This invention relates to a disposable for analyzing biological specimens.
Fluorescent dyes conjugated to one or more antibodies are commonly used for immunofluorescence analysis. A vast number of variants in terms of antibodies, fluorescent dyes, flow cytometers, flow sorters, and fluorescence microscopes has been developed in the last two decades to enable specific detection and isolation of target cells.
Fluorochrome conjugates targeting the antigen of interest are used to detect and image cell structures of tissues. In these techniques, sequential elimination of the fluorescence signal and re-staining allow a higher multiplexing potential compared to standard procedures using simultaneous labeling and detection. For example, U.S. Pat. No. 7741045 B2, EP 0810 428 B1 or DE10143757 disclose elimination of the fluorescence signal by photo- or chemical destruction of the conjugated fluorescent moieties.
In the aforementioned techniques, the resulting fluorescence signals are collected as an image. By sequential elimination of the fluorescence signal and re-staining with different fluorochrome-conjugates, different antigens are detected, resulting in a plurality of images of the same specimen showing different parts (antigens) of the specimen. The quality of the information gathered with these techniques is highly dependent on the resolution of the images, the precision of the handling steps and the time required between steps, during which the sample is manipulated. The known techniques allow a very limited number of images of a particular biological sample through a series of stainings, due to the laborious handling steps. Accordingly, there is a need for an automated procedure for cycles of staining, imaging and elimination of the staining of biological specimens for analyzing proposes.
Described here is a system that allows sequential analysis of a biological sample in situ, under computer control. The device allows the sequential application of a number of fluorescent reagents to the same biological sample, and the observation of the sample through a transparent support by an imaging mechanism or by eye. The imaging mechanism may be a fluorescence imaging system which, in combination with a data-collecting computer, may form a visual image of the biological sample stained with a series of various reagents.
Central to the system is a multilevel disposable cartridge, which may be a small, inexpensive plastic cartridge composed of multiple layers. In one layer, a plurality of fluid wells or reservoirs may hold a plurality of fluid reagents. The disposable cartridge may also be configured to accept a biological sample on a transparent support, for example, on a glass slide.
The cartridge may include two rigid plastic layers and an elastomeric, flexible layer between the two rigid layers. The rigid layers may have small channels formed therein. The channels in one rigid layer may be configured for carrying fluids. The channels in the other rigid layer may be configured for carrying pneumatics, i.e. air pressure or suction. The pneumatic channels may deliver the pressure or suction to the underside of the elastomeric layer, thereby deflecting the elastomeric layer. This deflection may open or close a fluid valve, allowing fluid to flow in the fluid channels of the other rigid layer. In particular, a valve in the elastomeric layer may open a fluid channel between a fluid reservoir and a biological sample, to deliver a particular reagent to the sample.
Because these structures are all contained on a small, disposable cartridge, fluid volumes are minimized. The small volumes make efficient use of expensive reagents, minimize washing steps, and reduce the time needed to collect the data. Because the cartridge is disposable and all the fluid pathways are enclosed therein, there is no sterilization procedure, and the multilevel, disposable cartridge is simply thrown away.
Accordingly, a disposable for analyzing biological specimens, may include a first rigid layer (20), having a analyzing area (24), a plurality of fluid reservoirs (22) and a plurality of fluidic channels formed therein wherein the channels provide fluid communication to the fluid reservoirs and also include a flexible layer (30) having a plurality of fluid control points (33) in fluid communication with at least one of the fluid reservoirs (22). The disposable may further include a second rigid layer (40) with a plurality of pneumatic channels formed therein, wherein the channels provide pneumatic communication to the at least one fluid control point, wherein each fluid control point is pneumatically controllable to cause flow from only one of the plurality of fluid reservoirs (22) into and out of the fluidic channels.
The flexible layer (30) may be produced separate from first rigid layer (20) and second rigid layer (40) and disposable cartridge is assembled from the three separate layers as explained in detail in the following description. In this embodiment of the invention, the flexible layer (30) is produced separate from first rigid layer (20) and second rigid layer (40) and the disposable cartridge is assembled from the first rigid layer (20), the flexible layer (30) and the second rigid layer (40) each being a separate item.
