HU199990B - Automatic photometric apparatus - Google Patents

Abstract

The present invention relates to an automatic photometer apparatus having an illuminating optics, with a plurality of vents (V), against a storage plate (17) for the placement of samples of the material to be examined, and a storage plate (17) disposed alongside the illumination optics on the other side of the storage plate (17). There is a movable photo sensor (1) above the troughs (V). A control unit, preferably a microprocessor, has a measuring location display and a display showing the measured values. The apparatus is configured to have a dispensing bar (14) for receiving storage plates (17), the photo sensor (1) being disposed on a carrier slide (19). The carrier plate (19) is guided on a forced path (4) for continuous movement of the photo sensor (1). The carrier plate (19) is provided with two guides (2, 3) perpendicular to one another in a moving plane communicating with the drive motor (9), and a positioning bar (7) arranged in front of the guide (2) in front of the photocell (8). ). (Characteristic of the invention is shown in Figure 1a.) EN 199990 B Scope of the specification: 5 pages, 3 drawings, Figure 4 -1-

Description

BACKGROUND OF THE INVENTION The present invention relates to an automatic photometer apparatus, particularly for the detection of highly sensitive serological reactions, preferably enzyme-linked immunosorbent reactions (ELISA - Ensyme-Linked-ImmunoSorbent-Assay).

In practice, various types of automatic photometer equipment are common. GB-A-2,192,056, for example, discloses a solution in which a sample of the substance to be examined, placed on a transparent filter plate, is illuminated by the illumination characteristic of a photometer. The known solution has a reflective interior wall, the light reflected from the cylindrical surface is registered with a photo sensor. The electrical signals are encoded on magnetic tape after encoding. The measured values are analyzed and processed by a microcomputer.

GB-A-2,165,642, which is also GB, operates with different colors of light. The test substance is illuminated by green, blue and red LEDs and the voltage of the photoelectric sensors detecting reflected light is applied to A / D converters. The measured electrical signals are stored and subsequently evaluated in a manner known per se.

Preparation and photometry of large but small volumes of material samples - 50-200 μΐ - are known in Takátsy-developed rectangular plastic storage plate with 96 troughs (12 troughs in 8 rows), which also serves as a cuvette for the photometer. For example, liquid samples in the troughs are screened vertically from below to measure the degree of color reaction in the samples by means of a color filter, a light sensor and electronics known in the art. In practice, screening and sensing are performed in such a way that the light beam does not touch the trough wall, so that light scattering and reflection on the liquid / plastic interface causes photometric inaccuracy. One of the known solutions satisfies this necessary condition by having a spring-cone-shaped centering head, which includes the color filter and the photo sensor, which fits into the edges of the projections. According to this known solution, the storage plate itself is conveyed manually under the snap-on probe. The disadvantage of this solution is that it does not lack human intervention, and subjective measurement alone carries the possibility of error. The mechanics of the snap probe get dirty after a while and the spring becomes tired, which does not provide measurement in the center of each trough, which in turn results in photometric inaccuracies.

Alternatively, the storage disk is transmitted by a linearly moving mechanism along the x-axis according to the x-y coordinate system, and the measurement is performed in 8 troughs perpendicular to the y-axis. During the measurement, the light beam is introduced by fiber optics, which are obtained by dividing the monochromatic light beam from a given light source into eight halves. Detection is performed by eight independent photodiodes with multiplexed scanning. The evaluation is performed by a microcomputer in a manner known per se. The disadvantage of the known solution is that the eight optical channels have to be tuned very precisely to each other, the photo sensors have to be sorted so that they have the same characteristics and often have to be checked by rather complicated methods for aging, deterioration or contamination of the light detectors. Another problem with this solution is moving the light sensor, stopping it at the right place for measurement, and then retransmitting the light sensor.

It is an object of the present invention to provide an automatic photometer device which eliminates the errors of the known solutions, provides sufficient accuracy, and in which sequential automatic continuous measurement of ELISA plates and evaluation of measured values can be achieved.

