DE10060560A1 - Microtiter plate used for toxicological testing of pharmaceutically active ingredients and cosmetics, comprises a plate body with passages, and an infra red-permeable base formed on one side of the plate body - Google Patents

Abstract

Microtiter plate (10) comprises a plate body (12) with passages (14), and an infra red (IR)-permeable base formed on one side of the plate body. Preferred Features: The plate body and the base are separate elements. The base has a lattice or a perforated foil in the region of the passages. The base is made from ZnSe, germanium, silicon or other IR-transparent materials in the region of the passages. The base has a metal surface.

Description

The invention relates to a microtiter plate for infrared measurements with a plate provided with through holes body and one trained on one side of the plate body bottom and a microtiter plate, in which the Bo which is additionally designed to be diffusely reflective.

Such microtiter plates are known from DE 43 31 596 A1.  

For a large number of samples to be analyzed spectroscopically manageable and efficient to investigate were in the Past culture dishes with a variety of side by side other wells, so-called microtiter plates, ent wraps. A miniaturization of the test or Sample batches reached. It is also possible to use Stan Standardization of the formats of such microtiter plates is a direct one Evaluation on special microtiter plate photometers respectively. Such microtiter plates are particularly common toxicological tests of active pharmaceutical ingredients and cosmetics ka, or in connection with diagnostic examinations, at who have to test a larger sample volume, for Commitment.

The light beam, for example an infrared (IR) lamp, is in these measurements usually by the one to be analyzed Sample directed before it is on a reflective surface of the Sample carrier is reflected and from there, if necessary after further repeated scatter z. B. on a parabolic reflector a detector is steered. Now the wavelength of the measurement varies gradually and in parallel the reflected ones Signals recorded, so you get one for analysis specimen characteristic reflection spectrum. use but above all find so-called Fourier transform IR Spectrometer, in which the sample to be analyzed simultaneously with light of all wavelengths in a certain spectral range is irradiated and the reflected signals Fourier be transformed. About the comparison with standardized Measurement samples, e.g. B. Solutions with known concentrations of one Active substance or an indicator, body fluids healthy of the subjects, etc. can be determined on the content of the  Substances, e.g. B. toxins or disease markers, who closed the.

The recordings of Infrared spectra recognized.

In the above-mentioned DE 43 31 596 A1 a sample carrier is described which contains 4 × 13 = 52 wells for the introduction of samples in a grid. The samples are usually introduced as a liquid, but this is then dried before the measurement, so that the measurement is carried out on the dried-out rest of the sample, ie on a solid sample. The surface of the bottoms of the wells is made of a diffusely reflective material, e.g. B. various Me metals (aluminum, silver, platinum, gold) or alloys, formed from. Another variant described is the bottom of the wells from at least partially transparent material such as, for the radiation used. B. CaF ₂ , ZnSe, Po lyethylene or perfluorinated polyethylenes, and to coat the underside of the radiation-transmissive carrier with the said diffusely reflecting, preferably metallizing materials.

The disadvantage of these known microtiter plates is that the reflective bottom of the wells no IR trans mission measurements, e.g. B. for recording absorption spectra tren, can be carried out. With this type of measurement the permeability of a sample or the absorption of a Substance measured and the penetrated radiation by means of of a detector. From a continuous specter of the incoming IR light is absorbed into the beam  lengang brought the characteristic waves for him length out; the resulting IR spectrum is then measured sen. Such transmission or absorption spectra are today the main routine methods of spectral analysis in the organic chemistry and organic chemistry.

The invention is therefore based on the object, microtiter Provide plates where this disadvantage is avoided becomes.

With a microtiter plate of the type mentioned at the beginning se task solved according to the invention in that for implementation of transmission measurements of the soil overall for infrared is designed to be translucent.

The object of the invention is based on this Wei se completely solved.

The fact that the bottom of the microtiter plate for the first time no dif fus reflective surface, but completely IR is designed to be translucent, the passage of the Beam of light through the sample and through the adjacent floor e.g. B. on a detector mounted in the beam path light. Becomes the wavelength of the incoming infrared light varies, a specific one can be made for the respective sample IR absorption or transmission spectrum obtained.

A microtiter plate according to the invention is particularly preferred, where the plate body and the bottom are separate elements.  