In another embodiment of the invention, the flexible layer (30) is produced together with either the first rigid layer (20) or the second rigid layer (40). In this embodiment, the flexible layer (30) is produced for example by attaching, disposing or extruding of flexible material on or at the at the other rigid layers in a way that the functionality of the flexible layer (30) is still achieved but not as separate layer. In this embodiment, the disposable cartridge is assembled from the flexible layer (30) attached to the first rigid layer (20) and the second rigid layer (40) or from the flexible layer (30) attached to the second rigid layer (40) and the first rigid layer (20). In a variant of this embodiment, the flexible layer (30) is a continuous layer as shown for example in
Various exemplary details are described with reference to the following figures, wherein:
It should be understood that the drawings are not necessarily to scale, and that like numbers may refer to like features.
Systems and methods are described for analyzing a biological sample mounted on a transparent surface with a plurality of reagents in an automated fashion, using a multilevel, disposable cartridge. A plurality of reagents may each be stored in a separate fluid well on the cartridge. An elastomeric layer in the multilevel, disposable cartridge may be configured as the fluid valves and pumps, which allow the reagent fluid to flow from a well to a sample analyzing chamber in which the biological sample is placed. The fluid valves and pumps may be actuated using pneumatics from a source, and are under computer control. Accordingly, the biological sample may be analyzed with a plurality of reagents in an automated fashion. Because the fluid passages are very small, and contained within the multilevel disposable cartridge, the dead volume is small, and successive reagents can be applied in a short amount of time. The small volumes make efficient use of expensive reagents, minimize washing steps, and reduce the time needed to collect the data. Because the cartridge is disposable and all the fluid pathways are enclosed therein, there is no sterilization procedure, and the multilevel, disposable cartridge is simply thrown away.
The first rigid layer 20 and second rigid layer 40 may be comprised of a polymeric plastic, such as polycarbonate. The first rigid layer 20 and second rigid layer 40 may be injection molded. The elastomeric layer 30 may be made from a rubbery elastic material such as silicone, and may be stamped or otherwise formed in the structure shown. These components may be glued or snapped together to form the multilevel disposable cartridge 1.
The overall dimensions of the multilevel disposable cartridge 1 may be about 75 mm on a side, by about 30 mm in depth, by about 10 mm in height. It should be understood that these dimensions are exemplary only in the multilevel disposable cartridge 1 may be made of any convenient size, depending on the application.
The two rigid layers 20 and 40, may be separated by the elastomeric layer 30. The first rigid layer 20 may support the fluidic transport, and the second rigid layer 40 may support pneumatic structures such as channels and pores, which may deliver suction or vacuum to deformable portions of elastomeric layer 30. These deformable portions may comprise fluid control elements such as pumps and valves, as will be described further below. The remaining components such as the protective covering or top 10, the foil layer 50, and the transparent specimen support 60 maybe ancillary or optional. In some embodiments, the foil layer 50 may cover the pneumatic channels in the second rigid layer 40, so as to seal the gas therein. The specimen support 60 may carry the biological specimen on its surface and maybe sealed against the first rigid layer 20 by a seal, preferably by the flexible elastomeric layer 30, as will be described further below.
Analyzing the biological specimens may be conducted by optical microcopy and/or any method detecting emission, for example with a digital camera. Depending on the location of the light source and the detection means, analyzing area 24 (as seen in
Accordingly, a disposable for analyzing biological specimens may include a first rigid layer (20), having a analyzing area (24), a plurality of fluid reservoirs (22) and a plurality of fluidic channels formed therein wherein the channels provide fluid communication to the fluid reservoirs and also include a flexible layer (30) having a plurality of fluid control points (33) in fluid communication with at least one of the fluid reservoirs (22). The disposable may further include a second rigid layer (40) with a plurality of pneumatic channels formed therein, wherein the channels provide pneumatic communication to the at least one fluid control point, wherein each fluid control point is pneumatically controllable to cause flow from only one of the plurality of fluid reservoirs (22) into and out of the fluidic channels.