It has now been found that for fast, high-volume measurements, it is desirable to use a storage device that provides continuous sequential measurement of multiple storage discs and, in parallel, enables additional storage disks to be introduced or filled with material to be measured.

Experiments have been conducted which have shown that it is expedient to design this storage device as a circular drum, which can simultaneously contain multiple ELISA storage plates.

By moving them around the drum in the drum, it is easy and quick to replace individual ELISA plates and ensure continuous measurement. The advantage of the drum-like construction of the container structure with the conventional linear solution is that it can also be operated with continuous refilling. A further advantage is that the storage plates can be resized several times in a recurring cycle if necessary, for example by changing color filters, at different wavelengths, or after different incubation times.

The continuity of the measurement in the prior art solutions was significantly hindered by the fact that during the photometric measurement the light sensors had to be moved from one position to another and then stopped and the measurement continued. A further realization of our invention is that we have realized the need to provide a device that eliminates a succession of movements and stops, thus providing a simple and continuous

HU allows 199990 Β gaps. During our experiments, we succeeded in developing a solution that allows the measuring-optical system to be continuously moved over 96 wells on the ELISA storage plate during the measurement. To do this, we have developed an expedient forced course that allows and ensures continuous movement. We have also solved the need for measurements in this continuous motion sequence whenever the measuring optical system passes over one of the 96 troughs, just across the center. In addition to the forced path for continuous movement of the carrier of the photo sensor, the carrier of the carriage is provided with two guides perpendicular to the propeller, connected to a propulsion motor and arranged in front of the photocell, provided. The proper training of the forced track and the use of the positioning bar ensure that the measurement is carried out in the right place above the center of each trough, even with a photo sensor on a continuously moving slide.

BACKGROUND OF THE INVENTION The present invention relates to an automatic photometer apparatus having a luminous optic, a multi-troughed storage plate for receiving samples of material to be examined, opposed to a luminous optic, and a photoelectric sensor disposed on the other side of the storage plate. It comprises a control unit, preferably a microprocessor, to which is connected a measuring point display and a display of measured values. The photometer is configured with a metering drum for receiving storage discs, the photo sensor being mounted on a carrier slide. The carrier slide is guided on a slope path allowing continuous movement of the photo sensor. The carrier carriage is provided with two guides perpendicular to its propulsion plane, perpendicular to each other, and with a guide bar positioned in front of the photocell moving along with one of the guides.

In a preferred embodiment of the invention, the storage plates in the dispensing drum are disposed radially along the periphery of the dispensing drum. The motor of the metering drum is in communication with the positioning disc via a slow-speed gear and is equipped with a position sensor for sensing the position of the positioning disc.

In a further preferred embodiment of the invention, the metering drum is provided with sliding sticks for conveying the storage plates and a position sensor switch for detecting the presence of the storage plate.

lb. figure

Figure 2 is Figure 3

Preferably, the apparatus is configured such that the forced path has the same number of tracks of rows of troughs arranged in several rows in the storage plates as they are connected at their ends. The position indicator strip is provided with a notch corresponding to the number of columns in the troughs.

A possible exemplary embodiment of an automatic photometer device according to the invention will be described in detail in the appended drawings, wherein:

- la. FIG. 4B is a schematic diagram of the device, a preferred embodiment of the forced path, and a block diagram of the electronic units of the device, although the optical structure of the illuminating optic is preferred.

The la. The apparatus of the photometer shown in FIGS. 1A to 4b has a plurality of storage slots 17 for receiving samples of material to be tested. The storage plates 17 are arranged in a dispensing drum 14 suitable for receiving them. In each of the storage plates 17, the troughs V are arranged in several rows a, b ..... n and in columns A, B, ..., m.

