EP1815230A1

EP1815230A1 - Micro-fluidic system comprising an expanded channel

Info

Publication number: EP1815230A1
Application number: EP05823473A
Authority: EP
Inventors: Thomas Schnelle; Torsten Müller; Annette Pfennig
Original assignee: Evotec Technologies GmbH
Current assignee: PerkinElmer Cellular Technologies Germany GmbH
Priority date: 2004-11-18
Filing date: 2005-11-17
Publication date: 2007-08-08
Also published as: WO2006053892A1; DE102004055662A1; US20090148937A1

Abstract

The invention relates to a micro-fluidic system comprising a fluid medium channel (1) that holds a fluid medium containing particles (2) in suspension. According to the invention, the fluid medium channel (1) has an expanded section (5) with an enlarged cross-section along part of its length, in order to reduce the flow speed to allow the analysis of the particles (2).

Description

BESCHREIBtJNG

Microfluidic system with channel widening

The invention relates to a microfluidic system, in particular for a cell sorter, with a carrier flow channel for receiving a carrier flow with particles suspended therein according to the preamble of claim 1.

Such a microfluidic system is known for example from DE 103 20 956 A1 and can be used in a cell sorter to examine biological cells and to sort the cells depending on the result of the examination into one of several output channels. For this purpose, the known microfluidic system a carrier flow channel for receiving a carrier flow with suspended therein Par ^¬ tikeln, wherein the carrier flow channel into several ducts Ausgangska- branched, in which the biological cells by the ^¬. In addition, in the carrier flow channel, a Messsta ^¬ tion arranged, which examines the suspended biological cells by, for example, a transmitted light measurement, a fluorescence measurement or an impedance spectroscopy is performed. However, it is also possible for the measuring station to measure the deformation of the suspended particles or their rotational speed or an electrical or magnetic quantity. The investigation of the suspended biological cells in the measuring station requires in this case that the biological cells to be examined are spatially fixed during the examination or at least greatly slowed down. Therefore, the microfluidic system has be known ^¬ for fixation of the biological cells to be examined in the carrier flow channel on a field cage, the dielectrophoretically from a we- In the case of a suitable electrode, the biological cells which are suspended in the carrier flow are held fast by a suitable electrical control so that the measuring station can examine the cells in the stationary state.

A disadvantage of the known micro-fluidic system described above is the quantitatively unsatisfactory throughput or the high loading of the biological cells.

The invention is therefore based on the object, to increase the through ^¬ set of biological cells in such a microfluidic system.

This object is achieved by a microfluidic system according to the invention according to claim 1.

The invention is based on the newly gained insight that the throughput of biological cells at the outset be¬ signed known microfluidic system on the one hand by the maximum detection speed of the Messsta ^¬ tion and bounded on the other hand by the maximum allowable electrical control of the field cage.

To carry out an examination in the measuring station, the suspended biological cells must not exceed a certain flow velocity. The field cage slows the biological cells therefore from the normal flow rate in the carrier flow channel to such an extent that the flow rate drops of the test cells under the maximum permissible detection speed of the Messsta ^¬ tion.

However, this deceleration of the cells to be examined is only possible to a limited extent because the braking force is applied to the field cage or holding the cells applied electrical voltage can not be increased arbitrarily, since the cells can otherwise be damaged thermally or electrically.

The quantitative throughput can therefore by ^¬ He heightening the flow speed in the carrier flow channel raise only so far that despite maximum permissible elektri¬ shear control of the field cage, the maximum permissible Detek- tion speed of the measurement station is reached.

The invention therefore encompasses the general technical ^teaching that the carrier ^flow channel has a channel widening with a widened channel cross section over part of its length. The channel widening leads corresponding to the relationship of the channel cross-sections in front of the widened channel portion and in the channel widening in a corresponding reduction of the flow velocity, whereby it can be the deceleration to be un ^¬ tersuchenden cells supported by the box cage or so¬ even replaced.

