DE2255300A1 - METHOD AND EQUIPMENT FOR THE COLORIMETRIC EXAMINATION OF SUBSTANCES FOR SIGNIFICANT COMPONENTS - Google Patents

Description

Method and device for the colorimetric analysis of substances to significant components. The invention relates to a method and a Device for the colorimetric analysis of substances for significant constituents, particularly of blood in terms of the percentage of oxygenated hemoglobin on total hemoglobin (oxygen saturation of the hemoglobin) and / or more artificial Dye proportions (dye concentration) at which the Substance or reflection on the substance resulting exit intensities of light a first wave length, which is independent of the component to be detected of its percentage - in the substance, in essence, always the same is absorbed or reflected, as well as light of a different second Wavelength, which corresponds to different percentage values is absorbed or reflected to different degrees, determined and as a corresponding separate electrical signals means for display and / or computational processing, in particular for relationship formation. When measuring oxygen saturation of the hemoglobilis, for example, a value around 805 is available for the first wavelength Nanometers and for the second wavelength a value around 660 nanometers because at 805 nanometers is known to be oxyhemoglobin and reduced hemoglobin in the have essentially the same absorption or reflection, while for 660 nanometers the absorption or reflection for oxyhemoglobin and reduced hemoglobin in one relatively strong mass is different. For measuring the dye concentration in the blood, for which Cardiogreen is usually used as an indicator substance, and which are advantageous for determining the cardiac output or the heartbeat volume the second wavelength will be around 805 nanometers, for example chosen because the indicator substance "Cardiogreen" only wavelengths around this value relatively strongly absorbed. The first wavelength, on the other hand, is freely selectable and can e.g., according to normal practice, 910 nanometers can be selected. Since the freely selectable The first wavelength generally also depends on the oxygen saturation of the hemoglobin depends on the measurement of the dye concentration in order to avoid measurement errors occur in the arterial system (aorta).

Devices for determining the oxygen content of blood, which after the The above-mentioned procedures are available, for example, from DAS 1 498 513 or previously known from Swiss patent specification 5-3,995. These devices work but always in pulsed light mode, i.e. the light is pulsed into the blood irradiated and received again from the blood in impulses.

The light impulses are generated periodically Chopping of the transmitted light beam by means of a mechanical chopper, e.g. at the DAS 1 498 513 by alternately inserting the optical passage filters # ~ n for the first and second wavelength in the transmitted light beam and in the Swiss Patent specification 503 995 e.g. by means of a rotating device located in the light beam Perforated disc.

Working with light pulses, however, already has the disadvantage that a relatively wide range of different frequencies is processed in the receiving section must be, which on the one hand requires a lot of broadband amplifiers or other selection members conditionally and on the other hand to a not insignificant one Susceptibility of the device to external light or radiated electrical Interfering frequencies leads. Also the use of mechanical chopping to generate light pulses is disadvantageous because such mechanical chopper is relatively bulky and also expensive and thus unnecessarily increase the overall dimensions of the device or make the entire device more expensive. When chopping the transmitted light by means of light p ter are also for the selective reception of the individual wavelengths in the receiving part Electronic changeover switches working synchronously with the choppers are required.

The object of the invention is to obviate these # disadvantages, i. E.

to specify a method and a device of the type mentioned above, at the same time with a considerable reduction in the total technical effort a more precise specification of the measurement results is achieved.

The task is based on a method of the aforementioned Art solved according to the invention in that the substance during the entire measuring process continuously with the light of a frequency operated with an alternating current Light source is irradiated that just as uninterrupted from that of # the substance incoming light the exit intensities # for the first and second wavelength # determined and from the. in each case occurring electrical signals on-electrical Paths that lie in the range of the frequency of the irradiated alternating light component electrical frequency components selected and after amplitude demodulation the Means for the display or

for further computational processing. A device for carrying out this method according to the invention contains besides one light intensity meter each for each of the two wavelengths as well as in addition to means for display and / or computational Further processing of the electrical signals generated by the intensity meters according to the invention a frequency determined with an alternating current. operated light source as well as a series circuit connected to the output of each intensity meter from an electrical frequency selector for screening out those in the area dej frequency of the radiated alternating light component lying electrical frequencies from the output signals of the intensity meter and an amp demodulator for Amplitude demodulation of these electrical ones supplied by the selection elements Signals.

The method or device according to the invention does not work like that known methods and devices according to the # Liehtimpuls method, but in continuous wave operation, so that mechanical choppers are not needed in the first place. Since the continuous wave operation also takes place on a single frequency (frequency # of the alternating light component in the light of the light source fed with alternating current, e.g. 100 Hz with 50 Hz alternating current operation), On the one hand, the measurement is not susceptible to interference for all optical and electrical ones Frequencies outside the selected sendc; light frequency (e.g. 100 Hz). The selective Working on a single transmission light frequency also enables circuit technology Simplifications in the electronic receiving part, e.g. are now only selective Receiving amplifier needed instead of broadband, and on the receiving side electronic changeover switch can be dispensed with.

