DE1516417A1 - Apparatus for determining the blood circulation in the human or animal body - Google Patents

Description

Apparatus for determining the blood flow conditions in the human or animal body.

The invention relates to an apparatus for registering circulatory conditions and blood flow conditions in the human or animal body according to one speed-dependent and resistance-dependent yiodulation effect on the body built-up electric field.

@ Previously known arrangements that electrically circulate in the register the human body, work through and through as an ohmmeter.

These arrangements have the disadvantage that they can be done by hand or over Complicated electronic arrangements are coordinated, making them unwieldy Use and are prone to failure, one tapped at one or more places electric field created by an electric Electricity is built up is also known as a measuring arrangement a compensation voltage is superimposed.

The superposition of this compensation voltage also causes a Complication of the messtechninchen process.

The built-up electrical energy is generated by the circulatory processes modulated inside the body. This modulation process is also used in the device the invention used as a measurement basis. These modulation processes are explained in more detail are described in detail, as they are partly based on studies that have not yet been carried out are published. All previous arrangements have been based on the assumption that that the blood has a different unit resistance than the surrounding tissue. By displacing the surrounding tissue or changing the volume due to the pulsation accordingly there is a change in electrical resistance ii body. Geyer, However, Lechner, Rodier were able to test that there is an electrical 1 for operation In the field, not only these factors are decisive, but also the subsequent actuators a modulation cause. Biologically active blood behaves electrically when it is flowing and-rs, as rubbing blood. This has the effect that the electrical unit value of flowing blood appears larger than that of stiff blood. In fact this relative change between standstill and start of flow is greatest, while it approaches a saturation value with increasing speed.

Beginning of flow and speed-dependent change in conductance fall together. However, if the flow stops suddenly, the change in conductance has a delay and only approaches the initial value later.

In the case of alternating fields below 1.5 Müz, there is an essential i? Requency dependency not noticeable, while above 1.5 Ilüz the effect becomes smaller.

The more red blood cells there are per unit volume, the more This speed-dependent change in conductance is greater. Blood with damaged Blood cells do not exhibit this behavior.

This phenomenon, which is dependent on the flow velocity, was This rheoconductivity value comes in the form of an amplitude modulation in an electric field printed on the human or animal body However, the degree of modulation is very small, so an arrangement was made created, which is structured as follows: A constant generator flows through it the object with streams of low, medium, or high frequency.

The field built up by the electric straw is capacitively, inductively or galvanically tapped, strengthened and demodulated by means of electrodes at one or more points at the same time as a sub-area. According to the invention, there is a quadrupole in the measuring amplifiers that deepens the degree of modulation switched into the amplification gear, so that a modulation grave deepening takes place. reiter, the modulation level deepening quadrupole is provided with a sliding working point for adaptation to different voltages. This quadrupole can consist of a diode combination 1, 2, 3, with a high working resistance, which is bridged by a capacitor of high capacitance, the level of the resistance determining the level of the residual carrier amplitude.

According to the invention, the modulation depth deeper can also be done with a External voltage of low internal resistance can be controlled, with the control voltage can be set manually as DC voltage. However, this control voltage can also arise from a voltage that is dependent on the total field, whereby this is field-dependent Voltage can be regulated automatically according to the output voltage In doing so, however, it is useful that this regulation is not continuous, but rather in stages takes place, whereby the control voltage remains constant between the stages and means one jump to the next. This has the advantage of letting go on a continuous basis Registration by means of a registration device with an infinite time constant the Control processes are characterized by a stage and therefore at the same time the expression the change in sensitivity of the device. So that the degree of modulation deepening Quadrupole works with a good efficiency, it is expedient according to the invention to use a curve shape with a rectangular course as the Kesstrom.

According to the invention, the oscillator is used to build up the electric field by means of a current negative feedback that is controlled by the output current, and on the The input of the output stage of the oscillator acts, equipped so that it has a constant Measuring current supplies. The input voltage to the oscillator output stage is preferred Stabilized in terms of amplitude, for the operation of these apparatuses is of course a highly stabilized power supply required. To achieve even greater stability, it is advisable that the output measuring voltage of the individual measuring circuits as Difference value between two measuring systems is taken, with one measuring system with the measured value is applied, while the 2nd measuring system, which is completely the same is constructed, is applied with a comparison value, from the initially presented From theoretical considerations it can be deduced that two factors influence the measured values influence. Namely the volume expansion, 2nd the modulation processes, the caused by the speed-dependent change in conductance of the blood will.

Since the latter is only below 1.5 NDIz, it is not significantly dependent on the frequency is and also decreases, it is therefore possible to combine these two factors with one corresponding arrangement to subtract from each other. According to the invention is therefore When using a double measuring system, the one measuring amplifier is set to frequencies below 1.5 MHz and the comparison amplifier tuned well above 1.5 MHz, with these frequencies are screened out accordingly at the entrance, and so is the field structure takes place with these two frequencies.

The invention is explained in more detail using an example and specifically shows the figure shows an arrangement with 4 measuring circles and a comparison circle. 1 is here the object that is controlled by the oscillator 2 by means of a switching arrangement described below and a constant current flows through it.

3 is the output stage transistor, which is connected to the two Zener diodes 5 receives a stabilized voltage at the input and by means of the current-dependent Negative coupling 4 a constant output current through appropriate dimensioning supplies.

