DE2306285A1 - DEVICE FOR PERFORMING A VARIETY OF CHEMICAL ANALYZES OF LIQUID SAMPLES - Google Patents

Description

Device for performing a variety of chemical analyzes of Liquid samples The invention relates to a device for carrying out a Variety of chemical analyzes of liquid samples, especially for component concentration analysis for blood and for prothrombin time analysis.

The invention thus relates to the chemical quantitative Analysis of certain items found in the blood, urine or other body fluids Ingredients of essential medical and health interest relevant investigations are; the invention also allows the determination pathological states in human or animal bodies and serves as a guide for the indication of therapies and healing arrangements as well as parameters for the prognostic Diagnosis of the state of health or the clinical picture in the assessment of an organism.

From the point of view of chemical analysis as well as in terms of instrumental supply, are with progressive refinement on this technical field also procedural simplifications have been introduced. Simple in other words, the biochemical colorimeter measurement is based on a measurement of the Color 8 which is developed by certain chemical reactions -the developed Color is usually stoichiometric to the concentration of what is being analyzed Ingredient related In the early years biological or clinical, chemical Research was usually done on the colors developed in a chemical reaction visually compared with those of constant concentrations. In this way one could approach the unknown component and the result could be in certain Cases can even be interpolated. An optical colorimeter from the so-called Double shell type, also a so-called slit field comparator was used, 'um to indicate an approximation of the color equilibrium, focusing on different immersion depths of optical samples is related0 Later a filter photometer developed, which is used to isolate a useful and desired part of the spectrum a filter was used, and finally prisms, diffraction grids and inference filters were used introduced, all of which increased sensitivity and specific relatedness and improved the reproducibility and accuracy of the processes. Even the human element, which came from the visual comparison of the colors, switched off Other instruments in the field were used also the ultraviolet and infrared regions of the spectrum.

With the further advancement of technology, various chemical formulas of reagents developed, the specific goods and in increased Dimensions had the desirable stability properties. Until that state was reached, different amounts and baths of reagents had to be examined and graphically laid down to the color development with the terms of concentration related.

After all, the technology in this area is now up to a point advanced that the colorimeter or.

Spectrophotometer scales directly calibrated in terms of concentration and read instead of taking a reading on the meter and then a calibration table or graph can be used must in order to translate this reading into a meaningful concept of concentration. Methods have also been introduced that use a single calibrated measuring instrument can be inserted into a colorimeter with a key mechanism, whereby it was achieved that the appropriate filter was properly introduced into the light beam became; several scales can be written on the measuring instrument surface, however, no provision has been made for a filter change.

It is obvious that the first measure just described to the extent that it is disadvantageous as considerable costs arise, since for each special Test a separate gauge movement must be used, too, this is cumbersome and clumsy; the second option is subject to restrictions insofar as than the number of available standing arcs on the measuring area surface is limited to four or five, also because there are no choices for suitable ones Filters are in place.

The object of the present invention is therefore to provide a device for performing a variety of chemical analyzes on liquid samples in which only a single device with a single read and output unit is used, which can be standardized to the respective tests in all necessary references is.

To solve this problem, the invention is based on the above named device and according to the invention consists in that, provided that the concentration of a specific constituent of a sample for each particular one Analysis is proportional to the intensity of radiant energy given by a given the sample guided frequency range, a radiation source and one on the radiation energy responsive converter unit is provided that receiving arrangements for storage a cuvette containing the sample to be analyzed is provided in the beam path and that the transducer unit comprises a radiation intensity received on the filter attractive display arrangement for displaying a function of the intensity, mounting units with a multitude of standardizing means and with a multitude of individual ones Filters each a special frequency band emitted by the radiation source isolate from radiant energy that every standardizing means includes reference parameters, which are calibrated so that the display arrangement can be used to directly display the Konzeno trations of the respective specific components according to the respective carried out Analysis is forced and that assignment arrangements are provided that the normalizing Means for performing any particular analysis with the filters and related to the display arrangement.

The present invention therefore relates to a direct read Colorimeter and includes an apparatus that enables the selection of a suitable scale in Concepts of the quantitative component allowed as well as simultaneously the selection of an appropriate filter; all of this happens in a simpler and more usable way Wise, so that there is no more room for errors.

The invention therefore forms a combined blood component and Prothrombin time analyzer that has a variety of removable and reusable Has circuit modules that are used to the analyzer or the invention Apparatus to the suitable length of the light source, the reagent empty compensation, the scale factor and to calibrate the calibration parameters, the analyzer according to the invention being set to predetermined Standards itself is related in such a way that all results achieved by a common digital display instrument, for example a counter, are normalized. The entire analyzer is in a compact console with a suitable Housing included and also includes a storage area for too examining test samples in the form of an incubator. There are also slots intended for both component concentration analysis and the analysis of the prothrombin time. The results of each analysis are recorded by the analyzer normalized so that a common digital counter can be used to calculate this Convert results into numerical output that can be displayed on a common display arrangement can be displayed and read; of course these results will be almost immediately after the analyzer initiated any given test displayed. It is therefore carried out at Measurements of any kind, for which the present invention is plugged in, a digital reading, wherein the photometrically obtained results are self-related, i.e. based on a standard are.

The present invention provides an improvement in this way of arrangements described in U.S. Patents 3,561,878 and 3,676,007.

Advantages of the apparatus according to the invention are the possibility of this as a colorimetric blood analyzer as well as a prothrombin time analyzer with extreme Use test accuracy that is unmatched to this day. Here is the inventive Analyzer saves costs and can be done by hand, for example, in doctors' offices as well as in laboratories and hospitals.

The analyzer according to the invention further comprises advantageous Way a multitude of interchangeable plug-in modules, whereby each module for a specific examination to be carried out in a special way is equipped; in this way it is possible to selectively use the analyzer according to the invention to adapt to a given group of such analyzes or tests The module even, which is interchangeable, programs the analyzer to the appropriate one and correct light wavelength, on the reagent blank offset , on the scale factor and on the calibration parameters so that a direct reading, preferably the desired blood component concentrations is possible, this reading is made in numerical or digital way0 Furthermore, the invention includes Analyzer selectively transmitting filters, each test function being selectively set can be to compensate for the changeable total energy transfer to achieve through this filter.

Each test function can be switched selectively and already in the console can be set to compensate for those test variables that occur between different amounts and aging of the diagnostic reagents and changes in the filter parameters as well as in terms of the spectral characteristics of center wavelength, bandwidth and the like.

Further refinements of the invention are the subject of the subclaims and laid down in these.

The structure and mode of operation of exemplary embodiments are described below the invention explained in more detail with reference to the figures. They show: Fig. 1 shows a perspective illustration of a first exemplary embodiment with regard to FIG Arrangement of the individual filters, each filter having a plurality of circuit means is coordinated in such a way that each examination to be carried out is based on a single one End display can be normalized, Fig. 2 shows schematically as a block diagram a normalizing Circuit, which is assigned to the embodiment of Figure 1, Fig. 3 shows the test console in a perspective illustration and in a view from above as a preferred embodiment of the invention, which standardized a plurality of Allowed to perform component concentration tests and prothrombin time tests, whereby only a single display arrangement is provided. FIG. 4 shows the test console of Figure 3 in a view from above with partially broken away parts, Figure 5A shows a perspective view of a test module designed as an insert of the present invention FIG. 5B shows the module of FIG. 5A in a view from behind with an explanation of the connections that lead to the console of the Figure 3 are produced0 Figure 5C shows the main test recess in which the Substances to be examined are inserted in a side view with a Arrangement of the thereby actuated switch Fig.5D shows the test recess of the figure 5C is a view from above, FIG. 5E is a representation of the test recess in FIG Figure 5C from below, FIG. 5F shows the arrangement of FIG. 5C of FIG the page rotated 900, Figure 5G is a cross-section along the line 5G-5G of Figure 5F, Figure 5H is a side view of the main recess shown in Figure 5C rotated by 180 ° C, Fig. 51 shows the photodetector in an enlarged detail view, which is assigned to the main test recess and the way in which it is attached to the structure the recess of Figures 5C to 5H is attached, while Fig. 5J in a Side view shows the formation of a typical microswitch used in the invention shows.

Fig. 6 shows a unified and comprehensive block diagram of the in Figures 3 and 4 of the console-containing circuit, Figure 7 shows in schematic Representation of an embodiment of a preamplifier for the photo element as well the circuits of a logarithmic converter circuit, Fig. 8 is a graph Representation of the output voltage functions and the time interval, which from there originates; this diagram is related to the logarithmic converter circuit of Figure 7, Figure 9 is a graph of the concentration line functions of the system shown in Figs. 6 and 7, Fig. J0 shows a circuit example the main control circuit of Figure 6, Fig. 11 shows in detail the circuit of the Prothrombin time circuit according to Figure 6, Fig. 12 shows the commercial version 13 shows a photocell preamplifier mentioned generally in FIG in detail the structure of the counting, driver, decoder and display circuits FIG. 6 and FIG. 14 show in detail the arrangement of the switching matrix and its assignment for the system equilibrium and for the individual test modules, like this in general is described in Figure 6, Figure 15 forms a graph of concentration above absorbance for stock concentration tests with negative slope characteristic, Fig. 16 shows in a larger representation the control device for the filter wheel actuation, which is also already mentioned in Figure 6, Figure 17 also shows shows in more detail the control circuit for the incubator block, FIG In a perspective view, the exemplary embodiment of a module to be introduced, whereby provision is made for the setting of appropriate functional parameters around variable in terms of energy and spectral transmission in the selective filters to compensate, also a compensation for changes in the properties induce diagnostic reagents and the like; Figure 19 shows in perspective Representation of a console accommodating the apparatus according to the invention with a Cover, this having access openings that allow adjustments on modules inserted in the apparatus, FIG. 20 finally shows a cross section along the line Y-Y of Figure 19.

The table below gives an idea of the many Examination options and tests that are carried out on liquid samples it is preferable in any case to use a radiation source, which offers a specific optimal wavelength for each examination.

The table below shows the numerous ingredients that can be measured, the optimal wavelength of the filler to be used and the references to a procedural approach. This table given below in the form of a list is given for the sake of completeness and as an indication and does not mean that the reference to a procedural procedure or the displayed wavelength for carrying out the examinations for the respective Constituents represent a delimiting factor, as another suitable investigation Procedure and assigned wavelengths can be exchanged or different Components as a whole can be recorded in terms of quality without being in any Way the uniqueness and value of the present invention is lost.

optimal wavelength in relation to a component in µ for the quantity process Determined procedure Serum glutamic acid-oxaloacetic acid transaminase ... 505 Frankel et al.

Serum glutamic acid-pyruvic acid ... 505 DO hemoglobin ... 540 Drabkin.

Urea nitrogen ... 540 Berthelot.

Cholesterol ... 640 Liebermann-Burc-hardt Glucose ... 540 Washko, Rice.

Bilirubin ... 540 Malloy, Evelyn.

Optimal wavelength in relation to a component in A for quantity method determined procedure alkaline phosphatase ... 660 Bodansky.

Acid Phosphatase * 660 DO.

Jaundice index ... 420 Meulengracht.

Thymol Turbidity Test ... 640 Kunkel, Hoagland Calcium ... 550 Connerty, Rigs.

Inorganic phosphorus ... 660 Fiske, Subba Row.

Protein ... 540 biuret.

Albumen ... 615 Rodkey.

Zinc Sulphate Turbidity Test ... 650 Kunkel.

Uric acid ... 660 Henry, Caraway.

Lipoids ... 640 Kunkel, Ehrens, Eisenmenger.

True, the present analyzer is for the concentration of constituents suitable for various body fluids, the embodiments described below of the invention, however, will be specifically referred to with respect to blood component concentration and the analysis of prothrombin time described, using conventional instruments Acceptable errors are considerably reduced.

The invention comprises a console or a slide-in carrier, which consists of consists of a variety of specific test circuits for components, each are designed as a replaceable module for selective insertion into a new one Console structure. These consoles are particularly useful in the practice of doctors and the like.

useful in laboratories because of their small size and hospitals.

Through selective electrical switching of maintenance parameters, which are specifically suited for a given test and in one given Test module: arranged for this purpose, can use a variety of blood test options be achieved. Since these modules are interchangeable in the console, the selection can be made any group test setup can be made simply by insert the selected test modules into the console. Each of these test modules norm i.e. represents the console and the only digital indicator associated with it on the appropriate factors for the intended colorimetric or prothrombin analysis with the help of selected circuit parameters in the modules available.

In the case of the colorimetric component analysis, the defines this suitable and specified test module the suitable wavelength, the reagent empty compensation (reagent blank offset), the scale factor and the calibration parameters to obtain a direct To display the concentration units. This allows the use of a single, numerical or digital reading arrangement for the entire group of selected ones Investigations or tests carried out by the console assembly as an analyzer can be.

By including reference parameters in the test control circuits the apparatus, i.e. the console, is provided with self-referencing means, in such a way that for each component analysis or test a reference measurement made and then the reference value electronically from the value of the unknown measurement is subtracted, giving an ingredient concentration value for each test derives.

In this way the unknown quantity is always related to a correlated reference value measured The apparatus includes one Prothrombin timer, which is connected to the usual control circuits in the apparatus in coordinated in such a way that the same numerical or digital display arrangement used for both this test and the ingredient concentration tests can be.

An XUsette shaft for liquid samples together with an incubator or incubator are also provided in the apparatus, which in this way a Self-contained laboratory-like test arrangement in a compact design for blood component concentration analysis and prothrombin analysis.

First of all, it is now more precisely to the arrangements of FIGS and FIG. 2, which shows a simplified embodiment of a blood component concentration analyzer represent, with some of the features of the combined control shaft and the filter wheel the embodiments already mentioned above are shown together with the common control circuits made with external parametric and from the control shaft controlled forced circuits work together.

The embodiment shown in Figs. 1 and 2 is therefore to be understood as an exemplary embodiment; a description at this point however, it also serves as a introductory explanation between the various exemplary embodiments and the preferred apparatus equipped with interchangeable test modules which will be discussed in more detail below.

