DE10351160B3 - Continuous-flow cuvette and mid-range infra-red transmission spectrometer for biological fluids, comprises flow channel with two separate optical paths - Google Patents

Abstract

Continuous-flow cuvette and mid-range infra-red transmission spectrometer comprising a chamber (20) includes a flow channel (4) leading to an outlet (3) past two pairs of mid-range infra red- (MIR-) transparent windows (7a, 7a'; 7b, 7b') spaced about transmission paths (d) and inside the chamber, a projection (5) into the flow channel, includes an optical path (6), is new. Continuous-flow cuvette and mid-range infra-red transmission spectrometer comprises a chamber (20) includes a flow channel (4) leading to an outlet (3) past at least two pairs of mid-range infra red- (MIR-) transparent windows (7a, 7a'; 7b, 7b') spaced about transmission paths (d). Inside the chamber, a projection (5) into the flow channel, includes an optical path (6). This projection is integral with the wall (9a). The free end of the projection includes one window (7a) of the first pair (7a, 7a'), and one window (7b) of the second pair (7b, 7b'). These windows (7a, 7b) are adjacent, forming a step. The windows (7a, 7b) of the projection are angled. It is made of silicon. Walls of the chamber have a seal (8). This allows relative movement of the walls, to vary transmission path lengths (d, d'). The seal includes a bellows or a resilient polymer. An actuator motor (15) varies the transmission path. All windows are smaller than the cross-sectional area of the flow channel, at its narrowest point. The narrowest width of the flow channel is one fifth to preferably one tenth of a transmission path (d, d'). The width at this point is 0.1 to preferably 0.5 mm. Total volume of the flow channel (4) is preferably less than 0.7 ml. An independent claim is also included for the corresponding transmission spectrometer.

Description

The The invention relates to a flow measuring cuvette for transmission spectroscopic Examination of biological fluids in the mid-infrared spectral region (MIR) and a transmission spectrometer.

Known flow measuring cuvettes consist, for example, of two plates of an MIR-transparent material, for example silicon, which face each other at a small distance parallel or nearly parallel and form the window surfaces for the MIR radiation to be passed through. Between the two platelets, a metal ring can be fitted as a spacer, which has inlet and outlet openings for the biological fluids to be examined. Other cell constructions are for example in EP 1037035 B1 , in the US 2002/0182631 A1 and the DE 4137060 A1 described.

biological Liquids, such as blood, blood plasma, blood serum, hemolysate, Cerebrospinal fluid, urine, saliva, sperm, lymph fluid, synovial fluid, Amniotic fluid, tear fluid, Cyst fluid, sweat secretion or bile, are always aqueous solutions and Therefore, in the MIR range, the radiation of a wavelength of 2 to 20 μm includes, absorption coefficients with very large values. This leads to, that, for example at one wavelength of 10 μm 99.99% of a radiated infrared light intensity on one Transmission distance of 100 μm be absorbed. This results in the need to examine the biological fluid in the measuring cuvette in to arrange a layer thickness of only about 10 to 100 microns. At the beginning mentioned known flow measuring cuvettes is this is achieved in that between the two windows the cuvette Spacer is provided a correspondingly small thickness.

The with the study of native samples of biological liquids Problems associated with ME are discussed in WO 02/057753 A2. There, a transmission distance of less than 30 microns is required. However, no information is given as to how they are achieved can.

One special problem results from the fact that for filling a volume of formed two opposite with very small distance plates is due to the fluid dynamic laws a considerable pressure needed up to 50 bar becomes. Such a high pressure causes the walls of the Deform flow measuring cuvette and thereby the length the transmission distance between the two window areas changes. This leads to an unwanted change of the signal that is not spectroscopically or very difficult of to distinguish a concentration-related change in absorption is.

task The invention is therefore to show a way as in a MIR transmission spectroscopic examination of a biological fluid the measuring accuracy increases can be and in particular influences of the initiation of the examined liquid required in a flow-through cuvette filling pressure, can be reduced to the spectroscopic measurements.

The The object is achieved by a flow-through cuvette with the characteristics of Claim 1 solved.

A flow-through cuvette according to the invention goes to avoid unwanted Influences of the filling pressure on the measuring signal not the way, by a particularly robust execution of the cuvette one pressure-related curvature to counteract the window, but reduces the initiation a biological fluid required filling pressure. In a flow measuring cuvette according to the invention the flow resistance of the flow channel almost independent from the length of the Transmission route. The flow channel can therefore be optimized in terms of its flow characteristics become. This not only greatly reduces the filling pressure, but also also the cleaning ability a flow measuring cell according to the invention advantageously improved.

