the thermal investigation and influencing of the condition of media, in particular of biological tissue - Google Patents

Description

Processes and probes for thermal investigation and influencing the condition of media, especially biological tissue.

The invention relates to a method and probes for thermal examination and influencing the condition of media, especially biological tissue It supplements and expands the patent application dated October 21, 1-G67 P 16 48 905.5 claims for the purposes already explained there. The further development the method and apparatus set out in the cited patent application has to the Improvements and innovations made, which are the subject of the additional pat ent 5 should be. The purpose pursued by the arrangement and the method is thorough set out in the cited patent application, which is why unnecessary repetitions here should be avoided and only necessary additions are presented in detail.

First is the physical basis of our improved method the determination of thermal and mechanical quantities using pulse heating.

The two dimensionless ones go into the solution of the non-stationary heat conduction equation with convection for a system under consideration (Fourier numbers in. Here, Q is the density, c is the specific heat, and ak is the thermal conductivity the thermal conductivity) of the medium in the system, t0 characteristic time, 1 characteristic length, ir characteristic flow velocity in the system The spatiotemporal temperature profile in this system is determined by the two parameters. The value of the two parameters can be taken from it (locally, ie in the vicinity of the measuring point). The two numbers ND and NI contain the two quantities b Vo and γ in such a combination.

that one can determine both quantities, and X from them. It will the flow is assumed to be sufficiently homogeneous in the measuring range. Isn't that If this is the case, the measurements only give an average over the measuring range Speed.

To determine the two quantities Ub and y from measurements, two Requirements are met: 1) The evaluation of the temperature measurement curves should be as possible be easy.

2) The arrangement should be such that the angle of attack does not into the equations for determining the quantities Vo and)! comes in.

Regarding point 1) A simple evaluation of the temperature measurement curves is available especially possible if the method is highly non-stationary, that is when using a (physically) instantaneous source to generate the temperature. "Physical" currently means that the pulse time should be small compared to the characteristic time s0 introduced above (e.g. v0 is the half-life of the Measurement curve). (However, the quantities s and X can also be derived from measurement curves with a finite pulse time, i.e. pulse duration # can be taken.) Regarding point 2) By considering symmetry (or simple calculation) one can see that with a cylindrically symmetrical arrangement (e.g. ring-shaped spatially well-delimited source and measuring point on the cylinder axis) the The angle of incidence only affects the absolute level of the measured temperature, the dynamics the temperature spread does not change. (This is a consequence of the momentary Spread of the temperature field, which is assumed in dBf thermal conduction equation is.) Measurement curves can be evaluated as follows: We consider the arrangement of the momentary heat source and lueßstelle according to Figure 1; where Q is the ring-shaped one Source and M the temperature measuring point. Diagrams of temperature-time measurement curves are obtained of the form of Figure 2, where t11 t2 the first and second half-lives and to die Represent the time of the temperature maximum To. You can choose from two of these three sizes Determine Vo and X.

When selecting several curve points, regression calculation the desired quantities Xo and X can be determined more precisely.

The method just described and the associated wet arrangement thus differs essentially in method and arrangement from all known to us Arrangements and methods e.g. from the often used "anemometer arrangement", be it in the execution of the normal anemometer, as it is e.g. short and clear von Rasmussen and Nasen (1) are described, or in versions as in the medical technique by Golenhofen and Hensel t2) or Felix and Groll (3,4) will.

All of these arrangements have in common that the size X with a (quasi-) stationary method is measured: that of the conduction current additional convection flow increases the total heat flow.

The increase in the total current serves as a measure of the size of the convection.

A fundamental disadvantage of these methods is that from measurements in principle only the product X Xo can be determined, that is, for the determination the speed the thermal diffusivity must be known. This difficulty is used by Golenhofen and Eensel (2), for example, in medical applications circumvented the fact that primarily only an effective thermal or thermal conductivity is indicated will.

