DE3915920A1 - Micro-mechanical structures for storing and testing substances - e.g. for disease diagnosis, is made of inert material, e.g. glass, and has defined pattern of depressions, cavities, etc. - Google Patents

Abstract

Micromechanical structures with cavities, reservoirs, openings, channels, depressions, elevations and similar features, used to examine test substances for possible changes in physical and/or chemical properties, are made of (or contain) semiconducting elements (Gp. III-VIII), or glass, ceramic, diamond or carbon. They are prepd. by 'non-splintering' methods, pref. chemical etching. The structure comprises a block and cover of the same material, esp. silicon (or other single-crystal material) or glass. The block has a number of depressions of partic. size, shape, distribution, etc., and the cover has elevations which match these exactly so as to provide a hermetic closure. USE/ADVANTAGE - These structures are used for evaluation and documentation in biotechnology, genetic engineering, cell or immune research, or for other medical, agricultural or environmental research. They allow dangerous substances to be stored and handled (for testing, etc.) safely, and provide simple process control and evaluation of tests on very small amts. of sample. The structures can be made inexpensively on a large scale from inert materials.

Description

The invention relates to a micromechanical structure for the purposes of Biotechnology, in particular against illness and hunger, for purposes biotechnology, genetic engineering, cell research, for pharmacy, for healing and research, in particular of previously incurable diseases, also for agricultural research to find new food sources and energy sources to open up and restore the environment. For purposes of medi zin, z. B. blood tests but also of tissue or cells, for. B. Antibody, antigen immobilization for the production of monoclonal antibodies, for the production of antibiotics, insulin, but also for healing medium, sera, bacteria and other substance tests and ver equal attempts. There is always the task of a safe controlled Dealing with the respective substance before, during and after an examination chung, reaction or the like, especially if the substances Can pose a danger to the environment.

In order to be able to fulfill the purposes mentioned above, in particular for Combating disease and hunger in the world, it is necessary at Un examinations, reactions, tests, comparative examinations and examinations Series of tests with especially dangerous substances are also safe to be able to handle even the smallest amounts of substance.

The object of the invention is a clean, safe storage and hand have substances that are or can become dangerous - be it before, during or after an examination, reaction, test or similar chem - to facilitate or ensure.

This problem is solved by a microstructure according to the patent claim 1. This microstructure has many advantages. It can be large Quantities can be produced inexpensively. It is for a safe one Storage of a variety of substances as samples for tests, for loading actions, for investigations, for comparisons, for reactions etc. is suitable. The arrangement of suitable cavities in the structure Structure in the manner of a matrix or an array allows simple processes  control, simple investigation and execution of desired reak ions, of the desired small amounts of substance and their targeted loading action and investigation. The structure with the cavities consists of inert material, i.e. it changes in the examinations, treatments not lungs, the cavities are and can be closed reliably not attacked by most pollutants.

Training and further developments of the invention are further claims as well the description and drawing of an embodiment can be seen. Combinations of these features also belong to the invention. In the drawing shows

Fig. 1 is a structure with a single cavity and a specific surface orientation of the crystalline material;

Fig. 2 shows a modification of Fig. 1;

Fig. 3 is a structure made of crystalline material;

FIG. 4 shows a structure modified from FIG. 3;

FIG. 5 shows a structure in a constructive modification of FIG. 1;

Fig. 6 shows a modification to Figure 2 or 4, wherein a structured part in the middle between two different parts is arranged (sandwich structure).

Fig. 7 shows a modification of Fig 6, with the bottom plate and top plate to additionally arranged facilities.

FIG. 8 shows a further modification to FIG. 6 or 7 with additional layers or plates;

Fig. 9 is an embodiment with measuring or detecting means;

Fig. 10 shows a structure with measuring and detection device and, if appropriate, memory;

FIG. 11 is a transistor device with a biosensor, in particular field effect;

FIG. 12 shows a modification of the embodiment according to FIG. 11;

FIG. 13 is a device for detecting specific substances in fluids;

FIG. 14 is a device for the automatic investigation Documenta tion of the test results;

FIG. 15 is a heat exchanger, in particular radiator plate;

FIG. 16 is a top view of FIG. 15;

Fig. 17 shows a modification to Fig. 15 and

Fig. 18 is a plan view of Fig. 17.