As FIG. 1 shows, a common control shaft 100 is provided which a filter wheel 102 is mounted to perform one revolution with this, an increase function is also provided -Selector switch 104, a decimal position selector switch 106, and a K-factor selector switch 108. Each this selector switch 104, 106, 108 is keyed on the control shaft 100 in order to in this way, selectively external parameters in the common control and computing circuits 110 (as FIG. 12 shows) that are connected to the filters 102A of the filter wheel 102 are correlated or related; in this way become normative constraints or compulsory circuits exerted on these regulating and computing circuits 110 in FIG Way that the common digital display arrangement associated with these circuits llOE a readout and display for any given constituent concentration analysis which is selected by rotating the common control shaft 100.

The control and computation circuits 110 as shown in FIG. 2 include a converter circuit 110A from linear to logarithmic; a rise function circuit 110B, a "K" factor setting circuit 110C, a decimal position circuit 11OD and a digital display and output circuit 110E.

These circuits are so interconnected; that the converter circuit 110A of linear in logarithmic to the input of slope function circuit 110B connected; the output of the ramp function circuit 110B / to the input the "K" -factor setting circuit IIOC is connected, the output of which is in turn the input the decimal position circuit 11OD is supplied; the output of the decimal position circuit llOD is then connected to the input of the digital display and output circuit llOE.

The input 110Al of the converter circuit 110A from linear to logarithmic is via line 112 to output 114A a photoelectric Connected to detector 114, the latter receives light from an irradiated sample 118 in a test cuvette 12Q, which serves as an optical input circuit.

The irradiated sample 118 and the cuvette 120 assigned to it are irradiated from a standard light source 116 through a test filter 102A, which passes through corresponding positioning of the filter wheel 102 with respect to the light source 116 is selected.

If the filter wheel 102 is positioned in this way, then forcing the common control shaft 100 the selector switch to corresponding positions in in such a way that the appropriate external parameters are applied to the respectively assigned control circuits 11OD to 11OD are switched, whereby these circuits are normalized to the parameters for which the test is carried out.

The ramp function selector switch 104 is illustrated as that a rotating contact arm selectively fixed contacts 104A on a circuit disk 104 B or the like. Each of these contacts 104A schematically represents a circuit connection representing a suitable normalizing external reference parameter in the slope function circuit llOB switches. This circuit serves the purpose that algebraic signs of the slope function to determine that during a given test by the converter circuit 110A is generated from linear to logarithmic, as explained in more detail below will.

The decimal position selector switch 106 is also shown in the form a rotating contact arm, the selectively stationary one contacts 106A on a circuit board 106B or the like. touched; each of these contacts 106A represents schematically a circuit connection, which a suitable normalizing Reference parameter switches into the decimal position circuit 110D.

Likewise, the K-factor selector switch 108 is a rotating contact arm shown, the selectively fixed contacts 108A on a switching disk 108B or the like. recorded; each of these contacts 108A schematically represents a circuit connection serve suitable normalizing reference parameters in the K-factor setting circuit 110C switches; the latter acts in such a way that / is a standardized analog in digital conversion of the slope function generated in the logarithmic converter 110A is generated.

In other words, the K-factor circuit works as a gain or proportional parameters to the size of the resulting on circuit 110C Output signal to the appropriate area of the common digital output arrangement 110E to normalize. This output arrangement is shown in Figure 2- - so that it contains three digits in its output form, with the appropriate and correct decimal place takes place by forced point shift, which is carried out by the decimal position circuit 11 OD.

In this regard, normalizing input circuit connections 110BB1, 110C1 and 110D1 are provided, namely. each for the rise function circuit 1 lOB, the K-factor circuit 110C and the decimal position circuit 11.OD, -mit which the selector switches 104, 108 and 106 each by suitable ones, not shown Circuit means are connected.

The following is a more detailed look at the structure of the test console ~, i.e. entered into the design of the apparatus according to the invention.

This test console formed by the use of plug-in modules 122 is shown in Figures 3, 4, and 5A and 5B, along with one Individual module 122A, which is shown in FIGS. 5A and 5B as being taken from the console 122 is.

As FIG. 3 shows, the test modules 122A are in rows on the top of the console housing 124 is arranged. In the specific embodiment are sixteen test modules 122A each in rows of eight modules along with an incubator temperature control module 126 at the beginning of one of the module series 122A and a prothrombin time test module 128, located at the adjacent end of the other row of test modules 122A.

Each of the test modules, i.e. the plug-in modules that are used for certain Examinations and tests are provided, each is adjacent to a push-button switch 1223, with a plurality of these switches 122B in corresponding Rows of eight switches each are provided adjacent to the test modules 122A. In this way, each test module 122A includes a corresponding one, an examination introductory push-button switch 1223, which is located immediately adjacent to it is.

Adjacent to the row of modules arranged on the right hand side accordingly Figure 4, an incubator block 130 is provided, which has a plurality of cylindrical Has recesses or cavities 130A, for receiving with to be examined Sample-filled cuvettes.

These cuvettes have the shape as shown for example in FIG. 3 and are themselves provided with the reference number 120 and contain the samples to be examined 118, as has already been described above with reference to FIG.

The incubator block 130 consists of a block of anodized aluminum od. The like. And is in connection with the incubator temperature control module 126-, the has the ability to keep the test samples and the various cuvettes at one temperature of 37 ° C. As Figure 3 shows, this incubator block 130 has twelve Kü-etten warming cavities 13OA and an additional number of cavities 130B with a smaller diameter, in the embodiment 6 of these cavities 130B are shown, specifically for holding prothrombin test cuvettes to be heated, these latter are similar to those used for samples a constituent concentration studies, however, are of smaller diameter. At the top of the incubator block 130 a prothrombin test cavity 130C is arranged to form the seventeenth cavity and is suitable to accommodate prothrombin test cuvettes, as FIG. 4 shows, this is Make the cavity so that it is on one side for irradiation by an exciter lamp 132 is open for a prothrombin test; on the other side is the cavity in optical connection with a photocell detector 134 for the prothrombin test and with an associated optical filter 136 therefor. This component group is arranged so that the light from the exciter lamp 132 passes through the prosthombin test lumen 1-30C, the test cuvette and the sample it contains is running and then the prothrombin test filter 436 and gelanyt to the entrance of the prothrombin photocell detector 134, the together with the associated circuit, for their exact arrangement below will be discussed in more detail, is so designed that it can be detected by the prothrombin test sample running light responds.

As FIG. 4 shows, the uppermost end of the test console 122 is between the incubator temperature control module 126 and the sample thrombin time module 128 die digital output device 138 arranged, the one ahead already is similar to the digital display assembly 110C described in Figure 2.

At the lower end of the test console 122, as shown in FIGS. 3 and 4, the following test mechanism for the fraction concentration is arranged: the housing 124 of the console 122 is constructed to include a floor vent 140 as well an associated cooling fan 142, further is adjacent An exciter lamp 144 to the fan 142 for the proportion concentration investigations mounted in the housing. An ON-OFF circuit breaker 146 is for power supply the lamp 144 of the fan 142 and the circuitry within the console and is located in the upper area of the housing 124 adjacent to the plug-in modules.

Furthermore, an intermediate wall or a partition is in the housing 124 148 provided to the fan 142 and lamp 144 from the rest of the analyzer mechanism for the component concentrations to be kept separate in order to avoid any unsuitable heat or to exclude external light influences from the lamp 144 in a given test. The partition 148 therefore has a converging lens 150 in this context, to light from the lamp 144 through a selective test filter wheel 152, through a converging lens 154 and from there through a main test recess 156 for fraction concentration analysis to a main test photodetector 158.

The main test recess 156 is made of molded or injected plastic or other suitable material 156A and is contiguous with the arranged lower end of the incubator block 130, but does not form part of the same.

As Figure 4 shows, the main test recess 156 comprises an optical one Path or inlet 156B diametrically therethrough and into optical alignment with the Collecting lenses 150 and 154 and the Main photodetector 158 is located. In this way, the test filters on the, Filter wheel 152 passing light through optical inlet 156B, through the main test well 156 and passed to the main photodetector 158.

As Figure 3 shows, test cuvettes containing test samples 118 are made 120 placed one behind the other in this main test recess 156, the light impinging on the main photodetector 158 initially both through the cuvette 120 as well as through.

the sample 118 must run. This creates the absorption of selected wavelengths of this light through the sample the parameter from which then the particular concentration of the selected ingredient is calculated and applied the digital output device 138 can be displayed.

The lens 150 is therefore used to generate collected light, so that the transmission of scattered wavelengths of light through the interference filter in the filter wheel 152 is kept small. The lens 154 is a converging lens that converges or converges the monochromatic light that has passed through the filter wheel 152. summarizes, so that this runs only through part of the cuvette cross-section and generates a light pattern on the photocell which is fully in the active surface contained in the cell.

For automatic positioning of the suitable interference filter on the filter wheel 152 between the collective lens 150 and the collective lens 154 the filter wheel 152 is mounted on a rotatable shaft 152A driven by a servo motor 152B is rotated in order to position the filter wheel 152 in terms of index.

The work of this servo motor 152B and the resulting selective Positioning of the filter wheel 152 is with the power supply respectively of a special test module 122A in the console t22, as further below will be explained in more detail.

As can best be seen from FIGS. 5A and 5B, there is each of the modules 122A from a drawer in the form of a printed board 16t, i.e. a printed circuit board, with finger-like contacts 160A in a pertinent manner on the the lowest part of the printed board is arranged, furthermore is in the upper area same, a pair of brackets 164, a transparent display plate 162 with an inscription arranged, with a lamp 166 for displaying and making the inscription legible is arranged in a base 166B below the inscription plate 162. As an external disk-rete components are still a large number of items for investigation Selected resistors 168 and diodes 170 mounted to match the one on the back the printed circuit board 172 arranged on the plate 160 are electrically connected.

As FIG. 5B shows, each printed circuit board 160 is designed so that it can be slid into a conventional slide-in base 174 which is located in the housing 124 of the console 122 is mounted.

The test system arranged in the console 122 is now shown in FIG 200, which includes the component concentration analysis and the prothrombin time analysis performs.

As Figure 6 shows, the main photodetector 158 generates over a line 202 an input signal for a preamplifier circuit 204, which in turn is an output signal EK on output line 206. Ijierbei is a gain transfer switch 208 provided to selectively gain control resistors R1 and R2 in the Vorvcrs turn on intensifier circuit 204, so that the Preamplifier circuit 204 two specific amplification factors are imposed. These two gain factors are used by the system to generate a reagent blank reference ) during the various examinations to be carried out, as further is explained in more detail below. The gain regulators are steep two of the selected resistors 168 in Figure 5A, those in each of the selected Test modules i22A are included and with reference to the respective, at the executing Test values encountered are preselected.

First of all, and for a better understanding, it is considered sufficient, that the preamplifier circuit 204 has a linear transfer function and that input signal mediated by main photodetector 158 from one of the Main photodetector 158 received light intensity linearly proportional current in converts a proportional voltage E # on output line 206.

The output line 206 is then one with a first input 210A connected logarithmic converter circuit 210, this operates in such a way that it converts the voltage E # received from the preamplifier 204.

A digital pulse signal then appears on an output line 210B DPS which is supplied to the input terminal 212A of a main control circuit 212. This main control circuit 212 also has a second input connection 212B for a test signal to receive a prothrombin time test signal such as will be explained in more detail below.

The activation of the pulse signal DPS is forced by the application a start converter signal SCS1, which from a first output terminal 212C of the main control circuit 212 goes out and to a second input terminal 210C the logarithmic converter circuit 210 is applied. When the pulse interval C of the DPS signal is completed, the main control circuit 212 is controlled by a stop converter signal SCS2 reset, this signal originates from a second output terminal 210D of the logarithmic converter circuit 210 and is a third input terminal 212D is supplied to the main control circuit 212.

A variable resistor R3, which is the coefficient of the logarithmic Function of the logarithmic converter circuit 210 is controlled via a Input 210E in the converter circuit 210 switched on, as is also more precise is explained.

The main control circuit 212 has a second output terminal 212E on, which carries an UP / DOWN count signal UDS, which the input 214A a UP / DOWN counting circuit 214 is supplied; this latter far an exit 214B, from which a binary-coded decimal signal BCD emerges, which directly a first input 216A of a decoding driver circuit and a digital one Display network 216 is fed.

The driver circuit and display network 216 include a blanking signal input 216B, to which a blanking signal BS is applied, which originates from a blanking signal output 212F in main control circuit 212.

The UP / DOWN counting signal UDS, which is derived from the output 121E deriving from the main control circuit 212 is from an UP counter 218 controls an up count command to a first up count input 212G the main control circuit 212; furthermore the UP / DOWN Counting signal controlled by a countdown switch 220 which sends a countdown signal to a second count command input 212H of the main control circuit 212 supplies.

The remaining outer connections of the main control circuit 2.12 consist of a dial frequency command input 212J and a clock input 212K.

The count frequency command input 212J receives a count frequency signal FS from the output 222A of a reference oscillator 222, this oscillator has a Frequency control input 2223- which is connected to a control resistor RC for the frequency.

This control resistance RC is representative of another here of the selected test resistors 168 in Fig. 5A, into each. m of the test modules 122Aç The value of the rheostat RC is matched to the examination process to be carried out respectively test so that on this. Set the frequency signal FS to a certain value is forcibly discontinued when a predetermined one of the test modules 122A by one of the switches 122B is turned on.

The clock input 212A of the main control circuit 212-receives an in Frequency fixed clock or reference input signal CS, which comes from the output 224A of a frequency divider 224; this has an input 224B that is connected is connected to a frequency-fixed output 226A of a power supply section 226.

The input 226B of the supply part 226, i.e. the power supply unit of the Apparatus connected to an AC power line; so däß for example there is a 60 Hz signal at the output 226A with a fixed frequency.

This 60 Hz input signal is applied to input 224B of the frequency divider 2'2'4, which divides this frequency by a factor of 6, for example, so that / at the output 224A occurring clock signal, which the clock input 212K the main control circuit 212 is supplied with a clock signal having a frequency of 10 Hz is.

The power supply unit 226 finally includes outputs 226C and 226D, where the output 226C as a power supply for one or both of the exciter lamps 144 and / or 132 can serve, while output 226D can serve a number of output ports may include different circuit elements to a variety of required voltages the described system 200 available.