The measuring circuits are shown schematically and between 6 is an amplifier stage, 7 a measuring instrument showing the amplified tapped voltage. 8 is that The four-pole modulation level, which is again followed by an amplifier stage 9. In lo, the carrier deepening the modulation degree is demodulated and by a measuring instrument 11 is displayed. The modulation for write registration can then be set between 0 and A. be removed. The comparison channel E does not get its measurement voltage from the Object, but from a resistor 21, through which the same current flows as You object, the structure of the unit of reinforcement, the unit of measurement is perfect same as with the other arrangements. In order to get particularly stable conditions, can therefore be used to register instead between 0 and A, or O and B, or 0 and C, or 0 and D also the connections between A and E, B and E, C and E and D and E can be used for registration. This will remove all changes made by Current changes are caused, compensated.

In Figure 2, the modulation curve for sinusoidal currents or Voltages 26,27 and for square-wave currents or voltages 28,29, schematically shown, UG is part of the voltage caused by the modulation-deepening The quadrupole is cut out with the sinusoidal voltage curve therefore, that part of the modulation depth is lost, while with rectangular voltage curve this is less the case.

In Figure 3, the modulation degree deepening quadrupole as a diode combination 12 shown. 13 is the high resistance and 14 is the capacitance this resistance is bridged so that a sliding working point is created, through the switch 15 can be connected to a low-resistance potentiometer, ass the external voltage for manual adjustment from the modulation depth deeper feeds. 6, 7, 9, io, and 11 are the same units as in Figure 1.

FIG. 4 shows the diode arrangement for deepening the degree of modulation 12 with an automatic control unit for the degree of modulation deeper. 14 is The capacitor that bridges the control unit. The control voltage for the The diode combination is tapped from the current-dependent voltage value 21, amplified by means of an amplifier 20, demodulated and the stubbornly controllable Resistance 19 pressed on. From the output of the amplifier 9, 10 11, is by means of a Additional amplifier 18 obtained a control voltage, which the setting member 17, depending on Output voltage 11, regulates. This results in a step-by-step regulation, the vlon the output voltage of the amplifier 9, le and 11 depends and thus a uniform Registration for different fitting ratios automatically allowed, whereby Current fluctuations are compensated at the same time.

The extraction of the output measurement voltages is explained in more detail in FIG.

After demodulation by the demodulator 10, the output voltage is measured by the instrument 11, after which the output voltage is divided into 3 different outputs, u.zw. to the output E-via a potentiometer 25 and a. Capacitor for displaying curve progressions with a time constant of approx. 1 second, i.e. for registering the pulsation waves, output G which has a small time constant for the pulsation wave by means of a smaller capacitor 23 and a potentiometer 24, allows the registration of the differential quotient of this curve to O via the output F the processes are registered which should show fluctuations over a longer period of time. These are fluctuations in the capillaries or venous blood flow that are to be displayed. The measuring and recording instruments that can be used for these registrations must have the value 0 as the mean input voltage. In order to achieve this, the DC voltage component existing at the output is canceled by a Zener diode 22. It Of course, it goes without saying that with this measurement arrangement not only can registrations be made on the human and animal body itself, but measurements on blood to investigate it can also be carried out directly in exactly the same way.

Claims (13)

It is possible, if the temperature is kept constant and if the temperature is constant constant speed, from the measured values e.g. the number of red blood cells To this end, of course, various empirical values must be used. The advantage of such a measurement should be emphasized that it is not only the number of red blood cells is displayed, but also at the same time whether these blood cells are still active is included in the measured value, so that this A new blood test method results in patent claims: 1. Apparatus for registration of circulatory conditions in the human and animal body in which an electrical one Alternating field is built up on the object by means of electrical current flowing through it and this. r.ld capacitive inductive or gavanic by means of electrodes to one or several S places at the same time tapped as a sub-area, reinforced and is demodulated, characterized in that a modulation depth deepens Quadrupole (1), in the amplification gear is switched, so that a modulation depression takes place. 2. Claim according to 1 characterized in that the modulation depth ends Quadrupole with a sliding working point for adaptation to different tapped Tension is provided. 3. Claim according to 2 characterized in that the quadrupole consists of a Diodenkoribination 1,2,3, with a high working resistance, which by a Capacitor with high capacitance is bridged, whereby the level of resistance, determines the level of the residual beam amplitude, 4. Claim according to 1-3, characterized in that that the modulation depth deeper with an external voltage with low internal resistance is controlled. 5. Claims according to 1-4 dz marked by that this control voltage can be set as DC voltage from Mand. 6. Claim according to 1-5- characterized in that the modulationsgradverti ^ fende Quadrupole is controlled with a voltage dependent on the total field0 7. Claim 6 characterized in that this field-dependent voltage corresponds to the Output voltage is regulated automatically 0 8. Claim according to 6-7- characterized in that this regulation is not carried out continuously, but in stages, with the control voltage remains constant between the levels and jumps to the next. 9. Claims according to 1-8-characterized in that a measuring atom Curve shape with a rectangular course is used. 10, claims according to 1-9 gekennzeici, inet that the oscillator to build up the electric field by means of a current coupling that comes from the output current is controlled and also acts on the input of the output stage of the oscillator, one supplies constant measuring current. 11 * Claim according to 1-10, characterized in that the input voltage to the oscillator output stage, iRt stabilized in terms of amplitude. 12. Claim according to 1-11, characterized in that the output measurement voltage of the individual measuring circuits as a difference value between two measuring systems ttrd, whereby the measured value is applied to one measuring system, while the second A comparison value is applied to the measuring system, which has a completely identical structure is. 13. Claim according to 12, characterized in that the measuring amplifier with frequencies below 1.5 MHz, while the comparison amplifier operates above 1.5 MHz, these are filtered out accordingly at the input and so is the field structure done with two frequencies.