DE3500639A1 - Photometric analyser for chemical analyses - Google Patents

Abstract

The photometric analyser for chemical analyses comprises a turntable (1) on which along its circumference a number of reaction vessels (2) is arranged which, during each working period, can be rotated intermittently by a plurality of divisions. The analyser further comprises a sample dispenser (7) which, during a working period, dispenses the respective sample into a multiplicity of reaction vessels (2), and a reagent dispenser which, during a working period, dispenses different reagents, corresponding to different test objectives, into a multiplicity of reaction vessels (2). A multiplicity of test fluids contained in a multiplicity of reaction vessels (2) is measured during an operational period by means of a multiplicity of photometers (16) in order to obtain a multiplicity of measured values. Based on this multiplicity of measured values of the respective sample, a computer (26) calculates the analysis result of a sample. <IMAGE>

Description

Photometric analyzer for chemical analysis

The invention relates to a photometric analyzer for chemical Analyzes, in particular an automatic analyzing device according to the preamble of claim 1.

In Japanese Patent Application Publication No. 113 737/83 a device for chemical analysis is disclosed, which has a turntable a number of reaction vessels arranged along the circumference thereof and one has single photometer, the measuring light path through the row arrangement of the reaction vessels runs. For each operating period, the turntable is one revolution plus one Rotated division, a sample and one or more reagents at predetermined locations poured into a reaction vessel to produce a test liquid, which is then the Is subjected to photometry to determine the course of the reaction. For every test liquid Several photometric measurements are made to determine the chemical property to examine the test liquid.

As in the known analyzer, the turntable for each operating period has to be rotated by more than one revolution, the working time and the process speed is reduced. This can be seen in an analyzer for multiple analysis tasks in which a large number of tests are performed on each Sample is made. When a large number of arrays of reaction vessels concentrically on the turntable is provided to a multi-channel analyzer this can increase the weight of the turntable so that the rotation of the same cannot be precisely controlled. Since those in the reaction vessels contained test liquids during the rotation of the turntable one after the other are subjected to the light measurement, also allows the accuracy of the photometry to be desired, and the accuracy of the analysis could be greater.

The object of the invention is to provide an analyzer of the type mentioned at the beginning To create a way with which the aforementioned disadvantages of the known device are avoided and the operating period is shortened, so that samples can be made at high speed and can still be measured with improved accuracy. The analyzer according to the invention is intended as a single-channel or multi-channel device for multiple tests be designed.

An analyzer that solves this task is with its refinements characterized in the claims.

A large number of reaction vessels are used during each operating period fed intermittently, and a large number of in a large number of reaction vessels The test liquids contained in it are measured using a large number of photometers, while the reaction vessels stand still. This makes it possible to adjust the duration of the operating period to shorten and the process speed as well as the analytical accuracy to increase raise. In addition, an analyzer for chemical analyzes can easily be implemented, which is designed as a single-channel device for multi-facet tests or as a multi-channel device is.

The following is the invention with further advantageous details explained in more detail using a schematically illustrated embodiment. In The drawings show: FIG. 1 a diagram of an exemplary embodiment of a photometric Analyzer; Fig. 2 is a time table for explaining the operation of the in Fig. 1 shown device; 3 shows a diagram of an exemplary embodiment a photometer provided in the device according to FIG. 1; 4 shows a scheme of another embodiment of a photometer according to the invention.

The analyzer has a turntable 1 on which two concentric Circles along the circumference a number of reaction vessels 2 are arranged. the Reaction vessels 2 are provided on the turntable 1 with a constant pitch.

The turntable 1 is with interruptions in each case by a division rotated in the direction indicated by the arrow by means of a control device 3. In the present embodiment, two test channels can be in each of two test channels Tests are carried out so that the device has a total of four test posts can be analyzed. Containers are controlled by the control device 3 4, which contain samples, for example blood serum, intermittently in the through Arrow indicated - moved forward in a sample container feed device. A sample contained in a container 4 is at a predetermined stop a in two nozzles 6a and 6b of a sample dispensing device intended for dispensing the sample 7 sucked, and then at a stop b the sample from each nozzle is in two successive reaction vessels 2 delivered each reaction vessel channel. So received four reaction vessels hold a sample.