The filter wheel 152, the associated drive control shaft 152A and the Both positioning servomotors IS2B are controlled with the aid of a control circuit 228, which has an input 228A and a position-determining output 228B, as well as a fed back input 228C, this input is taken from the output 230A of a feedback generator 220, a feedback error signal PS indicative of the position fed. The feedback generator 220 is suitably of the position that the drive shaft 152A of the filter wheel 152 assumes, positively controlled, to act on this Way to generate the position error signal PS The input 228A for the position the filter wheel on control circuit 228 is selective with a control command resistor RS connected, which is formed here again by a resistor chosen by me 168 in Figure 5A, in each of the test modules 122A. In this way it is possible to have different Bringing the values of the resistor RS into the circuit, i.e. the position input 228A to forward such values to the control circuit that the servo motor 152B is caused by the control circuit 228 under forced control, the filter wheel -152 in a given rotational position, creating a special inference filter between the exciter lamp 144 and the main test recess 156 (as mentioned earlier described in connection with Figure 4) is brought. Used by selective actuation one of the switches 122B will energize any given test module 122A, i.e., its If the power supply is switched on, the filter wheel 152 is also automatically switched on the particular test to be performed related to the appropriate and correct one To offer the wavelength of the sample to be examined, specifically for the measurement of the particular constituent concentration desired in each case.

The incubator block 130 in the console 122 receives the required heat is supplied via an inlet 130C, the supplied heat emerges at an outlet 232B for the heat in the temperature control circuit 232. Incubator block 130 includes furthermore a heat probe connection 130D, which is connected to an input 232C for scanning the heat of the temperature control circuit 232 is connected.

Finally, there is a rule input 232A for the one to be developed Heat is provided on the control circuit 232, which is a changeable, heat controlling Resistor RH is assigned, this resistor is in the temperature control module built-in for the incubator block, the control module is shown in Figures 3 and 4 the reference numeral 126 and allows the selection of a desired frying temperature in the incubator block 130.

The photodetector 134 for the prothrombin time carries its output current the input 234A of a prothrombin timing circuit 234, the output terminal 234B of which directly to input 2123 for the prothrombin information of the main control circuit 212 is connected.

The prothrombin timing circuit 234 amplifies and differentiates the output current of prothrombin photodetector 136, this output current being two predictable Changes during the prothrombin test includes, as explained in more detail below will.

These changes lead to two prothrombin control signals PCS, the occur at output 234B and fed to input 121B of the main control circuit to ultimately control the UP / DOWN counting circuit, as in Connection with the mode of operation of Figure 6 will be described.

The entire system is completed by a selection switch matrix 236, which includes selector switches 222B. This matrix will be discussed in more detail below received, at the present time it is sufficient to understand that each of the switches 122B places a particular given module 122A in the circuit of the System 200 forcibly brings in, together with the selective associated with this module Resistors R1, R2, RC and RS, whose values are specific to the investigation process are selected and tailored to which module this module is intended for. on in this way, such a switching operation normalizes the system 200 to the particular one selected test.

As in connection with further details below ~ are labeled with Figure 7, / uer the auto-counter switch and the down-counter switch 220 positioned in the console 122 so that se by the introduction of a cuvette 120 (Figures 3 and 4) in the main test recess 156 can be controlled to a digital Count (upcount) for an open test recess condition and a digital one Generate count (downcount) for a full test recess condition; this the latter state involves the complete introduction of a sample to be examined 118 containing cuvette 120 into main test recess 156.

The following describes the preamplifier and the logic converter circuits received in more detail. The studies carried out in accordance with the present invention and tests are based on photometric absorption. The phys-ical- Laws of absorption photometry require that the light output or related Parameters can be converted into a logarithmic function to a parameter Inferring that directly on the concentration of the absorbent component is related.

Referring to the circuit shown in FIG in the following a preferred embodiment of such a logarithmic conversion and such a logarithmic converter circuit 210, along with a preferred one Embodiment of a preamplifier circuit 204 for the main photodetector 158 described.

The main photodetector 158 consists of a photo element as shown or a junction photocell that generates a current on input line 202 iJl generated that of the incident on the cell from the exciter lamp 144 (Figure 4> Light output is directly proportional.

This current is converted into a voltage in the preamplifier 204, the preamplifier includes an operational amplifier 104A for general reasons, one input of which is connected to the input line 202. The other entrance is provided with the reference symbol 102A and is connected to ground.

The gain control switch 208 is designed as a single-pole changeover switch, a normally closed contact (NC) said first gain variable resistor R1 connects the preamplifier output -206 to input 202 in a feedback loop.

The normally closed contact of the gain control switch 208 serves to selectively connect the second gain control resistor R2 from preamp output 206 to input 202 in a feedback loop, this Input, as mentioned, the cell current of the photo element is also fed.

The reason why these two amplifier variable resistors are provided are explained in more detail below. The gain equation for the preamp circuit reads (1) Ey i. R, where R is the selected value of the feedback resistors R1 and R2 is.

Once the voltage EiN is generated by the preamplifier 204, then it is from output 206 to input 210A of the logarithmic converter circuit 210 supplied. The input terminal 210A corresponds to the first input terminal VC1 of a voltage comparison circuit VC, which also has a second input terminal VC2 in connection with an operational amplifier VC3, and a bias connection VC4 for this operational amplifier, which is connected to a suitable, not shown Bias source is connected.

The output of the voltage comparison circuit VC consists of the output terminal 210D of the logarithmic converter circuit 210, at which output the digital Pulse signal DPS for transmission to the input terminal indicating the end of conversion 212D of main control circuit 212 appears.

Once the voltage function E # is generated by the preamplifier 204 then the logarithmic conversion of this function is carried out by an exponetXlle time function is generated from a changing over time Voltage EL is shown and the second input VC2 of the voltage comparison circuit VC is supplied; this tension, which changes over time, increases until it the input voltage E # is the same, whereupon at output 210D a signal is generated and fed to input 212D of the main control circuit, to indicate that the conversion has been completed. In this context it should be noted that the digital pulse signal DPS and its time interval T in the representation of Figure 6 'are shown in dashed lines, as they are the circuit path 21QB'- - 121A follow to illustrate the system of the present invention in schematic form To be able to show the block diagram functionally. Actually be the signal DPS and its time interval T, (as will be explained in more detail below) determined between the converter logic circuit 210 and the main control circuit 212 as Function of the time interval T, in each case between the beginning of the conversion and, signals SCS1 and SCS2 indicating the end of the conversion.

The logarithmic converter circuit 210 further comprises first and second operational amplifiers 210F and 210G, the first being a conventional analog integrator and the; second as an inverting buffer amplifier in a feedback configuration is connected to the integrating amplifier 210F.

Integrating amplifier 210F has one of its inputs connected to one end of a variable resistor R3, on which further has already been entered at the front with reference to FIG. 6, specifically for setting the Coefficients of the logarithmic conversion function, those of the logarithmic Converter circuit 110 is generated. The other end of the changeable resistor R3- is connected directly to the output 210G3 of the buffer amplifier 110G, where this amplifier in turn has first and second input terminals 210G1 and 210G2.

The integrating amplifier 210F still has one second input terminal 210F2 and an output 210F3, this output is direct with the end of an input resistance R4 connected. The other The end of this resistor R4 is connected to the first input terminal 210G1 of the buffer amplifier 210G connected.

Furthermore, the integrating amplifier 210F comprises an integrating one Capacitor Cl, which is directly between the output 210F3 and the first input 210E is laid.

The buffer amplifier 210B has a feedback resistor R5, the connected directly between its output 210G3 and its first input 210G1 is.

A first clamping network consists of a diode D1 and a clamping transistor Q1 with base Q1A, collector Q1B and emitter QlC, this clamping network at the output 210F3 of the integrating amplifier 210F is arranged. This network is like that connected that the diode Dl with its anode to the output terminal 210F3 of the integrating Amplifier and connected with its cathode to the collector Q1B of the transistor Q1 is. The emitter QIC of the transistor Q1 is connected to ground, while sen base Q1A directly to the input 210C of the logarithmic Converter circuit 210 is connected or forms this. This beginning of change -Input 210C is, as has been explained above with reference to FIG. 6, direct connected to the conversion start input 212C of the main control circuit 212. The base Q1A The transistor is still connected to a suitable bias voltage source, through a bias resistor R6, so that in this way the first Clamping is complete.

A second clamping circuit is provided, which consists of two diodes Dl and D3 consists, which with their respective anodes at a common circuit point are connected is the cathode of one diode D2 at the terminal input 210F4 of the integrating amplifier 210F. The other diode D3 has its cathode connected to ground, and the common, diode-connecting one The connection point is to a bias voltage source via a suitable bias resistor R7 placed.

The input 210E of the integrating amplifier 210F is via the cathode-anode path of a fourth clamping diode D4 fixed or biased, the anode of which is connected to ground.

The resistors and capacitors still remaining in FIG logarithmic converter circuit 210 are used for compensation and bias, how-this: is known per se, so.

that no more. Explanation of these elements is necessary.

Before proceeding to the mode of operation of the system 200 described in FIG and went into a more detailed description of the other elements and circuits- is, first of all, the mode of operation of the logarithmic converter circuit 210 and their connections to the design of system 200 are discussed below. Assuming that transistor Q1 is conductive, the converter logic circuit begins 210 then with the generation of its exponential function, - which leads to the the time varying voltage EL. at the second input terminal VC2 of the voltage comparison circuit VC leads .- when. a starting transducer signal SCS at the base Q1A of the clamp transistor Q1 is applied via the input connection 210C and the transistor Q1 blocks, as a result of which suspension of the normal, forward-biased conductive state the clamp diode D1 and the clamp transistor Q1 caused. The second clamping network, which consists of the resistor -R7 and the two diodes D2 and D3 acts in such that it prevents the value of the voltage EL from going below a voltage level to go from 0 volts.

The fourth clamping diode D4 limits the negative deviation at the input 210E of integrating amplifier 210F to the voltage drop across the diode junction and accelerates the recovery of the integrating amplifier 210F caused by the Removal of the start converter signal CS1 is reset, thereby making it possible it the clamping diode D1 and the clamping transistor Q1 against their normal.leitenden state and returns the voltage EL to an initial value which determines is forward conduction through this state.

The mathematical relationship between the parameter E # and the sici: voltage EL, which varies with time, is as follows: R5 where B = the buffer gain of amplifier 210G.

R4 The solution to equation (2) is: R3C1 EL (3) t = in B e0 where e0 means the initial value of the voltage EL at t = O.

A graphical representation of this exponential function is in Figure 8 is shown and explained below; For a given, on the main photodetector 158 incident light component is the output voltage E # of the preamplifier 204 a constant voltage at the first input VCl. Therefore, in the representation of the FIG. 8 as a horizontal line on the representing the dependence of EL over T (time) Coordinate cross shown.

It is a time T (the duration of the information signal DPS of the figure 6) required so that the voltage EL exponentially increases from its initial value eo builds up to the same amplitude as the differential voltage Eg. When both tensions same.

are, the cross point COP from the voltage comparison circuit VC detected, this circuit then at its output 210D the conversion stop signal SCS2 generated.

In this way the time interval T is defined and can be as follows can be expressed as follows: R3C1 E # (4) T = ln B e0 In expressing the logarithm to the base 10 this can be written as follows: R3C1 E # (5) T = 2.3026 log10 B e0 Avg Inserting the equation (1} leads to-: R3C1 R (6) T = 2.3026 log i # B e0 In this equation, R can be either R1 or R2, depending on the chosen one Position of gain switch 208 in preamplifier 204.

In the following, the overall concept of the system will be discussed in more detail.

Having set out the relationships just described, The overall concept of the system 200 of the present invention is best understood by development of Beer-Lambert's law, on which the photometric measurements, the occur in the invention are based.

This law can be expressed as follows: (7) P = P 10 abC, where 0 P is that transmitted by the unknown (i.e., cuvette 120 and sample 118) Light output is PO is a reference light output, i.e. the empty or reactive equivalent for the zero concentration of a constituent under test a is the absorption capacity or the absorption coefficient b is the length of the light path through which the test is carried out located medium C is the concentration of the unknowns.

Expressed as a logarithmic function, equation (7) is: p (7a) log P = log TR = -abC P where TR = # the relative permeability or transparency-0 rence expressed as a fraction.

Therefore: (7b) abC = -log TR = A, where A is the absorbance; It it also results: 1 # (7c) C = - log TR, from this it follows that TR = is: from P0 1 (7d) C = - (log P - log P0) or (8) C = log P0 - log P.

ab ab Hence it follows that the concentration C is an unknown in a test sample can be expressed as the difference between two logaritmic Functions.

In the system 200 the digital up counter 214 is used, to derive this constituent concentration value.

The count made by counter 214 is equal to frequency (f) of the oscillator input signal FS multiplied by the time interval over which the count is made.

Therefore, the time interval C of the signal DPS can be logarithmic Converter circuit 210 (i.e., the interval between the conversion start signal SCS1 and the conversion stop signal SCS2) are used directly in the counter 214, the Frequency f is treated as a scale factor.

Therefore, from equation (6): R3C1 R (9) count = 2.3026f log i # B e0 Since i # = K # P, where K # is the transfer function of the photo element 158, it follows that: R3C1 R (10) count = 2.3026f log K # P.

B e0 equation (8) suggests that a calibrated and related measurement (measurement related to a reference) can be made from two basic measurements. Once with a stranger and a corresponding one Light output P, which is transmitted by this and, secondly, with a reference and the one assigned to it, transmitted light power Po.

By doing this with the counting factor set by equation (10) links are used in determining any given constituent concentration made two measurements in a test sample which lead to two such counts.

For positive functions, i.e. for those that result from an increasing Extunction (adsorbence) are generated with increasing concentration of constituents, the first count is an up count (the count increases from zero), where the main test recess 15. Figures 3 and 4) is open.

In the present invention, an open test well 156 used, in contrast to generally known two-beam processes, because due to of the technical features of the present invention, the elimination of environment variables is carried out and only common optical elements need to be used, to a maximum rejection of these environment variables, which these other optical Realities are assigned to achieve.

The reference or open recess count 0oc can now be as follows To be defined.

R3C1 R1 (11) Coc = 2.3026f log K # Poc B e0 where P is the light output represents the main photodetector through the open recess 156 (Figures 3 and 4) 158 is supplied.

