DE3226906A1 - Method and device for determining the size of very small particles in test samples, in particular for measuring agglutinations - Google Patents

Abstract

Method for determining the size of very small particles in test samples (5), in particular for measuring agglutinations, a laser beam (1a) being guided onto the test sample (5) and the reflection and/or scattered radiation of the particles situated in the probe (5) being measured and the direct reflection being blocked out at the sample carrier (4) and the focus diameter of the laser beam (1a) being less than/equal to the smallest particle size to be measured. <IMAGE>

Description

Method and device for determining the size of

smallest particles in test samples, especially for measuring agglutinations The present invention relates to a method for determining the size of the smallest Particles in test samples, in particular for measuring agglutinations.

Such methods are used, for example, to determine blood groups. Blood group tests are currently often carried out purely visually by using certain degrees of agglutination can be determined by visual inspection. This determination but is imprecise and already has led to many incorrect determinations, because it makes it difficult to identify certain blood subgroups.

So-called transmission methods are also already known.

With these, a pure absorption measurement is carried out. Here exist but also inaccuracies, since it cannot be distinguished whether z. B. a large or several small particles are present, but their amount is the same Cause absorption. But it is precisely the size of the particles that makes a statement the blood subgroup to be determined.

The invention is based on the object of a method and a device to create, with which the size of the individual particles can be measured precisely, in order to be able to make a precise determination of agglutinations in this way.

According to the invention this is achieved in that a laser beam the test sample passed and the reflection and / or scattered radiation in the sample located particles is measured, the direct reflection on the sample carrier is faded out and the focus diameter of the laser beam is less than / equal to the smallest the parcel size to be measured. It is particularly advantageous if after the exit from the laser the laser beam is widened and the widened Parallel beams then focused in the plane of the particles to be measured will. The inventive use of laser radiation as a measuring beam is allows a focus to be achieved that is of the order of magnitude of the to measuring particle lies. Here is a focus of up to 1 Fm and smaller diameters achievable. This makes it possible for the maximum particle size to have a focus size and particle size match and maximum absorption and reflection occur, so that a signal peak occurs here in the measurement signal and thus an exact determination the existing agglutination is possible, which is due to the respective characteristic Particle size is marked. In the event that particles smaller than the focus size are present, the absorption and thus also the reflection is lower and thus also the resulting measurement signal. If there are larger particles than the focus size, this is expressed by the fact that saddles are present in the measurement signal, so that can also be precisely determined by means of the method according to the invention whether the characteristic particle size has been exceeded.

Furthermore, it can be expedient according to the invention if the focus of the expanded parallel beams is variable. Thus, an adaptation of the measurement method to the expected particle size.

In a further embodiment of the invention it can be provided that the transmission of the forward scattered radiation of the particles can be measured. the Forward scattered radiation emerges on the back of the test sample, namely together with any existing radiation. By doing so in a further advantageous embodiment of the method according to the invention, the forward scattered radiation after passing through the sample is hidden, the Real absorption can be measured. This can be increased by coloring the sample.

Especially with small agglutinations, where mainly scattered light occurs, which occurs especially with latex particles in the size of the wavelength of approx. 632.8 nm is the case, it is important to be able to measure the forward scatter. Because there is practically no reflection.

The invention also relates to a device for determining the size of the smallest particles, in particular for measuring agglutinations, in particular for carrying out the method according to the invention as described in claims 7 to 14 is included.

On the basis of the exemplary embodiments shown in the accompanying drawings the invention is explained in more detail.

1 shows a basic view of a device according to the invention, 2 shows an alternative embodiment of part of the device according to the invention according to FIG. 2, FIG. 3 shows a basic view of a further embodiment of an inventive Contraption.

A device according to the invention consists of a laser 1, which is a parallel, coherent and monochromatic radiation la is generated. The radiation beam diameter can range from 0.3 to 1 mm. The laser 1 is an expansion optics 2, consisting of a lens system, connected downstream in the beam path, with which the laser radiation la initially spread, d. H. is widened. The expansion optics 2 is followed by one Converging lens 3 with which the expanded laser beam la is focused.

Here, a focus can be made up to a focus diameter of about 1 µm and smaller. The lenses of the optics 2 and the lens 3 have one special patency and compensation for laser light, so that about 100 ° Ó permeability is achieved. The converging lens 3 is followed in the beam path by a sample carrier 4 from translucent material, in particular glass. Are on the sample carrier 4 one or more samples 5 to be examined are arranged. For these samples 5 can it is z. B. blood samples or latex suspensions. The arrangement of the sample carrier 4 to the converging lens 3 is such that the focal point of the converging lens 3 on the surface of the sample carrier 4 lies within the sample 5.

A receiving device is located in front of the sample 5 in the direction of radiation 6 arranged. With this receiving device 6, the reflected from the sample 5 can and scattered light are captured. Under scattered radiation, the radiation is closed understand that results from the natural radiation of the particles in the sample 5. These Natural radiation is created by the particles absorbing energy and has the same wavelength like the absorbed radiation. The receiving device 6 is at a small distance above the sample 5 arranged and allows the entire reflected Capture radiation. The receiving device 6 has approximately a diaphragm in the middle 7, which on the one hand allows the incidence of radiation and on the other hand continues to do so serves to reduce the direct reflection radiation, which is directed vertically upwards from the sample carrier 4 is reflected, so that they do not affect the measurement signal can. The size of the receiving device 6 is such that the entire possible Reflection area of the test sample 5 is covered. The receiving device 6 consists advantageously from a photodetector. The converging lens 3 is in the longitudinal axis of the radiation Movable back and forth, see double arrow. This is a change the focus size possible, so that an adaptation of the focus size to different Particle sizes in the test sample 5 can be carried out. Furthermore, the receiving device 6 can also be arranged to be displaceable to and fro in the longitudinal axis of the radiation to be able to recognize the reflection characteristics. The entire device is like this arranged and the individual parts are connected to one another, so that they one the sample carrier 4 can be gradually moved from sample to sample. Therefore a continuous measurement can be carried out with the device according to the invention and a large number of samples are examined one after the other.

