EP2764919A1 - Device for analysing a test fluid - Google Patents

Abstract

The apparatus has housing (11) has cylindrical housing interior (16) having entrance chamber (19), processing chamber, visible analysis element. The processing chamber has processing element (17), The inlet chamber has input element (18) to receive the test liquid. Test liquid is moved from the inlet chamber via the processing chamber to the analysis element. The processing element is rotatable relative to the input element and the housing.

Description

The invention relates to a device for analyzing a test fluid according to the preamble of claim 1.

Such devices can be used, for example, for the analysis of saliva or urine of a subject. However, it is also possible that other liquids are analyzed or a sample substance to be analyzed, for example in the form of a solid, is first mixed or dissolved in a so-called leaching solution and the test liquid obtained is subsequently analyzed. The analysis can be used, for example, for the detection of drugs, explosives or other substances, such as traces of nuts.

In such analyzes, first of all the sample substance, for example in the form of saliva, is mixed with the washout fluid, thus producing a test fluid which can be analyzed. In particular, the mixture is achieved in such a way that a sample collector with which the sample substance can be taken up is washed out in the washing-out liquid. Subsequently, the test liquid is usually processed. For this purpose, the test fluid can be brought into contact with a reaction partner, for example in the form of gold conjugate. The treatment is also referred to as a so-called incubation. After a specified waiting period, the thus prepared test fluid is passed to an analysis element containing, for example, a test strip, also referred to as a so-called lateral flow assay. The test strip is loaded at one end with the test fluid, which then flows through the test strip and collects in a collection pad at the opposite end of the test strip. The test strip may have a nitrocellulose membrane on which test lines and control lines are arranged, which react with the test liquid and on which a reaction and thus the analysis result are readable. The analysis result can be read and processed for example by means of a special electronic evaluation device.

In the US 2006/0292034 A1 An apparatus for analyzing a test fluid is described. The device has an input chamber, a processing chamber and an analysis element with a test strip. The device also has a housing with a housing interior, in which a treatment element at least partially limiting conditioning element and an input chamber at least partially limiting input element are arranged. The test strip is arranged in the housing so that it is at least partially visible from the outside. The test liquid in the form of saliva of a subject can be picked up with a sample collector and introduced into the inlet chamber. The sample collector is expressed so that test liquid enters the input chamber. By pushing the sample collector to the bottom of the input chamber, it is moved in the direction of the processing chamber below it. The input chamber is displaced until the bottom of the input chamber ruptures, thus flowing an undefined amount of the test fluid from the input chamber into the processing chamber. After a defined incubation period of about 2 to 3 minutes, a slide arranged between the processing chamber and the test strip is opened so that the conditioned test liquid can reach one end of the test strip. After a reaction time, the analysis result on the test strip can then be read as described above. An opening of the input element is arranged perpendicular to the test strip.

In the DE 20 2008 017 883 U1 An apparatus for analyzing a test fluid is also described. The device has a processing chamber in the form of a mixing chamber and an analysis element with a test strip. When using the device test liquid is filled from a separate washout in the processing chamber, from which it is passed to the test strip after preparation. To fill a certain amount of test fluid into the processing chamber, it has a level mark up to which a user of the device is to fill test fluid. It is not possible to monitor or check the amount of test fluid actually filled in.

In contrast, it is the object of the invention to propose a device for analyzing a test fluid, which is made very compact. According to the invention, this object is achieved with a device for analyzing a test fluid having the features of claim 1.

The device according to the invention for analyzing a test fluid has an inlet chamber, a treatment chamber and an analysis element. The device also has a housing with a housing interior, in which a treatment element at least partially limiting conditioning element and an input chamber at least partially limiting input element are arranged. The test strip is arranged in the housing so that it is at least partially visible from the outside. The input chamber is intended to receive the test fluid. Test fluid can be transferred from the input chamber to the analysis element via the treatment chamber.