In an advantageous embodiment of the device according to the invention as a light source a 100 watt lamp operated with 12 V at 50 Hz is less thermal Inertia and used with built-in elliptical mirror condenser. As selection members are narrow band filter with one of the frequency of the alternating light component corresponding center frequency, i.e. 100 Hz for 50 Hz AC operation. The bandwidth of the bandpass filters should expediently be of the order of 20 Hz lie.

This bandwidth ensures that especially when measuring oxygen in the blood fluctuations in light intensity and thus in oxygen saturation up to about + 10 Hz processed exactly. The amplitude demodulation of the bandpass filter output signals is conveniently done by means of precision double-wave rectifiers (for elimination possible phase differences between the respective signal processing channels) as well as downstream 10 Hz low-pass filters.

According to a further invention, irradiation is also advantageous of the light into the substance or to receive the light coming from the substance uses a fiber optic probe made up of a plurality of at the distal end of the probe statistically mixed and at the proximal end of the probe into a transmission line or consists of optical fibers divided into individual receiving strands. Such a one Fiber optic probe brings compared to conventional fiber optic probes, in which the individual Send resp.

Receiving strands are also arranged separately at the measuring end, the surprising Advantage that the irradiation of light into the substance over the entire distal The probe cross-section is statistically distributed and, accordingly, also Cas e.g. an the substance reflected light again distributed over the entire cross-section is received so that the measurement of the light intensity at the desired wavelengths therefore always takes place in the same place at the same time and possible measurement errors due to from place to place fluctuating distribution of the substance constituent to be detected thus avoided from the outset.

Further advantages of the invention are illustrated below with reference to a figure explained in more detail.

The figure shows a device according to the invention in a basic circuit diagram. This device is used in particular to measure the oxygen content of blood and to simultaneous detection of the ~ Gardiogreen "dye concentration in the blood for the purpose the determination of the cardiac output or the heartbeat volume.

In the figure, 1 denotes a human blood vessel.

A light guide probe 2 is inserted into the blood vessel 1. The fiber optic probe 2 consists of a large number of optical fibers, e.g. glass fiber fibers, which at the distal end of the probe 3 statistically mixed and only at a certain distance from the distal end of the probe into a transmit strand 4 and a total of three receive strands 5, 6 and 7 are divided.

There is a light generator 8 at the input of the transmission line i, which from a 100 watt incandescent lamp operated with 12 V at 50 Hz is less thermal Inertia and with built-in elliptical mirror condenser.

The proximal ends of the receiving strands 5 to 7 are in turn in optical connection with light receivers 9 to 11, each consisting of a photodetector (preferably epitaxial Si phototransistor with subsequent FET stage) and upstream Frequency filters for filtering out the wavelengths 805 nanometers, 660 nanometers as well as 910 nanometers consist of the received light. Each receiving member 9 to 11 electrical amplifiers 12 to 14 are also connected in series for the output signals the photodetectors, active band filters 15 to 17 with a center frequency of 100 Hz and a bandwidth of 20 dz (preferably integrated operational amplifiers with a double-T network of RC elements in the feedback circuit), precision two-way rectifier 18 to 20, as well as 10 Hz low passages 21 to 23.

Furthermore, two dividing members 24 and 25 are provided for formation the quotient 1R (805) / IR (660) from the output signals 1R (805) and IR (660) of the low-pass filters 21, 22 on the one hand and the quotient IR (910) / IR (805) from the output signals IR (910) and IR (660) of the low-pass filters 23 and 21 on the other hand. The output signals of the dividing elements 24 and 25 can be switched by means of a switch 26 are shown separately on a display device 27 Bl, the dividing members 24 and 25 are designed to handle input voltages in the range of 1 to 10 V- # process with an accuracy of + 1%. A visual threshold detector 28 signals on a display lamp 29 input voltages of the Div @ diodes outside this Area. In this case, to avoid incorrect measurement results, the Gain in the three channels simultaneously by a certain, constant amount be increased or decreased.

With the device according to the figure, the oxygen content of the blood can be measured or determine the "Cardiogreen" dye distribution in the blood as follows: Before beginning For the measurement, the distal end of the probe 3 is inserted into the blood vessel to be examined. The lamp 8 is then switched on and thus uninterrupted over the end 3 of the probe 2 light with an alternating light component of 100 Hz is radiated into the blood. The part of the incident light reflected in the blood is from the end 3 of the probe 2-resumed and just as uninterrupted through the individual reception lines 5 to 7 to the respective receiving element 9 to 11 for the optical filtering of the 805, 660 and 910 nm wavelengths and their intensity measurement supplied.