The photo sensor 1 of the photometer is mounted on a carrier slide 19. The figure does not show the illumination optics that provide the photo sensor 1 of the apparatus with the required light, which together with the illumination optic, the photo sensor 1 can be moved over the troughs V of the storage plate 17. The carrier slide 19 is guided on a forced path 4 allowing continuous movement of the photo sensor 1, preferably such that in the path sections 40 of the forced path 4 the forced guide pin 6 of the carrier slide 19 is movably arranged. A preferred embodiment of the forced path 4 is illustrated in FIG. illustrates that the forced path 4 in the storage plates 17 has the same number of rows a, b, ..., n of the troughs V, a, b, ..., n, e.g. It has 40 stages. Because the track sections 40 are interconnected, they allow the sliding pin 6 of the carriage 19 to move continuously.

The la. 2 to 3, two guides 2, 3 which allow perpendicular movement in the plane of their movement are provided. The carriage 19 has a drive motor 9 whose output shaft preferably drives a string conveyor 11 through a deceleration gear 10. The string conveyor 11 provides a continuous drive of the steel string 12 on the string guides 13. The steel string 12 moving on the string guide discs 13 moves the photo sensor 1 through the carriage 19 via the guides 2, 3. The equipment a

HU 199990 tartalmaz Contains 7 position indicator strips in front of 8 photocells moving with guide.

The la. As shown in Fig. 11, the storage plates 17 are disposed radially along the circumference of the dispensing drum 14 in the dosing drum 14. In the illustrated dosing drum 14, six storage plates 17 can be disposed in this case. The dispensing drum 14 is provided with push rods 16 for conveying the storage plates 17 and a positioning bar 15 ensures that it is in the correct position for measurement. The dosing drum 14 has a motor 23 which is connected to the positioning disk 21 via a slowing gear 20 in a transmission. The positioning disc 21 is equipped with a position sensor 22 for sensing its position, which allows a simple exchange of the storage plates 17 for measurement. The positioning of the storage plates 17 is ensured by the positioning strip 15. The motor 23 of the dosing drum 14 and the drive motor 9 of the carriage 19 are controlled by the known motor control 24.

Figure 2 is a block diagram of the electronic units of the automatic photometer. In the figure, the positioning strip 7 is marked with the photocell 8, the output of which is connected to a control unit 31. Also illustrated schematically is a positioning bar 15 and a position sensor switch 18 for sensing the insertion of the storage plate 17 in the dosing drum 14. These input signals are also connected to the control unit 31. A further input of the control unit 31 is connected to a converter 34 by the measurement results measured by the photo sensor 1 on the carriage 19. The converter 34 is preferably a linear / logarithmic converter known per se. Conventionally, one output of the control unit 31 is provided with a measuring point display 32 and a display 33 showing measured values. If necessary, the device is also provided with a line printer 36 and a central computer 37 is connected to the further output of the control unit 31 for possible further central processing. The known motor control 24 of the motor 23 of the dosing drum 14 and of the drive motor 9 of the carriage 19 may also be controlled by the control unit 31. This solution is advantageous, inter alia, if the control unit 31 is preferably configured as a microprocessor.

A possible practical design of the illuminating optic is shown in Figure 3. The illumination optic preferably moves with the photo sensor 1 and is located below the photo sensor 1 on the other side of the storage plate 17. The illumination optic comprises a light source F as shown in Figure 3, a lens system consisting of Li, L2, Ls lenses in the light path of the light source F, and a T mirror. The light source F can be fixed in position by means of screws CS, and the lenses L1, L2, L3 shown in Fig. 3 have focal lengths fi, f2, wood. The light rays of the light source F of the illuminating optic are transmitted through the lenses L1, L2, La to the mirror T, which is reflected back through the slit R to the photo sensor 1.

The automatic photometer apparatus of the present invention operates in detail as follows.

