KR20140058642A - Cuvette - Google Patents

Abstract

A cuvette for removably retaining a liquid sample in situ in an analytical device, such as a spectrophotometer, is elongate and includes a body having a first portion (8) and a second portion (10). The body includes a chamber (40, 50, 52) for holding a sample, the chamber having respective parts of the inner surface of the chamber, which are supported on the two body parts. Either part can be away from the other part to open the chamber, allowing access to the other part at a distance from the ends of the body.

Description

Cuvette {CUVETTE}

The present invention relates to cuvettes for removably retaining liquid samples in situ in an analytical device and to such devices when fitted to such cuvettes.

Conventional cuvettes are sealed at one end and are small tubes of circular or square cross-section that removably hold the sample in an analytical device, such as a device for performing a photometric or spectrophotometric analysis of a liquid sample. Sometimes, this type of device is used for the analysis of small volumes of liquid samples, such as volumes of 5 mu l or less, as can be used for quantitative analysis of aqueous samples of DNA made in the laboratory. Such DNA is a valuable resource, and only very few samples are typically available for assessment.

Typically, a beam of electromagnetic radiation, such as ultraviolet light, can be incident on the transparent wall of the cuvette, passing through the sample in the cuvette, and then passing through a subsequent analysis, specifically the amount of light / radiation absorbed at the different wavelengths To exit the cuvette through the opposed transparent walls.

During the analysis, introducing relatively few samples into conventional cuvettes such that the sample is properly positioned in the path of the beam can be complicated because it may be possible to remove the sample after measurement. The sample is introduced or removed through the open end of the cuvette, which open end may be spaced a predetermined distance from the measurement position (i.e., the portion of the cuvette through which the beam passes through during use).

US 7688492 describes a device for constructing a standard spectrophotometer to facilitate handling of small samples more easily. To this end, the apparatus comprises a housing, which comprises a reflector which is inserted into a cuvette holder of a spectrophotometer and reflects the light from the cuvette holder to a sample stage at the top of the apparatus. The device is capped and the light passing through the sample in the sample stage is then reflected back onto another specular surface that redirects the light back to the spectrometer of the instrument, .

Although the sample is in an elevated, relatively accessible position, the apparatus is also complicated and uses optical elements to escape the path of light generated by the spectrophotometer, which is a spectrophotometer Lt; RTI ID = 0.0 > the < / RTI > In addition, the device is heavy and relatively fragile.

According to the present invention there is provided a cuvette for removably retaining a liquid sample in situ in an analytical device such that the sample can be analyzed by a method comprising irradiating the sample with electromagnetic radiation, And a body having a chamber for holding a sample in use, the body having a first body portion and a second body portion, each of the body portions having a respective component of the inner surface of the chamber, To open the chamber to allow access to the other part and to move away from the other part.

Preferably, the cuvette body is so formed that it can be fitted into a cuvette holder of a conventional spectrophotometer, which is a square section for this purpose.

For example, the body is cubic and can be inserted into or removed from the cuvette holder by a elongate handle, such as a rod, permanently or removably mounted on the body.

Preferably, however, the body is elongated and the chamber is accessible at a position spaced from either ends of the body when opened.

Thus, the sample can be introduced into or removed from the chamber without the need for the user to access the chamber through one end of the cuvette. Thus, the cuvette facilitates analysis of small volume samples.

Preferably, therefore, the cuvette is a micro-volume cuvette.

The chamber of such a cuvette may have a volume of less than 10 mu l, but preferably has a volume in the range of 1 to 2 mu l. Preferably, the body is a cuboid (i.e., in a parallelepiped form), and preferably has a square cross-section.

The shape of this body corresponds to the shape of conventional cuvettes for use in spectrophotometers and thus can be accommodated in the cuvette holder of such a device without the need to modify the device. Typically, the external dimension of a conventional cuvette is 12.5 x 12.5 x 45 mm.

Preferably, the chamber comprises a window mounted on one body portion, a surface opposite to the window and mounted on another body portion and at least one chamber defining a thickness of the chamber and thus a path length of electromagnetic radiation through the sample And a rigid spacer member, the surface facing the window or window being resiliently mounted on its respective body portion.