According to the invention, the housing interior is cylindrical and the treatment element is rotatable relative to the input element and the housing. This makes it possible to make the housing very compact, in particular with a cylindrical or cuboid outer contour. The device is also easy and reliable to handle, since the various necessary for the analysis positions of the individual components to each other by a simple rotation of the processing element relative to the input member and the housing are adjustable.

In particular, the analysis element has one or more test strips which are arranged in the axial direction of the housing.

In an embodiment of the invention, the treatment element and the input element each have a mainly hollow cylindrical basic shape and the input element is disposed within the treatment element. The housing, the treatment element and the input element are designed and arranged so that in an initial position, the input chamber and the processing chamber are separated from each other. By rotating the treatment element relative to the input element, a filling position is adjustable, in which the treatment chamber is connected to the input chamber and separated from the analysis element. By rotating the treatment element relative to the housing, an analysis position is adjustable, in which the treatment chamber is connected to the analysis element. This allows a particularly compact design of the device and a particularly simple handling.

The rotation of the processing element from the starting position into the filling position and further into the analysis position takes place in particular in only one direction of rotation. It is possible that for safe adjustment of the various positions detents between the housing and processing element are provided, which fix the processing element in the individual positions, but can be suppressed. For this purpose, the processing element may have one or more recesses and the housing correspondingly positioned elevations. The detents can also be provided between the housing and a component connected to the treatment element, with which, for example, a force for rotating the treatment element can be introduced.

In an embodiment of the invention, the input chamber is separated from the analysis element in the analysis position. This prevents further test liquid from flowing during or after preparation and thus influencing the analysis result.

In an embodiment of the invention, the input element and the housing are rotatably connected to each other. This is necessary to adjust the various positions only a rotation of the treatment element. This allows a simple construction and easy handling of the device.

In an embodiment of the invention starting from the filling position by further rotation of the treatment element relative to the housing before reaching the analysis position, a treatment position is adjustable, in which the processing chamber is separated from the input chamber and the analysis element. This prevents further test liquid from flowing during or after preparation and thus influencing the analysis result. This makes very precise analyzes possible.

In an embodiment of the invention, the input chamber has at least one passage in the direction of the treatment element and the treatment chamber is designed as a continuous recess in the treatment element. This allows a particularly simple and inexpensive construction of the device.

Between the passage of the input chamber and the processing chamber, in particular, there is a connection only in the filling position. This prevents, on the one hand, unwanted test liquid from entering the processing chamber in the starting position and, on the other hand, prevents further test liquid from flowing during or after preparation and thus influencing the analysis result. This makes very precise analyzes possible.

By rotating the treatment element from the starting position relative to the input element and thus opposite the input chamber, the recess of the treatment element can be positioned so that it overlaps with said passage of the input chamber and is thus connected to the input chamber. This is the case in the filling phase, in which then fills the recess and thus the processing chamber with test liquid from the input chamber. The The inlet chamber and the treatment chamber are designed so that the treatment chamber is completely filled. Since the recess has a defined size, the treatment chamber contains a defined amount of test fluid after filling. This ensures a defined preparation of the test fluid and thus an accurate analysis result.

If the analysis element has more than one test strip, in particular for each test strip a separate passage of the input chamber and a separate recess of the treatment element and thus a separate processing chamber are provided. This makes it possible in an advantageous manner to be able to process the test liquid differently in the different processing chambers. For this purpose, for example, be contained in the different test chambers different reactants.

After filling, the input member is further rotated until the analysis position is reached, in which the recess of the input member does not overlap with the passage of the input chamber.

In an embodiment of the invention, the device has a plug, which can be inserted into an opening of the treatment element. A force for rotating the treatment element can be introduced via the plug. Thus, on the one hand, the input chamber can be closed in an initial state of the device and so contamination of the input chamber, which could falsify the analysis result, can be prevented. In this context, an initial state of the device should be understood to be an unused state, that is to say the state before the start of an analysis of a sample substance or a test fluid. In addition, the plug can additionally be used to adjust the various positions of the treatment element necessary for the analysis of the test fluid.