The storage plates 17 are placed in the dispensing drum 14 and the measurement is started. The motor 23 of the roller drum 14 rotates the metering drum 14 through the deceleration gear 20, which pushes the weighing plate 17 to be weighed into the weighing position by means of the sliding stick 16, and the positioning pulley 21

22 position sensors to adjust position. After the position sensor switch 18 indicates that the storage plate 17 is in the metering position, the metering drum 14 can then be measured. If the position sensor switch 18 does not detect the storage plate 17, i.e. the metering drum 14 is empty in the measuring position, the motor 23 will continue to rotate and will push the next storage plate 17 into the measuring position using the push rod 16.

During the measurement, the drive motor 9 starts to move the carrier slider 19 through the guide wire 2 via the steel string 12 in the deceleration gear 10, where the photo sensor 1 makes the first measurement in column A of the row of the storage field 17 to be measured. The carrier slide 19 is continuously moving in contiguous sections 40 of the forced path 4. Each measurement is caused by the appearance of a notch 70 corresponding to the number of columns A, B, ..., m of the V troughs moving along with the guide 2 and positioned in front of the photocell 8. Thus, in each case, the measurement is made in the center of the troughs V on the storage plate 17. From the first a-line to the eighth n-line, the forced organizing pin 6, with the aid of a further 3 guides, passes through the contiguous sections 40 of the forced path 4.

19 Carriers. After completion of the last n-row measurements, the carriage 19 returns to its starting position by means of the positioning strip 5 and the positioning strip 7. In the case of a new measurement, the organizer pin 6 is guaranteed to enter the forced path 4 with a funnel-shaped guide 41 in the initial section of the forced path 4. After returning the carriage 19 to its original position, the subsequent storage plate 17 of the dosing drum 14 may be measured.

The expedient arrangement of the dosing drum 14 according to the invention provides the possibility that the measurement of the given samples can be repeated automatically, if necessary, for example at different wavelengths or after different incubation times. Given that our photometric equipment is measured in a single-channel system, there is no need for calibration as is customary for known multi-channel directors55. The photometer is on5

EN 199990 Β, similarly to known similar devices, stores the measured extinction values and displays the measurement location in a known manner by means of the display 32 and the display 33 of the measured values. The control unit 31 may conveniently be configured as a microprocessor in accordance with similar prior art solutions. The control unit 31 performs the processing, displaying and, if necessary, transmitting the measured values to a further central computer 37 in a known manner, the implementation of which is not directly within the scope of the present invention.

The present invention has also stood the test of practice and is preferably suitable for measuring high sensitivity serological reactions.

Claims (4)

1. An automatic photometer apparatus having a luminous optic, a plurality of trough plates 5 for holding specimens of the substance to be examined, and a photoconductor acting on the target over the storage plate, opposed to the luminous optics, comprising a measuring point display and a display showing measured values, characterized in that it has a metering drum (14) for receiving the storage plates (17), the photo sensor (1) being arranged on a carrier slide (19), the carrier slide (19) guided on a forced path (4) allowing continuous movement of the photo sensor (1), The carrier carriage (19) is provided with two guides (2, 3) perpendicular to each other and connected to the drive motor (9), and a photocell (8) movable with the guide (2). It comprises a position indicator strip (7) arranged in front of it. Apparatus according to claim 1, characterized in that the storage plates (17) in the dosing drum (14) are disposed radially along the circumference of the dosing drum (14) with the motor (23) of the dosing drum (14) in a deceleration gear (20). and is provided with a positioning disc (21) in motion transmission and is provided with a position sensor (22) for sensing the position of the positioning disc (21). Apparatus according to claim 2, characterized in that the metering drum (14) is provided with sliding sticks (16) for conveying the storage plates (17) and the storage plate (17). There is a position sensor switch (18) for presence of 4Q. 4. Device according to any one of claims 1 to 3, characterized in that the forced path (4) in the storage plates (17) 45 has a plurality of rows (a, b ..... n) of troughs (V) having the same number of rows (40) of mutually connected ends (40) on the position indicator strip (7) and a notch (70) corresponding to the number of columns (A, B, ..., m) of the troughs (V).