At stops c and d, which are divided by two or three divisions in the direction of rotation of the turntable 1, seen from the stop b, are the ones to be made Tests correspondingly selected first reagents 12 to 15 by means of first reagent dispensing devices 8 to 11 under the control of the control device 3 into the four reaction vessels 2 submitted.

When dispensing, the reagents are forced into the reaction vessels injected to mix the sample and reagent together. At one of the stops The test liquids contained in the reaction vessels become c adjacent bus stop e exposed to the light measurement by a first photometer 16-1.

Controlled by the control device 3 are at stops f and g by means of second reagent delivery devices 17 to 20, second reagents 21 to 24 in four consecutive reaction vessels according to further tests required submitted. The test liquids that have arisen in the reaction vessels are then used at stops h and i, again controlled by the control device 3, by means of a Agitating or shaking device 25 shaken and then a photometry section fed.

In the photometry section there are nine photometers 16-2 to 16-10 at stops k to r provided corresponding to every second division, starting next the stop i, where the test liquids are shaken. From the photometers 16-2 to 16-10 generated photometric values are shared with those from the first photometer 16-1 supplied photometric values to a computer 26, in which under a number of photometer values ten photometer values for a respective test liquid to be selected. A linear response range is created based on the selected values judged and then based on the photometer values within the linear Reaction area, which calculates the enzyme activity. The obtained analysis result is displayed by means of a display device 27, but can also be via an interface be passed on to an external facility.

After the photometry, the reaction vessels 2 become a rinsing device 28 fed, where they are washed and in preparation for the next examination to be dried. In the embodiment described here, there are sinks for the flushing system Stops s to t are provided.

Fig. 2 is a time chart showing the operating times of the main elements of the analyzer according to FIG. 1 reproduces. In the present embodiment one operating period is twelve seconds, and during each operating period the turntable 1 is rotated intermittently twice by one division. To the local rotation according to a division is a sample in two reaction vessels that are currently at stop b, and test liquids in those reaction vessels that are currently at stops e and j to r are located, a light measurement using the corresponding photometer 16-1 subjected to 16-10.

After the second rotary movement by one division, the test liquids are in those reaction vessels that have just stopped at stops e and j to r have measured the sample delivery device by means of the corresponding photometer 16-1 to 16-10 7 releases the same sample into two reaction vessels, which are located at the stop b, the first and second reagents 12-15 and 21-24 are by means of of the first and second reagent dispensing devices 8 to 11 and 17 to 20, respectively, into those Reaction vessels delivered that are currently at stops c, d or - f, g, the test liquids are in the reaction vessels at stops h and i stirred by means of the stirring or shaking device 25, and the reaction vessels, which are located at the stops s to t, are by means of the flushing device 28 cleaned.

Since, according to the invention, four tests for every twelve operating period can be made on each sample, the process speed is extraordinary high. In addition, the test liquid in each reaction vessel by means of the photometer 16-2 to 16-10 is measured nine times, the reaction process can be examined exactly will. Since, in addition, the photometry is carried out when the reaction vessels are at a standstill its accuracy is quite great.

An embodiment of one used in the device according to FIG. 1 The photometer is shown schematically in FIG. 3. The one emanating from a lamp 31 Light is passed through a lens 32 into a slot 33, and that through the Light flux passing through the slit is rotatable by means of one of several Filter ring 34 arranged interference filter 35 caused on optical fibers 36 to apply. The said an interference filter lets in light a wavelength that corresponds to the desired test task. The exit ends of the optical fibers 36 are arranged at the photometric locations, and those of the Light fluxes emitted by optical fibers 36 are passed through prisms 37 onto the reaction vessels 2 headed.

The light flows passing through the reaction vessels 2 are recorded by photodiodes 38, whose output signals are amplified by amplifiers 39 and then fed to computer 26 (FIG. 1).

In Fig. 4 is another embodiment of a photometer for an analyzer according to FIG. 1 is shown. With this out.

Management example falls from a lamp 31 outgoing light a lens' 32 on optical fibers 36, and the output from the optical fibers 36 Light beams fall through prisms 37 onto the reaction vessels 2. Those from the reaction vessels 2 transmitted light rays pass through prisms 40 and fall into optical fibers 41 a. The output ends of the optical fibers 41 lead into a light multiplexer 42 having a rotatable, crank-like optical fiber 42a. Each of the light multiplexer 42 selected light beam is through a lens 43 on Diffraction grating 44 passed and, after appropriate diffraction, arrives at one of several photodiodes 45. So each photodiode can the corresponding light beam received at a given wavelength corresponding to a given test task. The output signals of the photodiodes 45 are amplified via amplifiers (not shown here) entered into the computer 26 shown in FIG.