In an embodiment of the invention, the stopper and the said opening of the treatment element have corresponding cross sections in the form of a so-called equal dia. The plug and the opening are made conical, in particular in the axial direction. When inserting, this causes the stopper to self-center in the opening. Thus, the plug can be easily inserted into the opening and it is still a good power transmission from the plug to the treatment element guaranteed.

An equal thickness is a closed line that always touches all four sides in any position within a suitable square. The cross section may also be referred to as a so-called harmonic polygon profile with a so-called continuous P3 shape curve.

In an embodiment of the invention, the plug has a sample collector. Thus, only a few parts are necessary for the device.

In an embodiment of the invention, the plug has a storage cylinder. The storage cylinder contains in the initial state of the device leaching. Thus, the leaching liquid can only be filled in the input chamber when it is really needed, without providing for the leaching a separate container. For example, if the plug was removed with the sample collector to take a sample, there is still no leaching in the input chamber, which could leak out unintentionally.

In an embodiment of the invention, the plug has a base body with a mainly cylindrical inner contour and a relative to the main body immovable inner part. The inner part dives when inserting the storage cylinder into the main body in the storage cylinder and closes the storage cylinder in a start position. It also has a connecting line, which is connected after leaving the starting position with the storage cylinder and over which is inserted in the plug leaching fluid into the input chamber can be conducted. This allows in a very simple manner, the feeding of the leaching into the input chamber. This only needs the supply cylinder in the direction Input chamber are pressed and thus pushed onto the inner part. The inner part and the base body of the plug can consist of either one or more parts, in particular two parts.

In an embodiment of the invention, the storage cylinder has an inner circumferential sealing lip on which the inner part of the base body is present in the starting position and thus concludes the storage cylinder. The connecting line has a radial section and an axial section which are designed such that after the radial section has at least partially passed over the sealing lip of the storage cylinder, leaching fluid can be pressed out of the storage chamber via the radial section into the axial section. This allows a particularly simple construction of the plug.

Said radial section does not have to be exactly radial; it is sufficient if it has a radially inward component from one edge of the inner part, so that leaching fluid can flow inward from the edge of the inner part to the axial section. The axial section also does not have to be exactly aligned axially. It is sufficient if it is designed so that it can guide leaching fluid from the radial section in the axial direction in the direction of the inlet chamber. The axial section runs in particular at least partially in a shaft of the sample collector.

In an embodiment of the invention, the housing has a first recess, through which markings on the treatment element, which indicate a current position of the treatment element, are visible. In addition, you can also be informed about corresponding waiting times in the individual positions. This allows a user to be informed simply about the current progress of the analysis and to be alerted to any waiting times to be observed. This ensures safe handling and thus reliable analysis results.

In an embodiment of the invention, the analysis element has at least one or more, in particular two test strips, which is arranged in the housing and is visible through a second recess in the housing.

The individual parts of the device may for example be made of polyethylene or polypropylene and in particular be produced by means of an injection molding process.

Further advantages, features and details of the invention will become apparent from the following description of exemplary embodiments and with reference to the drawings, in which the same or functionally identical elements are provided with identical reference numerals.

Fig. 1

eine Vorrichtung zur Analyse einer Test-Flüssigkeit in einem Ausgangszustand,

Fig. 2

die Vorrichtung aus Fig. 1 mit abgenommenem Stopfen,

Fig. 3

die Vorrichtung aus Fig. 1 in einer Schnittdarstellung,

Fig. 4

ein Stopfen mit einem Probesammler in einer Schnittdarstellung,

Fig. 5

eine Schnittdarstellung der Vorrichtung in einer Ausgangsposition,

Fig. 6

eine Fig. 5 entsprechende Schnittdarstellung der Vorrichtung in einer Füllposition,

Fig. 7

eine Fig. 5 entsprechende Schnittdarstellung der Vorrichtung in einer Analyseposition und

Fig. 7

eine zweite Schnittdarstellung der Vorrichtung an einer anderen axialen Position.