Preferably, the surface opposite the window is another window or reflector, and the spacer member comprises a ring.

Advantageously, the cuvette includes a pair of opposing windows, the windows defining a part of the chamber, allowing a beam of electromagnetic radiation, wherein the windows are aligned in use in the analyzer Passes through the chamber, interacts with the sample, and then exits the chamber for analysis by the apparatus.

Accordingly, the beam can interact with the sample in the same way as if the sample were contained in a conventional cuvette, and the beam's direction would be such that the beam exiting the sample would reach the corresponding part of the analyzer (e.g., a spectrometer of a spectrophotometer) And need not be changed in order for the sample to be investigated.

In this regard, it may be advantageous that the windows are positioned so that the distance from the bottom of the device to the centerline of each window is either 15 mm or 8.5 mm.

These distances correspond to the two standards used in spectrophotometry, so that when the cuvette is placed in the cuvette holder of the device, the windows of the cuvette are in contact with the electromagnetic radiation generated by the device Will be automatically aligned by the beam.

Preferably, each window is mounted on a respective body portion, with each body portion having at least one surface that faces away from the chamber, and the windows are positioned such that the windows are spaced from the surface when the body portions are so supported.

To this end, the windows are preferably recessed in the body.

As a result, the body or part of the body can be placed on the support surface, exposing each part of the interior surface of the chamber without the support surface and window touching. This facilitates emptying or recharging of the chamber, for example, without scratching or contaminating any one window.

Preferably, each body portion extends along the length of the cuvette, which portions meet at the longitudinal interface.

Thus, the area of the interface can be large with respect to the size of the chamber, which helps to maintain accurate positioning of parts relative to each other and parts at precise relative positions.

Preferably, the body portions are separate components.

Thus, the body portions are not joined together, for example, by a hinge or other link. This simplifies the structure of the cuvette, helps to ensure uniform contact across the interface, and allows parts to be handled individually (when separated from each other).

It is advantageous that the body portions are so formed that the body portions matingly engage with each other.

This facilitates positioning the body portions in register with each other, thereby enabling precise positioning of the portions on the inner surface of the chamber. At least one portion of the body portions may have one or more protrusions, each of the protrusions engaging with a respective recess in the other body portion in use.

Advantageously, the cuvette includes one or more magnets to releasably hold the two body portions together.

The chamber may advantageously be defined by two windows and a spacer ring mounted on one window. In this case, one of the windows is resiliently mounted on each body portion to impose a compressive biasing force which forces the windows to each other, preferably in an assembled cuvette. This allows the cuvette to absorb the shock of the excess sample, and the sample can be discharged into the receptacle (such as a containment ring) in the cuvette body.

In addition, the path length of the light through the samples will be defined by the spacer ring, and can be accurately determined in advance by using a spacer ring made with high dimensional accuracy. This allows the body portions to have a higher dimensional tolerance (i.e., greater inaccuracies / deviations with respect to body portions) without adversely affecting the accuracy with which the path length was determined.

The present invention also relates to a spectrophotometer, a fluorometer or a spectrofluorometer having a cuvette holder and a cuvet as described above, wherein the cuvet is releasably fitted to the cuvette holder The dimensions are determined.

The invention will now be described, by way of example only, with reference to the accompanying drawings, in which: Fig.

Figure 1 is an isometric view of a first embodiment of a cuvette according to the present invention.
2 is a side cross-sectional view of the cuvette.
3 is a side sectional exploded view showing a cuvette when two body portions of the cuvette are separated;
Figure 4 is an isometric view of one of the body portions.
5 is a side cross-sectional view of the body portion when a droplet of liquid sample is deposited on the same body portion;
Figure 6 is a corresponding view showing two body portions mounted to each other after the sample is depotted as shown in Figure 5;
Figure 7 shows a cuvette having a sample when mounted in a cuvette holder of a spectrophotometer.
Figure 8 is a side elevation of a second embodiment of a cuvette according to the present invention.
Figure 9 is an elevational view of the lower side of the cuvette of Figure 8;
Figure 10 is a side cross-sectional view of a second embodiment of the cuvette corresponding to Figure 2;
11 is a side sectional exploded view of a second embodiment of a cuvette showing two body portions of the cuvette when detached.
Figure 12 is a front elevational view of one of the body portions of the second embodiment of the cuvette.
13 is a corresponding view of the second body portion of the second embodiment.
Figs. 14 and 15 are views of respective sides of the opposite sides of the body portions of Figs. 12 and 13, i.e., the exterior side of the assembled cuvette.
16 is an isometric view of the body portion shown in Figs. 12 and 14. Fig.
Figure 17 is a corresponding view of another body part.
18 is an exploded isometric view of two body portions of an embodiment.

