JP2803809B2 - Pipette tips - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

FIELD OF THE INVENTION The present invention relates to aerosol barriers for use in disposable pipette tips.
For more information, see Air flow liquid detection (monitoring air flow).
To detect the liquid in the pipette tip
Disposable pipette tip having an aerosol barrier made from an absorbent open cell foam that provides sufficient air flow through the disposable pipette tip to perform the method) but sufficiently blocks droplets and aerosol from flow through the disposable pipette tip About.

[0002]

BACKGROUND OF THE INVENTION Pipettes are devices commonly used in reagent experiments as liquid transporters for adding and mixing liquid components such as reagents and samples.

[0003] Early transporters were generally glass pipettes or tubes with a hollow interior that applied a vacuum to their proximal ends to draw liquid to their distal ends. Vacuum was typically applied using the experimenter's mouth or with a suction valve connected to the proximal end of a glass pipette. Because these types of glass pipettes are often reused, they had to be very clean to prevent cross-contamination of reagents or samples.

Later, disposable pipette tips were introduced to avoid cross-contamination problems with reusable pipettes and to aid experiments. The disposable pipette tip is connected to the distal end of the mechanical aspirator or pipettor and is designed to fit over the distal end of the mechanical aspirator and only vent from the mechanical aspirator is outside the proximal end of the disposable pipette tip. Was. Mechanical aspirators typically use a plunger to pump air through the aspirator outside the proximal end of the disposable pipette tip and then insert the proximal end from the supply container into the liquid to be aspirated. After placing the proximal end in the liquid, the plunger in the mechanical aspirator was loosened and the disposable pipette tip was depressurized, thereby drawing the liquid from the supply container into the disposable pipette tip. The aspirated liquid contained in the disposable pipette tip was then dispensed to the target container using a plunger.

[0005] After use, the disposable pipette tip was typically extruded from the mechanical aspirator using a tubular or extrusion sleeve that applied pressure to the top of the disposable pipette tip to push the pipette tip out of the mechanical aspirator. By extruding a disposable pipette tip from such a mechanical aspirator,
Aerosols could be made from the residual liquid in the disposable tip in a mechanical aspirator. Furthermore, when liquid is aspirated into a disposable pipette tip,
Aerosols may form in mechanical aspirators. The aerosol coming from the pipette tip to the mechanical aspirator can contaminate the mechanical aspirator, and thus other reagents or samples. One proposal to solve the aerosol problem has been to add a porous barrier between the liquid and the mechanical aspirator. Typically, using a hydrophobic filter plug made of, for example, polyethylene, the liquid and aerosol can be transferred from the end of the pipette tip to a mechanical aspirator without strongly affecting aspiration and administration of the liquid from the disposable pipette tip. Blocked passage.

More recently, especially in labor-intensive environments where high throughput or greater automation is desired,
Robotic suction devices are replacing manual mechanical aspirators. Robotic suction devices typically consist of a stainless steel needle that draws liquid from the target container to the distal end by applying pressure to its proximal end, for example, by hydraulic displacement. Of course, such robotic suction devices must be periodically cleaned to prevent cross-contamination of reagents or samples. Because of this problem, the disposable pipette tips must be connected to a robotic suction device to reduce the risk of cross-contamination. However, when using a suction device by a robot in an automated environment, a controller of the device that detects when the end of the suction device is placed in the liquid of the target container is important. This problem is addressed by providing a robotic suction device with a liquid detection capability that prevents these ends from being pushed too far into the liquid. Generally, when using metal or stainless steel needle,
Liquid detection can be achieved by monitoring the capacitance of the needle where a change in capacitance indicates insertion of the distal tip into the liquid. However, detection of flow by capacitance will not be possible without the use of more expensive and non-standard disposable plastic pipette tips, generally conductive plastic. When using a standard non-conductive disposable plastic pipette tip, liquid detection is performed by monitoring the air flow, where a change in air flow indicates that the liquid has blocked the end of the pipette tip. I do.

However, with the use of airflow detection, the problem is encountered whether the disposable pipette tip includes a barrier to prevent the robot from passing the aerosol to the suction device. Aerosol filter barriers used in disposable pipette tips are micro-hydrophobic plugs that often create significant resistance to air flow. Such barriers are too dense to allow sufficient air flow, are disadvantageous for performing small pipetting operations, and do not work at all with automated robotic suction devices that use air flow liquid detection. Thus, there is a need for a new barrier in a disposable pipette tip that sufficiently captures liquid and aerosol from the flow to the suction device by the robot, but provides sufficient air flow for the air flow liquid detection system to operate.

[0008]

SUMMARY OF THE INVENTION The present invention provides an airflow detection system for operation that allows sufficient airflow to flow through a pipette tip to a robotic suction device, but the pipette tip to a robotic suction device. Adequate entrapment of liquids and aerosols overcomes the problems identified with prior art materials by providing a barrier for the disposable pipette tip to continue.