Showing:

Fig. 1

a device for analyzing a test fluid in an initial state,

Fig. 2

the device off Fig. 1 with removed plug,

Fig. 3

the device off Fig. 1 in a sectional view,

Fig. 4

a plug with a sample collector in a sectional view,

Fig. 5

a sectional view of the device in a starting position,

Fig. 6

a Fig. 5 corresponding sectional view of the device in a filling position,

Fig. 7

a Fig. 5 corresponding sectional view of the device in an analysis position and

Fig. 7

a second sectional view of the device at a different axial position.

According to Fig. 1 For example, a device 10 for analyzing a test fluid has a housing 11 which has a basically cylindrical outer contour. On and partially into the housing 11, a plug 12 is attached, which has a in Fig. 1 not visible opening of the housing 11 closes. The plug 12 can be rotated relative to the housing 11, whereby different phases of the analysis, in which different components of the device must assume certain positions, can be adjusted.

In Fig. 2 the plug 12 is removed from the housing 11. The plug 12 has a sample collector 13 which, in the inserted state of the plug 12 in accordance Fig. 1 is disposed within the housing 11. The sample collector 13 has a shaft 14 and a receiving tip 15. The shaft 14 of the sample collector 13 also has a sealing washer 46, which for sealing a in Fig. 2 not shown inlet chamber is used.

According to Fig. 3 the housing 11 has a cylindrical housing interior 16, in which a mainly hollow-cylindrical processing element 17 is arranged. The processing element 17 partially limits two treatment chambers, but only in the FIGS. 5, 6 and 7 are shown in more detail. Within the treatment element 17, a likewise mainly hollow-cylindrical input element 18 is arranged, which forms an input chamber 19 in its interior. The input element 18 and thus the input chamber 19 have two diametrically opposite passages 20, 21 in the direction of treatment element 17. As will be described further below, a connection between the inlet chamber 19 and the treatment chambers can be established via the two passages 20, 21.

The stopper 12 closes on the one hand with an inner part 22, the input chamber 19 and is used on the other with an outer part 23 in an opening 42 of the treatment element 17.

The outer part 23 of the plug 12 and the opening 42 of the treatment element 17 have no circular cross-section, but the contour of a DC, in particular a so-called continuous P3 shape curve, which is not clearly seen in the figures. The outer part 23 of the plug 12 and the opening 42 are also made conical only a few degrees in the direction of receiving tip 15. By said contour can be exerted or introduced by the plug 12, a force to rotate with respect to the input member 18 and the housing 11 1 on the processing element 17. Thus, the processing element 17 by means of the plug 12 relative to the input member 18 and the housing 11 are rotated. The input element 18 and the housing 11 are rotatably connected to each other, which is realized via a snap connection between input element 18 housing 11, not shown.

As in Fig. 4 illustrated, the plug 12 has a storage cylinder 25 which contains a leaching liquid in an initial state of the device 10. The storage cylinder 25 is inserted in the initial state of the device only a piece into a base body 26 of the plug 12, which corresponds to a starting position of the storage cylinder 25. The main body 26 has a mainly cylindrical inner contour, which corresponds to an outer contour of the storage cylinder 25. Within the base body 26, a stationary relative to the base body 26 inner part 27 is arranged, which is arranged within the storage cylinder 25. The inner part 27 abuts in the starting position of the storage cylinder 25 at an inner peripheral sealing lip 28 of the storage cylinder 25, whereby the storage cylinder 25 is sealed and no washout liquid can escape from the storage cylinder 25.

After a sample substance, for example, saliva of a subject was taken with the receiving tip 15 of the sample collector 13 and the plug 12 has been attached to the housing 11, the leaching liquid from the storage cylinder 25 must be brought into the input chamber 19. For this purpose, the storage cylinder 25 is pressed starting from its starting position in the direction of the housing 11, whereby a radial section 29 of a connecting line 30 via the sealing lip 28 and then to you are pushed past. This leaching fluid from the storage cylinder 25 can flow into the radial section 29 of the connecting line 30, which extends from the radially outside to the inside. The radial section 29 of the connecting line 30 is connected to an axial section 31 of the connecting line 30, which extends within the shaft 14 of the sample collector 13. The axial section 31 of the connecting line 30 extends up to an outlet opening 32, which is seen from the storage cylinder 25 below the sealing disc 46. Thus, 12 can be brought from the storage cylinder 25 in the input chamber 19 by inserting or pushing the stock cylinder 25 into the main body 26 of the plug 12 leaching. Thus, the receiving tip 15 of the sample collector 13 is immersed in the leaching liquid located in the inlet chamber 19. By shaking the device 10, the recorded sample substance is washed out. The mixture of sample substance and leachate gives a test liquid, which can then be analyzed.

