Microfluidic Treatment Apparatus and Method for Operating a Microfluidic Treatment Apparatus

Abstract

A microfluidic treatment apparatus has a microfluidic channel system having a filtering branch, a pumping branch connected in parallel with the filtering branch, and a filter chamber arranged in the filtering branch and configured to accommodate a filter element. The filtering branch is coupled to a channel inlet via a first channel-crossover element and to a channel outlet via a second channel-crossover element, and the filter chamber can be isolated from the rest of the channel system by at least two filter valves. A pumping device is arranged in the pumping branch, is configured to produce fluid flow in the channel system, and includes at least one pumping valve and at least one pumping chamber. The pumping branch is coupled to the channel inlet via a connection of the first channel-crossover element and to the channel outlet via a connection of the second channel-crossover element

Description

Claims

1. A microfluidic treatment apparatus for treating a sample liquid, the microfluidic treatment apparatus comprising: at least one microfluidic channel system having at least one filtering branch and a pumping branch connected in parallel with the filtering branch;at least one filter chamber arranged in the filtering branch and is configured to accommodate a filter element;a first channel-crossover element configured to fluidically couple the filtering branch to a channel inlet;a second channel-crossover element configured to fluidically couple the filtering branch to a channel outlet;at least two filter valves configured to fluidically isolate the filter chamber from the rest of the channel system ; anda pumping device arranged in the pumping branch and configured to produce a fluidic flow in the channel system, the pumping device comprising at least one pumping valve and/or at least one pumping chamber,wherein the pumping branch is configured to be coupled fluidically to the channel inlet via a first connection of the first channel-crossover element which is different from a second connection of the first channel-crossover element for the filtering branch, and the pumping branch is configured to be coupled fluidically to the channel outlet via a first connection of the second channel-crossover element which is different from a second connection of the second channel-crossover element for the filtering branch.

2. The treatment apparatus according to claim 1, wherein the at least one pumping chamber includes at least two first pumping chambers arranged or connected in a row adjacent to one another.

3. The treatment apparatus according to claim 2, wherein the at least one pumping chamber further includes a second pumping chamber configured to be separated from the at least two first pumping chambers by at least one pumping valve.

4. The treatment apparatus according to claim 3, wherein each of the at least two first pumping chambers and the second pumping chamber have a volume that is substantially the same size.

5. The treatment apparatus according to claim 2, wherein at least two of the at least two first pumping chambers are configured to be temperature-controlled independently of one another.

6. The treatment apparatus according to claim 1, further comprising: a channel system expansion module configured to be fluidically coupled to the pumping branch the channel system expansion module comprising at least one upstream arrangement chamber configured for upstream arrangement of reagents and/or at least one evaluation chamber having evaluation cavities configured for evaluating sample constituents of a sample liquid.

7. The treatment apparatus according to claim 6, wherein: the upstream arrangement chamber configured to be fluidically coupled to the pumping branch by a channel connecting element that be is closed with an upstream arrangement valve; andthe evaluation chamber is configured to be fluidically coupled to the pumping branch by a further channel connecting element that is closed with an evaluation valve.

8. The treatment apparatus (490) according to claim 1, wherein the the at least one pumping chamber comprises a single pumping chamber and the at least one pumping valve comprises at least three pumping valves.

9. The treatment apparatus according to claim 1, wherein an inlet valve is arranged between the channel inlet and the first channel-crossover element, and/or an outlet valve is arranged between the channel outlet and the second channel-crossover element.

10. A method for operating a microfluidic treatment apparatus having (i) at least one microfluidic channel system having at least one filtering branch and a pumping branch connected in parallel with the filtering branch, (ii) at least one filter chamber arranged in the filtering branch and configured to accommodate a filter element, (iii) a first channel-crossover element configured to fluidically couple the filtering branch to a channel inlet, (iv) a second channel-crossover element configured to fluidically couple the filtering branch to a channel outlet, (v) at least two filter valves configured to fluidically isolate the filter chamber from the rest of the channel system, and (vi) a pumping device arranged in the pumping branch and configured to produce a fluidic flow in the channel system, the pumping device comprising at least one pumping valve and/or at least one pumping chamber, the pumping branch configured to be coupled fluidically to the channel inlet via a first connection of the first channel-crossover element which is different from a second connection of the first channel-crossover element for the filtering branch, and the pumping branch configured to be coupled fluidically to the channel outlet via a first connection of the second channel-crossover element which is different from a second connection of the second channel-crossover element for the filtering branch the method comprising: introducing a sample liquid into the microfluidic treatment apparatus;extracting sample constituents present in the sample liquid through a filter element; andeluting sample constituents from the filter element.

11. The method according to claim 10, further comprising: lysing the sample liquid following the introduction of the sample liquid and before the extraction of the sample constituents; and/orwashing the filter element and the filter chamber following the extraction of the sample constituents and before the elution of the sample constituents.

12. The method according to claim 10, further comprising one or more of the following: providing a reaction liquid by dissolving a reagent using the sample constituents following the elution of the sample constituents;carrying out an amplification reaction;aliquoting the reaction liquid;carrying out a detection reaction; andevaluating the reaction result.

13. A control unit configured to execute program instructions stored in a memory to carry out and/or actuate method according to claim 10 in corresponding units .

14. A computer program configured to carry out and/or actuate the method according to claim 10.

15. A non-transitory machine-readable storage medium on which the computer program according to claim 14 is stored.

16. The treatment apparatus according to claim 1, wherein the first and second channel-crossover elements are T-shaped.

17. The treatment apparatus according to claim 2, wherein the at least two pumping chambers includes three pumping chambers arranged or connected in series in the row.