The channel widening according to the invention the carrier flow channel has the advantage that the flow velocity in the carrier flow channel outside of the channel widening and thus also the quantitative throughput of biological cells or sons- term particles can be increased without having to investi ^¬ sponding particles at the measuring station, the maximum detection - exceed speed.

Another advantage of the widened channel portion is may be that the field cage and the measuring station further ent from the channel edge arranged ^¬ removed. This is particularly advantageous in the case of high-resolution fluorescence measurements, which can be hindered by fluorescing channel materials or adhesives. In the preferred exemplary embodiment of the invention, at least one measuring station is arranged in the region of the channel widening in order to examine the cells or other particles suspended in the carrier flow. The station itself can be constructed in a conventional manner, as example, described ^¬ in the already cited patent application DE 103 20 956 Al, so that the content of this publication with respect to training and function of the measuring station of the present description in full environmental fang is attributable.

It is also possible in the invention that in the region of the channel widening a Manipula ^¬ is arranged at least tion device to manipulate the suspended particles, wherein the reduced flow velocities facilitates speed in the region of the channel widening the manipulation of the suspended particles. For example, in the region of the channel widening, a sorting device (eg a dielectric switch) may be arranged as a manipulation device, which can arrange different particles (eg red and white)

Blood corpuscles). The manipulation device may also be a holding device, which holds the suspended particles in a suitable control. Alternatively, however, it is also possible for the manipulation device to carry out a manipulation in the strict sense by stretching the particles or by pairing (for example by electrofusion), which is known per se. In this case, the manipulation device may be, for example, a laser or a laser tweezers or a dielectrophoretic electrode arrangement.

In this case, the channel widening is preferably restricted to the area of the measuring station or the manipulation device in the flow direction, since only there is a lowering of the flow mungsgeschwindigkeit is required to er¬ possible an investigation in the measuring station or a manipulation of the particles.

In addition, the measuring station in a preferred embodiment of the present invention to a predetermined, maximum permissible speed of detection, up to which the measurement ^¬ station can search the particles suspended in the carrier flow unter¬. However, the carrier stream comprises a stream have on speed, which lies in the region of the widened channel portion below the maximum detection speed and outside the Ka ^¬ nalaufweitung above the maximum detection speed. Can be so the channel widening leads in this case to a Absen ^¬ effect of the flow rate to below the maximum permissible speed of detection of the measuring station, so that the flow velocity in the carrier flow channel before the channel widening increased accordingly, thereby increasing the quantitative flow rate of particles.

In addition, the reduction provides the Strömungsgeschwindig ^¬ ness in the range of the channel widening the possibility that can be dispensed to a field cage or other fixing means for retaining the particles during the investigation.

A great advantage of the use of microchannels for the investigation of biological samples (eg cells), in particular for the investigation of their reaction to the addition of agents (eg pharmaceutically or cell-differentiating substances), is that only the smallest volumes are needed. This is of great importance in drug scission. However, the small channel dimensions place narrow limits on the parallel investigation. If a plurality of manipulation elements are accommodated in a channel widening, in In which individual cells or cell aggregates can be held, the advantages of the small amounts of substance can be combined with the parallelizability.

However, the invention is not limited to such embodiments in which no field cage is arranged in the region of the channel widening. Rather, there is also the Mög ^¬ friendliness that the braking or fixing together through the channel widening and a field cage is carried to the investi ^¬ sponding particles during the examination, whereby the

Flow rate in the carrier flow channel before Ka ^¬ nalaufweitung and thus the throughput of particles can be further increased wei¬ ter.

The field cage is preferably arranged in the region of the measuring station in order to decelerate or even fix the particles for examination by the measuring station.

However, there are also the possibility that the field cage together with its electrodes at the same station, so that the field cage and the measuring station in a bifunktiona ^¬ len component integrated. Lektrodenanordnungen Such bifunctional E- are, for example described in the patent applica ^¬ application DE 10 2004 017 482.2, so that the contents of this patent application, the present description is attributable in vol¬ lem screen.