As shown in FIG. 1, a structure 1 consists of walls with one, preferably several cavities therein, for receiving small amounts of substance, and the block is closed by a cover 3 . Block 1 and cover 3 are made of crystalline material, such as semiconductor material. Likewise, for the closure of the container according to the invention with a second mask, a counterpart is produced = cover 3 , which has corresponding elevations 4 corresponding to the recesses 2 , since the masks are geometrically identical. The mask technique allows a high precision in the production; it is known per se from semiconductor technology.

In the technique mentioned, it is advantageous to use a crystal direction-dependent anisotropic etching process because, using the self-limiting effect of ( 111 ) crystal planes, recesses can be realized with high geometric precision and very tight tolerances. The container in FIG. 1 can be made of ( 100 ) silicon, the laterally delimiting ( 111 ) planes having an angle of 54.7 ° to the wafer surface. However, the invention is not limited to the above-mentioned etching techniques. Other known ways of making recesses in semiconductor or similar crystalline lines material can be used, such as laser beam drilling.

The lid 3 can be provided with an elevation 4 , which has the same 54.7 ° inclination to the crystal surface as the container block 1 in the area 2 and thus seals perfectly. This also applies if the cover has a large number of elevations and the block 1 has a large number of wells 2 . If the accuracy of fit, the elevations and depressions on cover 3 and block 1 produced in the etching process are not sufficient for individual applications of particularly dangerous substances, a circumferential seal can also be used. Fig. 5 shows an embodiment which in turn corresponds to the 54.7 ° slope of the elevation 4 of the lid and form a closure with another. Adhesives or other joining techniques can also be used to increase tightness. In particular, a laser beam can also be used in the seam welding process on the circumferential edge of the lid. A variety of cavities 2 is not limited by size, design and distribution in the block of the container.

The cavities 2 (and the elevations 4 ) can in particular be square, rectangular, circular, oval or diamond-shaped. You can taper downwards or expand - see Fig. 1 and Fig. 2 - or keep the same cross-section, if they are drilled, for example, with a laser beam ( Fig. 4). They can also have other cross sections or shapes (form openings, channels).

An additional layer or plate 5 serves as a carrier or intermediate carrier (removable again), advantageously made of the same material, for example silicon or the like, as the bottom of the container, also hermetically sealing.

The worked out of a block material structure 1 forms in a geous manner (for mass production) a flat plate with continuous cavities 2 such as openings, channels or the like desired shape wet chemically etched with advantage of silicon while the lid 3 and bottom 5 from with this material Structure 1 preferably well connectable, in particular hermetically sealable material such as glass, quartz glass, glass ceramic or silicon plastic or silicon metal composite material.

In Fig. 6, as shown, the bottom 5 is still covered to the structure 1 with a layer 7 which z. B. a filter layer, a sedimentation layer, an inert, or catalytic or otherwise reactive layer of a material or just absorbent material. A non-woven fabric or other large-pore or with a large open area provided non-woven fabric, fiber fabric, foam or similar permeable structure can be used depending on the application (collecting, storing, reacting). It can be a neutral carrier material or an active carrier material which is used for the layer 7 and below which valves or other devices (see FIG. 8) could optionally be arranged. The block 1 with the cavities 2 advantageously contains these in a grid dimension in XY over the surface of the preferred silicon crystal, arranged as an array or in matrix form (see FIG. 3), so that they are filled with substances, for example, by means of automatic devices. fumigated, inoculated, diluted, depleted, sucked off or the like., can be mixed or reacted. The feed or removal elements are then program-controlled line by line until the entire surface is scanned, as is known per se in automated analyzers or automatic handling machines or robots for medical or other research purposes.

The material of block 1 must in any case be inert to the substance which is to be examined, treated, diluted, mixed or brought to a reaction or is tested for its absence (comparative or anti-test).