This results in special advantages in manufacturing such a microtiter plate. It is often required lich, due to the necessary permeability of the soil, the sen from separate material, e.g. B. a metal grid, to fer term. Furthermore, there are advantages for the customer when cleaning the microtiter plate. After graduation During the analysis, the plate body is simply separated from the floor and discarded the samples. Both parts can then simply ge are cleaned and are available for further use Available. There is no risk of liquid residues remain in the wells and u. U. Kontami cause nations in further analyzes.

In terms of the nature of the soil, it is according to the invention particularly preferred if the floor is at least in the range of Through holes a net, grid, a perforated film, ZnSe, Ge, Si or other IR-transparent materials, e.g. B. KRS-5. Designated under the trade name KRS-5 neten substance is a material based specially grown thallium bromide crystals.

With sufficient surface tension of the analyte Nets or grids or perforated foils are the sample suitable carrier to fixate the sample and the complete passage of the irradiated infrared light enable. The floor is also suitable for this purpose continuous materials made of ZnSe, Ge, Si or other IR transparent materials, e.g. B. KRS-5 on which the samples are based be worn.  

Because of these advantages mentioned is an inventive Microtiter plate in which the bottom is at least in the range of Through holes on the above materials also includes within the scope of the invention.

Furthermore, a microtiter plate according to the invention is preferred in which the microtiter plate has a substantially rectangular, standardized shape with a grid of, for. B. 8 × 12 = 96, 16 × 24 = 384 or 32 × 48 = 1,536 (generally: 2 ⁿ × 3.2 ^n-1 ) has through holes. The through holes ("wells") are also standardized in their shape and dimensions.

This has the particular advantage that this training the microtiter plate is a common, established one Standard format. From different providers this pipetting devices, for. B. multichannel pipettes with 8 channels or specially adapted IR photometer that this Can record plates and carry out the analysis directly, provided. As a result, routine analysis, e.g. B. in diagnostic laboratories or clinics or in large industrial laboratories, time-saving, practical work possible.

Because of these advantages of standardizing the panels formats is also the subject of the present invention a microtiter plate for infrared measurements with a Through holes provided plate body and one diffuse reflection formed on one side of the plate body soil, the microtiter plate being a substantially rectangular standardized shape with a grid of z. B.  8 × 12 = 96, 16 × 24 = 384 or 32 × 48 = 1,536 rounds has holes.

The standardized microtiter plate format means that water microtiter plate according to the invention, for. B. on a large scale chem scope, also reflectance measurements of the description above Nen possible using the advantages described above Lich.

A particularly preferred development of this invention According microtiter plate is that the bottom is rough hey d. H. has diffusely reflective metal surface.

Metals or rough metallized surfaces stand out by from that the measuring radiation, z. B. infrared light, be reflect very well. This measure therefore has the advantage partly that hereby met the constructive requirements be a diffusely reflective floor of the interes here able to realize.

Further advantages and features of the invention result from the exemplary embodiments, which are described below with reference to the figures are explained. Show it:

Figure 1 is a plan view of a schematic section of an embodiment of the microtiter plate according to the invention.

Fig. 2 shows a cross section through a schematic embodiment of the inventive microtiter plate;

Figure 3 is a plan view of a schematic embodiment example of the microtiter plate according to the invention with the standard grid of 8 × 12 through holes.

Figure 4 is a cross section through an embodiment of the inventive microtiter plate with grid floor for transmission measurements.

Fig. 5 is a cross section through an embodiment of the microtiter plate according to the invention with reflect the metallized ground with a rough surface for reflection measurements;

Fig. 6 is a schematic representation of a transmission measurement with an embodiment of the microtiter plate OF INVENTION to the invention;

Fig. 7 is a schematic representation of a reflection measurement with an embodiment of the inventive microtiter plate.

In Fig. 1, a microtiter plate, a section of which is shown, is designated overall by 10 . A plate body 12 and a through hole 14 are shown. The plat body 12 is preferably made of a plastic, for. B. poly styrene.

In the schematic representation of FIG. 2, a detail of the microtiter plate 10 is shown in lateral cross-section. In this case, a grid 16 , a net, a perforated film or the like rests on the underside of the plate body 12 . The sample to be analyzed is placed in the through hole 14 on the grid 16 . Due to the surface tension of the liquid sample (cohesion in the liquid, adhesion to the grid), passage through the grid 16 is prevented. At the same time, the complete passage of an IR light beam through the sample, for example onto a detector, is made possible. The sample is usually first introduced in liquid form and then dried.