Of the in the flow channel protruding light channel projection is of the liquid to be examined lapped on the side, so that one low total flow resistance of the flow channel is achieved, which makes a high inflation pressure superfluous. At the same time, the liquid to be examined lies on the transmission path between the free end of the light channel projection and the opposite Window in a sufficiently thin layer thickness in front. In particular, in a flow measuring cuvette according to the invention by the distance the window provided at the free end of the light channel projection to the opposite Window predetermined transmission distance in the range of 10 to 100 microns free according to Requirements of the fluid to be examined are selected, without that the flow resistance of the flow channel being affected.

Preferably, the flow channel at its narrowest point in each direction has a width which is at least five times, preferably at least ten times the transmission distance. In this way it is achieved that the liquid to be examined laterally of the light channel projection finds sufficient space to flow past with low filling pressure can. Particularly favorable flow conditions arise when the flow channel at its narrowest point - in particular the side of the transmission path - in each direction has a width of at least 0.1 mm, preferably 0.5 mm. An upper limit for the narrowest point of the flow channel does not exist under fluidic aspects, but increases with increasing cross-section of the flow channel and the chamber volume and thus required for an investigation amount of biological fluid. Preferably, the total volume of the flow channel is at most 1 ml, more preferably at most 0.7 ml.

Of the Light channel projection contains a light channel through which the radiated from a light emitter into the cuvette primary light up to the window located at its free end or after the Passing the transmission path resulting secondary light of the window at its free end towards one Detector is passed. The term "window" should not be understood as limiting in the sense may be that one Window must be present. Rather, the transparent ones Solid surfaces, the limit the transmission path on both sides, referred to as windows.

For the MIR area Suitable light guides can be produced, for example, as silver halide fibers. So that these of the to be examined aqueous biological fluids Not to be attacked, it is recommended to use the optical fiber on its peripheral surface through a suitable envelope, for example, a water resistant Protect paint. The free end of the fiber forming the window can pass through to be protected by a MIR-transparent coating.

A advantageous development of the measuring cuvette provides that the distance changeable between the two windows of the window pair is. This is preferably achieved in that the wall, the chamber encloses a first and a second wall element. On the wall element each one of the two windows is provided. The two wall elements are about Connected sealing means which are so flexible and / or elastic are that the first Wall element is movable relative to the second wall element and so the distance between the two windows can be changed.

at the MIR transmission spectroscopic examination biological Liquids come it often before that the optical absorption in parts of the spectrum is very strong, while other areas have low absorption. For the signal-to-noise ratio are with strong absorption shorter Transmission distances and with less absorption longer transmission distances advantageous. By varying the distance of the window of a flow measuring cuvette according to the invention, the Transmissionsstrecke adapted to the occurring absorption structures and thereby the signal-to-noise ratio be optimized. It is advantageous not only an improved accuracy, but also, that yourself at the investigated Spetralbereich strongly changing absorption the sample must be introduced only once in a flow measuring cuvette and not about two or even three flow cuvettes with Different transmission distances must be prepared. The Examination of a biological fluid in two flow measuring cuvettes with different transmission distances does not just mean one considerable effort, but also that the acquired spectra, e.g. due to unavoidable drift effects of the spectrometer, only to a limited extent are comparable.

When Seal between the two wall elements is suitable, for example an elastic plastic which has a relative mobility allows the two wall elements to each other. As for a MIR transmission spectroscopic Analysis of a biological fluid As a rule, no transmission links outside of a range of 10 to 100 μm needed be enough a relatively low mobility of the two wall elements to each other, as easily ensured by elastomeric sealing materials can be. Preferably, the movable seal by means of a Bellows running, since this is u.a. offers the advantage, with a low force change the transmission path to be able to. This can be done for example with a servomotor.

For the examination of biological fluids, a method for transmission spectroscopic analysis is suitable in which radiation emitted by a light source is passed through a flow measuring cuvette in which the fluid is passed between two transparent windows through whose distance a transmission path is predetermined, wherein a portion of the light is absorbed by the liquid, and detects the resulting after passing through the transmission path intensity of the light passed through the sample and from a spectrum of the liquid is determined, which is characterized in that the length of the transmission path is changed in dependence on the detected intensity. This method allows a biological fluid over the entire spectral range examined with an optimal signal-to-noise ratio and thus high accuracy of measurement to investigate. If it is determined during a measurement that the absorption is so low or so high that the resulting increase or decrease of the detected secondary light intensity leads to a deterioration of the signal-to-noise ratio, the transmission distance can be increased or decreased immediately and thus the signal Improve noise ratio.