The bifunctional integration described above is not limited to the combination of a dielectric field cage with a measuring station. It is for example also mög ^¬ Lich to integrate the station with a manipulating device (eg, a laser or a laser tweezers) in a component, wherein the manipulating device can also operate mag¬ netic. Preferably, the channel cross section of the carrier flow channel in the region of the channel widening is extended by 5% to 400% in relation to the region outside the channel revaluation, any intermediate values being possible within the scope of the invention and a range of 10% to 500%, preferably 10% to 300 %, ^¬ is particularly advantageous.

In the preferred embodiments of the invention comparable to the carrier flow channel branches off passages in a located downstream of the channel widening branch portion into a plurality of Aus¬ into which the sor to be examined can be particles ^¬ advantage. Such branching is at ^¬ play writing from the already cited DE 103 20 956 Al disclosure known, so that its contents towards ^¬ clearly the structural design of the microfluidic system in the branching region of the present Beschrei¬ bung is hereby fully incorporated.

In the branching region a Sortierein¬ is preferably arranged direction which NEN the suspended particles in Ab ^¬ dependence on the actuation of the sorting device in ei¬ of the output channels, sorted and such Sor ^¬ also animal facility from the already cited patent application DE 103 20 956 Al is known.

Further, vorzugswei in at least one of the output channels ^¬ se a centering device which centers the suspen arranged ^¬-founded particles in the output channel and thereby prevents transmission channels a gravitational settling of the particles in the off ^¬. In addition, preferably at least one of the output flow channels opens into at least one of the output channels, which is also known per se.

In the carrier flow channel, a holding device ( "Hook" eng.) May be upstream of the measuring station are ^¬ which retains the suspended particles, depending on their dently ^¬ tion or to pass through. This offers the possibility that the particles to be examined are held upstream of the measuring station and fed to the measuring station in a targeted manner.

The sorting device ("switch"), the centering device ("funnel"), the field cage (English: "cage") and / or the holding device ("hook") preferably have a dielectrophoretic manner in this case acting electrode arrangement. Such dielectrophoretically acting electrode drive North ^¬ voltages are, for example, from Mueller, T. et al. : "A 3-D microelectrode system for handling and caging single cells and particles", Biosensors and Bioelectronics 14 (1999), 247-256, known, so that the content of this publication of the present description is attributable in its entirety ,

Instead of dielectrophoretic electrode arrangements, however, it is also possible within the scope of the invention to utilize other electrokinetic forces which are based, for example, on electrophoresis or electroosmosis. For this purpose, an additional channel may be provided, which is connected to the carrier flow channel and extends substantially transversely to the carrier flow channel, wherein the additional channel is connected with DC voltage signals for deflecting the particles. Moreover be ^¬ is also the possibility that the particles are magnetically manipulated by laser (for example by means of laser tweezers) or. The individual particles can also be stretched, which is described, for example, in DE 103 52 416, so that the contents of this document are to be fully attributed to the present description.

Furthermore, there is the possibility that the sorting ^device and / or the measuring station is arranged eccentrically in the carrier flow channel. The eccentric arrangement of the sorting ^device in front of the mouth opening of one of the output channels offers the possibility that the particles to be sorted independently flow into the respective output channel without an active control of the sorting device, so that the sorting device is merely sorted into one of the Other output channels must be actively controlled.

, The channel widening may in the inventive microfluidic system be one-dimensional, for example, the width of only the carrier flow channel in the region of the channel ^¬ expansion is increased while the height of the carrier flow channel ^¬ is constant.

However, there is also the possibility that the channel ^{widening is} two-dimensional in that both the height and the width of the carrier flow channel in the region of the channel widening are increased.

Furthermore, it is advantageous if the micro fluidic system according to the invention is integrated on a chip.

Furthermore, the advertising can also be achieved by the channel widening, the carrier flow channel that upstream of the Ka ^¬ nalaufweitung into several parallel sub-channels branched, which are returned zusammenge¬ downstream of the channel extension. The total cross section of the individual subchannels is preferably larger than the cross section of the carrier. gerstromkanals outside the channel extension, so that in this case the flow velocity in the region of Kanalauf ^¬ expansion is reduced.

