DE4318692C2 - Procedure for the examination of blood serum samples containing antigens - Google Patents

Description

The invention relates to a method for testing of antigen-containing blood serum samples, which are carried out using simple radial Immune diffusion (RID) precipitate rings have formed on a gel plate.

A radial immunodiffusion test reveals antigen Test material in punch holes approximately 1 mm thick filled with agarose gel layer, with which a Pro benplatte is prepared. In the subsequent Dif fusion migrate the dissolved antigens radially into the environment the punch holes until in the equivalence range with the anti form an antigen-antibody immune complex as an insoluble, visible precipitate fails. The higher the antigen concentration tion of the sample, the larger the ring of precipitate, that arises around the punch hole. The evaluation of the serum samples, i. H. the Quantification of the antigen in the serum can thus be done via the suitable ratios measurable square of the ring diameter or diameter within the precipitate ring compared to Standard samples are made.

Measuring the precipitate with a diameter of about 10 mm rings usually take place under enlargers Skilled personnel. As a rule, each with a magnifying glass Measure the sample individually and its measured value and position no animals.

DE 31 19 269 A1 is already in place of a measuring magnifier the use of a converted microfilm reader for off measure has been mentioned.

A device according to US Pat. No. 4,021,200 works in a similar way disk-shaped gel plate with samples arranged in a circle is inserted. The illuminable plate can be through a visible cover. With a motorized ver adjustable crosshairs are successively the diameter  of the precipitate rings visually narrowed and the results of the Measurement displayed digitally. The measured values are noted.

The measurement is made difficult by a relative bad picture quality. So the rings are low contrast and be there are blurred and irregular, incoherent cones doors. Sometimes real foothills also form, which means there are significant deviations from the ideal circular shape. Therefore, the evaluation leads to strongly subjective Er results. In addition, there are the usual visual sources of error Measuring activity, i.e. reading and notation errors. Not forgotten Ultimately, the heavy strain on the eyes may be added permanent implementation of this work.

For further evaluation, the measured values noted must be entered via a Keyboard can be entered into a computer, which in turn makes reading and contains input errors.

All in all, the known methods are not very precise, ergonomically stressful, time-consuming and personnel-binding (GIT Laboratory medicine 7-8 / 90, p. 362).

In itself, it makes sense to measure and evaluate using elec Automate tronic image processing, especially Process for the photogrammetric recording of static images objects using opto-electronic solid-state sensors ren have been known for some time. With such a procedure (DE 38 11 837 A1) the recording object is in geometric loading train set to a grid and both stored digitally. A contrasting border area of the physically extensive ob project is differently focused by corresponding Target images.

Such a method can be used to measure simple ra Dialen immunodiffusion but do not use.

On the one hand, a different focus would not be a determinant the blurred zone boundaries. On the other hand the foothills or fraying are not suppressed. To  concerns are also sources of interference caused by scratches, dust and dirt particles, labels or streaks in the gel or are formed in the sample plate and in practical operation are inevitable.

According to DE 40 13 180 A1, a test liquid is used for detection of hemolysis examined image processing whether the test liquid through an image (triangle) painted onto a microplate its edge sharpness is recognized or by particles in the Test fluid out of focus with a threshold and so it doesn't become relevant. Measuring a size variable, disturbed object does not take place.

Also a process based on contour tracking differentiating the image information according to DE 40 40 726 A1 must be eliminated due to the variety of disturbances mentioned, since it leads to completely wrong or non-evaluable results would lead. By the variation ratio of the light intensity is measured at the limits of the existing pattern, Wür regardless of whether the pattern corresponds to the object to be determined belongs or to disturbances, inevitable object malformations and Interference objects are included in the contour formation.

According to US 4,794,450 is a high speed apparatus for image processing recognition of agglutination patterns for known diagnostic examinations. Several hundred samples are analyzed, depending on the findings, marked differently net plotted and the image obtained evaluated. The sub different patterns in a low-interference environment but not the subject of this patent.

The first problem to be overcome with the present invention is that in the gel plates under consideration the individual punched holes made by hand in the plate are sufficiently exact th diameter, but their location per hole field is not correct can be positioned precisely enough. Although it can be ensured be that only one punch hole is made per hole field, but This can be found in different locations within this field are located. This place must first be found through image processing  become.

Interference objects such as labeling are another difficulty scratches, streaks, fingerprints, foreign particles and risks se in the gel. They can also be used with extreme care Avoid reliable avoidance.

Third, the pixels that belong to the sample only form ideally a concentric, closed ring around that Punch hole in the gel. As practice shows, these are ideal spread multiple deviations rather the rule. The circles are therefore not always concentric. Often they are not closed, but only semicircular. The circular periphery rie can also look like small, unrelated Pitch arcs are available. Bumps also occur on, i.e. deformations of the ideal circular shape or even off Bays, i.e. small continuations that hang on the edge of the circle. In addition, the circles are of different quality, they are more or less blurry, low-contrast and sturgeon sources superimposed.