Depending on the purpose for which the invention is applied, the cavities for examination or storage (storage containers) can be made larger, in particular in which the cavities 2 in block 1 are only part of sample or examination or reaction chambers - see Fig. 7. The matrix or array arrangement in the XY direction is maintained as described above and also the essentially sandwich-like structure according to Fig. 6. In addition, in the cover plate 3 and in the base plate 5 each of the cavities, a further suitable depression 8 or 9 assigned net, which overall seen the chamber volume or volume of the cavity 2 significantly increased. Now a medium can also be supplied or removed at the drawing level if, for. B. the same medium should be supplied or discharged to all chambers.

As a rule, substances such as solids in a fluid are examined for the purposes mentioned at the beginning; gases in a liquid or gases or liquid in a solid can also be examined. This applies in particular to immune reactions, to the investigation of enzymes or microorganisms. Chemical or physical properties or their changes can be determined in the course of investigations or analyzes of substances / mixtures with regard to one or more properties such as flow, density, surface or boundary effects, special characteristics of particles, permeability, friction, adhesion. In the simplest case, storage under certain conditions such as pressure or vacuum for a certain time can be investigated, or a reaction to this or the absence of a reaction can be investigated under external influence. External influences can be: radiation, heat treatment, application of reagents, measuring the change in material properties in heat, cold, steam, moisture or supplied substances / particles, by using electrical / electrochemical or magnetic means, by using sound, infrasound , Ultrasound. Furthermore, colorimetric, spectrophotometric or fluororometric studies, e.g. B. using reagent layers such as reagent papers are performed as layer 7 . Heating and / or cooling elements can in the form of tempered media in channels 10 and 11 z. B. through the plates 3 and 5 to the chambers 2 or thermocouples, in particular pellet animal elements can be arranged at least partially in the region of these cavities. Substances can be used with fluorescent labels, with radioactive labels or with enzyme labels with or without carriers, bound or separable, organic or inorganic, with cells or cell fragments, gel or other for the detection of microorganisms, bacteria, viruses and others, but also for the detection of cancer, for the determination of individual substances in the blood or for the determination of the pH value, blood sugar, blood cholesterol or for the determination of narcotics or other substances in the blood. Suitable methods of investigation, especially biological / medical, chemical / physical, are known, especially for blood tests, for the examination of sera etc. Also test methods for other body fluids such as lymphatic fluid, urine etc. are known, depending on whether small particles are marked or unmarked, organically / Inorganic, with or without a carrier of known type, X-rays are recommended, but also examinations with the help of gamma rays, with visible infrared light or ultraviolet light (optical method). Evaluation methods with the aid of light guides are shown, for example, in FIGS. 9 and 10. In studies of the flow properties of substances or mixtures of substances, as shown in FIG. 8, it is advantageous to control the inflow, outflow or both (flow) with the help of microvalves 12 and 13 in the lid or bottom 5 of block 1 with the microcavities 2 Micro valves themselves are known per se (see, for example, EP 02 50 948 A2). They are preferably arranged in the same array or in the same matrix in the XY direction as the cavities 2 in the block 1 and thus provide a simple evaluation option for the respective examinations. A layer 7 can be arranged in the bottom 5 as in FIG. 6. Below the bottom 5 , a further carrier or end plate 14 can be arranged, which also has a detection device, for example photo elements in the same array arrangement, for evaluation to a microprocessor (not shown here). can forward. The lines for supplying and removing substances, reagents, etc. are not shown, nor are the radiation sources, which in FIG. 8 advantageously radiate from above, ie above the cover 3 . The parts 3 and 5 can also in FIG. 8 advantageously consist of glass, quartz glass or silicon ceramic or a silicon composite material and be at least partially transparent, at least partially mirrored. The lid or bottom can also be replaced, at least in part, by foil tapes made of opaque material, e.g. a plastic film can also be glued over the lid 3 , if it contains the microvalves, which creates a hermetically sealed seal, but is pierced by a hollow needle can be. Foils or layers can be optically opaque or opaque, they can be designed as heating layers 10 or heat sink 11 or for speci cal purposes mirroring / non-reflecting, for certain wavelengths through casual, filtering, partially transparent or similar. Carbon or diamond layers and / or mask layers that cover the time or partially the cavity can also be used.