Referring to Figure 1, the cuvette according to the present invention comprises a generally parallelepipedal shape with a square horizontal section in the horizontal direction and an oblong rectangular longitudinal section, And a body referred to as reference numeral 1. The width and depth of the body, that is, the length of the side surfaces 2 and 4 is 12.5 mm, while the height of the body, i.e., the length of the side surface 6 is 50 mm.

The main body 1 is formed of two main body parts which are a first main body part 8 and a second main body part 10 which can be separated to longitudinally divide the main body 1 And meets along a substantially rectangular longitudinal interface 12. 2 and 3, each body portion has the same width and height as the body 1, and the thickness is half the thickness of the body 1. [ The body portions 8, 10 are formed of PEEK thermoplastic resin.

The body portion 8 comprises two protrusions 14, 16 in the form of cylindrical bosses which protrude vertically from the upper and lower regions of the body portion 8. As can be assumed in Fig. 1, the projections 14, 16 are each equidistant from the longer sides of the body portion 8. Each projection is located at the end of each blind bore 18,20 in the body portion 8. The blind bores allow the magnets 22 and 24 to be inserted into the body portion 8 and to define opposite sides of the protrusions 14 and 16 facing the sides forming part of the interface 12, To be placed against.

The body portion 10 is provided with a pair of recesses in the form of cylindrical blind bores 26, 28 at the surface of the portion forming part of the interface 12. The recesses 26 and 28 are complementary in shape to the bosses 14 and 16 and in the positions corresponding to these bosses the two body parts 8 and 10 are brought together, The bosses 14 and 16 help position the body portions 8 and 10 with the recesses 26 and 28 in register with each other. Behind each of the recesses 26,28 there is a respective blind bore 30,32 which accommodates a respective magnet 34,36 at its inboard end.

The pole of the magnet 34 placed against the inboard end of the bore 30 is opposite to the pole of the magnet 22 seated against the end of the bore 18 and the magnets 24, 26 are similarly oriented relative to each other such that the two body portions 8,10 are engaged so that the protrusions 16 extend into the recess 28 and the protrusions 14 extend into the recess 26 The magnets impose an attractive force on each other.

4, the body portion 10 includes a pair of opposing concave recesses, referred to as 29 and 31 at its sides, and a surface for forming the interface 12, . The body portion 8 has a corresponding pair of recesses, one of which can be seen in Figures 1 to 33. Each of these recesses in the body portion 8 is arranged in a recess of a respective one of the recesses 29 and 31 in the assembled cuvette so that the four recesses are opposed by the user against the action of the magnets Two opposed thumb holders are formed to facilitate separation of the body portions 8,10.

The body portion 8 also has a tapered through bore 38 whose inboard end includes an annular shoulder on which a circular window 40 is mounted And held in place by a suitable adhesive. The material constituting the window 40 is selected according to the need for the window so as to be able to transmit the light of the wavelength used in the spectrophotometer to be used with the cuvette. In this example, the wavelength of the light may be as low as 200 nm, and the window 40 is formed of fused silica.

The window 40 is surrounded by an annular ridge 42. The ridge 42 is surrounded by an overflow capture ring shaped channel 44 in order and at the same height as the main face 43 of the location 8 to provide an opening, Through which the excess sample can leave the ring 44 until the windows settle into the rest position of the windows. The portion 10 has a cylindrical bore 46 machined within the portion 10 to a depth sufficient to leave a thin PEEK membrane 48 at its inboard end. A circular aperture is formed in the center of the membrane 48 and thus is annular and a second fused silica circular window 50 is attached to the inner edge of the membrane 48 by an adhesive. A stainless steel spacer ring 52 is supported against the window 40 in the cuvette bonded and bonded to the inboard side of the window 50 so that the thickness of the chamber containing the sample, Defines the path length.