All these rejections due to the most varied of circumstances The ideal case results in something so disturbed Image, so far using a radial immunodiffusion measurement Image processing was impossible.

It is therefore the object of the present invention a method for fully automatic evaluation of blood serum samples after simple radial immunodiffusion sion test to indicate that largely insensitive to egg high noise content and imperfect image information is reliable and including comparative samples statement finished.

 This object is achieved by a method having the features of patent claim 1. In this process, from a known ideal Geometry of the measurement object, the measurement object that this geometry only partially visible, from parts of the picture that belong to real object parts and of a similar quality,  which are based on interference objects, found and reconstructed to then measure its area in a known manner.

The working steps according to the invention are: objects, detection of one or more object parts and recon structure of the entire object from the recognizable presumed Object boundaries and size related to Stan standard objects. For the first time, these process steps leave a reliable, automatic Evaluation possible after the single radial immunodiffusion test become. As a result, results are taken into account faster and more precisely than through visual evaluation and without gaining ergonomic strain on the staff.

In a first procedural step, an attempt is first made to iteratively Location of the punch hole approximately known in shape and size approach with predeterminable accuracy by using a punch hole circular mask as a reference surface in size (for a single calibration of the image processing system) and Location is so congruent that its medium gray worth a minimum.

Is the exact location of a punch hole found and therefore one Rough positioning with respect to the sample is achieved Ver search, the precipitate parts recognized around the punch hole, to a Circle to complete. Each pixel is made according to a known procedure position and intensity. The pixels either come from the precipitate ring or interference objects to be measured. A pc saves all pixels as a whole and determines them Main emphasis. A mask is in turn around this focus Positioned in a circular shape and constantly repeating the position and size changed this mask until an optimal coverage with the ring components is found. Through this procedure who which practically only utilizes precipitate parts, that of the sample are to be counted and delimited from interference objects. Is on this Wise location and size of the sample to a predeterminable accuracy the circle diameter can be determined after a known ten procedures are calculated and output. He provides information about the antigen concentration of the sample.  

As part of the process, the size of a reference punch hole is used measured to calibrate the system. To find the next Most punch hole in the next hole field then only needs the location the calibrated mask to be changed in the X-Y plane since all punch holes have a sufficiently exact same diameter.

The location and size of the punch hole or the precipitate ring is done by iteratively changing the position and size of the mask found until these have a minimum or maximum mean Gray value achieved with the largest possible mask diameter.

The advantages of the method are in particular in that the samples are free from subjectivity with sufficient Precision measured and compared. Due to the ge selected image evaluation method, the samples are despite the irregularity moderation in their position and geometry as well as in the picture quality activity is reliably recognized and measured. Ergonomic loads for the staff as well as a time-consuming and operation and evaluation tending to errors.

The use of a high-end is particularly user-friendly detaching flatbed scanner as an image recording device.

Instead of such a scanner, a black and white CCD camera can also be used with macro zoom optics can be used with good success. Here can advantageously a han for sample positioning retrofit conventional plotter by instead of the plotter pen tes a simple slide is clamped. He also stands like the capturing camera and the personal computer after completion sample measurements for other tasks. The individual steps are program-controlled and ver do not require any special knowledge from the specialist staff.

Using an exemplary embodiment using a CCD camera and a plotter the invention will be explained in more detail.

In the accompanying drawing:  

1 shows a program flow diagram for the process sequence;

Fig. 2 shows the schematic structure of the measuring devices for performing the method;

Figure 3 pens a slide in exchange for a conventional plotter.

Fig. 4 is a plan view of a sample plate; and

Fig. 5 is a Programmflußbild that Probenausmessung veranschauli accordingly.

The automated work steps for evaluating a serum sample according to the single-radial immunodiffusion method are shown in FIG. 1. First, the operator places a plate 1 , as shown in FIG. 4, of course without sample numbering, on a defined position on the plotter of a plotter 2 with the gel facing down. On the plate 1 , punch holes 3 , around which the samples 3 'are spread out, are introduced in such a way that they fall into an imaginary grid, exactly one punch hole 3 per grid or hole field. Then a slider 4 used in place of a plotter pen is positioned cf. ( Fig. 3) the plate 1 so that there is a first sample 3 'under a fixed camera 5 . The camera 5 , a black and white CCD camera, can if necessary be adjusted on its tripod 6 under control on the monitor so that the sample 3 'appears tig and sharp, whereby all hole fields of the plate 1 are positioned with respect to the plotter board . In addition, the lighting fixtures are fine-tuned. All further work steps take place fully automatically, controlled by a personal computer 7 .