The microvalves can be activated and activated in a manner known per se be driven or in the manner as in the German patent message P 38 11 052.0-31. The reaction in the cavities can then by moving e.g. piezoelectric, magnetic, electro static or similar. A nutrient solution, a mutant, a regance or the like is diluted, enriched, dosed and the Dwell time by closing and opening the micro valves be controlled. The heat treatment or cooling treatment can be carried out using Peltier elements, heat pipes, Thomson-Joule coolers or the like be performed.

As sensors, arranged in the same array in the lowest layer, silicon sensors are again preferred, in particular for investigation of physical or chemical properties such as black white or gray value, contrast, turbidity, transmission, transparency, re flexion, conductivity, resistance, capacity, pressure, elongation, tempera ture volume, quantity, time, etc. For evaluation, the measured values are sent to an egg NEN not shown microprocessor or microcomputer passed. The reading can follow in a manner known per se if the Evaluation is done optically, e.g. B. in the manner of P 38 17 153.8-33.  

The storage or documentation of the data of the measurement or test program and the storage of, for example, patient data or disease data or data from sera or pharmaceuticals can be carried out on the same chip (bottom layer in FIGS . 8 to 10). The storage can be done either with the help of an optical memory, e.g. B. according to DE-OS 38 04 751 with amorphous silicon as a storage medium (bubble memory) or as inte grated semiconductor memory (DE-OS 38 17 153) or with a RAM component (P 37 01 295.9-52). As FIG. 9 shows, it is possible in a simple manner to use an optical waveguide 15 in an optical or optoelectronic evaluation, which passes through the micro-chamber or cavity 2 in block 1 or approaches it and is etched from its jacket in the interesting area and z . B. is coated to bring about a reaction, in particular with substrate.

Modifications of the embodiment according to FIG. 9 are possible in many ways, in particular for photoelectric or other photoelectric evaluation in particular not only with the aid of light guides. The light guides are preferably in V-pits, fixed to the bottom and not only continuously, but also cut obliquely according to the inclination of the pit, and at least partial areas 15 a , 15 b of the light guide 15 (cut surface) or the V-pit are mirrored. The arrangement can be parallel to the pit, transverse to the pit from above or below at a 90 ° angle, 180 ° or the like. The optical fibers are led out and are connected to photocells, such as line sensors or arrays, for the purpose of analog or, preferably, digital reading. The reading can be done in rows and rows, for example by a scanner using a photoelectric line sensor as described in DE-OS 38 04 200. An optical bus can be used for this. A suitable optical data system is described in DE-PS 36 19 778. Transmitter and receiver, in particular diodes, can be integrated in the structural unit. The pits can be adjusted or changed in their V-angle (slope, see DE-OS 36 13 181). Integrated optical waveguides and their structure and applications are described in the magazine Laser and Optoelectronics, No. 4, 1986, pages 323 to 336. On page 338 of the same magazine, applications of optical fiber sensors in medicine are also described.

In Fig. 10, a block 1 with bottom 5 and lid 3 with microcavities 2 is shown, in particular expanded by recesses in the lid 3 and bottom 5 - similar to FIG. 7 - but above the microcavities in array arrangement 2 each treatment openings , Valves, supply and discharge elements, windows, doping areas, etc. are attached in accordance with the chamber volume in the lid 3 , while in the bottom 5, for example, an array of photoelectric cells or a CCD array or a MOS field effect transistor is arranged for reading and Evaluation is connected to an evaluation unit, for example via the aforementioned optical or an electrical bus, in particular with microprocessors of the microcomputers. A light pen 16 scans the array in rows and rows, for example in binary code 8 × 8 microcavities or cells or 10 × 10 for direct digital interrogation. Instead of the light pen 16 , a piezoelectric, a capacitive, a magnetic or an electrical sensor can also be used. The pin 16 is then suitable for applying a voltage, force or light or the like, through the window 17 in the lid 3 through into the chambers 2 of the block 1 for direct readout, for example via a CCD array in the same arrangement as that Mi crocavities or cells, indicated here by the CCD cells 17 '. A MOSFET or a RAM component can also be arranged in the same way. The reading can also be carried out using components of the integrated optics, in particular in a contactless and two-dimensional manner (cf. DE-OS 36 05 018 or US Pat. No. 4,778,989). Instead of the light pen 16 , an ion-selective measuring electrode could also be used as an exchangeable sensor element, in particular for measuring the ion activities in liquids and on tissue surfaces. Such ion selective measuring systems are known and commercially available. They are based on a purely electrical evaluation principle in contrast to the embodiment in FIG. 9, which is used, for example, for the optical determination of the catalytic enzyme activity of a substance sample, the change in spectral properties of an enzyme substrate or its reaction products caused by the enzymatic reaction being recorded per unit of time . The enzyme substrate is assigned to the exposed area of a light guide with which the sample substance to be measured is brought into contact.