Furthermore, there is the possibility that a plurality of channel widenings are arranged one behind the other in the carrier flow channel. This can be particularly useful when several stations are arranged one behind the other in the Trä ^¬ gerstromkanal. The individual channel widenings are then preferably arranged in each case at the location of the measuring stations, in order there to

Flow velocity of the suspended particles to ver ^¬ reduce and thereby allow a measurement.

In addition, there is the possibility that the inventive microfluidic system has a plurality of parallel or verzwei ^¬ ing carrier flow channels, in each of which at least one channel widening is arranged.

Furthermore, the lowering of the invention is the flow velocity in the channel widening, not only for a study of the particle makes sense, but also for de¬ ren manipulation, such as education for a specific pair ^¬. Therefore, within the scope of the invention, there is also the possibility that a manipulation device is arranged in the region of the channel widening.

It should also be mentioned that the microfluidic system according to the invention can be advantageously used in a cell sorter.

By a suitable channel widening the holdup can also time the micro objects at unchanged pumping rate so Longer side ^¬ be set siege / as is necessary in the context of a necessary Assayinkubationszeit. This is the coupling of continuous pumping rate and discontinuous Zeitre¬ time.

Furthermore, the invention also encompasses the novel use of such a microfluidic system in medical or pharmaceutical research, in diagnostics or in forensic medicine.

In addition, the invention also encompasses the use of a microfluidic system according to the invention for separating different cell types from one another, in particular apoptotic and necrotic cells, cells with different expression patterns and / or stem cells. Furthermore, in the microfluidic system according to the invention, it is also possible to sort cells or, in general, particles of different size and / or different morphology.

It should also be mentioned that the term particle used in the context of the invention is to be understood generally and is not restricted to individual biological cells.

Rather, this term also encompasses synthetic or biological particles, with particular advantages if the particles are biological materials, for example biological cells, cell groups, cell constituents or biologically relevant macromolecules, in each case optionally in combination with other biological particles or synthetic Carrier particles comprise. Synthetic particles may comprise solid particles, liquid particles separated from the suspension medium, or multiphase particles which form a separate phase with respect to the suspension medium in the carrier stream.

Finally, it should be mentioned that the term of a microfluidic system used in the context of the invention means that the carrier flow channel contains a volume which is preferred. wise in the milli-, micro- or nanoliter range. The Vo¬ lumen of the carrier flow channel can therefore in the inventive ^¬ microfluidic system SEN, for example in the range of 0.01 nl to 10 ml or in the narrower range of 1 nl to 1 ml lie, wherein any intermediate values are also possible.

Other advantageous developments of the invention are characterized in the subclaims or are explained in more detail below together with the description of the preferred exemplary embodiments with reference to the figures. Show it:

Figure IA is a schematic representation of a microfluidic system according to the invention ^¬ SEN tung with a Kanalaufwei¬ and a field cage for the joint braking or fixing of the particles to be examined,

Figure IB shows an alternative embodiment of a microfluidic system according OF INVENTION ^¬ dung nalaufweitung with a Ka¬ and a non-central field cage for the joint braking or fixing of the particles to be examined,

Figure 2A shows an alternative embodiment of a microfluidic system according OF INVENTION ^¬ dung with a Ka nalaufweitung for braking to be examined the

Particles without an additional field cage, as well

Figure 2B shows an alternative embodiment of a microfluidic system according OF INVENTION ^¬ dung with a Ka nalaufweitung for fixation and load to be un¬ tersuchenden particles.

The microfluidic system in accordance with FIG IA is partly formed forth ^¬ kömmlich so that in addition to the publication Müller, T. et al. : "A 3-D microelectrode system for handling and caging single cells and particles", Biosensors and Bioelectronics 14 (1999), 247-256 and to DE 103 20 956 Al.