One corresponding transmission spectrometer has a flow measuring cell with two variable spacing Windows that specify a transmission path, and a motor for changing the Distance between the two windows. For evaluation by a detector detected intensity an evaluation and control unit is provided by pressing the Motors the distance between the two windows and thus the length of the transmission path automatically depending on detected Intensity changes.

Further details and advantages of the measuring cuvette and the spectrometer will become apparent from an embodiment with reference to the accompanying 2 explained. The remaining figures serve for general explanation but show no embodiment of the measuring cuvette.

Same or corresponding components are with matching reference numerals characterized. Show it:

1 a flow-through cuvette in cross-section,

2 An embodiment of a flow measuring cuvette according to the invention in cross section,

3a a schematic sketch of a MIR transmission spectrometer and

3b a detailed presentation of in 3a shown flow measuring cuvette with an enlarged detail.

In the 1 shown flow measuring cuvette 1 is used for transmission spectroscopic examination of biological fluids in the MIR. A biological fluid to be tested passes through a fluid inlet 2 in a chamber 20 which has a flow channel 4 between the liquid inlet 2 and the liquid outlet 3 provides. Inside the chamber 20 is a light channel projection 5 provided in the flow channel 4 protrudes. The light channel projection 5 contains a light channel 6 , which is formed as an optical fiber, and has at its free end a MIR-transparent window 7 on. It forms together with a window opposite it 7 ' located at the free end of a second light channel projection 5 ' located, a transmission path d, which is filled by the liquid to be examined. The flow-through cuvette 1 is formed so that the flow channel 4 one of the width of the gap between the windows 7 . 7 ' (ie, the length of the transmission path d) decoupled low flow resistance. The liquid to be tested flows on its way from the liquid inlet 2 to the liquid outlet 3 laterally around the two light channel projections 5 . 5 ' around, without the need for high pressure. The flow channel has at its narrowest point in each direction to a width which is a multiple of the transmission path, at least five times, preferably ten times. In absolute terms, this means in the embodiment shown a minimum width of 1 mm with a total volume of the flow channel of 0.7 ml.

The light channel projections 5 . 5 ' contain an optical fiber 6 . 6 ' from silver halide. Other suitable MIR-transparent optical waveguide materials are, for example, sodium chloride, potassium bromide, cesium iodide, barium fluoride, cadmium telluride, diamond, gallium arsenide, germanium, silicon or zinc selenide, with zinc selenite, silicon and diamond being particularly preferred in addition to silver halide. If the optical fiber 6 . 6 ' is not attacked by aqueous biological fluids, the opposing MIR transparent windows 7 . 7 ' from the end surfaces of the optical fibers 6 . 6 ' be formed. Is the material of the optical fibers 6 . 6 ' not water resistant, need the optical fibers 6 . 6 ' be protected by a water-resistant, MIR-transparent material from the biological fluid to be examined.

In the 1 shown flow measuring cuvette 1 has two wall elements 9a . 9b on, who together form the wall, the chamber 20 encloses. The wall elements 9a . 9b are made of metal, preferably stainless steel. They each form one of the two light channel projections 5 . 5 ' out and envelop the optical fibers 6 . 6 ' ,

As an alternative to the in 1 shown construction, the light channel projections 5 . 5 ' Also include a longitudinally extending cavity in which the MIR radiation is guided as a free jet, so that advantageous to the optical fibers 6 . 6 ' can be waived. The in the light channel protrusions 5 . 5 ' contained cavities are of windows 7 . 7 ' made of a MIR transparent material, eg zinc selenide.

The two wall elements 9a . 9b are about moving sealants 8th liquid-tight connected. These sealants 8th are preferably designed as a bellows, in particular metal bellows, or as a sealing element made of an elastic polymer and allow it, the transmission distance d between the opposite windows 7 . 7 ' by moving the two wall elements toward or away from each other 9a . 9b to change. This can be done for example by means of a servomotor. In this way, the length of the transmission path d can be adapted to the absorption properties of the biological fluid under investigation: this can even be done automatically during a measurement by means of a corresponding evaluation and control device of a spectrometer. Below the intensity of the through the measuring cuvette 1 light transmitted through a predetermined value, so the transmission distance d can be reduced, which leads to an increase in the intensity and thus to an improvement of the signal-to-noise ratio. Conversely, the transmission distance d can be increased as soon as the intensity of the through the measuring cuvette 1 passed MIR radiation exceeds a predetermined value. For the evaluation of the measurements, it is particularly favorable if the transmission path d is changed stepwise in always the same steps.