The methods used by Golenhofen in () and Kanzow in (6) are by their nature equally stationary methods. From a steady drop in temperature (The temperature gradient between the measuring points is constant.) And the power supplied an effective thermal conductivity is determined, which the heat transport through Contains conduction and convection, but does not allow a distinction between the two.

In summary, it can be stated: In contrast to that mentioned arrangements which use (quasi-) stationary methods are oei der The arrangement given by us uses a non-stationary method. This has Significant advantages over stationary methods: 1) Both variables V0 and X can be taken separately from a measurement, 2) because of the short measurement time the result in living biological tissue is not due to the reaction of the tissue falsified to the thermal stimulus, 5) the method still works in the area where heat transport through conduction and luonvection are comparable, i.e. at very small -speed.-eiten.

The limits of the method of our arrangement are at high flow velocities, so when the heat flow through convection becomes large compared to that through conduction. In Again, the anemometer method has advantages in this speed range.

In order to be able to apply the method presented experimentally, it was necessary to develop a new probe, the first implementation medication of which is shown in Figure 3 is shown. Here, 1 represents a rigid metal tube, which is from a second in this concentrically introduced metal tube 2 through an electrical insulating layer 3, e.g. Teflon, is separated. These two tubes 1 and 2 can & can be made shiftable in relation to each other.

On the axis of the tube 2 there is, rapping beyond the ear end, a gene the pipes 1 and 2 electrically insulated by an insulation 4 Temperature sensor 5, its feed lines 6 and 7 through the interior of tube 2 to the other end of the tube lead and end in the probe head located there, in which all other electrical Connections end in suitable contacts in a known manner. The heat is generated by current flow in the electrically conductive medium 8 between the metallic end faces 9 and 10 of pipes 1 and 2.

Previously known forms of such electrodes have compared to "unipolar" or "different" electrodes, (i.e. electrodes from which the current is fed to a large-area, inactive electrode, e.g.

an Iletall plate, flows, see e.g. (5)), as it has been for a long time in stimulus physiology and electrosurgery as a whole, especially the Advantage of a better defined and more easily surveyable or calculable current flow Known electrodes of this type consist, for example, of two concentric insulated ones Metal tubes, which can be slid into one another, the uninsulated being ring-shaped End face of the outer tube which forms one electrode, while the other electrode is formed by a metallic spherical cap which closes the inner tube. (See e.g. (7)). Another form of construction of a bipolar electrode, the earlier with the help of one of us (E.G.) from the electrode shape described according to (7) has been further developed, contains in the interior of the inner tube closing Spherical cap a temperature sensor, which is metallic with the metal cap is permanently connected conductive or isolated. All probe parts are no longer here slidable, but rigidly connected to each other. With such a probe is optionally electrophysiological stimulation, reversible temperature-controlled stimulation Heating, an irreversible temperature-controlled naturalization (coagulation) of biological tissue and a measurement of the change in heat transport can be carried out (see e.g. (8) (9)).

We have these known probes for the one described above and in Fig. 3 iorm shown further developed and thus the application of the above-described Method of determining the thermal diffusivity and burchströmun, g enables. This method can also be used if the probes are modified, such as will be described in more detail below: 1) The basic ufoau of a modified one The probe corresponds to Figure 3, but there are btirnf1; c, len that serve as electrodes the pipe and the temperature sensor in one Erene.

2) The basic structure of a modified probe corresponds to figure 3, but the end faces of tubes 1 and 2 and the temperature sensor are located on a concave surface.

3) All the modifications described can be made while retaining the basic structure are carried out so that flexible instead of rigid pipes Electrically conductive materials are used, so that the entire assembly becomes flexible.

4) Another variant of this probe arrangement is that the energy required to heat the medium is not supplied via galvanic lines and is carried out by supplying electrical energy, but by supplying it of electromagnetic radiation via a light guide or waveguide. The warming of the medium can be done in two different ways: 4a) By absorption the radiation in the aluminum, as FIG. 4 shows.