The second count performed to be subtracted from the first count to become; they derived from the unknown substance (Cuvette 120 and sample (118) of FIG. 3 in the light path 0 running through the test recess 156 This count is conceptually referred to as a closed recess count Ccc and defined as follows: R3C1 R2 (12) Ccc = 2.3026f log B e0 Da the open state of the main test recess 156 is used to simulate a reference (distilled Water or a standard blank reagent) the following equation defines the relationship of the gain controller resistors R1 and R2: (12a) R2Po = R1Poc zu this point in time will have a different definition of transparency given which is referred to as recess permeability and has two shapes namely, the permeability (Toc) of the open recess and the permeability Do the filled recess. The latter with the unknown substance in the light path reads as follows: Poc P (12b) Toc = and Tu =, Pin Pin where Pin is in the main test recess 156 penetrating light output is.

Therefore, the transmittance Tu of the closed recess is expressed as the ratio of the light power (P) incident on the photodetector 158 with respect to the light power (PX in the recess 156 The following combined definitions result: R3C1 R1 (13) Coc = 2.3026f log K # Pin Toc B eo R3C1 R2 (13a) Ccc = 2.3026f log K # Pin Tu B eo By getting Ccc of Coc using the Up / Down -Counter 214 (Figure 6), one derives the desired value Cv) of the component concentration in the counter as follows: Equation (14) can be rewritten as follows: R3C1 R1 Toc (15) C # = 2.3026f log u where all of the remaining terms have been canceled (eo, K #, and Pin), The use of the described double measurement (counting and common Light path) leads to the elimination of the usual photometric variables that normally have to be taken into account in such measurements. The parameter Pin includes such things as the exciter lamp 144 in FIG. 4, the intensity of which changes with the voltage, the position of the lamp and foreign matter on the enclosure of the lamp, also the accumulation of foreign bodies on the various optical elements, namely on the lenses 150 and 154, the filters in the detected 152 and on the main photodetector 158 (All shown in Figure 4. Also taken into account are the transfer functions (K #) of the photocell and the initial value of EL (eo). This latter indication is of particular interest since the circuit design of the logarithmic converter circuit 210 (Figure 7) can be simplified , a need for control and regulation of the initial value (eo) of the voltage EL is eliminated.

The remaining terms in equation (15), namely the oscillator frequency (f) and the circuit parameters R1, R2, R3, R4, R5 and C1 can be based on the now component technology achieved in this area within very tight tolerances werden0 All that remains is the permeability Toc of the open recess as a possibly poorly definable concept of a set in relation to the others Parameter. However, the following is a description of an exemplary embodiment of a preamplifier which compensates for this state and a better quantity term for more precise test results defined at the present time it suffices to state that the permeability Toc of the open recess is sufficient is controlled and controlled.

In FIG. 9 there is now the graphic representation of the constituent concentration CV shown as concentration line Cv, which has two defining parameters, namely the rise of the line and the reagent blank offset.

From equation (15) it can be seen that the slope of the line the oscillator frequency is changed in direct proportion to the oscillator frequency (f) is the frequency of the counting signal FS connected to input 212J of the Main control circuit 212 (Figair 6) is supplied; the change of one of the factors <R1 R2, Tcc) of the logarithm, causes a shift in the concentration line Cv from left to right in the graph of FIG. 9.

This shift in the component concentration line Cv is determined By the empty reagent, from which the quantity concept Q? 3 is deffnlert, namely from equation (12a): R1 (15a) Po = Poc, which is quite obviously a function R2 of the ratio of the gain control resistors R1, R2 in the preamplifier circuit 204 of Figs.

The following describes the general operation of the system according to FIG 6 described.

After just further forward the theoretical fundamentals and their references produced with regard to the design of the examination system according to the invention reference is now made again to FIG. 6 for the general purpose To explain the operation of the apparatus according to the invention. The explanation of this general working method is given before more detailed and detailed on construction and operation of such main control circuit 212, the servo motor control circuit 228, the temperature control circuit 232, to the oscillator circuit 222, to the Test switch matrix 236 and other related components of system 200 are discussed is to this way also a better understanding of the subsequent more precise Description of these components as they work in this way in a more general way Frames are provided.

Assume that amplifier 204 is the output voltage B, generated and the logarithmic converter circuit which changes over time. Generated voltage EL; It is also assumed that the counting control signal UDS is on the up / down counter 214 has been applied via its input 214A Counter 214 then counts at a count rate proportional to the frequency s; the FR equenz (f) is the frequency of the reference and oscillator signal FS, which is sent to the Input terminal 212J of main control circuit 212 is applied. Counter 214 operates as a so-called "BCD counter" (binary coded decimal); the resulting count is displayed in decimal form by the digital display arrangement 216 displayed. However, the display or output of any given count will blanked selectively via the blanking signal BS, i.e. covered or covered in terms of signals hidden. The blanking signal BS originates from one of the outputs 212F of the main control circuit 212 and is present at the input '216B of the display arrangement 216.

In this way, the main control circuit 212 generates the blanking signal BS and only allows the final test count results to be shown i.e. the resulting difference between the up and down counts and vice versa, that for a given concentration of constituents in the test be performed by system 200.

After this has been clarified, the following procedure results: The operation of a. given selected switch push button 122B switches the this respectively assigned test module 122A in the system 200 such that the Values of the standard resistance parameters R1, R2, Rc and RS in the circuit with the Preamplifier 204 (R1 and R2) can be shaded to adjust the gain and the so-called Set reagent blank ratio; activation continues at the reference oscillator 222 (RC) to set the correct counting frequency; one The servomotor control circuit 228 is still switched on (with regard to the Resistance RS) to find the position of the correct interference filter (on the wheel 152) in the optical path between the main excitation lamp 144 and the main test well 156 (see Figures 3 and 4) to be specified; in this way the system 200 turns on normalized the given test to be carried out. That is why the digital one too Output or display on the display arrangement 216 in the correct order of magnitude for the respective constituent concentration that the searched for unknown in the respective investigation procedure.

Assume now that a positive increase d "'. Ingredient Concentration Function Cv is present in Figure 9, then the count up switch 218 is activated when a KüvetTe 120 first introduced into the upper area of the main test recess 156 Although this is not shown in Figures 3 and 4, the count-up switch 218 may, however, comprise a microswitch that is operatively connected to the cuvette te 120 is actuated, for example by contacting; Of course the switch can also be operated manually.

After actuation of the upward number slide; it 218 gives the main control circuit an up counting command UDS to the counter 214. At this point lies in the case of the preamplifier 204, the gain control resistor. R1 for the open recess in the circuit, as mentioned earlier, via the normally closed Kon.taktbrücke the gain control switch 208, which due to the action of the log converter circuit 210 converts the voltage into a count in the Counter 214 is converted, this count is the time interval T of the digital Pulse signal DPS and the frequency (s) of the reference oscillator proportional.

The blocking signal BS remains switched on until the desired net result the count is reached at which time the main control circuit 212 of this blocking or blanking signal BS removes from the input 216B of the display arrangement and the Display of the actual constituent concentration in the display assembly 216 permitted.

As in the case of the other switches already mentioned (208 and 218) The countdown switch 220 also includes a microswitch located at the bottom of the main test recess 126 is arranged in such a way that it is fully lowered from the test recess 156 Cuvette 120 is detected and actuated.

The prothrombin test is based on the coagulation time of the in one Test cuvette containing sample, i.e. on the time between the addition of a citric acid (citrated) blood plasma sample in a previously mixed with a thrombokinase-calcium mixture filled test cuvette up to a point at which a predetermined blood coagulation state occurs.

As shown here in FIGS. 3, 4 and 5, the prothrombin tester control lamp is used 132 outgoing light beam through a filled with a thrombokinase-calcium mixture Cuvette.

Such a mixture is known per se, the cuvette is full in the prothrombin test recess 130C in the incubator block 130 of the console 122 is inserted. By activating the prothrombin time test module 128, as further below In more detail, the control lamp 132 has been turned on.

The light passes through the prothrombin test recess 130C and the cuvette with the sample contained in it passes through the prothrombin filter 136 from there (a green glass filter of 525 NM), then to the prothrombin photodetector 134 to attract attention and brighten it up.

The initial excitation of the prothrombin test module 128 causes it Main control circuit 212 to release a count control signal UDS at its output 212E and to input 21 4A of up / down counter 214. This signal is of the type that it forcibly places the counter 214 in a reset state.

Now becomes a P # ob a cited blood plasma that is in the test kit containing thrombokinase-calcium mixture is added, then passes through the light transparency or permeability in it an abrupt change. This abrupt change is caused by the prothrombin photodetector 136 is scanned and the resulting signal (the photovoltaic cell current) applied to input 234A of prothrombin timer circuit 234; this latter acts in such a way that it amplifies and differentiates the signal stream and an actuation signal from its output 234B to input 212B of main control circuit 212; this then sends a counting latch signal UDS from the main control circuit to its Output 212E delivered and fed to input 214A of up / down counter 214, to begin counting up.

The counting frequency is derived from the clock signal CS, which how already explained earlier, is 10 Hz. If the available grid frequency in As opposed to 60 Hz, if only 50 Hz, then frequency divider 224 simply becomes like this set to have a division factor of five instead of six.

The appearance of an output signal on the prothrombin = timing circuit 234 at the input 212B of the main control circuit 212 conducts the clock signal CS in a gated manner into up / down counter 214 via output 212E of the main control circuit 212 and input 214A of up / down counter 214.

If any form of blood clotting occurs in the test cuvette, then the increasing opacity (absorbance) from the prothrombin photodetector 136 and determined by the prothrombin timer circuit 234, such that a predetermined Rate of change of the absorption capacity a gate-like blocking of the clock signal CS by the main control circuit 212 caused the counter 214 to terminate as well of its counting process is initiated0 At this point in time, the in dssia Counter 214 remaining count, which is accordingly provided by the decoder driver circuit and display assembly 216 displays the prothrombin timing in seconds and tenths of a second.

It can therefore be seen that the present invention provides the means and provides equipment with the help of which an extremely large test area to all possible investigation is possible by using a single common Control circuit a large variety. of standardized result units, included therein Concentration units and time units from a single output arrangement or 0 Display device can be measured In this way one arrives at a considerable Cost savings, as well as the small number of circuit elements required and measuring devices have hitherto remained completely unmatched.

The following now turns to the main control circuit and the reference oscillator This is discussed in more detail in FIG. 10 referenced in which Figure the main control circuit 212 and the reference oscillator 222 of the investigation system 200 are shown; otherwise the same components are also used in these figures and elements that have already been mentioned above have the same reference numerals Mistake. In the block diagram of Figure 6 are all the elements of the main control circuit 212, with the exception of the portion associated with the prothroibine timer circuit 234 is. This part is further explained below in connection with a more detailed explanation of Figure 11 can be specified.

The reference oscillator 222 is of a conventional type and structure is therefore no longer explained, with the exception of the fact that the Frequency control resistor RC in the test modules 122A in the switching of the reference oscillator 122 is built in circuit, as also shown in Figure 10, to the output frequency (i.e., the frequency of the output signal FS) of the reference oscillator 222; the output signal appears at output 222A and is then applied to input 212J for the reference frequency of the main control circuit 212 is supplied.

In the main control circuit 212, the count-up switch 218 is in FIG presented in the way that it is normally open and normally closed Contacts, i.e. make and break contacts, the switch itself is single-pole designed as a changeover switch, each contact of this switch is in each case with the associated input 250A or 252A of a pair of cross-coupled NAND gates 250 and 252 connected.

The NAND gate 252 has an output 252B which has a Output control line 212E3 with a suitable reset connection, not shown of the up / down counter 214 of Figure 6 is connected. The control output line or the control output 212E3 is like that described generally with reference to FIG Main control circuit counter control output 212E.

The NAND gate 250 has an output terminal 250B, the represents a latch input to the other NAND gate 252.

The down counter switch 220 is also a single pole changeover switch with normally open and normally closed contacts, i.e. with Normally open and normally closed contacts are shown, each contact is connected to the inputs 254A and 256A of a pair of cross-coupled NAND gates 254 and 256 connected. The NAND gate 254 has an output terminal 254B, the serves as a locking input for the other NAND gate 256, this in turn has an output terminal 256B.

The main control circuit further includes first, second, third and fourth flip-flops FF1, FF2, FF3 and FF4, which are in the following way with the different Elements of the main control circuit 212 are connected: The first flip-flop FF1 is with its Voreins'tellanschlüß PR1 (preset) and its data connection D1 (data terminal3 connected to a positive bias source V; its setting connection ST1 (set terminal) is directly connected to the output 250B of the NAND gate 250, which is the count-up switch 218 is associated, connected; its reset terminal RST1 (reset terminal) is located directly at the control input 212D for the conversion stop (stop conversion control input),, the arrangement of the first and second outputs U1 and U is described below will be described in more detail below 0 The preset terminal PR2 of the second flip-flop FF2 is directly connected to a positive bias voltage source V, its data terminal D2 is directly at the output U3 of the third flip-flop F3; its adjustment port 5T2 is directly connected to the output 254B of NAND gate 254 on the countdown switch 220 connected; the -es reset terminal RST2 of the flip-flop is directly to the control input 212D for the converter stop, as well as the reset connection of the first flip-flop, on the arrangement and mode of operation of the two outputs U2 and U2 will be discussed in more detail below.

The preset terminal PR3 of the third flip-flop FF3 and its data terminal D3 are directly and commonly connected to a positive bias voltage source V; the setting connection ST3 of this flip-flop is connected to the output U2 of the second flip Flops FF2, the reset connection RST3 is directly connected to the output 250B of the NAND gate 250 connected to up switch 218. Furthermore there is only one exit U3 provided, the control output 212F for applying the Ausatsignals B8 to the Decoder driver stage and display assembly 216 of FIG.

The presetting connection PR4 of the fourth flip-flop wF4 is directly connected to the lock connector 250F -. NAND gate 250 connected to up switch 218; the data connection D4 is directly connected to the control input 212D for the converter stop; the setting connection ST4 of this flip-flop is directly connected to the output 254B of the NAND gate 254 connected, the reset terminal RST4 is directly connected to the positive bias voltage source V; the single output U4 will be discussed in more detail below.

The outputs of the flip-flops FF1, FF2 and FF4 are circuit-wise with first and second output NAND gates 258 and 260, with a negative output OR gate 262 and first and second inverters 264 and 266 connected as follows: The output U1 of the first flip-flop is directly connected to the first input 258A of the first output NAND gate 258 connected.