The microfluidic system has a carrier flow channel 1, in which a carrier stream with particles 2 suspended therein flows, which is known per se.

In the carrier flow channel 1 is a funnel-shaped, dielectrophoretic electrode assembly 3, which centered in the carrier flow stream 2 suspended particles in the Trä¬ gerstromkanal 1 and therefore also as "Funnel" be ^¬ draws.

Downstream of the electrode assembly 3 there is another dielectrophoretically acting electrode ^arrangement 4, which can temporarily hold the particles 2 centered and lined up by the funnel-shaped electrode arrangement 3 and therefore and also referred to as "hook".

Downstream of the hook-shaped electrode arrangement 4, the carrier flow channel 1 has a channel widening 5, wherein the channel cross section in the area of the channel widening 5 is increased by 50% compared to the channel cross section outside the channel widening 5. The channel widening 5 brings about a reduction in the flow rate in the range of Ka ^¬ nalaufweitung what 2 is Tikel important for the subsequent investigation of Par, as subsequently wrote more detail be ^¬.

In the region of the channel widening 5 there is a measuring station 6, which examines the particles 2. The measuring station 6 may in this case be formed in a conventional manner, as is described in the two publications mentioned above, so that a detailed description of the measuring station 6 can be dispensed with at this point.

It should be mentioned, however, that the measuring station 6 can only examine the particles 2 if the flow velocity of the particles 2 does not exceed a predetermined maximum permissible detection speed.

In the area of the widened channel portion 5 therefore is additionally a further dielectrophoretically acting electrode driving voltage North ^¬ 7 is arranged, which is formed cage-shaped, and the particles 2 can fix dielectrophoretically at a suitable electrical control and is therefore also referred to as a "cage".

The channel portion 5, and the cage-shaped electrode drive North ^¬ voltage 7 act here taken together with the target, the particles 2 in the carrier flow channel 1 decelerate so far and to be noted that the station 6 can chen the particles 2 investi ^¬.

Downstream of the channel widening 5 the Trä- branched gerstromkanal into two output channels 8, 9, wherein the desperation of the two output channels 8, 9, a further di ^¬ electrophoretically acting electrode assembly 10 is disposed ^¬ supply area, which acts as a particulate soft and therefore also called a "switch" referred to as. The soft like Elektrodenanord- voltage 10 sorts the particles 2 in function of their At ^¬ control and what is known per se in dependence on the result of the process performed by the observation station 6 Investigation into one of the two output channels 8,. 9 In this case, there is another funnel-shaped, dielectrophoretically acting electrode arrangement 11 in the outlet channel 9 which centers the particles 2 in the outlet channel 9 and thereby prevents the particles 2 in the outlet channel 9 from sinking as a result of gravity.

Further, in the output channel 9 two Hüllstromkanäle 12, 13, which is also known per se.

The microfluidic system according to FIG. 1B largely corresponds to the ^exemplary embodiment described above and illustrated in FIG. 1A, so that in order to avoid repetition, reference is largely made to the above description of FIG. 1A, the same reference numerals being used for corresponding components below.

The special features of this embodiment exist represents ^¬ in, is that the measuring station 6 and the cage-shaped electric ^¬ not end assembly 7 centrally in the region of the widened channel portion 5 are, and also the hook-shaped electrode assembly 4 in Figure IA ei¬ through the electrode assembly 4 with the function ner particles diverter ( engl. "Switch") was replaced. Advantage ^¬ way legally can (engl. "Cage") when loaded electrode structure 7 other particles 2 on the basis of the channel widening 5 in the main channel 8 (engl. "Waste") are transferred close to the cage-like electrode assembly 7 over which the Ge ^¬ driving a Channel blockage reduced. In addition, the particles 2, which were evaluated positively by means of the measuring station 6, reach the desired output channel 9 without additional switching.

The embodiment of a ^¬ OF INVENTION shown in Figure 2A to the invention microfluidic system shown agrees substantially with the above described and in Figure IA Embodiment match, so that in order to avoid repeats ^¬ largely referenced to the above description of Figure IA, wherein the same reference numerals are used for corresponding components below.