As can be seen from FIG. 4, the ring 52 has hemispherical protrusions 54 spaced three equally (i.e., 120 degrees apart). In use, there are portions of the ring that engage the window 40, thereby also defining a small gap between the ring and the window. In use, a droplet of (1 to 2 [mu] l) of the sample is deposited on the upper surface of the window 50 as shown in Fig. Thereafter, the two portions 8, 10 are brought together as shown in FIG. As this happens, the sample 56 will spread to fill the space between the windows 40, 50. The impact of any excess sample that is compressing (i. E., The volume of the sample is greater than the volume of the chamber) is absorbed by the membrane 48, and the excess sample is absorbed through the spaces between the protrusions 54 and overflow capturing (44). ≪ / RTI >

The cuvette may then be inserted into the cuvette holder 57 of the spectrophotometer as shown in Figure 7 where the beam 58 of ultraviolet (or other) light is directed onto the window 40, A beam of light passes into the sample chamber to interact with the sample 56 and out of the chamber through the window 50 and into the spectrometer of the spectrophotometer in the path indicated by the arrows 60. The input beam 58 (generally centered on the center of the cuvette (i.e., on the sample chamber)) is conically conical in shape. The tapered design of the bore 38 helps to ensure that the beam 58 is not unnecessarily clipped by the body of the cuvette.

A chamber containing the sample is formed by the windows 40 and 50 and the spacer ring 52 and the inner surface of the chamber is defined by the opposite faces of the windows, the inner circumferential surface of the ring 52 and the inner portion of the hemispherical protrusions 54 As shown in FIG. The thickness of the chamber is determined by the axial extent of the ring 52 (and protrusions 54) and will typically be 0.2 or 0.5 mm with an accuracy of less than 99% (less than 1% error).

If it is known that the pathlength is within 1% of its stated value (as governed by the spacer ring), then the user is allowed to apply the Beer's law equation to the values obtained using a spectrophotometer. You will not need to perform time consumption calculations. In this design, only ring 52 (with protrusions 54) needs to be made with high dimensional accuracy to obtain path length accuracy.

As can be seen in Fig. 5, when the portion 10 rests on the underlying supporting surface (which can bear against the surface of the opposite portion 10 forming part of the interface) It is easily accessible for application (or removal) of the deop while it is recessed into the body 10 and is kept out of contact with the base surface.

9 to 19, the second embodiment of the cuvette according to the present invention is substantially the same as the first embodiment, and the parts of the second embodiment corresponding to the parts of the first embodiment are the same as those of the first embodiment shown in Fig. 1 To < RTI ID = 0.0 > 100 < / RTI >

10 and 11, for example, the bore 146 of the body portion 110 is not a straight cylinder, but instead has a smaller diameter portion 147 at the inlet to the bore, Is guided to the larger diameter portion 149 terminated by the membrane 148 and the window 150. Another major difference is that the body portion 108 has a handle 200 to facilitate insertion of the cuvette into the spectrophotometer and subsequent removal of the cuvette from the spectrophotometer. However, the two body portions 108, 110 fit exactly together in the same manner as the body portions 8, 10 of the first embodiment. 14 and 15, when the body portions are together, the north pole of the magnet 134 may be adjacent to the south pole of the magnet 122, while the south pole of the magnet 136 may be adjacent to the magnet 124, So that the orientation of the magnets 122, 124, 134, 136 is such that the body portions are releasably held together by the attraction force between these two pairs of magnets.

Because of the handle 200, the second embodiment of the cuvette is longer than the first embodiment and has external dimensions of 12.5 mm x 12.5 mm x 60 mm. In the second embodiment, it is more convenient for the droplet to be initially placed on the body portion 108 when the body portion is laid horizontally, e.g., in the orientation shown in FIG. 11, on the support surface.