This NAND gate has a second input 258B, the direct is connected to the control input 121J in order to obtain from the output 222A of the reference oscillator 222 to receive the reference frequency signal FS. The output 258C of the first output NAND gate 258 is directly connected to the counter control output 212E1 and forms this output and in this way comprises the count up command element at the input 214A of the Up / Down counter 214. The output 212E1 represents a special part of the generally already described control output 212E for the counting control signal UDS of the Figure 6 shows the output UT of the first flip-flop FF1 is directly on. - the first Input 262A of the negative .Output 0DER gate 262 connected,, a second Input 262B of this OR gate is directly connected to the output U2 of the second flip-flop FF2 and connected to the setting terminal ST3 of the third flip-flop FF3. Of the Output 262C of negative output OR gate 262 - is direct - to the input 264A of the first inverter 264 connected, this has an output 264B, the is closed directly to the control output 212C for the start of conversion and this forms; from this output the start conversion signal SCS1 is fed to input 210C (i.e.

the base Q1A of the transistor Q1 in Figure 7) of the logarithmic converter circuit 210 of FIGS. 6 and 7.

The output U2 of the second flip-flop FF2 is directly connected to the first Input 260A of the second output NAND gate 260 connected. This latter has a second input 260B, which is directly connected to the control input 212J for the Reference frequency is connected, in common with the second input 258B the first output NAND gate 258; the output 260C of this NAND gate is direct connected to the control output 212E2 for downcounting and forms this. Of the Countdown output 212E2 is part of the general counter control output 212E of the figure 6, of which the general counter control signal UDS at the entrance 214A of the up / down counter 214 has arrived.

The interconnections of the outputs of the U2 and U3 of the second and third flip-flops FF2 and FF3 have each been described.

The output U4 of the fourth flip-flop FF4 is directly connected to the input 266A of the second inverter 266, which is the output 266B of this inverter designed so that it is connected to the decoder driver stage and / 3e display device of the FIG. 7 can be connected via a control output 216B1; this exit The blanking signal BS overflows or prevents the general blanking input 216B to the extent that a particular indication, such as a dash (-) in each digital row of numeric display assembly 216 appears on output. This indicates an incorrect state or one that is running out of the set range State, for example, an impermissibly high sample density, a burned out Excitation lamp, incorrect filter wheel position and the like.

The main test recess and structure of the Microswitches received more precisely.

With common reference to Figures 5C, 5D, 6E, 5F, 5G, SB, 51 and 5J will now show the structure of the main test recesses 156 and that of the Gain control switch 208, count up switch 218 and count down switch 220 positions taken are explained in more detail.

The main test recess 156 is defined by a rectangular one Covering. 156A with one top flange 156B swinging outward, one swinging outward opening lower base part 156C, from which lugs 156C1 down extend and through an axially extending, with a thread provided Fitting 156D extending below lower base 156C.

The threaded fitting 156D is formed so that, he be screwed into a suitable, not 'shown' socket of the console 122 can.

The area receiving the cuvette 120 is defined by a plurality Diagonally and symmetrically arranged guide rails 156E-within the. rectangular Envelope 1 56A.

These guide rails 156E extend from the top to the bottom Part inside the rectangular envelope 156A and go from the side walls the same and form positions arranged at the same distance from the center point.

The optical axis 156F of the main test recess 156 passes through a optical inlet port 156G and an optical outlet port 156H, which are used in the aforesaid Figures are shown as rectangular openings made in opposite side walls of the rectangular shell 156A are incorporated.

As can best be seen in Fig. 51, an infrared -Shut-off filter (to define border areas) 156I across the opening 156H placed over the front of the main test photodetector 158. According to a preferred Embodiment of the present invention includes this main photodetector 158 a blue-enhanced silicone photo element. The infrared cut filter 156I forms a spectral eorm filter, the sensitivity range of the wavelengths on which the photodetector 158 is forced during the various constituent concentration tests, of the present invention responds, squeezes, i.e. there is a peak response between about 400 - 600 nanometers.

Normal to optical axis 156G on opposite sides of FIG Rectangular shell 156A, a first switch bracket 208A is arranged, which is in the Is able to accommodate gain control microswitch 208; is opposite a double switch bracket 218A and 220A arranged to accommodate the upper resp. Count up switch 218 and the count down switch 220, respectively, are also designed as a microswitch.

The structure of microswitches 208, 218 and 220 is typical shown in Fig. 5J, it includes a roller actuator 218B which is external of the switch body 218B at one end of a cantilever spring or a cantilevered lever 218E is arranged; the lever 218E will be about another end 218F pivoted so that it touches a switch actuating immersion element 218G, when at the opposite end of lever 218E the switch actuating roller actuator 218B is pushed inward toward the main switch body 218D. the Structure of microswitch 218 is identical to the structure of microswitches 208 and 220. Accordingly, only the structure of the switch 218 is more precise has been described, the same parts of the further switches 220 and 208 as shown in FIG 5C are therefore given reference numerals which are the basic reference numerals correspond to the respective switches, but have the same end letters such as switch 218, which was described in more detail with reference to FIG. 5J.

As shown in Figure 5F, the sheath 156A has rectangular inlet openings 218C and 220C on 1 around the roller actuators 218B and 220B respectively in the To let inside the recess 156.

On the opposite side of the shell 156A is a corresponding one Opening 208.c for the inlet of the actuating roller 208B of the gain control microswitch 208 provided adjacent to the switch bracket 208A. The relative position of this Inlet ports 208C, 218C and 220C are determined by the position of the actuation rollers 208B, 218B and 220B shown in Figure 5C. As can be seen from FIG. 5C, is located the actuating roller 218B of the SC holder 218 is adjacent to the upper and / or open to the outside. Flange 156B of main test recess 156; the actuating role 208B of the gain control switch 208 is just below the optical aperture 156G and l'56H, whereas -the actuating roller 220B of the downcounting microswitch 120 on the opposite side of the shell 156A in a further down to the Actuating roller 208D is arranged lying position.

Accordingly, the insertion of the cuvette 120 into the upper one causes Part of the main test recess 156 that the cuvette from the guide rails 156E is detected within the recess 156 when it continues into the recess 156 intrudes, as mentioned earlier with reference to the functioning of the system 200 and its associated components has been described. The cuvette 120 progressively detects the up-counter actuator roller 218B as it is inserted 218, the operation roller 208B of the gain control switch 208 and the operation roller 220B of the down-counter switch 220, after which the cuvette 120 is fully in operative connection with the bottom of the main test recess 156 immediately above the lower one outwardly facing base part 156C occurs.

The purpose of the lugs 15XC1, extending down below the base part 156C, it can be seen that they have a suitable reference surface, not shown within the console 122 detect in such a way that the test recess fits or related to a suitable position, so that the optical Axis 156F of the recess 156 with the optical axis of the exciter lamp 144, the Collective lens 150 and the collective lens 154 in the console 122 is aligned.

This ensures that a proper incidence of light of the appropriate Wavelength on the main photodetector 158 through the infrared cut filter 1561 he follows.

The operation of the main control circuit will now be described in more detail explained, in conjunction with an explanation of Figs. 3, 4, 5C-J, 6, 7 and lO.

As above with reference to the figures already mentioned with the exception 10, the count up switch 218 consists of a microswitch, the one at the top of the Main test recess 156 is arranged and by inserting a test cuvette 120 with a sample to be examined 118 is activated while the cuvette l20 is still outside the light path, which emanates from the exciter lamp 144 through the main test recess 156 and onto the Main photodetector 158.

At the same time, as already explained above, the up-counting switch is activated 218 the reference count or the count with an open recess of the respective to be carried out Testing.

Before inserting the cuvette 120 to be examined into the main recess 156, the count up switch 218 is in its normally closed position Position and causes the latch NAND gate 250 to have it over r Output 250B via output control line 212E3 to counter 214 a reset condition imposes, the output line 212E3 is part of that already explained above Counter control output 212E.

Activation of the up-counter switch 218 now causes closure its normally open contact the resulting signal on output 250B of the latch NAND gate 250, the setting of the first flip-flop FF1 and in this way controls the first output NAND gate 258 through the first output Ul of the first flip-flop and its input 258A.

This control of the NAND gate 258 allows the reference oscillator frequency of the oscillator signal FS, which is applied to the control input 212J, to be transmitted to the counter 214 via the output 212E1 is the output 212E1 corresponds, as already mentioned, "to the output 258C of the first output NAND gate 258

The second output U1 of this flip-flop also has an effect at this time to the first input 262A of the negative output OR gate 262, resulting in energizing the output 262C thereof and the input 264A of the first inverter 264 leads, whereupon at the output 264B of the first inverter 264 the start conversion signal SCSl is generated, this output corresponds to 264B the control output terminal 212C of the main control circuit 212. It is therefore the startwandlungsnGnalScSl the base QlA of the transistor Ql in the bgarithmic converter circuit 210 (Fig. 7), whereupon this transistor is blocked and the Beginning of the time interval is set in motion, with a corresponding start-up counting up in counter 214.

At the same time, from output terminal 250B of the latch NAND gate 250 the reset terminal RST3 of the third flip-flop FF3 is de-energized, which is the following Setting the third flip-flop FF3, as described below, allows.

After the completion of the time interval T, the stop conversion signal becomes SCS2 from the comparison circuit VC (control output 210D of the logarithmic converter circuit) in Fig. 7 via the control input 212D to the reset terminal RSTl of the first flip-flop FF1 supplied. This causes the first flip-flop FF1 to be reset and terminated thus the upward cooling of the counter 214 (Fig. 6) by the output signal Ul is removed from the output gate 258A of the output NAND gate 258. After that, and after a brief propagation delay, the second output signal becomes Ul of the first flip-flop FF1 removed from the negative output OR gate 262, thereby ultimately the start conversion signal SCS1 from the output control terminal 212C is removed for the start conversion, with the result that the transistor Ql in the logarithmic converter circuit 210 of FIG. 7 again is turned on, resetting the logarithmic converter circuit 210 leads for a subsequent counting interval.

If the test cuvette 120 is now moved further into the main test recess 156 then the middle microswitch of this cuvette, which continues previously identified as the gain control switch 208 'of FIGS. 6 and 7 was activated and causes the necessary gain change in the preamplifier 204, as mentioned earlier. If the cuvette 120 then reaches the bottom of the Recess 156 and thus get the unknown substance into the light path like this everything has already been explained above, then the one arranged on the ground Microswitch, i.e. the countdown switch 220 operated to its normal close open contacts and energize the second latch NAND gate 254; a signal then appears at output 254B and at the same time at the setting input ST4 of the fourth flip-flop FF4 and at ~ the setting input ST2 of the second flip-flop FF2 The setting of the second flip-flop FF2 is effected by the output 254B of the NAND gate that the output signal U2 of the flip-flop at the input 260A of the second output NAND gate 260 is applied, whereupon this gate is switched off and a signal appears at its output 260C, the output 260C being the Control connection 2,12E2. For counting down as part of the general counter control connection 212E This signal is fed to the input 214A of the counter 214, which is now forced to count down from segner's previous count down by one Period of time to count until the second counting time interval T is completed This second Counting period T begins due to the application of the output U2 of the second flip-flop FF2 at the input terminal 262B of the negative output OR gate 26? Which, as described above, the control terminal 212C for the start conversion energized, whereby the start conversion signal SCSl the input 210C derlogarithmischen Converter circuit and thus the base QlA of the transistor Ql in FIG will.

When this second downward counting process is finished, then the comparison circuit VC3 outputs a stop conversion signal SCS2 at its output terminal 210D free, which is sent via the control input 212D to the reset connection RST2 of the second flip-flops FF2 is applied. This flip-flop is then reset and the downcounting enabling output signal U2 is from the input of the second .Ausgangs-NAND gate 260 removed, whereupon the counter 214 the further Sets down counting.

At the same time causes the reset of the second flip-flop FF2 via its output U2 and r ~: n setting terminal ST3 of the third flip-flop PF3 a setting of this third flip-flop. This leads to two kinds of processes. First of all, the output U3 prevents the second flip-flop from accessing its data input D2 act and secondly, the blanking signal BS by forced action of the output U3 is removed from the display command terminal 212F so that each type blanking acting on display device 216 as well is removed and the count is enabled, i.e.

it is made possible that for the constituent concentration in the unknown sample 118 representative net count can be displayed and ejected can.

After removal of the cuvette 120 from the main test recess 156 leads the resulting retraction of the up switch 218 and the down switch 220 in their normally closed Positions to defer of the flop flop FF3 via the output of the first locking NAND gate 250B and the reset terminal RST3, whereby the corresponding output U3 of this third Flip-flops is de-energized and the decoder-driver stage and the display device blanked again by the blanking signal at control output 212, i.e. switched to empty , this blanking signal runs on the input 216B of the display device 216, as Fig. 6 shows. At this time, the interlock output 252B is also reset The resulting signal is passed on via the counter reset output 212E3 and the counter 214 is then reset.

An additional feature of the invention is provided by the fourth flip-flops FF4 created. When the interlock output 254B, which is the countdown switch 220 is assigned 1 is set.

and the stop conversion signal SCS2 is on line 212D in its lower state, indicating that E # is one other than eo (see Fig. 6, 7 and 8), then the fourth flip-flop FF4 is activated by the output signal at the output 254B of the NAND gate 254 is reset by namely the setting terminal ST4 a signal is fed to this fourth flip-flop.

The fourth flip-flop FF4 was before the introduction of the cuvette 120 in the Main test recess 156 set (set) from the first interlock output 250B, this output 250B to the preset terminal PR4 of the fourth flip-flop FF4 acts.

The condition described above occurs when the unknown substance 118 in the test cuvette 120 is too tight to be measured. (the light level is located. below # limit as shown in Fig. 9) or if any faulty states present, such as burnout the lamp 144 or when the filter wheel 152 has assumed an inaccurate position.

As a result of the resetting of the fourth flip-flop FF4 appears on its output U4 a signal which the input 266A of the second inverter 266 is assigned; this results in an output control signal at output 256B, which fed to the input terminal 216B1 of the decoder driver and display device will. This particular input control port 216B1 was already connected earlier mentioned with Fig. 6 as general blanking input 216B. As a result of the 'excitement of the rule input 216B1, a special display, for example a dash in each digital position of the display device 216 to the operator to indicate that such an incorrect state has occurred in the test apparatus.