In the embodiment according to FIG. 10, an evaluation with the aid of a CCD array, for example according to DE-OS 38 17 153 or with the help of semiconductors according to DE-OS 37 15 674 or with the help of liquid crystal elements, as for example in DE, is recommended -PS 36 02 796. With such elements, a direct storage of a test or analysis result is possible and can be queried at any time, even for individual microcavities.

FIGS. 11 and 12 show optronic / electronic sensors which are adapted to the properties to be investigated and which are generally known under the term “biosensors”. Such biosensors generally work with field effect transistor 18 in silicon technology. Manufactured together, the biosensor has a biological component on the surface that is connected to the gate of the transistor. This biological component or the reagent or enzyme substrate 19 must be capable of the desired reaction. Then you can, after the Ar beitsbereich is optimally set, for. B. at R using one or more voltage sources U 1 , U 2 , apply voltage to drain and source and measure corresponding changes in ion activity. The measurement can also take place in an integrated manner according to FIG. 12 by photoelectric means with the aid of light guides between the transmitter and receiver, such as diodes, lasers. A biosensor of the type in question is described in DE-PS 36 34 573.

In Fig. 13, a sensor on a silicon wafer 20 is shown purely schematically, wherein a sensor chip 21 is caused to react with the substance sample, for. B. a soil sample, a liquid sample, a food sample or a tissue sample with pollutants therein, the part of which, for. B. to be determined. An oxygen demand or oxygen content or the like can also be determined. The sensor is a usual termistor or conductivity sensor. Sound or ultrasound or infrasound sensors are also suitable if the sample is to be exposed to them. Miniature microphones are known.

In Fig. 14, the embodiment is shown of a test machine. A microcomputer or microprocessor controls the test sequence according to a predefined test program. The program can be exchangeably contained in an external memory, for example in a PROM or EPROM or an erasable read / write memory. Patient data, data of the substances to be tested, the reagents, etc. are also interchangeable and after a test has been completed, the test results are also stored in the microcomputer or microprocessor, in particular in a memory for random access and self-documenting, for example as a CCD image, Thermal image or piezoresistive on magnetic tape, electrostatic or ferroelectric etc.

In the exemplary embodiment according to FIG. 14, a film carrier 23 is shown, on which macrochips made of a plurality of individual chips according to FIGS . 1 to 5 are glued or detachably fastened, the film carrier having a transport perforation 24 in order to transport the film with the usual film, like Maltese cross controlled from roll to roll over a treatment time of the program, and from station to station 25 , ie here IX. First, one or more substances are filled into the microcavities of the chips in station I according to the test program. A reaction then takes place in station II, either with or without treatment, and after a reaction time has elapsed, measurements are automatically carried out and transported to test station III in order to carry out further tests if necessary, the test results being automatically assigned to the individual cavities and possibly individual test substances , as well as patients. The self-documentation and storage he follows in the microcomputer or microprocessor 22 for automatic test control and test application.

The invention further describes a device for a micromechanical device heat exchangers, especially Joule-Thomson coolers.

According to the current state of the art, there are ver different versions of miniaturized heat exchangers, such as Joule-Thomson coolers. They are all characterized by very high piece count out.  

A Joule-Thomson cooler (e.g. from Hymatik) on the market a very long metal spiral sits on the surface of a cone is wound up. The overall arrangement is in a Dewar-Ge housing, the expanded gas covering a large area with the cooling fins metal spiral between the Dewar wall and the cone surface flows.