The Adjustability of length the transmission path d leads in certain circumstances to that the absolute Length of Transmission line initially not is readily known. The absolute length of the transmission path d can, however, based on the law of absorption, according to which the light intensity with increasing Transmission distance d exponentially declines, calculated with little effort become. For this the must Absorption at at least two different transmission path lengths d, measured d + Δd which differ by a known distance Δd, (one step). The length or a change in length the transmission path d can also be independent of a transmission signal be determined, in particular by an interferometric measurement. For example, visible laser light, such as from a HeNe laser, blasted through the measuring cuvette and tested for interference effects become.

2 shows an embodiment of the flow measuring cuvette 1 according to claim 1 in cross section. It has a substantially planar structure and consists essentially of two wall elements 9a . 9b and a seal 8th put together the chamber 20 and the flow channel 4 form for the biological fluid to be examined. The seal 8th is designed as a metal ring, which has a liquid inlet 2 and a liquid outlet 3 having.

Unlike the in 1 shown cuvette are the wall elements 9a . 9b at the in 2 ge showed embodiment as a flat surfaces made of silicon. Not only does silicon have the advantage of being transparent to MIR radiation, but it can also be easily processed in various geometries; in particular, flat geometries can be used, as in the case of wall elements 9a . 9b , cost-effective manufacture. Integral with the wall element 9a is at the in 2 shown embodiment of the light channel projection 5 educated. Because of the strong absorption of aqueous liquids in the mid-infrared range, it penetrates the wall element 9a or 9b irradiated MIR radiation 16 the cuvette 1 practically only in the area of the light channel projection 5 and is otherwise absorbed by the aqueous biological fluid.

The light channel projection 5 consists in this embodiment, as the wall elements 9a and 9b , made of silicon, which simplifies the manufacturing and sealing problems in the area of the light channel projection 5 the chamber 20 avoids. Two of the transmission line d facing windows 7a . 7b are from the end surfaces of the light channel projection 5 and two windows 7a ' and 7b ' from these opposite parts of the wall element 9b educated.

The as a spacer and seal 8th used metal ring allows no change in the distance b of the two opposing wall elements 9a . 9b , Although in itself could be in this embodiment, an elastomeric seal, which is an adjustability of the distance b of the wall elements 9a . 9b and thus also the transmission path d allowed to be used. Even without the expense of changing the distance b between the wall elements 9a . 9b different transmission distances d, d 'are to be provided in the in 2 shown embodiment, two different pairs of windows, namely 7a . 7a ' and 7b . 7b ' intended.

The window 7a . 7b are directly next to each other on the light channel projection 5 intended. The window 7a it borders on the window 7b training one level. The out of the window 7a Exiting MIR radiation passes through a shorter transmission distance d than that from the window 7b exiting MIR radiation and is therefore subjected to lower absorption. The window 7a . 7b The two pairs of windows, which define different transmission line lengths, can in principle also be provided on separate light channel projections.

Depending on the absorption behavior of the examined biological fluid in the flow channel 4 performs a measurement with the transmission path d or with the transmission path d ' at a better signal-to-noise ratio. The windows are preferred 7a . 7b and 7a ' . 7b ' designed and arranged so that multiple reflections between opposite windows 7a . 7b . 7a ' . 7b ' be avoided. For example, the windows 7a and 7b beveled. The bevel is in 2 for exaggeration illustrated and is less than 10 °, preferably less than 1 ° and in the embodiment shown actually only 0.3 °. In order to avoid multiple reflections but other window geometries are possible, for example, curved or conical surfaces.

3a schematically shows the structure and function of an IR transmission spectrometer. From an IR transmitter 12 , preferably an IR laser, in particular a quantum cascade laser, emitted MIR radiation is transmitted via optical fibers 6 . 6 ' through an in 3b and the associated detail enlargement detailed flow measuring cuvette 1 through and to a detector 10 , preferably a pyroelectric detector, passed. The one from the detector 10 detected intensity is determined by means of an evaluation 11 evaluated, the resulting absorption spectrum 13 created. If an unfavorable signal-to-noise ratio is detected during this evaluation, an electronic control unit operates 14 a servomotor 15 who is the light guide 6 to change the length of the transmission path d a little further from the measuring cuvette 1 pull it out or push it deeper into it. The transmission spectrometer described thus makes possible a method for transmission-spectroscopic analysis of a biological fluid, in particular in the MIR range, in which radiation emitted by a light source is passed through a flow-through measuring cuvette in which the fluid is between two windows 7 . 7 ' is present, through whose distance a transmission path d is given, wherein a part of the light is absorbed by the liquid and the length of the transmission path is changed in dependence on the detected intensity. The change in the length of a transmission path by moving optical fibers is a constructive measure known in another context ( DE 10016023 C2 ).