A numerical blanking is in the display device 216 automatically for this state, because the second flip flop FF2 by the signal level at the control input 212D remains reset for the stop command.

The following now turns to the measuring and switching circuit for prothrombin time measurement and its relationship to the main control circuit. There the system 200 shown in FIG. 6 includes a counter 214 and one from a decoder driver stage and a display device has existing output and display arrangement 216, it enables relatively few additional circuitry to be added to the parameters of the system necessary for the determination of the prothrombin time 200, drni't also the prothrombin time directly on the display assembly 216 by selective normalizing excitation of the counter -214 can be read and displayed.

The prothrombin test recess 130C, the exciter lamp 132, the filter 136 and der'Photodetektor 134 for the prothrombin test are already with reference to the rig. 13 and 14, they are part of the incubator block 130 in FIG the console 122 embedded. The additional circuits that are needed to investigate unknown samples with regard to the prothrombin time are now explained in connection with FIG. 11. As shown in Fig. 11, the prothrombin photodetector is 134 with the input 134C1 of a pre-amplifier stage 234C in the prothrombin time measuring circuit 234 connected. The preamplifier stage 234C includes a second input 234cm, the , a, is connected to ground, as well as an output 234C3, at which a voltage occurs, which is proportional to the light transmitted through the sample to be examined.

To complete this preamplifier stage 234C is a feedback resistor 234C4 provided.

The output 234C3 of this stage is through a filter resistor 234G and a capacitor 234F to the input terminal 234D1 of an operational amplifier 234D connected1 its second input terminal 234D2 is also connected to ground. The output 234D3 of the op amp is through a feedback resistor 234E and a capacitor 234H connected in parallel therewith with its one input 234D1 connected. Capacitor 234F and feedback resistor 234E form FIG Connection to the operational amplifier 234D creates a differentiating circuit. Resistor 234G at the input and capacitor 234H in parallel with the resistor 234E form a low-pass filter, which is necessary to filter out unwanted noise and to eliminate scatter influences in the permeability measurement of the unknown sample. The output 234D3 of the differentiating circuit is through an input resistor 234D4 with. connected to a first input 234K1 of a comparative amplifier 234K, its second input 234K2 one appropriately tapped Resistor 234L is connected to a reference voltage so that there is a related Potential. The output 234K3 of this comparative amplifier is via a Resistor 234M with the variable tap reference resistor 234L connected, together with the second input terminal 234K2 this Amplifier. Also, output 234K3 is comparative amplifier 234K connected to an inverting amplifier 234P, the output of which in turn has the Prothrombin cell circuit output 234B forms, which is already in connection above with Fig.

6 has been explained. As shown, output 2343 is directly on the input 212B for the prothrombin time control of the main control circuit 212 is connected.

The input terminal 212B for prothrombin time control of the main control circuit 212 is directly connected to the setting terminal ST5 of a flip-flop FF5, the furthermore via a data input D5, an output connection U5 and a reset connection RSTS, the latter is directly connected to the reset connection RST6 of a sixth Flip-flops FF6 connected.

This sixth flip-flop FF6 also has a data connection D6 connected to a suitable source of positive bias voltage, as well as via an adjustment connection ST6, which is connected directly to the output 214C for the counter control for up / down counter 214 is connected; one exit U6 is crossed connected to the data input D5 of the fifth flip-flop FF5.

In the control circuit 212 for the prothrombin time investigation also arranged a sampling switch 270 which is a normally open single pole Switch includes (with a normally open contact) and the one at the bottom of the prothrombin test recess 130C 3 and 4 'in essentially the same manner Down counting switch 220 is arranged, which has already been explained with reference to FIG. 5C has been. One side of the sampling switch 270 is connected to ground, while the other contact side is connected to a circuit reference point 270A, A bias resistor 270B is also connected at this point, which is also connected to it the other end is connected to a suitable voltage source of positive potential. from circuit reference point 270A is directly connected to input 272A a third inverter 272 of the main control circuit 212, the output of which is 272B directly together with the two reset connections RST5 and RST6 of the fifth and sixth Flip-flops connected.

The circuit reference point 270A is still directly connected "to" a first input terminal 274A of a second negative output OR gate 274 and to a first input terminal 278A of a third negative output OR gate 278. The second negative output OR gate 274 has a second input terminal 274B; which is directly connected to the counter down output 212E3 on the up counter 218 is connected to the main control circuit 212 associated NAND gate. Of the Output 274C of the second negative output OR gate 274 is connected directly to the input of a fourth inverter 276, the output of which in turn is direct is connected to the counter control output 212E4, which is part of the general: As in connection with Fig. 6th The third negative output OR gate 278 has a second input 278B on ,, which is directly connected to the output 212F for the blanking signal on third flip-flop FF3, as above already in connection with Fig. 10 described; furthermore, the output 278C of this OR gate 278 is direct connected to a fifth inverter 280, whose output 212F1 in turn for regulation of the output signal and part of the general control output 212F for the Represents the blanking signal, as already described above in connection with FIG. 6.

The output 224A of the frequency divider 224 (as mentioned earlier with Described with reference to Figure 6, the input 224B of this frequency divider is direct connected to a 60 Hz mains voltage) is connected to the clock input 212K, which represents a first input 282A of a third output NAND gate 282, this NAND gate has a second input 282B which is directly connected to the output U5 of the fifth flip-flop FF5 is connected; the output is 282C of the NhND gate directly to the first input 284A of a fourth negative output OR gate 284 connected.

This fourth negative OR gate 284 has a second Input 284B, which is connected directly to output 212E1 of the counter control at the first output of NAND gate 258 is connected, the output 284C of this OR gate provides an output terminal 212E5 for the counter control and thus forms a part of the general counter control output 212E of the main control circuit 212, as further already described with reference to FIG.

The counter control output 212E5 is directly connected to the input 214A of the Up-down counter 214 connected. This counter 214 has a control output 214C, which in turn is connected to the setting terminal ST6 of the sixth flip-flop FF6 is connected. The reason for this connection is to be seen in that a delay is introduced before the prothrombin time is measured, namely, to eliminate disturbances and fluctuations in the sample caused by the addition of the plasma. It has been found that there is a delay of 4 seconds is sufficient for the. Disruptions and fluctuations enough time to give to calm down. The delay is indicated by the corresponding in state d This delay is brought about by appropriate / state-of-the-art means The following is more detailed on the operation of the prothrombin time circuit received, received, reference being made to FIGS. 3, 4, 6, 10 and 11. The through that located in a suitable cuvette mix 118 in a suitable cuvette 120 The light passed through the thrombokinase-plasma mixture falls after the cuvette 120 into the test recess 130C of the -.... on .

Incubator block 130 is inserted, the prothrombin photodetector 134 and generates a current at the input 234C1 of the preamplifier stage 234C; these the latter produces one. Voltage at its output 234C3 which is proportional to the is through the mixture .118 transmitted light component. This tension is determined by the differentiating circuit consisting of amplifier 234D, resistor 234E and capacitor 234F is differentiated.

As previously described, resistor 234G and capacitor form 234H has a low-pass filter to eliminate noise.

When the transmitted light is due to the addition of plasma or the clotting of the thrombokinase-plasma mixture decreases, then the voltage increases at output 234D3 of the differentiating circuit in a manner that is proportional is the timely change in the light transmitted through the mixture 118.

At a threshold value that is determined by the reference voltage at the second input 234K2 of the comparative amplifier 234K - being this reference voltage is set by the variable resistor 234L - then sends the comparative Amplifier 234K sends a setting command to the fifth flip-flop FF5 via the inverter 234P and via the prothrombin time control input 212B and the setting connection ST5 this fifth flip-flop FF5. In the comparative circuit the generates further Resistor 234M already described above has a threshold hysteresis function that is necessary is to avoid any noise appearing at the first input 234K1 of the comparative Amplifier 234K has to be rejected.

The detector switch 270 for the prothrombin cuvette is in the bottom of the Prothrombin recess 130C stored and is when inserting the cuvette 120, which the Thrombokinase calcium mixture 118 contains activated in the recess 130C. before The fifth and sixth flip-flops FF5 and FF6 become over theirs to this slot common reset terminal connection to the output 272B of the third inverter 272 held in a reset state. After insertion, it is put back State made ineffective by closing the sampling switch 270 and the second negative O5ER gate 274 takes effect and causes the fourth inverter 276 on to generate ineffective signal at output 212E4 as a counter reset command, whereby the counter 214 remains at zero in any di-digital position. Furthermore the third negative output OR gate 278 is enabled in such a way that that it is the removal of the pending at the output 212F1 for the display control Blanking signal caused by the fifth inverter 280. That is why it is on the display arrangement 216 no blank display or blanking signal available. The following events now occur in the following time sequence: First, 'the resulting sudden change in light transmission properties then, if the plasma of the thrombokinase-calcium mixture to be examined is in the test cuvette 120 is added, a setting command at output 234B of the prothrombin timer circuit and accordingly at the input 212B of the prothrombin control of the main control circuit 212 - the sudden change in the permeability of the sample becomes a matter of course, h detected by the prothrombin photodetector 134. Through these processes, the fifth flip-flop FF5 set or set at its setting terminal STS, there the sixth flip-flop FF6 remains reset and its output U6 (and that of this, output to the data terminal 25 of the fifth flip-flop FF5 transmitted signal) remains high This enables the third output NAND gate 282 to reach 10Hz Clock frequency gate moderately via its output terminal 282C to the first input 284A of the fourth negative output OR gate 284 to be transmitted causing counting pulses The counter control is fed to the input 214A of the counter control via the output 212E5 of the counter control will.

All of the counting units of the counter 214 and the fifth and sixth Flip-Flop FF5. And FF6 are automatically activated when the prothrombin test cuvette is removed 120 is reset from the test recess 130C in that the cuvette presses the sampling switch 270 deactivates the second and third negative due to its opening Output oDER gates 274 and 278 ineffective and the third and fourth inverters 276 and 280 causes the control outputs 212E4 and 212F1 of the main control circuit 212 generate reset and blanking pulses.

The following is a commercial implementation of the invention Apparatus Detailed Referring to Figure 12, reference is made to the preamplifier stage 204, as already explained above, and to the logarithmic converter circuit the Fig. 17 discussed in more detail. In the embodiment of FIG. 12, that is according to The operational amplifier 204A shown in the exemplary embodiment of FIG. 7 is shown as that it has a normalizing stage 204A1 and a gain transfer stage 204A2 includes. The normalizing stage 2Q4A1 includes a normalizing feedback resistor PN, which is switched from output 206A of normalizing stage 204A1 back to input 202 which, as mentioned earlier, is also connected to the main photodetector 158 is.

The output 206A of the normalizing stage 204Al serves as an intermediate output terminal in the embodiment of FIG. 12 and is via an input resistor RW connected to a first input terminal 202B of the gain transfer stage 204A2, this stage has an output 206 which is similar to that already with reference to FIG said output 206 corresponds, and a second input terminal 202C, the the connection of the gain control switch 208 (middle microswitch), such as already explained earlier in FIG. 7, corresponds. The gain transfer stage 204A2 can also be viewed as a gain control stage in this sense.

Between the output 206 of the preamplifier stage and this second Input terminal 202C of gain control stage 204A2 is still a fixed feedback resistor RX switched.

The gain control switch 208 is also shown as that it includes a normally open contact terminal, of which a detached Resistor R2 (off set resistor) goes out and as described above with ground connected is.

The microswitch 208 as a gain control switch further comprises a normally closed contact terminal, of which one starting with a resistor R1A for setting the recess correlation with ground is connected, such a resistance is already described above as resistance Rl and been designated. Accordingly, the gain is selectively changed, when the gain control switch 208 is from its normally closed position is shifted to its normally open position and vice versa, which also the output voltage E # is modified accordingly. The working of the preferred Embodiment 204 of this preamplifier circuit of FIG. 12 now becomes described, but initially again on the earlier in connection the equations mentioned with the circuit of FIG. 12 are resorted to: From equation 15a and 12b one obtains PO R1 POC = and Poc Toc = P in Equation 15 results Cv = 2.3026 f R3C1 log R1 Toc B R2 Tu Ein often in practical applications Occurring problem also'der present invention is to see that the The ratio of PO to Poc differs from instrument to instrument due to their differences Can change the optics, for example in the lamp position, the focal lengths the lenses, the.

Beam geometry and the photocell transmission function.

In other words, it should be noted that Toc for different instruments is not the same or deals with different uses and replacing a Can change the lamp slightly. A correction for this change can be made are by changing the ratio Rl, as found in equation 15a. -R2 However, all test modules 122A must have some instrument panel 122 interchangeable and interchangeable with each other. It is therefore not possible to introduce a correction to these modules, but this correction must be made to the Instrument console 122 can be made. A solution to this problem wins by passing the photocell preamplifier 204 of FIG. 7 through the preamplifier circuit 204 'of FIG. 12 is replaced.

The normalizing stage 204A1 normalizes Eilv for the different ones used Filter. Since each filter transmits changing light output, it compensates for it Stage these changes in such a way that E # is caused to "open test recess" to remain at an approximately constant value for each filter. man ,.. -This is achieved in that the gain of the normalizing stage 204A1 with the normalizing resistance RN changed. This resistance is on the test modules 122A, and has a specific one for each filter on the filter wheel 152 Value on.

Gain control stage 204A1 has two gains, one for the "open recess" and one for the "filled recess", with the gain control X is performed by the gain control switch (middle microswitch) 208. For the open recess, the resistance RAl is for the setting .the cavity correlation adjustment resistor in the console 122 is located, not on the test modules 122 and set so that it is the "open "Recess" equates to a distilled water void. This is done by that you have about a standard resistor for the offset resistor R2 is used, the value of which depends on the gain for the filled test recess.

is true. The setting of the gain for the open test recess through R1A is performed to make the same count for the open test well to initiate the same as the count made with distilled water (standard reference) in the test recess is obtained by using the rheostat R2 for the gain the filled test recess is used. This is the way to effect the output and display of 'NULL.