A special feature of this embodiment is that in the region of the channel widening 5 no additional kä¬ figartige electrode assembly 7 is arranged, so that the deceleration of the particles 2 for the investigation by the measuring station 6 alone by the channel widening 5 is effected.

Another special feature of this embodiment is that the channel widening 5 extends in comparison to the embodiment of Figure 1 over a much larger ^¬ re length of the carrier flow channel 1.

Finally, a special feature of this Ausführungsbei ^¬ game is that the funnel-shaped electrode assembly 3, the measuring station 6 and the soft-type electrode assembly

10 in this case in the carrier flow channel 1 in the region of Kanalauf ^¬ expansion 5 eccentrically in front of the mouth opening of Ausgangsska¬ nals 9 are arranged. The soft-type electrode assembly 10 must be in this case thus only activated when the particles are to be sorted in the output channel 8 2 ^¬ wohinge gen the particles to be sorted 2 without an active dently ^¬ tion of the soft-type electrode assembly 10 independently flow into the output pin 9.

The embodiment of a microfluidic system according OF INVENTION ^¬ dung shown in Figure 2B largely corresponds to the above-described and illustrated in Figure 2A embodiment consistent, so as to avoid repetitions ^¬ largely to the foregoing description to FIG. 2A, the same reference numbers being used for corresponding components in the following.

A special feature of this embodiment is that in the region of the channel widening 5 a plurality of electrode arrangements 7 are accommodated, wherein the electrode arrangements 7 can also comprise measuring stations.

Furthermore, instead of the funnel-shaped electrode arrangement 3 ("Funnel"), an electrode arrangement 3 as

Distributor element used, which allows the loading of the electric ^¬ denanordnungen 7.

In addition, in addition to the carrier flow channel 1, an additional loading channel 1 'opens in the area of the channel ^widening 5. In this embodiment, cells in the cage-like electrode arrangements 7 (cages) can first be caught and then adjusted by suitable regulation of the flow conditions in the carrier flow channel 1 or the loading channel 1 'are exposed to a spatial or temporal chemical concentration profile. This may be, for example, the supply of artificial particles, pharmacological substances, antibodies, viruses, etc. via the loading channel 1 '. Subsequently, sorting can take place as a function of the detection. This exemplary embodiment advantageously combines the low substance consumption with parallel evaluation in the microsystem.

The invention is not limited to the preferred embodiments described above. Rather, a multiplicity of variants and modifications is possible, which likewise make use of the concept of the invention and therefore fall within the scope of protection. LIST OF REFERENCE NUMBERS

1 carrier flow channel

1 'loading channel

2 particles

3 electrode arrangement

4 electrode arrangement

5 channel widening

6 measuring station

7 electrode arrangement

8 output channel

9 output channel

10 electrode arrangement

11 electrode arrangement

12 envelope flow channel

13 envelope flow channel

Claims

1. The microfluidic system for receiving a carrier flow with particles therein sus ^¬ pendierten (2), characterized characterized at least one carrier ^¬ flow channel (1) that the

Carrier flow channel (1) on a part of its length at least one channel widening (5) having an extended channel cross-section.

2. Microfluidic system according to claim 1, characterized by at least one measuring station (6) for examining suspended in the carrier stream particles (2), wherein the measuring station (6) at least partially or completely in the region of the channel widening (5) is arranged.

3. Microfluidic system according to claim 2, characterized by a plurality of measuring stations (6) for examining the suspended in the carrier stream particles (2), wherein at least one of the measuring stations (6) in the region of the channel widening (5) is arranged an¬, while at least one the measuring stations (6) outside the range of the channel widening (5) is arranged.

4. Microfluidic system according to one of the preceding claims, characterized by at least one Manipulati ^¬ onseinrichtung for manipulating the suspended particles, wherein the manipulation device is at least partially or completely in the region of the channel widening (5).