For the further analysis of the test liquid, first a certain amount of the test liquid has to be brought into one or more processing chambers and from there on to an analysis element.

The necessary steps will be taken by hand FIGS. 5, 6 and 7 described. In these figures, outside the housing 11 is shown, in which diametrically opposite two test strips 35, 36 are arranged as part of an analysis element. A flow direction of the test strips is parallel to the shaft 14 of the sample collector 13, ie in the axial direction. Within the housing 11, the processing element 17 is arranged. The treatment element 17 has two diametrically opposite recesses, which form treatment chambers 33, 34. Within the treatment element 17, the input element 18 is arranged with its already described passages 20, 21. The individual, in the FIGS. 5, 6 and 7 shown positions of the device 10 differ only in the position of the processing chambers 33, 34 to the passages 20, 21 and to the test strips 35, 36th

In an in Fig. 5 illustrated starting position of the device 10, the input chamber 19 in the direction of treatment chambers 33, 34 and test strips 35, 36 closed. The processing chambers 33, 34 have no overlap with the passages 20, 21 of the input chamber 19.

By rotating the processing element 17 relative to the input member 18 by means of the plug 12, the in Fig. 6 set filling position shown. In the filling position, the treatment chambers 33, 34 overlap each with a passage 20, 21 of the inlet chamber 19, but not with the test strips 35, 36. Thus, the treatment chambers 33, 34 are filled with test liquid. For this to happen reliably, the device 10 should be held so that the plug 12 is located at the top and the shaft 14 of the sample collector is aligned as vertically as possible upwards. Then it is ensured that due to gravity, the treatment chambers 33, 34 completely filled with test liquid and thus each a defined amount of test liquid from the input chamber 19 into the processing chambers 33, 34 is filled. In the processing chambers 33, 34 is in each case a reaction partner, for example in the form of gold conjugate, which processes the test liquid.

After filling the treatment chambers 33, 34, the treatment element 17 is rotated further into a processing position, not shown. In the preparation position, the treatment chambers 33, 34 have neither a cover with the passages 20, 21 of the input chamber 19, nor with the test strips 35, 36 as in the starting position. The treatment takes a fixed period of, for example, 4 minutes, which must be awaited.

It is not absolutely necessary that the filling position is fixed for a certain time. It is sufficient if the filling position is run over during rotation of the processing element 17 from the starting position to the processing position.

After the end of the treatment, the processed test liquid from the processing chambers 33, 34 must be brought to one end of the test strips 35, 36. For this purpose, the processing element 17 from the processing position in the in Fig. 7 rotated analysis position shown. In the analysis position, the treatment chambers 33, 34 have an overlap with the test strips 35, 36, so that processed test liquid can reach the test strips 35, 36. The test fluid then flows through the test strips as described above, so that after a specified waiting time of, for example, 8 minutes, the analysis result can be read on the test strip. In the analysis position, the treatment chambers 33, 34 have no overlap with the passages 20, 21 of the inlet chamber 19.

As in Fig. 8 illustrated, the housing 11 has a first recess 37, through which markings 38 on the processing element 17, which indicate the current position processing element 17, are visible. The display of the position may also consist of the fact that the duration of a waiting time already described above is displayed.

The housing 11 has parallel to the first recess 37 and offset by 90 ° to a second recess 39, through which the test strip 35 of the analysis element visible and thus the analysis result is read.