Now the expansion of equations 5 can be modified by 15, to reflect the above parameters m: If ON. = the reinforcement of the first stage is (through RN) Ag = the reinforcement of the second stage with an open recess (through RIA) and AF = the reinforcement of the second stage when the recess is filled (by R2), then equation 11 can be modified: Coc = 2.3026 f R3C1 log ANAOK # Poc (17> B eO Equation 12 can be modified as follows: Ccc = 2.3026 f R3C1 log ANAFK # P (18) B eo If rewritten in the terms of the equation 12b one obtains modified equations 12 and 13: R3C1 ANAOK # PinToc Coc = 2.3026 f log (19) B eo o Ccc = 2.3026 f R3C1 log ANAOKPin u B eO equation 15 in modified Form then becomes R3C1 ## Ao Toc Cv = 2.3026 f log - (20) B ## AF Tu It is in this Context to indicate that, as can be seen, the gain AN of the first stage does not affect the result. The purpose of this stage is merely, the operation of the circuits of the present invention to its linear To bring areas and to hold them there. About a reagent blanking It is only to enable a reagent blank offset necessary to change the gain AF to the compensation or offset resistor R2. Therefore this resistance is localized on the test modules 122A. Like an equation 15, the effect of this change is a shift in the concentration line Cv of Fig. 9 to the left or right.

In the following the counter, the counter driver stage and the decoder and the display arrangement discussed in more detail. The counting process, the one ahead with has been described with the general reference numeral on a counter 214 actually performed by three binary coded decimal up / down counters (BCD) 214 X, 214Y and 214Z, which are connected together in series. These counters are provided with a common reset terminal 300, which is to the output terminal 212E4 for the reset control of FIG. the Counters are discussed in greater detail in connection with FIG. The common connection 300 connects the reset inputs 302X, 302 ?, 302Z 'of the respective up and down counters 214X, 214? and 214Z with each other.

The meters are still connected to a common connection 304 Ineffectiveness provided, which are jointly connected to the data load connections 306X, 306Y and 306Z the counter is connected, aa the. Data load connections of the Counters should not be used This common, ineffective connection 304 is so inoperative when connected to a suitable bias source made that data load characteristics of the counters are prevented.

The first counter 214X includes an up count input CUX and one Down counting input CDX, which is part of the counter input already described in general 214A ind. The up-counting input CUX is direct, with the output control connection 212E5 11 connected. The countdown terminal CDX is direct to the countdown control output 212E2 of FIG. 10, thereby making use of the ingredient concentration testing to get excited.

The second counter 214Y has an up-counting input CU? and a down count input CDY, which is connected to the corresponding outputs of the first Counters 214X are connected; the third counter 214Z also has an up-counting input CUZ and a down count input CDZ, which are connected to the corresponding. Outputs of the second counter 214? are connected in the usual series circuit. For example the operation of the counters of the present invention is such that these respectively go through a decade.

Counters 214X, 214Y and 214Z are connected via output lines 214B connected to inputs 216A of dec. or driver circuits 216U, 216V and 216W. These decoder driver circuits have a variety of current limiting features Resistors 308X, 308Y, 308Z each with the input terminals of digital Display modules 216X, 216Y and 216Z connected. These digital display modules include seven display arrangements in the manner of light-emitting diodes, with characters in bar or grid-like type are shown.

The decoder and driver circuits 216U, 216V and 216W are respectively with the blanking signal input 216B of the decoder driver circuit and display circuit 216 connected via inverting amplifiers 310U, 310V and 310W, -whose inputs are applied to the input terminal 216B and their outputs each to the blanking terminals 312U, 312V and 312W of the decoder driver circuits are connected.

In this context and at this point it should be pointed out that that the counter 214X the least significant digit, the counter 214Y the middle Digit and the counter 214Z counts the most important digit. Accordingly, they are Decoder driver circuits 216U, 216V and 216W connected together in such a way that as is customary according to the technology.

As a result, the display arrangement 2X6X shows the least important Digit with or without the creation of a 'decimal point, the' display arrangement 216? represents the display of the middle digit, and the display arrangement 216Z represents the display of the most important digit is available.

The least important digit display 216X includes a decimal point input DX, which is connected via a gate 314, this gate in known Way is enabled using a decimal command diode 170A, like will be explained further below with reference to FIG. 14. At this time it is sufficient it should be noted that diode 170A is selective in a given test module 122A is located so that the proper dial reading is thereby performed is that the appearance of the decimal point between the least important and the center digit display is selectively commanded.

When used for prothrombin time studies, only the up counter input CUX from the control output 212E5 of the main control circuit 212 energized as forced by prothrombin timer circuit 234. These Interconnections between prothrombin timing circuit 234 and the main control circuit have already been explained with reference to FIG.

Regarding the counter and display operation for an ingredient concentration test during the first or up counting, the clock frequency is gated from the Main control circuit 212 via its control output connection 212E5 (FIG. 11) to the up-counting connection CUX, the least significant.

Digital counter 214X and the up count inputs of counter 214Y and 214Z.

If the second counting process is initiated as instructed during the test cycle is, as already described above, this counting process takes place in the Way that it is performed inversely subtracting from the first count, by adding the clock frequency to the downcount input CDX's for the least important digit responsible counter 214X from the control output 212E2 of the main control circuit 212 of Fig. 10 sets.

The resulting number in counters 214X - 214Z is then the desired one Concentration value, as above in connection with the general description of the system in Fig. 6 is explained. This count is then decoded into a seven-digit number or seven-bar display, as is common today, so digits can be read decoding is performed by the decoder driver circuits 216U - 216W, as mentioned earlier. These decoder driver circuits have blanking features which are known per se; a general blanking is achieved by means of a common line 216B leading to inverting amplifiers 310U through 310 W carries and applies the blanking signals to terminals 312U-312 W like this is known in this field. This common connection through the blanking input port 216B scans the entire display until the second count is completed, whichever Time the blanking signal BS is then removed and the concentration value is displayed will.

To in connection with the selected clock or reference frequency to provide the correct scale factor to carry out the count, will be the presence or absence of a decimal point between the least important digit and the middle digit, as shown on the display arrangements 216X and 216Y, performed by a gate 314 which, as etn already explained to the input DX for the decimal point of the display device 216X for affects the least important Digi.t. The actual implementation of the decimal function is created by a simple logic circuit known in the art by one of the presence or absence of a decimal point command diode 170A logic instruction derived from test modules 122A (FIG. 14) is used.

In the following, the test function selection and the switch matrix are discussed detailed for the test modules; these circuit components that selectively Variables to be switched for normalizing the entire test system 200 to the each special test to be carried out are already referenced 6, 7, 10 and 11 and 13 have been described. It is already mentioned there that the various predetermined positions of the filter wheel 152 are controlled by entering a resistance RS of a preselected value, the reference frequency of the oscillator 222 is also controlled by the selective input of a resistor RC with a specific value in this 'oscillator', also the reagent empty compensation is controlled by the selective input of a resistor R2 in the photocell preamplifiers 204 adjacent to gain control switch 208; normalization continues the entire system to compensate for variations in filter permeability, carried out by selectively inserting a resistor RN of known value into the Photocell preamplifier 204, more precisely in its n6rmie'ren, de stage 204Al turns on.

Referring now to Fig. 14, the specific interaction of a test module 122A with the switch matrix 236 showing the test selection switches 122B includes, described.

The test module 122A shown in Figure 14 includes the resistors RS, RC, RN and R2, one end of which is each at an individual, usually open contact connection of a single single pole multiple switch connected is, this multiple switch represents the respective test selection switch for this Module.

Continue to be open with another individual, normally Contact connection of the test selection switch 122B via a common connection line G the other side of resistor R2 as well as either side of two Diodes 170A and 170B connected, each providing the decimal point logic and the rise sign logic of the test system 200 control.

The last connection with an individual, normally open Contact connection of the test select switch 122B is then made for one Side of the indicator light 166 belonging to the module.

The other sides of the resistors'RS, RC, RN and the other sides of the first and second diodes 170A and 170B and the other terminal side of the indicator lamp 166 are each all through individually assigned lines with very general Connection lines of the console 122 are connected, also for the other modules apply, there are still common external circuit connections available, through which the resistors RS, RC, RN, the decimal point control diode 170A and the Rise sign control diode 170B and indicator lamp 166 each with the on they are connected to related circuits, as explained earlier in the Figures 6, 7, 10, 11, 12 and 13.

The opposite side of the test selection switch facing away from each other 122B for the particular module, as shown in Fig.

14 is shown with its individual poles to a plurality parallel common lines laid out to the other test select switches 122B in the console 122 in an identical manner, -w: Le this for the particular Test module 122A of FIG. 4 is shown. This is where the common connection point is located G opposite pole in the test selection switch 122 at a ground terminal GR for resistor R2, diode 170A and diode 170B.

Based on the arrangement just described and selected, the necessary normalizing components for each given test in their respectively assigned circuits from their position on the test module 12 with the help of the test selection switch 122B, and for each such test module 122A a test selection switch 122B is provided which is composed of a six-way push-button switch The only function that is not n6c'h further on exists in a single-pole version described is that of the rise sign command diode 170B. This is explained below now explained in connection with Fig. 15, which relates to the condition at which a negative sign of increase is the characteristic of the transfer function of a given concentration test.

To explain the negative rise of such a function let pointed out that in some photometric measurements there are conditions in which the concentration is reversed with the impermeability or extinction changes. To carry out such a measurement, it is only necessary to set the order the counting processes as in the inventive concept described so far, to reverse.

For further explanation, reference is made to the exemplary embodiment shown in FIG referenced, with the test recess 156 open, the first counting process from zero is made down. This gives a first counted number Coc't that in effect negative is. The second count will be Ccc with the unknown substance in the light path made up and in effect adds to the initial count -COC. The resulting concentration line Cv = -Coc + Cc.c is shown in FIG.

Since there is a counting limit for a given frequency, namely due to the limited range of T (all parameters must be used in the practical Application are kept within the linear working area of the amplifiers), the overall gain ANAF must not allow the count to exceed limit C for to exceed a maximum light state (for example, the open recess can be regarded as the maximum light state). Because Ao for a given instrument is fixed, AN must be reduced sufficiently to guarantee the above conditions.

The realization of this negative increase therefore only requires that the outputs 258C and 260C of the first and second output tAND gates of the Main control circuit 212 of Fig.

10 can be reversed. This is done through a simple logic circuit performed, which is controlled by the rise sign diode 170B included in this Context is known and which are therefore not discussed in more detail got to. The logic control governing clock reversal is derived from the test modules.

The following is a description of the positioning and servo circuits for the filters were discussed in more detail. Each test is performed at an appropriate wavelength of light carried out. How to select the correct filter for each component concentration test is carried out by the control circuit shown in FIG. This circuit is basically known and therefore does not need to be explained in more detail, except of course for the unique characteristics inherent in it Relation to the test system 200 to be emphasized in more detail. The control arrangement of Fig. 16 positions the filter wheel 152 so that the voltage at input 228C approximates is the same as that at input 228A of operational amplifier 228E.

The voltage at input 22 8A is determined by the filter selection resistor RS located on test module 122A was changed.

These resistance values are selected so that at the input.

228A a voltage is generated which is equal to the voltage at the input 228C with the correct filter in place on filter wheel 152. Furthermore, a damping resistor 228D 'is provided so that when the Resistor RS is removed from the circuit (for example if all test select switches 122B are not depressed, the control circuit does not go into an open loop. In addition, the circuit that uses the most commonly used filter is so designed; that to save circuit components these filters in position is located when the resistor RS responsible for the selection of the filter is not is switched on, i.e. for this particular wavelength is then on the test module no resistance RS available - this test module - then applies to all tests that just need this special filter.

The following describes the temperature control of the incubator block are discussed in more detail, the temperature controller 232 further ahead has already been explained in general terms with reference to FIG. 6; here a more detailed explanation of the temperature control with reference to Fig. 17, the same elements in FIGS. 17 and 6 also have the same reference numerals on.

The resistance RH responsible for temperature control is variable Resistance shown and with a thermistor 330 in a voltage divider circuit arranged, the common connection point of both resistors also being the same represents the first input 232A of an operational amplifier 332.

The voltage divider hold of the thermistor 330 with the temperature control resistor RH is symmetrically preloaded.

The operational amplifier 332 has a second input 332A, which is connected to ground through a resistor 334; at this entrance is still also via a feedback resistor 336 the output 3323 of the operational amplifier connected.

The thermistor 330 is in a sne heat exchange with the incubator block 130 enabling connection coupled so that it is the temperature of the incubator block scans.

The output 332B of operational amplifier 332 is connected to base 338A a power transistor 338 so physically connected to the incubator block 130 is connected that this is used as a heat dissipation for the power transistor 338 serves.

The emitter connection 338B of the power amplifier is via a variable resistor 340 is connected to ground, the collector connection 338C is connected to a negative voltage source.

The operational amplifier 332 has a terminal input or Bias input 332C, which is in reverse with a row of clamp diodes in front 342, which in turn are connected to the base 344A of a switching transistor 344, its emitter to ground and its collector 344C via a low temperature Indicating lamp 346 connected to a source of negative voltage The temperature control 232 is designed in such a way that, during operation, the incubator block 130 is at a temperature of 37 ° C.

De'r temperature control resistor RH is set so that if the thermistor 330 is at a temperature of 37 ° C, the input 232A of the operational amplifier 332 on occurring voltage when it is over the closed Loop with loop reinforcement Ag, = R336 + R334 reinforced with R334, at the output 332B of the amplifier results in such a voltage and at the same time, too at the emitter terminal 3382 of the power transistor 338 that through the resistor 340 and the conduction transistor 338 a sufficiently high current flows, which causes that the transistor 338 picks up such a quiescent power and emits.t0 as heat that the incubator block ï3C is kept at a temperature of 370C.

If the temperature of the incubator block 130 decreases, then also decreases the voltage at the input 232A of the operational amplifier 332 (the thermistor 330 has a negative temperature coefficient), as does the voltage at the emitter 338B of the power transistor causes a decrease. This does one Current increase and a greater power loss in the power transistor 33, since the latter falls at a constant voltage BS via its collector State on, then the voltage on the base reaches 338A of the power transistor 338 a point under which. they due to the biasing or clamping effect of the Diode row 342 and the base-emitter path of the switching transistor 334 do not drop can. The temperature corresponding to this voltage is the threshold between a "full heating on" state (a maximum output that the power transistor 338 as power loss, can consume) and a proportional system with closed Ribbon. This temperature is very close to the 370C control temperature (approx 36.50C) and is determined by the gain AT for the closed loop.