According to FIG. 4, the probe required for this consists of a rigid one orflexible sliver-shaped light guide or waveguide 11. On the axis of this Hose 11 is located, protruding over the hose end, with the hose rigidly connected temperature sensor 12, whose leads 13 and 14 through the Lead the inside of the hose to the other end of the hose and into the probe head located there end, in which the coupling of the electromagnetic radiation in well-known Way is done. The electromagnetic radiation is emitted from it the front surface 13 of the light guide or hollow conductor is absorbed in the medium 16.

4b) By absorbing the radiation on the front face made absorbent of the light guide or waveguide. The probe is basically the same constructed as shown in Figure 4 and described in paragraph 4a. In this modification the probe is the entire electromagnetic energy at the end face 13 of the Light guide or waveguide 11 absorbed, converted into heat and predominantly handed over to the ivedium 16.

The probe arrangements described in Sections 4, 4a, 4b can can be modified in the same way as for the electrical probe in the sections 1 and 2 was described.

Some of the probes described here are in conjunction with suitable known apparatus universally usable in the sense that many those to be performed in physiology and surgery, especially lseurosurgery1 interventions and isie ounces have it carried out. These include e.g. Electrophysiological nerve irritation, denaturation of tissue (coagulation) 5 Fitness measurement, measurement of blood flow and temperature stress literature 1) Rasmussen, C.G .; B.B. Madsen: Arch. F. Techn. Messen, Febr. 1968, Lfg. 385, R17-R22 2) Golenhofen, K .; H. Hensel, G. Hildebrandt: Blood flow measurements with heat conducting elements, Stuttgart 1963, Thieme publishing house 3) Felix, W .; H. Groll: Zeitschr. Biol. 106 (1953) 208 4) Felix, W .: Compt. Rend. d. Congr. Int. D'Angiol. à Friborg II 1955, 266-7 5) Golenhofen, K: German Patent Office, published no. 1 121 274 from 4.1.1962 6) Kanzow, E.

Pflüger's arch. 273 (1961) 199 7) See e.g. company brochures of the company F.L. Fischer, 78 FreiburgjBr.

Hospital Supply Factory: Stereotactic Targeting Device Accessories 8) Gabriel, E .; H. Faion, G. Dieckmann: Confin. neurol. 29 (213-219) (1967) 9) Dieckmann, G.; L. Gabriel, R. Hassler: Confin. neurol. 26 (134-142) (1965)

Claims (4)

Claims. () 1) Method and probe for thermal investigation and influencing the condition of media, in particular of living biological tissue, thereby characterized in that the tissue area to be detected is fed through a probe, The energy to be converted into heat is added in pulses (i.e. in the form of an impulse) is and that with simultaneous and after landing of the impulse taking place s ;; measurement and registration of the tissue area (medium area) outside the heat generation area resulting temperature and its change at only one temperature measuring point the probe. 2) probe for performing the method according to claim 1, which is suitable is for the delivery of electrical energy in the form of briefly flowing direct currents as well as alternating currents of different frequencies for the purpose of generating heating areas in media, especially in living biological tissue, characterized in that that the heating area is annular and concentric due to the flow of current arranged circular electrodes in the medium is generated, with the temperature There is only one sensor outside the area of the uninsulated electrode parts is measured on a point outside the axis of cylindrical symmetry of the heat generation area. 3v probe for performing the method according to claim 1, which in connection with known pulse generators is suitable for generating heating areas in media, especially in living biological tissue, characterized in that that the energy is supplied through a suitable light guide or waveguide and only enter the end of the probe on the medium side, namely at the end face can and there by absorption to a heating in an annular area leads, whereby the temperature is measured at only one measuring point and that on one Point of the axis of cylinder symmetry outside the heat generation area. 4) probe for performing the method according to claim 1, which in connection with known pulse generators is suitable for generating heating areas in media, especially in living biological tissue, characterized in that that the energy at the probe tip in the annular absorbent face the light guide or hollow pus is absorbed and the resulting amount of heat emits mainly to the tissue, the temperature being measured at only one measuring point is on a point of the axis of cylinder symmetry outside oes heat generation area.