Another arrangement, developed by W.A. Little (AIP Proceedings of Future Trends in superconductive electronics; p. 421, University of Virginia, Charlottesville, published in 1978, consists of several, too glued glass plates, worked into the lateral cooling channels were. These coolers are less effective because of the bad ones Thermal conductivity of the glass the efficiency of the heat exchanger be is bordered.

The invention has for its object a miniaturized heat rope shear, especially Joule-Thomson cooler to create the inexpensive is producible and provides an increased exchanger performance.

This task is solved, unlike known ones, at this Miniature cooler the flow channels of a plate heat exchanger vertically are arranged in a thin substrate. This substrate is (sand enclosed) by two cover plates, in the connecting channels are incorporated, the vertical channels of the substrate, in the cross seen cut, close to a meander. The individual cells of the Heat exchangers will spiral on the substrate (viewed from above) arranged in a shape. There is an expansion cam in the center of the substrate in which the main cooling output is generated. The highly compressed gas meanders from outside to inside on the heat exchanger spiral, expands in the central expansion chamber, and is then countercurrent via Ka channels with a substantially enlarged cross-section on the spiral again led to the outside, already pre-cooling the inflowing gas. Around the large radial temperature gradient across the substrate to keep and the losses due to heat conduction in the substrate and in To keep the cover plates as small as possible are between the individual  Arms of the spirals incorporated vertical separation channels. The total arrangement voltage is provided at the top and bottom with two insulating plates with the lowest possible Provide heat conduction (e.g. glass). It can also cover glass panels directly be connected to the central plate (sandwich-like).

The invention is particularly suitable for cooling infrared CCD's. A highly compressed gas (e.g. nitrogen) is used as the cooling medium det, the boiling point of the gas being reached as the limit temperature can (in the central expansion chamber).

The invention is described below with reference to the drawing Embodiments explained. Show it

Fig. 15 is a cross section through a heat exchanger as a Joule-Thom son cooler in the high-pressure channels

Fig. 16 top plan view of an elementary cell heat exchanger of the Joule-Thomson cooler in the area of the central silicon wafer,

Fig. 17 is a cross section through the Joule-Thomson cooler in the low pressure channels,

Fig. 18 is an overall arrangement of the elementary heat exchanger cells, as well as the expansion chamber in the center of the silicon wafer.

An embodiment of the Joule-Thomson cooler will now be described. The overall arrangement consists of three processed silicon wafers 1 , 1 a , 1 b , which are connected together and two Deckplat th, z. B. of glass 3, 5 , which in turn are verbun with the silicon wafers according to FIG. 1st

Fig. 15 shows a cross section of the overall assembly by the smaller cooling channels 26. In the upper and lower silicon wafers are recesses 27 etched, which close the channels of the central silicon wafer to meander. These depressions are also etched into ( 110 ) silicon disks, the depth of which is independently limited by the crystallography. The etching is carried out anisotropically in a batch process.

Vertical channels 26 are incorporated into the central silicon wafer, which guide the gas flowing back and forth and at the same time serve as a heat exchanger through the thin partition walls. An elementary cell of this heat exchanger is shown in Fig. 16. The inner, smaller channels 26 lead the compressed (e.g. typically to 50-100 bar) flowing gas. The outer, large channels 29 are interconnected, so that they form a channel with a large cross section for the backflow de, expanded gas. The partitions in the outer area 28 le diglich the task of ensuring the most effective heat exchange and mechanical stability. The stronger walls between high and low pressure channels 30 must absorb the entire pressure difference and at the same time allow good heat transfer. The special geometry of the channels in this version is due to the crystalline line structure of the silicon, with vertical ( 111 ) planes on ( 110 ) disks.

Fig. 17 shows a cross section through the outer area of the channels 29 for the returning gas. Here, the outer silicon wafers 1 a and 1 b are completely etched through in order to obtain the largest possible cross section for the meanders of the expanded gas.