If operational amplifier 332 goes into this clamped state, then a current flows into the amplifier 332 via the terminal input 332C. This stream is detected and amplified by the switching transistor 344, resulting in an enlightenment the low temperature indicating lamp. 346 leads, in which the temperature control module 126 is arranged and indicates to the operator of the console 122 of FIGS. 3 and 4, that a low temperature condition exists in the incubator block 130.

The following are some components in the form of a table of the system and the places where these are commercially available that in the left column only shows its reference number. The middle column then shows the type of component, while in the right column the trade name is listed.

Examples of components used Reference symbols Description Trade designation 1. 204A, 210G, 204A2, operation- Motorola MC1458 234C stronger 2. 210F, 228E, 332 "National LM 301A 3. 234D, 204A1" National LM 312H 4. VC3, 234K comparator - Motorola 1458 with circuit output clamped to TTL levels 5. 214X, 214Y, 214Z BCD Up / T1 SN74192 Down Counter 6. 216U, 216V, 216W Decoder Driver Tl SN7447 7. 216X, 216Y, 216Z 7 »Purchase order Monsanto MAN-l 8. 264 (typical) Inverter Tl SN7404 9. 258 (typical) NAND gate Tl SN7400 10. FF1, FF2, FF3, flip-flop vom Tl SN7474 FF4, FF5, FF6 Type D 11.224 6 Counters Tl SN7492 These examples are intended to only indicate the fact that various electronic and in the invention Apparatus and components used in the system are commercially available, of course these can also be produced in other ways. Not even in this table components contained and specified are available in this way.

From the preceding description and the drawings it can be seen that the invention relates to an analyzer for colorimetric blood component analysis and relates to prothrombin time analysis, such analyzes being considerably improved and their implementation will be accelerated, also will be mistakes made with earlier Systems that occurred in the usual way, eliminated or reduced. Furthermore enables the invention enables a heretofore unavailable variety of such to be carried out Analyzes with minimal equipment costs. More to see parts aes errinagemein systems are included in these analyzes, the influences of variables are eliminated that normally have to be considered, for example the Lamp intensity, the transfer functions of the photodetectors and foreign matter in optical systems; the apparatus according to the invention is self-normalizing in a way that all test results on a common digital display Scale and the like. Can be displayed, and even scales moderately in the correct Units of concentration values and time brought.

In addition, it is particularly advantageous that the inventive Structure in your console structure the interchangeability of a set of test parameters with another allows in such a way that selectively the ultimately possible number from. Analyzes can be selected and changed using the system according to the invention allowed to carry out.

Finally, in the following, FIGS. 18, 19 and 20 a preferred commercial embodiment of the test console and the already test modules described earlier with reference to FIGS. 3, 4, 5A and 5B, namely with special attention to the compensation of actually occurring Variables, whereby in the following description the corresponding known Reference numerals are denoted by a suffix Y.

The 122AY test modules in the console are in the main circuit board 174Y inserted by means of printed connection connections 160AY, namely in such a way that, the inscription display plate 162Y along the upper inner Edge of the module circuit board 160Y immediately adjacent to the associated Push-button switch 122BY is arranged in the console 122Y.

The printed connection terminals 160AY are along the bottom inner edge of the module circuit board 160Y directly below the inscription display board 162Y and the associated housing 162Y1, which holds the bearings 164, includes lamp 166 and lamp cap 166B, as discussed earlier in connection illustrated with Figure 5A. The lower outer edge of the module circuit board 160Y is cut to create a cam-shaped cutout area 160Y1 such that that in this way floating freely the entire outer side of the module circuit board 160Y is held above main circuit board 174Y in module 122AY.

In this way you get to a mounting surface on the top inner Eeke adjoining the housing 162Y1 for the inscription board to one variable normalizing resistor RNY to be mounted with an assigned adjusting screw RN? L, which is located below the top edge of the module circuit board 160Y In addition, are then also and essentially concluding with the upper outer Edge of the module circuit board 160Y more variable, the frequency controlling resistor RCY and a variable one that brings about the empty reagent compensation Resistor R2Y provided with appropriately assigned adjusting screws RC? 1 and R2? L and with immediately adjacent to the top edge of the module circuit board 160Y and immediately below the housing 124Y of the console 122 ?.

The housing 124Y, as shown in Fig. 19, is provided with a plurality of access openings 124kl that are aligned with the adjustment screws ARC? 1 and R2Y1 in such a way that that an immediate setting of the control resistor RC? for the oscillator frequency and the empty reagent equalization resistor R2Y of each test module 122ar in the inserted Position in the console can be made.

However, the housing 124Y must be lifted to gain access to the To create adjusting screw RNY1 of the normalizing resistance RNY, since this in Basically only needs to be adjusted to compensate for changes in the total Energy transfer through the corresponding one interference filter into the Filter wheels 102 or 152, as mentioned earlier in connection with FIGS. 1 and 4 described.

By adjusting the value of the normalizing resistor RNY, you can the value of Eh for an open test recess 156? on the same constant arbitrary value can be set for each interference filter used in the test to be performed by console 122Y is used. This arbitrary value is, as already described above in connection with FIGS. 9 and 12, within of the linear region of the normalizing stage 204A1 of FIG. 12 is selected and located is within the value range which is designated in FIG. 9 as "full scale".

The values of the frequency controlling resistor RC? and that further Resistance R2Y designated as 'remote resistor' in front are set, in order to compensate for variables that have the concentration line Cv, which are already ahead has been defined in connection with Figs. 9 and 15, affect.

It turned out that these variables for different Quantities of diagnostic reagents for the various concentration and prothrombin tests occur, there can be aging effects of such reagents, but it can also involve changes in the spectral properties of the interference filters, for example the central wavelength and the bandwidth.

The various related circuits that through the resistors RNY, R2Y and RC? influenced and operated as well as their Working methods are already described earlier in the description of the main control circuit and the reference oscillator as well as in the description of the operation of the main control circuit has been explained.

In the description given earlier, these are variable Resistors RN ?, RCY and R2Y have been referred to as RN, RC and R2. The variable Resistances RCY and R2Y compensate for the usual internal field changes caused by console 122 users must and therefore are these resistors also pass through access openings 124Yl in console housing 124Y has been made accessible and adjustable ', and everything can be done with help of small screwdrivers or the like. So that you have quick access to this Has.

Because of these externally possible attitudes, the results succeed and display values of the system according to the invention when a plurality is detected of different light transmission phenomena through corresponding liquid samples for keeping the tests at a quantitatively accurate level.

Claims (13)

P a t e n t a n s p r ü c h e Device for performing a variety of chemical analyzes of Fluid samples, especially for component concentration analysis of blood and for prothrombin time analysis, d a d -u r c h e k e n n n z e i zu c h n e t, that provided 'that the concentration of a specific component of a Sample for any particular analysis is proportional to the intensity of radiant energy of a given frequency range passed through the sample, a radiation source 116, 1144) and a converter unit responsive to the radiation energy is provided is that recording arrangements g156) for the storage of a sample to be analyzed containing cuvette (120) are provided in the beam path and that the transducer unit includes one responsive to the radiation intensity received by a filter (102A) Display arrangement (-216) for displaying a function of the intensity, mounting units (122A, 104) with a variety of normalizing means (168, RN, R2, RC, RS 170) and with a variety of individual filters (104B), each with a special, Isolate the frequency band emitted by the radiation source from radiation energy, that each normalizing means includes reference parameters which are calibrated in such a way that that the display arrangement (216) for a direct display of the concentration of the respective specific constituent according to the analysis carried out is and that assignment arrangements are provided that the normalizing means to carry out the special analysis with the filters and the display arrangement (216) relate. 2. Apparatus according to claim 1, characterized in that the samples (118> can be irradiated by light of a preselected wavelength and detector arrangements (158, 134) are provided which affect the light intensity transmitted by the samples respond and according to the component concentration and prothrombin time Having output signals and converting these signals into a digital display Converter arrangements (234, 212, 214; 204, 210, 212, 214) are provided and that for direct numerical display of the digital output signals of the converter arrangements a display arrangement (216) are fed. 3. Apparatus according to claim 1 or 2, characterized in that To determine and display the prothrombin time, the detector arrangement (photo element 134) a variable current output signal corresponding to the intensity of the transmitted light generated and that the detector arrangements amplifiers (234C, 234D, 234K) are connected downstream are those on the first and second, respectively at the beginning and the end of the prothrombin time determination address occurring change values of the variable current signal, these change values vary from a predetermined limit value and that circuit arrangements are provided are, the first and second, the occurrence of the first and second change value output control signals indicating that a clock signal generator (226, 224) and a counter (214) are provided and that the first and second output control signals receiving and the clock signal gated into the counter (214) conducting logic Circuits (FF5, FF6, 282, 284) are provided such that from the counter during of the time interval defined by the first and second output signal is one of the Prothrombin time of the blood test sample representative count can be established. 40 Device according to one or more of claims 1 to 3, characterized characterized in that a console (122) consists of for carrying out the analyzes a housing (124) is provided, in which the a plurality of to be carried out Sample analyzes common analyzing circuit arrangements are arranged, that test modules (122A) with the common circuit arrangements in the console (122) can be connected in such a way that the individual modules share the common circuit arrangement form in each case on a predetermined analysis that in the housing (124) a radiation source (144, 132) and optical assemblies (150, 154) are provided and that adjacent to the radiation source (144, 132) and the optical arrangements one to be examined Sample receiving device (test recess 156, 130C) is arranged, which the the sample to be analyzed exposed to radiation energy 5. Device according to one or several of claims 1 to 4, characterized in that for receiving the liquid sample a test recess (156, 130C) is provided with a light path (156H) therethrough is that the detector arrangements (photo element 134, 158) that the test recesses (156.130C) That light is supplied with and without an inserted sample, wherein first and second of / detector assemblies (134, 158), the intensity of the at open test recess and let through test recess containing the sample Light proportional current signals are generated that the detector arrangements (134, 158) amplifiers (204, 234) are connected downstream, which convert the first current signal into a first of the light transmission of the open (without inserted sample test recess (156) convert corresponding output voltage at a first conversion gain and that these amplifiers the second current signal which the Light transmission by the introduced sample corresponds to a second output voltage at a convert second conversion gain that these gains given different Have values such that the amplifiers (204, 234) when the test recess and in the presence of a standard reagent blank in the test cavity the actual sample have the same output voltages that converter circuits (210) are provided, the first and second output voltages (E #) in first and convert second time intervals (T), the time intervals corresponding to the respective Logarithms of the first and second output voltages are proportional to that further Clock pulse arrangements (226) are provided and counters (214) and that a main control circuit (212> with the converter circuit (204), the clock pulse circuit (226) and the Counter (214) is connected, so that the converter circuit (204) to initiate the time intervals (T) and for the gated supply of the clock pulses to the counters (214) at the beginning 'and during the time intervals (T; - is made effective 6. Device according to claim 5, characterized in that the main control circuit (212) has selection arrangements has the counter (214) causes during the first and second Time interval to count in opposite directions, such that the e one Counting is deducted from the other and that the counting difference of the respective The component concentration in the test sample. 7. Device according to one or more of claims 1 to fs, characterized characterized in that the first and second output voltages (E #) from the converter circuit (210) in first are second digital signals that are convertible and that the size Difference between the digital signals from a computer can be determined. 8. Device according to one or more of claims 11 to 7, characterized characterized in that the converter circuits (210) are logarithmic converter circuits and generate a digital output signal that is the logaritm of the analog Input variable corresponds to the fact that comparator circuits (VC3) are provided with a first and a second input, one input (VC1) being the analog input signal ) can be supplied that a function generator (210f, 210G) is provided for generation an exponentially increasing output signal and for supplying this signal to the other input (VC2) of the comparator circuit, (VC3) that the main control circuit (212) the function generator (210F, 210E, Q1) via a signal (S, CS1) and the counter (214) initiates via a signal (UDS) for generating a digital output variable and that the comparator circuit (VC3) at its output when the value of the exponential The rising signal (EL) and the analog signal (E #) are the same, z a control signal (DPS, 212D), which the arrangement generating a digital output signal (Counter 214) via main control circuit (121) stops, so that it gives itself digital output signal corresponds to the logarithm of the analog input signal. 9. Device according to one or more of claims 1 to 8, characterized characterized in that the logarithmic converter circuit (210) provides a first time interval signal (T) generates, weld: les the intensity of the incident which is guided by a reference sample Corresponds to light and a second time interval signal (T), which corresponds to the intensity of the incident light transmitted through the sample to be analyzed corresponds to 0 10. Device according to one or more of Claims 1 to 9, characterized in that that an incubator block (130) is provided which comprises a heat dissipation arrangement with at least one recess (156, 130C) that on the heat dissipation arrangement (cooling plate) a power transistor (338) is mounted in thermally conductive connection that with the input of the power transistor (338au the output of an operational amplifier (332) with a reference input (332A) and a control input (232) is connected that a thermistor (330) and a variable resistor (RH) symmetrically connected in series between symmetrical bias voltage source (+ V, -V) and have a common connection point (232A) which is directly connected to the control input of the operational amplifier (332) is connected that the thermistor (330) in thermal There is a coupling with the cooling plate and interacts with the rheostat (RH), that the operational level amplifier (332) the power transistor (338) for outputting Power loss to the cooling plate (incubator block 130) causes such that a predetermined temperature can be achieved. 11. The device according to one or more of claims 1 to 10, characterized characterized in that the normalizing arrangements (resistors RN, R2, RC) are adjustable are in such a way that the transducer systems responding to the transmitted radiation power, which provide a display as a function of the light intensity received, in the absence of the person respond to the sample to be analyzed in the light path as if the from the individual filter (102au transmitting total radiant energy of essentially is the same size. 12. The device according to one or more of claims 1 to 11, characterized. characterized in that a single display arrangement for all examinations to be carried out (216) is provided and that the normalizing arrangements the time interval signals Set (T) proportionally and program the downstream computing circuits so that that all constituent concentration measurements are on a display from the common Display arrangement (216 '> are standardized and the standardizing arrangements compensate Means for making the logarithmic converter circuits responsive (210) selectively for the incident light transmitted through the reference sample vary so that changes in the transmission properties of the reference sample, the spectral properties of the incident light and the total energy of the given Wavelengths can be compensated over the wavelength spectrum. 13. The apparatus according to claim 14, characterized in that the compensating means to compensate for changes in responsiveness selectively change the detector arrangements. L e r s e i t e