The invention is not limited to the exemplary embodiments described above limited but can be modified in various ways. So z. B. only one or more than two rows of reaction vessels can be provided. Further more than two tests can be carried out in each channel.

The greater the number of possible test tasks, the more versatile becomes the device in its analyzes. It can also be used as the first and second reagent the same substance is used, and various samples can instead be dispensed into different reaction vessels at the same time. Then a single inspection task can be performed in a single channel at very high speed be performed. In the embodiment shown in Fig. 1 are on each second division arranged after the dispensing station for the second reagent nine photometers; but any number of photometers can be used at the desired dividing points be provided. Furthermore, in the embodiment according to FIG. 1, the reaction vessels used repeatedly. But they can also be thrown away after photometry.-During here the reaction vessels are transported in a circle in a horizontal plane, they can also be done linearly or by means of a conveyor belt in a vertical plane to be continued. It should also be noted that the reaction vessels through an air or liquid thermostat can be passed through. In this Case can be the photodiodes according to FIG. 3 and the amplifier within the thermostat be arranged so that any temperature deviation can be avoided.

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Claims (8)

Claims 1. Photometric analyzer for chemical analysis, g e k e n n n n z e i n e t by - a device for intermittent feeding a plurality of reaction vessels (2) along a given feed path during every operating period; - a sample delivery device (7), which during each operating period dispenses at least one sample into a plurality of reaction vessels (2); - a reagent dispenser (8-11; 17-20) containing at least one reagent during each operating period dispenses into a large number of reaction vessels (2); - a photometric device with a large number of photometers (16-1 to 16-10), each arranged in such a way that that they measure a large number of test liquids during each operating period, contained in a plurality of reaction vessels (2), and a plurality generate photometric values of the plurality of test liquids; - a calculator (26), which is based on the number of photometers for the corresponding Test liquid supplied photometric values the chemical properties of each test liquid calculated. 2. Analyzer according to claim 1, characterized in that it is e k e n n z e i c h n e t that the reagent delivery device comprises a plurality of reagent delivery devices (8 to 11, 17 to 20) has different reagents for measuring different Submit inspection item. 3. Analyzer according to claim 1 or 2, characterized in that g e k e n n z e i c h n e t that the device for supplying reaction vessels simultaneously several Feeds rows of reaction vessels. 4. Analyzer according to claim 3, characterized. g e k e n n n z e i c h n e t that the plurality of rows of reaction vessels are concentric along the circumference a turntable (1) is arranged. 5. Analyzing device according to claim 1, characterized in that it k e n n z e i c h n e t that a stirring or shaking device (25) is provided, which in the The test liquids contained in the reaction vessels (2) are stirred up. 6. Analyzer according to one of the preceding claims, characterized it is not noted that a rinsing device (28) for cleaning the reaction vessels (2) is provided. 7. Analyzer according to one of the preceding claims, characterized it is noted that the plurality of photometers (16) provide a light source which emits a light beam along an optical axis, a rotatable one Filter ring (34), along the circumference of which a plurality of filters is arranged which let through given wavelengths according to the test tasks and from each of them one can be switched to the optical axis, as well as optics that allow the from the light beam allowed to pass through the filter switched to the optical axis a plurality of reaction vessels (2) conducts. 8. Analyzer according to claim 7, characterized in that it is e k e n n z e i c h n e t that the optics has a plurality of optical fibers (36), the input ends of which are arranged so that they pass the filter connected to the optical axis received transmitted light beam, and their output ends so arranged are that they the transmitted by the optical fibers light rays in a Conduct a large number of reaction vessels (2). Analyzer according to one of Claims 1 to 6, characterized in that it is It is noted that the plurality of photometers (16) have a beam of light emitting light source and a first set of optical fibers (36), direct the light beams into a large number of reaction vessels, a light multiplexer (42), a second set of optical fibers (41) running through the reaction vessels Guide the light rays let through into the light multiplexer, a diffraction grating (44), which diffracts a light beam selected by the light multiplexer, as well as a plurality of light receiving elements corresponding to the one diffracted by the diffraction grating Receive light beam.