The plurality of fluid wells or reservoirs 22 may be filled with the separate, different, biologically reactive material such as such as reagents, antigen recognizing moieties having detection moieties, such as antibodies with fluorescent dyes, antibiotics, biological nutrients, toxins, stains, oxidants. In one embodiment, the fluid wells or reservoirs 22 may contain an antibody conjugated to a fluorescent dye moiety. The plurality of fluid wells or reservoirs 22 may serve as a reservoir for each of these reagents, whereby they may be sequentially applied to a biological specimen, as will be described in further detail below. Each of the fluid wells or reservoirs 22 may be independently accessed by an array of fluid control points which may be disposed below them and formed from the elastomeric layer 30. Accordingly, the first rigid layer may include a plurality of fluidic channels through which fluids may flow from the plurality of fluid wells or reservoirs 22 to the sample analyzing chamber 500. These fluidic channels may be disposed on the underside of the first rigid layer 20, and so are not shown in
On the other side of the first rigid layer 20 is a analyzing area, such as depression or analyzing area 24 which may be disposed over the sample analyzing volume 500. The depression or analyzing area 24 may be made of the same polycarbonate material of the first rigid layer 20. Depression or analyzing area 24 may be a transparent viewing window or viewing surface formed in the first rigid layer 20, using the same material as the first rigid structure. For example, the viewing depression or analyzing area 24 may comprise a transparent polycarbonate plastic. The viewing depression or analyzing area 24 may be the part of the rigid layer 20 which may be pressed against the biological sample, and against the specimen support 60 upon which the biological sample may be placed. These features will be described further below. The first rigid layer 20 may be sealed against the elastomeric layer 30 with a non-leaking fluid seal. Similarly, the elastomeric layer 30, may also form a fluid seal against the support, 60. Accordingly, the flexible elastomeric layer (30) may seal the first rigid layer (20) against the second rigid layer (40) and/or the second rigid layer (40) against the specimen support (60).
Some details of the elastomeric layer 30 are shown in
Both of these mechanisms, the valves and the pump, are fluid control points, and are described in detail below. The fine features of the pumps and valves are difficult to depict on the scale used in
Finally, the elastomeric seal 34 may include a rubberized seal, that provides the fluid seal between the first rigid layer 20, and the second rigid layer 40, and the specimen support 60.
The plurality of raised pressure points 43 applies the suction or pressure obtained from the suction or pressure sources to the plurality of valves 33 of the elastomeric layer 30. Accordingly, to allow fluid to flow in and out of the sample analyzing volume (500), fluidic control points are pneumatically controlled by a suction applied from a pneumatic channel of the second rigid layer against the backside of the flexible elastomeric layer 30, whereby the flexible elastomeric layer (30) may be withdrawn from a first stop against a second stop. In order to prevent fluid from flowing in and out of the sample analyzing volume (500), fluidic control points may be pneumatically controlled by a suction removed from a pneumatic channel of the second rigid layer 40 against the backside of the flexible elastomeric layer 30, whereby the flexible elastomeric layer 30 rests against a first stop. The functioning of the valve in response to pressure or suction is described below with respect to
A viewing aperture 44 allows the depression or analyzing area 24 which may be formed in the first rigid layer 20, to protrude through the elastomeric layer seal 34 and through the second rigid layer 44 against the biological specimen resting on the transparent specimen support 60. The specimen support 60 may be held against the second rigid layer 40 by the clamps 45. Accordingly, the second rigid layer further comprises an attachment mechanism (45) like clamps for holding the specimen support (60), wherein the specimen support (60), the rigid layers (20, 40) and the flexible membrane (30) define the sample analyzing volume (500).
Specimen support 60 may be an optically transparent standard glass slide, upon which biological sample may be resting. The biological sample may be cells such as T cells, stem cells or lymphocytes, or tissue, for example.
In
As can be seen in
In
Close inspection of
The multilevel disposable cartridge 1 may further comprise a fluidic pump which pumps fluid through the multilevel disposable cartridge 1. This fluidic pump may be a part of the flexible layer (30), wherein the flexible layer (30) further comprises a pumping mechanism (200) actuated by a pneumatic force. The pumping mechanism (200) may comprise a movable part (210) in the flexible layer (30) configured to alter the volume of a fluidic channel and wherein said movable part (210) is in fluidic communication between a first valve (100) and a second valve (300).