The handle includes on its top a recess 202 (FIG. 18) that can have a label to indicate the path length of the cuvette. Alternatively, or in addition, a handle attached to the portion 108 by a screw retainer (not shown) may be colored by anodising to display path length variations (using a color coding system) in the specification .

Claims (24)

A cuvette for removably retaining a liquid sample in situ in an analytical device such that the sample can be analyzed by a method comprising irradiating the sample with electromagnetic radiation,
A body including a chamber for holding a sample in use,
The body having a first body portion and a second body portion,
Each of these body portions has respective parts of the inner surface of the chamber,
One of which may be away from the other to open the chamber to allow access to the other,
The cuvette.
The method according to claim 1,
The body is elongate,
Said chamber being accessible from a position spaced from the ends of the body when opened,
The cuvette.
3. The method according to claim 1 or 2,
The cuvette is a micro-volume cuvette,
The cuvette.
The method of claim 3,
Wherein the volume of the chamber is less than < RTI ID = 0.0 > 10,
The cuvette.
5. The method of claim 4,
Said chamber having a volume ranging from 1 to 2 < RTI ID = 0.0 > uL. ≪
The cuvette.
6. The method according to any one of claims 1 to 5,
The body is a cuboid,
The cuvette.
The method according to claim 6,
Said body having a square cross-
The cuvette.
8. The method according to any one of claims 1 to 7,
The cuvette includes a pair of facing windows,
The pair of windows defining a part of the chamber, allowing a beam of electromagnetic radiation,
Wherein the windows allow the windows to be aligned in use in the analyzer to pass into the chamber, interact with the sample, and then exit the chamber for analysis by the apparatus,
The cuvette.
9. The method of claim 8,
Wherein the window is one of a distance from the bottom of the cuvette to a center line of each window of either 15 mm or 8.5 mm,
The cuvette.
10. The method according to claim 8 or 9,
Each window being mounted to a respective one of the body portions,
The cuvette.
11. The method of claim 10,
The windows are recessed in the body,
The cuvette.
12. The method according to any one of claims 1 to 11,
Each of the body portions extending along the length of the cuvette,
Said portions meeting at a longitudinal interface,
The cuvette.
13. The method according to any one of claims 1 to 12,
The body portions are separate components of the cuvette,
The cuvette.
14. The method according to any one of claims 1 to 13,
The body portion may be shaped such that, in use, the body portions matingly engage with each other,
The cuvette.
15. The method of claim 14,
At least one portion of the body portions having one or more protrusions,
Each of the protrusions being adapted to engage with a respective recess in the other body portion when the body portions are brought together,
The cuvette.
16. The method according to any one of claims 1 to 15,
Wherein the cuvet includes one or more magnets to releasably hold the two body portions together,
The cuvette.
The method according to any one of claims 8 to 11,
The chamber is defined by a rigid spacer member that defines the thickness of the two windows and the chamber and thus the path length of the electromagnetic radiation through the sample,
The cuvette.
18. The method of claim 17,
Wherein one window of the windows is resiliently mounted on each body portion to impose a compressive biasing force to force the windows toward each other in the assembled cuvette,
The cuvette.
The method according to claim 17 or 18,
Wherein the rigid spacer member comprises a spacer ring,
The cuvette.
20. The method according to any one of claims 1 to 19,
Wherein the cuvette includes a handle for facilitating insertion of the cuvette into the cuvette holder or removal of the cuvette from the holder,
The cuvette.
21. The method of claim 20,
The handle is mounted or formed on one portion of the body portions,
The cuvette.
The method according to claim 1,
The chamber includes at least one rigid spacer member defining a window mounted on one body portion, a surface opposed to the window and mounted on another body portion, and a thickness of the chamber and thus a path length of electromagnetic radiation through the sample ≪ / RTI &
The surface facing the window or window is resiliently mounted on its respective body portion,
The cuvette.
23. The method of claim 22,
Wherein the surface opposite the window is another window or reflector, the spacer member comprising a ring,
The cuvette.
A spectrophotometer, a fluorometer or a spectrofluorometer with a cuvette holder in which the cuvette according to any one of claims 1 to 23 is accommodated.

Images