5. Microfluidic system according to one of claims 2 to 4, characterized in that the channel extension (5) in Flow direction is limited to the area of the measuring station (6) or the manipulation device.

6. Microfluidic system according to one of claims 2 to 5, characterized in that the measuring station (6) has a pre ^¬ given maximum detection speed, to which the measuring station (6) can examine suspended in the carrier stream particles (2), wherein comprising the carrier flow with particles suspended therein (2) a flow rate in the range of the channel widening (5) spreading under the maximum detection speed and outside the channel ^¬ (5) is above the maximum detection speed.

7. Microfluidic system according to claim 6, characterized ge indicates that in the region of the channel widening (5) no field cage (7) and / or no manipulation device is ange¬ arranged.

8. Microfluidic system according to one of claims 1 to 5, characterized by a field cage (7) for fixing the suspended particles (2) in the carrier flow channel (1), wherein the field cage (7) in the region of the channel widening (5) and / or is arranged at the measuring station (6).

9. Microfluidic system according to one of the preceding claims, characterized in that the channel cross section of the carrier flow channel (1) in the region of the channel widening (5) with respect to the area outside the channel widening (5) is extended by 10% to 500%.

10. Microfluidic system according to one of the preceding claims, characterized in that the carrier flow channel

(1) in a downstream downstream of the channel widening (5) branches branching branched into a plurality of output channels (8, 9).

11, microfluidic system according to claim 10, character- ized in that in the branching area a sorting device (10) is arranged, which the suspended particles (2) in response to the control of the sorting device (10) in one of the output channels (8, 9) sorted.

12. The microfluidic system of any one of claims 10 o 11, characterized in that in at least one of the output channels (8, 9) a centering device (11) is angeord ^¬ net which the suspended particles (2) in the off ^¬ passage (9) centered.

13. Microfluidic system according to one of claims 10 to

12, characterized in that in at least one of the ^¬ output channels (8, 9) at least one Hüllstromkanal (12, 13) opens.

14. Microfluidic system according to one of claims 2 to

13, characterized in that in the carrier flow channel (1) upstream of the measuring station (6), a holding device (4) is arranged, which holds the suspended particles (2) depending on their control or passes.

15. Microfluidic system according to one of claims 8 to

14, characterized in that the sorting device (10) and / or the centering device (11) and / or the field cage (7) and / or the holding device (4) has a dielektrophore- tisch acting electrode assembly.

16. Microfluidic system according to one of claims 2 to

15, characterized in that the sorting device (10) and / or the measuring station (6) in the carrier flow channel (1) is arranged ex ^¬ centrically.

17. Microfluidic system according to one of the preceding claims, characterized in that the carrier flow channel (1) in the region of the channel widening (5) is widened only in a spatial dimension.

18. Microfluidic system according to one of claims 1 to 16, characterized in that the carrier flow channel (1) in

Region of the channel widening (5) auf¬ is widened in two spatial dimensions.

19. Microfluidic system according to one of the preceding claims, characterized by integration on one

Chip.

20. The microfluidic system according to one of the preceding claims, characterized in that the channel widening consists of a breakdown of the carrier flow channel into a plurality of paral ^¬ Lele subchannels.

21. Cell sorter with a microfluidic system according to one of the preceding claims.

22. Use of a microfluidic system according to one of claims 1 to 20 in medical and / or pharmaceutical research and / or in diagnostics and / or in forensic medicine.

23. Use of a microfluidic system according to one of claims 1 to 20 for the separation of different cell types from each other, in particular apoptotic and necrotic Cells, cells with different expression patterns and / or stem cells.

24. Use of a microfluidic system according to a

5 of the claims 1 to 20 blocks at least one of the following Zwe ^¬:

- formation of pairs of cells,

- cell fusion,

- Stretching of cells, 10 - as a collector's chamber.

25. Use of a microfluidic system according to any one of claims 1 to 20 for incubation of cells and / or for

Collecting cells. ] ^ * * * * *