The device described above thus enables the measurement of the entire Reflection radiation, where the size of the reflection signal is a measure of the particle size is. Because the invention provides that the maximum to be recorded Particle size should correspond to the size of the focus. Are larger particles in the Measurement sample, the size of which is larger than the focus diameter, arise in the measurement signal not spikes, but saddles, so that these can also be recognized.

An alternative embodiment to the device according to FIG.

1 is shown in FIG. 2, this being different from that in FIG. 1 distinguishes that the receiving device is designed differently. This receiving device consists here of a so-called integrating sphere 10. This sphere 10 is provided with an inlet opening 11 for the laser radiation la, which with a funnel-shaped edge 12 can be bordered.

Its outlet opening 13 is arranged directly above the sample 5, so that the radiation reflected by this is completely absorbed by the sphere 10 can be. Here, the size of the opening 13 is chosen such that the entire Reflection area is detected.

Through the integrating sphere 10, the whole of the test sample 5 reflected and possibly backscattered light is collected and sent to the photodetector 15 passed in the spherical wall and detected there as a measurement signal.

In Fig. 3 is a further embodiment of the device according to the invention shown. This differs from that of FIG. 1 in that below of the sample carrier 4 still has an additional measuring device for the forward scattering resulting radiation and is arranged for the irradiation. This measuring device expediently consists of an integrating ball 15, whose entrance opening is arranged exactly in the middle under the focus of the beam path la and whose size is dimensioned such that all of the scattered light and the irradiation be caught. This additional measuring device below the sample 5 the forward scattering and the transmission are detected, d. H. the one not reflected Part of the measuring beam.

In addition, in front of the inlet opening of the integrating sphere a diaphragm 16 is arranged, the size of which is approximately adapted to the exit beam, the forward scattered radiation can be masked out so that only that portion of the radiation remains is detected, which is absorbed and / or irradiated. The Ulbrich sphere 15 is connected together with the measuring device arranged above the test sample, so that it can be moved together with it. The integrating sphere 15 is also suitable for purely densitometric measurements, e.g. for evaluating Electrophoresis.

Claims (14)

Claims: Method for determining the size of the smallest particles in measurement sample, especially for measuring agglutinations, d a d u r c h g e k e n n -z e i c h n e t that a laser beam is directed onto the test sample and the reflection and / or scattered radiation of the particles located in the sample is measured, wherein the direct reflection on the sample carrier is masked out and the focus diameter of the laser beam is smaller than / equal to the smallest particle size to be measured. 2. The method according to claim 1, d a d u r c h g e - k It is noted that after exiting the laser, the beam widened and the expanded parallel rays are then in the plane of the to be measured Particles are focused. 3. The method according to claim 1 or 2, d a d u r c h g e k e n n z e i c h n e t that the focus of the expanded parallel beams is variable. 4. The method according to one or more of claims 1 to 3, d a d It is indicated that the reflection and the forward scattered radiation and / or radiation can be measured. 5. The method according to one or more of claims 1 to 4, d a d u r c h e k e n n n e i c h n e t that the forward scattered radiation has passed through is measured by the sample. 6. The method according to claim 4, d a d u r c h g e -k e n n z e i c h n e t that the forward scattered radiation is masked out after passing through the sample will. 7. Device for determining the size of the smallest particles in test samples, in particular for measuring agglutinations, in particular for performing the Method according to claims 1 to 6, g e -k e n n z e i c h n e t d u r c h a light source designed as a laser (I), in whose beam path (la) an expansion optic (2) is arranged and behind this a converging lens (3) whose focal point is on the surface of a sample carrier (4), in the direction of radiation at the focal point a photoelectric receiving device (6) for measuring the reflected radiation is arranged. 8. Apparatus according to claim 7, d a d u r c h g e -k e n n z e i c h n e t that the receiving device (6) is centered directly above the focal point is arranged and has a passage opening (7) for the focused radiation. 9. Apparatus according to claim 7 or 8, d a d u r c h g e k e n n shows that the converging lens (3) can be changed with respect to its focal length is. 10. Device according to one or more of claims 7 to 9, d a d u r c h g e k e n n n z e i c h n e t that the receiving device (6) is plate-shaped is designed as a photodetector. 11. The device according to one or more of claims 7 to 9, d a d u r c h g e k e n n n z e i c h n e t that the receiving device consists of an Ulbricht Ball (10) has two openings (11, 13) arranged one behind the other for passage the focused radiation and a photodetector arranged in the spherical wall (14). 12. The apparatus of claim 11, d a d u r c h g e -k e n n z e i c h n e t that the upper inlet opening (11) of the integrating sphere (10) one funnel-shaped Edge (12) possesses. 13. The device according to one or more of claims 7 to 12, d a d u r c h e k e n n n z e i c h n e t that below the sample carrier (4) and of the focus another receiving device, in particular designed as an integrating sphere (15) is arranged to receive the irradiation and the forward scattered radiation. 14. The apparatus of claim 13, d a d u r c h g e -k e n n z e i c h n e t that in front of the inlet opening (16) of the integrating sphere (15) a Diaphragm (17) is arranged, the diameter of which corresponds to the exit beam from the sample is adapted.