As soon as the image of the first sample 3 'is stored in the personal computer 7 , the plotter 2 begins with the positioning on the next sample 3 ' by moving the plate 1 under the camera 5 to the corresponding hole field. For this purpose, the slide 4 clamped in place of the plotter pen acts on the sample plate edges in the center. The slider 4 ( FIG. 3) has the same geometry in the clamping area as the plotter pins matching the plotter 2 , only a milled groove 8 prevents rotation of the shaft. The slider 4 is cuboid, its side edges are 15 mm in length in the exemplary embodiment. About a grub screw 9, it is adjustable in height 50 so that it just does not touch the plotter panel.

The video signal of the first sample supplied by the CCD camera is in control digitized using a frame grabber card and as Grayscale matrix in a graphic file format on the hard disk saved, then to a defined medium brightness converted, insignificant details become by means of low pass filtered out and contrast enhancement is carried out.

The fact is used that the dark Precitathof the sample 3 ', which appears circular with a variable diameter ( Fig. 4), is located around a lighter punch hole 3 with a constant diameter.

As shown schematically in Fig. 5, the image processing software is now looking for the bright punch hole 3 in the center of the image field as a search feature by moving a circular mask on the image field so that its mean gray values result in a minimum. The center of gravity in the XY plane and the size of the mask are changed iteratively until the mean gray value has reached its minimum with the largest possible radius. Since the true diameter of the punched hole 3 is sufficiently known, the computer can use it to calculate the scale of the image and calibrate the image processing system.

The diameter of the associated precipitate ring of the sample 3 'is determined by calculating the mean gray value of the circular ring-like area between the punched hole 3 and a larger circle concentric with the punched hole 3 . The diameter of the mask is changed until the mean gray value has a maximum with the largest possible diameter. Since the precipitate courtyard is not always concentric with the punch hole 3 , the center of the circle can also shift slightly. The diameter and center of gravity of the mask are changed iteratively until the average gray value is at its maximum at the greatest possible radius. The mask diameter thus represents the measured value.

The computer records the next image of the second sample, whereupon the plotter 2 begins to position another hole field of the third sample under the camera 5 .

The punching hole 3 , which is now known in size, is now found for the second sample during image processing in the manner described above and, analogously, the diameter of the precipitate of the second sample 3 'is determined. If all other samples 3 'have been measured one after the other, the results are processed by a statistical calculation method based on the evaluation program and the quantitative characteristics of the preparation are determined and output in the form of a measurement report.

Instead of a CCD camera, a high-resolution scanner is also very suitable for image acquisition. The plate 1 is positioned by means of a suitable frame for the scanner. The scanner records every single hole field, whereupon the evaluation is carried out with the same steps. The use of a scanner not only simplifies the outlay on equipment, but also the manual adjustment work when setting up the measuring station.

Claims (8)

1.Procedure for the investigation of antigen-containing blood serum samples which were introduced into punch holes of an antibody-containing gel plate for comparison with standard samples containing antigen, whereby and by simple radial immunodiffusion (RID) a precipitate ring was formed around each punch hole, hole field for hole field of the plate ( 1 ) optoelectronically scanned, stored as a gray scale raster image and evaluated as image processing as follows:

• a) Determining the position of each punch hole ( 3 ) in the respective hole field by iteratively moving a software-formed mask in the XY plane, and at least once determining the size of a reference punch hole ( 3 ) by additionally changing the size of the mask, until the greatest possible coverage with the reference Punch hole ( 3 );
• b) sizing the Präzipitatrings (3 ') by iterative size and position change of the mask around each found punched hole (3) and the punch (3) surrounding Präzipitatring (3') up to the maximum coverage with the Präzipitatring (3 '), wherein carried out a calibration of the magnification with the aid of the known size of the measured reference-punched hole (3) and wherein the size of Präzipitatringe is (3 ') adjusted to be examined blood serum samples with the size of Präzipitatringe (3') of the standard samples ver.

2. The method according to claim 1, characterized by iteratively changing the position and size of the mask with respect to a bright punch hole ( 3 ) and the surrounding precipitate ring ( 3 ') until the masked image section has a maximum average gray value with the largest possible area. 3. The method according to claim 1, wherein several reference punch holes ( 3 ) are scanned for calibration of the system, stored and evaluated, the relevant reference punch holes ( 3 ) being selected at random. 4. The method of claim 1, wherein a flatbed scanner as an electronic image acquisition  device is used. 5. The method according to claim 1, wherein a black and white CCD camera ( 5 ) with macro zoom optics is used as an electronic image recording device. 6. The method according to claim 5, wherein after each hole field recording, the plate ( 1 ) by a further res hole field with respect to the CCD camera ( 5 ) is shifted. 7. The method according to claim 6, wherein a plotter ( 2 ) with a instead of the plotter pin clamped cuboid slide ( 4 ) for positioning the plate ( 1 ) is used. 8. The method of claim 1, wherein a PC as a control computer, image processing device and is used for statistical evaluation of the measurement results.