Claims (15)

Device for analyzing a test fluid with an input chamber (19), a processing chamber (33, 34), an analysis element (35, 36), a housing (11) having a housing interior (16), - A treatment element (17) which at least partially limits the processing chamber (33, 34) and within the housing interior (16) is arranged and an input element (18) which at least partially delimits the input chamber (19) and is arranged inside the housing interior (16),
in which the input chamber (19) is provided to receive the test fluid, - Test fluid from the input chamber (19) via the processing chamber (33, 34) on the analysis element (35, 36) can be brought and - The analysis element (35, 36) is arranged in the housing (11) that it is at least partially visible from the outside,
characterized in that - The housing interior (16) is cylindrical and - The processing element (17) relative to the input member (18) and the housing (11) is rotatable. Device according to claim 1,
characterized in that - The treatment element (17) has a mainly hollow cylindrical basic shape, - The input member (18) has a mainly hollow cylindrical basic shape and is disposed within the treatment element (17) and - The housing (11), the treatment element (17) and the input member (18) are designed and arranged so that in an initial position, the input chamber (19) and the treatment chamber (33, 34) are separated from each other, by rotating the treatment element ( 17) relative to the input member (18) a filling position is adjustable, in which the treatment chamber (33, 34) connected to the input chamber (19) and the analysis element (35, 36) is separated and by rotating the treatment element (17) relative to the housing (11) an analysis position is adjustable, in which the treatment chamber (33, 34) with the analysis element (35, 36) is connected. Apparatus according to claim 1 or 2,
characterized in that
in the analysis position, the input chamber (19) is separated from the analysis element (35, 36). Apparatus according to claim 1, 2 or 3,
characterized in that
the input member (18) and the housing (11) are rotatably connected to each other. Device according to one of claims 1 to 4,
characterized in that
Starting from the filling position by further rotation of the treatment element (17) relative to the housing (11) before reaching the analysis position, a treatment position is adjustable, in which the treatment chamber (33, 34) of the input chamber (19) and the analysis element (35, 36) is disconnected. Device according to one of claims 1 to 5,
characterized in that
the inlet chamber (19) has at least one passage (20, 21) in the direction of the treatment element (17) and the treatment chamber (33, 34) is designed as a continuous recess in the treatment element (17). Device according to claim 6,
characterized in that
between the passage (20, 21) of the inlet chamber (19) and the treatment chamber (33, 34) only in the filling position is a connection. Device according to one of claims 1 to 7,
marked by
a plug (12) which can be inserted into an opening (42) of the treatment element (17) and via which a force for rotating the treatment element (17) can be introduced. Device according to claim 8,
characterized in that
the stopper (12) and said opening (42) of the treatment element (17) have corresponding cross-sections in the form of a so-called equal dia and in particular are conical in the axial direction. Device according to claim 8 or 9,
characterized in that
the plug (12) has a sample collector (13). Apparatus according to claim 8, 9 or 10,
characterized in that
the plug (12) has a storage cylinder (25) which contains leaching liquid in an initial state. Device according to claim 11,
characterized in that
the stopper (12) has a main body (26) with a mainly cylindrical inner contour and an inner part (27) which is immovable relative to the main body (26) and engages in the supply cylinder (25) when the supply cylinder (25) is pushed into the main body (26). submerges, closes the supply cylinder (25) in a start position and has a connecting line (30) which is connected to the supply cylinder (25) after leaving the starting position and via which leaching liquid into the input chamber (19) can be conducted. Device according to claim 12,
characterized in that
the supply cylinder (25) has an inner circumferential sealing lip (28) on which the inner part (27) of the main body (26) is in the starting position,
the connecting line (30) has a radial section (29) and an axial section (31) which are designed so that after the radial section (29) has at least partially passed over the sealing lip (28) of the supply cylinder (25), washout fluid from the storage chamber ( 25) can be pressed into the axial section (31) via the radial section (29). Device according to one of claims 1 to 13,
characterized in that
the housing (11) has a first recess (37) through which markings (38) on the treatment element (17), which indicate a current position of the treatment element (17), are visible. Device according to one of claims 1 to 14,
characterized in that
the analysis element has a test strip (35, 36) disposed in the housing (11) and visible through a second recess (39) in the housing (11).

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