The overall arrangement of the individual heat exchanger cells on the central silicon wafer is shown in FIG. 18. The cells are arranged next to each other and guided in a spiral from the outer area to the center of the disk. In the center of the pane there is an expansion chamber 31 in which the cooling capacity is generated. About this chamber z. B. immediately a silicon chip to be cooled or the like. Semiconductors or ICs can be arranged. The individual spiral arms are thermally insulated from one another by separation channels 32 , 33 .

The new micromechanical Joule-Thomson cooler stands out above the existing systems mainly from the fact that he with the be knew batch process methods of micromechanics, as in the Her Position of semiconductor devices are used, much cheaper ger can be produced. Furthermore, due to the vertical arrangement cooling channels and the frequent meandering a very good swirl of the gas and thus a high efficiency of the heat exchanger Furthermore, a semiconductor chip to be cooled can be directly in the system or overall arrangement can be integrated so that the cold performance without additional partitions directly on the chip.

The invention is not based on the use of any particular medium limited heat exchange. Besides, the leadership of the media is not limited to the illustrated embodiment. Also heat pipes (heat pipes) are applicable.

Claims (15)

1.Micromechanical structure with cavities, containers, openings, channels, depressions, elevations or the like for investigations of test substances for any changes in physical and / or chemical properties with targeted evaluation and documentation for the purposes of biotechnology, genetic engineering, cell and immune research and other medical, agricultural and environmental research, characterized in that the structure consists of semiconducting material (group III to VIII of the elements of the periodic table) or contains it ent or glass or ceramic, diamond or carbon and in a non-exciting way, especially in chemical etching technology. 2. Microstructure according to claim 1, characterized in that the The block and the cover are made of the same material. 3. Microstructure according to claim 1 or 2, characterized in that that the block or lid made of silicon or other monocrystalline Ma material or glass. 4. Microstructure according to one of the preceding claims, characterized characterized in that a plurality of wells be in the block agreed shape, size, arrangement or distribution over the lid swept surface are introduced. 5. Microstructure according to claim 4, characterized in that the Wells are introduced by directional chemical etching. 6. Microstructure according to claim 4, characterized in that the Depressions are introduced by anisotropic etching.   7. Microstructure according to claim 4, characterized in that the Cover with elevations complementary to the recesses in the block hen and fits hermetically. 8. Microstructure according to claim 4, characterized in that a Large number of cavities side by side on a carrier, over a top are arranged distributed. 9. Microstructure according to one of the preceding claims, characterized in that the arrangement pattern of the cavities, depressions, openings is constructed according to a grid dimension, so that it (in XY direction) by automatic filling or emptying elements or samplers, pumps, Suction lifters, or similar mouthpieces thereof can be snapped in particular according to a predetermined program, micro-valves in particular arranged in the same grid dimension being controllable from the outside. 10. Microstructure according to claim 8 or 9, characterized in that openings (closable) or windows in the same pitch Cover and optical, optronic, electronic, piezoelectric, fer ritical, magnetic, capacitive, ohmic or other measurement and evaluation Devices such as CCD or RAM or other arrays assigned to the floor are and this array or the matrix directly with a microprocessor (MP) or microcomputer (MC) is connected. 11. Microstructure according to claim 10, characterized in that the measurement results from the cavities and cells can be queried automatically and are self-documenting (results storage). 12. Microstructure according to one of claims 8 to 10, characterized ge indicates that at least in one cavity an etched light wel lenleiter opens, which is directly accessible to an optical evaluation is. 13. Microstructure according to one of claims 8 to 11, characterized in that the individual cavities / cells for external influencing solution a pin (light pen or the like) can be located (in the XY direction). 14. Microstructure according to one of the preceding claims, characterized characterized in that several are arranged on a film carrier for Transport from station to station for automatic control and evaluation tung. 15. microstructure with heat exchanger, heating and / or cooling device, in particular plate, produced by micromechanical way, preferred according to the countercurrent principle or with heating and / or cooling agents such as Layer structure / thermocouples, characterized in that in a central, sandwich-like plate or disc made of good heat conductive material, such as silicon or the like Semiconductor material, one in the cross a meandering flow path is formed for a carrier medium, in which partitions remain in the central plate, the ones with Erhe exercises in a cover plate and opposite depressions in the correspond to another cover plate.