In
However pumping element 200 may still be in the closed position against second stop pressure point 43. Second valve 300 may also be in the closed position. Accordingly, no fluid may flow through the structure. In
In
These figures taken together
Using this array architecture, each fluid well may be addressed with a minimum number of pneumatic lines. Therefore, in this system, the second rigid layer 40 may comprise a first pneumatic channel providing suction to a row of fluidic control points 33, and a second pneumatic channel providing suction to a column of fluid control points 33, such that the two pneumatic channels together cause fluid to be dispensed from only one of the fluid reservoirs at a time.
In any case, the fluid flows through an input trench 220 into the sample analyzing volume 500. In another embodiment, this fluid is distributed before entering the sample analyzing volume 500 over at least one side to achieve a flow parallel to this side and over the sample as to prevent a laminar flow which might leave out parts of the sample. To this end, the first rigid layer 20 may further comprise at least one cavity or trench (220, 222) adjacent to at least one side of the sample analyzing volume (500), which accepts and distributes fluid flowing from at least one reservoir 22 over the whole side of the analyzing volume (500). The trenches are shown in detail in
For example, the fluid may flow from left to right as shown in
In order to control impedance of the flow through the sample analyzing volume 500, the first rigid layer 20 may further comprise a barrier (240) adjacent to at least one side of the analyzing volume (500), which protrudes into the sample analyzing volume (500), such that the fluid flows between the barrier 240 and the specimen support 60 into the sample analyzing volume (500). The barrier 240 is shown in
The second rigid layer 40 may hold the specimen support 60 at a level that the sample analyzing volume (500) has a height hl with respect to the depression or analyzing area 24 of the first layer 20. To ensure uniform flow and good contact of the sample with the fluid, the biological sample may be at a height of h4 with respect to the specimen support 60. Therefore, when the cartridge is assembled, the sample analyzing chamber (500) may have a height hl, the trench (220, 222) a depth h2, the rim or barrier (240) a depth h3 and the biological specimen a height h4, wherein h1, h2, h3 and h4 have ratios of (0.05 to 0.5)×h3=h4 and/or (0.1 to 0.5)×h2=h1 and/or (0.1 to 0.5)×h1=h4. The dimensions are shown schematically in
The multilevel disposable cartridge 1 may be constructed as follows: The plastic components of the multilevel disposable cartridge 1 include a first rigid layer 20, and a second rigid layer 40. These components may be injection molded from polycarbonate, poly styrene, polyethylene and COC, for example. The elastomeric layer 30 may be poly siloxane and may be cut or stamped. These components may then be joined by a glue, by plasma activation of the layers or high frequencies welding. The fine details such as the fluidic/pneumatic channels may be formed by chemical etching or laser removal or as a part of the mold.
In operation, the plurality of fluid wells or reservoirs 22 may each be filled robotically or by hand pipette with a quantity of reagent. A biological sample may then be laid on the specimen support 60 and in the sample analyzing volume 500, along with a quantity of buffer fluid to keep the sample moist. The support 60 may then be snapped into place on multilevel disposable cartridge 1 by clamping structures 45. The multilevel disposable cartridge 1 may then be coupled to sources of pressure and vacuum at input/output ports 42 on the second rigid layer 40. The plurality of fluid reservoirs may contain a plurality of reagents, of which at least one is an antibody conjugated to a fluorescent molecule. A controller or computer (not shown) may then direct the sources of pressure or vacuum to be applied to a particular valve through input/output port 42, and using the array architecture shown in
While various details have been described in conjunction with the exemplary implementations outlined above, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that are or may be presently unforeseen, may become apparent upon reviewing the foregoing disclosure. Accordingly, the exemplary implementations set forth above, are intended to be illustrative, not limiting.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/064886 | 6/19/2017 | WO | 00 |
Number | Date | Country | |
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62356310 | Jun 2016 | US |