The resulting at the output of the individual receiving elements 9 to 11 electrical signals (output signals of the photodetectors ) will after amplification in the amplifiers 12 to 14, the 100 Hz band filters 15 to 17 are supplied. The signals occurring at the output of this band filter are transmitted by means of the elements 18 to 23 demodulated in amplitude and then the amplitude demodulated signals given to the dividing members 24 and 25, respectively.

Since, as already described at the beginning, the intensity IR (660) #der reflected 660 nanometer light wave directly a measure of the oxyhemoglobin content, the intensity In (805), on the other hand, is a measure of the total hemoglobin content in the examined Represents blood, thus represents the output signal In (805) / IR (660) of the divider 24 represents a measure of the oxygen saturation of the examined blood. Correspondingly results when the measuring end 3 of the probe 2 is introduced into a blood vessel of the articular System, e.g. aorta, into which "Cardiogreen" has been injected, at the exit of the dividing member 25 a signal which is an immediate measure of the concentration of the "Cardiogreen" indicator substance represents in this blood vessel.

Claims (11)

Claims 1. Process for the colorimetric analysis of substances significant components, especially of blood in terms of percentage of odydated hemoglobin in the total hemoglobin (oxygen saturation of the hemoglobin) and / or artificial dye components (dye concentration), in which the exit intensities resulting from radiation of the substance or reflection on the substance of light of a first wavelength, which is independent of the component to be detected of its percentage in the substance is essentially always the same is absorbed or reflected as well as light of a different second Wavelength, which corresponds to different percentage heart values is absorbed or reflected to different degrees, determined and as a corresponding separate electrical signals, means for display and / or further computational processing, in particular for the formation of a relationship, which can be passed on Z e i c h n-e t that the substance is uninterrupted during the entire measuring process with the light of a light source operated with an alternating current of a certain frequency is irradiated, that is also continuously from the light coming from the substance the exit intensities for the first and second wavelength (e.g. 805 nm, 660 Tun or 9lC) nm, 805 iim) and determined from the electrical Signals by electrical means in the range of the frequency of the radiated light light component lying electrical frequency components selected and after amplitude demodulation forwarded to the means for the display or for the computational further processing will. 2. Apparatus for performing the method according to claim 1 with a Light source for irradiating light into the substance and each with a light intensity meter for each of the two wavelengths and with means for display and / or computational Further processing of the electrical signals generated by the intensity meters, G e k e n n e n n z e i n e t d u r c h a with an alternating current certain frequency operated light source (8) and one at the output of each intensity meter (9, 10, 11) connected series circuit consisting of an electrical frequency selector (15, 16, 17) for filtering out the alternating light components in the range of the frequency of the irradiated alternating light components lying electrical frequencies from the output signals of the intensity meter and an amplitude demodulator (18 #, 21; 19, 22; 20, 23) for amplitude demodulation these electrical signals supplied by the selection elements. 3. Apparatus according to claim 2, characterized in that the light source (8) with a low-frequency current, preferably with current of the mains frequency 50 Hz. 4. Apparatus according to claim 3, characterized in that the light source (8) a 100 W incandescent lamp operated with 12 V at 50 Hz with low thermal inertia and is used with a built-in elliptical mirror condenser. 5. Device according to one of claims 2 to 4, characterized in that that as selection elements (15, 16, 17) narrow-band band filters with one of the frequency the center frequency corresponding to the alternating light component are used. 6. Apparatus according to claim 5, characterized in that during operation the light source (8) with 50 Hz alternating current the center frequency of the band filter (15 to 17) is 100 Hz each. 7. Apparatus according to claim 5 or 6, characterized in that the Bandwidth of the band filters (15 to 17) is in the order of 20 Hz. 8. Device according to one of the claims 5 to 7, characterized in that that as band filters (15 to 17) active bandpass filters, preferably integrated operational amplifiers with a double-T network of RC elements in the feedback loop are used. 9. Device according to one of claims 2 to 8, characterized in that that each amplitude demodulator consists of a precision 1) oppelweg rectifier (18 to 20j with a downstream 10 Hz low pass (21 to 23). 10. Device according to one of claims 2 to 9, characterized in that that as processing means for the output signals of the amplitude demodulators Working in the range from 1 to 10 V with an accuracy of at least + 1% Dividing members (24 and 25) are used. 11. Apparatus according to claim 10, characterized in that the dividing elements (24 or 25) are assigned a threshold value detector (28) for displaying voltages exceeding the input range of the dividing element. L e r s e i t e