The through holes 14 are - if transmission measurements are to be carried out - forms IR-permeable bottom. ZnSe, Ge or so-called KRS-5 can be used as IR-permeable materials, which are understood to mean specially grown thallium bromide crystals.

Fig. 3 shows a plan view of a schematic representation of an embodiment of the microtiter plate 10 according to the invention with a standardized rectangular shape and a grid of 8 × 12 = 96 (generally: 2 ⁿ × 3.2 ^n-1 ), in the plate body 12 , also standardized through holes 14 .

Fig. 4 shows a detailed cross section through an exemplary embodiment of the microtiter plate 10 according to the invention for transmission measurements. The sample to be analyzed is applied here through the through holes 14 in the plate body 12 , analogously to FIG. 2, onto the grid 16 forming the bottom.

FIG. 5 shows a detailed cross section through a guide, for example from the microtiter plate 10 according to the invention for reflectance measurements. For this purpose, the sample to be analyzed is applied into the through holes 14 of the plate body 12 on a diffusely reflecting metallized floor 18 with a rough surface 18 a.

Fig. 6 shows the schematic representation of a TRANSMISSI onsmessung with an embodiment of a section of the microtiter plate 10 according to the invention. Here, an infrared radiation source is denoted by 20 , the light rays of which pass through the through bores 14 made in the plate body 12 onto a sample 22 to be analyzed on the adjacent grid 16 and hit a detector 24 . The detector 24 then transmits the data to a connected computer to create a spectrogram.

Fig. 7 shows the schematic representation of a Reflekti onsmessung with a cutout of an embodiment of the microtiter plate 10 according to the invention. Here, the infrared radiation source 20 sends the light rays through the sample 22 , which is located on the reflective metallized floor 18 with a rough surface 18 a on the underside of the plate body 12 and the through holes 14 shown in FIG. 7. The rays that have passed through the sample 22 to be analyzed are reflected from the rough surface 18 a of the reflective metallized bottom 18 onto a parabolic collector 26 and directed onto the detector 24 . The data are then also transmitted to a downstream computer for creating a spectrogram.

It is understood that the exemplary embodiments described in can be varied in many ways without the order start leaving the present invention.

Claims (10)

1. Microtiter plate ( 10 ) for infrared measurements with a through-holes ( 14 ) provided plate body ( 12 ) and a on one side of the plate body ( 12 ) formed bottom, characterized in that the bottom is designed to be transparent to infrared light for carrying out transmission measurements is. 2. Microtiter plate ( 10 ) according to claim 1, characterized in that the plate body ( 12 ) and the bottom are separa te elements. 3. microtiter plate ( 10 ) according to claim 1 or 2, characterized in that the bottom has a network at least in the region of the through holes ( 14 ). 4. Microtiter plate ( 10 ) according to claim 1 or 2, characterized in that the bottom has a grid ( 16 ) at least in the region of the through holes ( 14 ). 5. microtiter plate ( 10 ) according to claim 1 or 2, characterized in that the bottom has a perforated film at least in the region of the through holes ( 14 ). 6. Microtiter plate ( 10 ) according to claim 1 or 2, characterized in that the bottom has at least in the region of the through holes ( 14 ) ZnSe, Ge, Si or other IR-transparent materials. 7. microtiter plate ( 10 ) according to claim 1 or 2, characterized in that the bottom has at least in the region of the through holes ( 14 ) KRS-5. 8. microtiter plate ( 10 ) according to any one of claims 1 to 7, characterized in that the microtiter plate ( 10 ) has a substantially rectangular standardized shape with a grid of 8 × 12 = 96, 16 × 24 = 384 or 32 × 48 = 1,536 Has through holes ( 14 ). 9. microtiter plate ( 10 ) for infrared measurements with a through-hole ( 14 ) provided plate body ( 12 ) and a diffusely reflecting bottom formed on one side of the plate body ( 12 ), characterized in that the microtiter plate has a substantially rectangular, standardized shape with a Has grid of 8 × 12 = 96, 16 × 24 = 384 or 32 × 48 = 1,536 through holes ( 14 ). 10. microtiter plate ( 10 ) according to claim 9, characterized in that the bottom has a metal surface.