At the in 3b shown flow measuring cuvette 1 the wall of a chamber consists essentially of a silicone tube 9 that has a flow channel 4 encloses. In the silicone tube 9 put two light guides 6 . 6 ' their opposite end surfaces of the transmission path facing window pairs 7 . 7 ' form. To change the length of the transmission path d between the two windows 7 . 7 ' becomes the light guide 6 with a servomotor deeper into the silicone tube 9 pushed in or pulled out of it. The silicone tube 9 has in its lateral surface two openings for the liquid inlet 2 and the liquid outlet 3 on.

Claims (11)

Flow-through cuvette for the transmission spectroscopic examination of biological fluids in the mid-infrared spectral region (MIR) with a chamber ( 20 ) for receiving the liquid to be examined, which has a flow channel ( 4 ) between a liquid inlet ( 2 ) and a liquid outlet ( 3 ), whereby - the chamber ( 20 ) at least two pairs of windows ( 7a . 7a '; 7b . 7b ' ) from two opposite MIR transparent windows ( 7a . 7a ' . 7b . 7b ' ), whose distance in each case a transmission distance (d, d ') is predetermined, - in the interior of the chamber ( 20 ) in the flow channel ( 4 ) protruding light channel projection ( 5 ) arranged in one piece with a wall element ( 9a ) the chamber ( 20 ) is formed, a light channel ( 6 ) and at its free end one of the two windows ( 7a ) of the first pair of windows ( 7a . 7a ' ) and one of the two windows ( 7b ) of the second window pair ( 7b . 7b ' ), - the two windows ( 7a . 7b ) adjoin one another to form a step. Flow-through cuvette according to claim 1, wherein the surface of at least one of the windows ( 7a . 7b ) of the light channel projection ( 5 ) is bevelled. Flow-through cuvette according to claim 1 or 2, wherein the one-piece with the wall element ( 9a ) formed Lichtkanalvorsprung ( 5 ) consists of silicon. Flow measuring cuvette according to one of claims 1 to 3, wherein the chamber ( 20 ) a second wall element ( 9a . 9b ) which integrally with the light channel projection ( 5 ) formed wall element ( 9a ), wherein the two wall elements ( 9a . 9b ) about sealants ( 8th ), which allow the first wall element ( 9a ) relative to the second wall element ( 9b ) and thus to change the transmission distances (d, d '). Flow measuring cuvette according to claim 4, wherein the sealing means ( 8th ) include a bellows or sealing element made of an elastic polymer. Flow measuring cuvette according to claim 4 or 5, wherein a servomotor ( 15 ) for changing the transmission paths (d, d ') is present. Flow measuring cuvette according to one of claims 1 to 6, wherein the windows ( 7a . 7a ' . 7b . 7b ' ) each have an area that is smaller than the Cross-sectional area of the flow channel ( 4 ) at its narrowest point. Flow measuring cuvette according to one of claims 1 to 7, wherein the flow channel ( 6 ) at its narrowest point in each direction has a width which is at least five times, preferably at least ten times, one of the transmission distances (d, d '). Flow measuring cuvette according to one of claims 1 to 8, wherein the Strömüngskanal ( 4 ) at its narrowest point in each direction has a width of at least 0.1 mm, preferably at least 0.5 mm. Flow measuring cuvette according to one of claims 1 to 9, wherein the flow channel ( 4 ) has a total volume of less than 1 ml, preferably less than 0.7 ml. Transmission spectrometer for the examination of biological fluids with a light source ( 12 ), a flow measuring cuvette ( 1 ) according to one of claims 1 to 10, a detector ( 10 ) for detecting the intensity resulting after passing through the transmission path (d), and an evaluation and control unit ( 11 . 14 ), by means of which the detected intensity is evaluated, wherein the length of the transmission paths (d, d ') by changing the distance between the wall elements ( 9a . 9b ) by means of a motor ( 15 ) is adjustable and the distance of the two wall elements ( 9a . 9b ) is adjusted automatically in response to the detected intensity by operating the motor under control of the evaluation and control unit.