A preferred embodiment of the pipette tip of the present invention has a proximal end and a distal end, the proximal end including a cannula that is larger than the distal end and both ends are connected by a passage. A barrier is provided in the passage of the pipette tip near the proximal end of the cannula and traps liquid and aerosol and prevents it from flowing out of the proximal end through the pipette tip. However, the barrier is such that sufficient air flows through the pipette tip so that the airflow liquid detection system in the robotic suction device can operate properly. Preferably, the barrier is sufficiently capture the aerosol is, however airflow
Made of high-absorbent open-cell foam that does not limit .

[0010] These and other aspects, features and advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings.

FIG. 1 is a perspective view of a pipette tip 10 according to the present invention for use in a manual or robotic suction device for transferring liquids in a laboratory.

The pipette tip 10 includes an open cannula 15 which is generally tapered and conical defined by a cylindrical outer wall 17. Cannula 15 has an open proximal end 20 and an open distal end 25 with a plurality of optional annular stepped members 130, 135 and 140 on outer wall 17 therebetween. Cannula 15 also includes a plurality of ribs 45 projecting from outer wall 17 and extending perpendicularly from proximal end 20 to distal end 25. Rib 45
Is provided for vertically supporting the pipette tip 10 when the pipette tip 10 is connected to a suction device.
The vertical axial alignment is important for robotically connecting the pet tip 10 to a suction device, especially in the absence of mechanical visual aid.

Optional steps 130, 135 and 140 divide cannula 15 into sections 30, 35 and 40, and each step 130, 135 and 140 has a respective step and proximal end 25 within cannula 15. Represents a predetermined volume of liquid that will be in between. These steps are used by the experimenter to visually measure the amount of liquid aspirated during manual pipetting. For example, cannula 15
If the level of liquid is aligned with the step 130 within the section 30 of the cannula 15 between the proximal end 25 and the step 130, the appropriate amount of liquid contained in the cannula 15 is 10 μl; The appropriate volume of liquid in sections 30 and 35 when aligned with step 135 is 50 μl; when the level is aligned with step 140 the appropriate amount of liquid in sections 30, 35 and 40 Is 100 μl. Preferably,
The total volume of liquid that can be retained in this usable portion of the pipette tip 10 is about 120 μl. Of course, the above volumes are merely exemplary, and the invention is also conceivable and very convenient for larger or smaller pipette tips, with or without stepped members.

FIG. 2 is a sectional view of the pipette tip 10 shown in FIG.
FIG. 2 is a cross-sectional view along 2 showing a passage 50 having a generally tapered conical shape extending from the proximal end 20 to the distal end 25.
As is apparent from FIG. 2, the passage 50 extends from the proximal end 20 to the distal end 2.
It is defined by an inner wall 57 whose diameter decreases towards 5. In accordance with the present invention, a foam barrier 60 is included in the passage 50 near the proximal end 20 and is preferably mounted in place using a light frictional fit. However, other methods, adhesives, can also be used to attach the foam barrier 60 at this location.

The foam barrier 60 has a continuous, web-like or filamentous structure similar to that shown in FIG. 3 in which air can flow through the foam but droplets or aerosols cannot pass through the foam. Preferably, it is a cellular aerosol-adsorbing foam.
FIG. 3 is an electron micrograph of an actual foam barrier 60 for use in a pipette tip 10 according to the present invention.
The foam barrier 60 having the structure of the present invention provides a barrier to droplets and aerosol flowing through the passageway 50 from the proximal end 20 to the distal end 25 during the suction process or when the pipette tip 10 is pushed out of the distal end of the suction device. It functions properly and hardly limits the airflow required to perform automated airflow liquid detection.

During use, the pipette tip 10 containing the foam barrier 60 is attached to the distal end of the suction device and held in place by friction at the distal end of the suction device. When transferring reagents or samples from the supply container to the target container, the end of the aspirator with the pipette tip 10 thereon is moved over the supply container and slowly moved down into the liquid to be aspirated. When the disposable pipette tip is moved down into the liquid, the suction device creates an air flow through the pipette tip 10, which measures the change in air flow when the distal end 25 of the pipette tip 10 enters the liquid. Monitored by a controller to If a decrease in airflow is detected, the suction device senses that the pipette tip 10 has entered the liquid and initiates the suction method, where a vacuum is applied to the proximal end 20 and the distal end 25 of the pipette tip 10 is applied. The liquid is aspirated through and enters the passage 50. The reduced pressure is applied until a predetermined volume of liquid is sucked into the passage 50. The suction device then removes the pipette tip 10 from the liquid source container and transports the aspirated liquid to the destination container for administration.

The suction device is used to place the pipette tip 10 on the target container.
When the is positioned, pneumatic pressure is applied to the proximal end 20 to dispense the volume of liquid in the passageway 50 to the target container. After the liquid has been dispensed into the target container, the aspirator removes the pipette tip 10 from the target container and once residual liquid has traversed the distal end 25,
The sudden movement of the pipette tip aerosolizes this residual liquid. After the transfer of liquid is completed, the suction device pushes the pipette tip 10 from its distal end into a disposable container, vigorously exchanges a large amount of air from the proximal end 20 of the passage 50 in the pipette tip 10 to cause an instantaneous decompression, and A high viscosity aerosolization of the residual liquid volume contained in the distal end 25 of the pipette tip 10 occurs. However, foam barrier
60, as described above, is constructed of a material designed to capture both such liquids and aerosols and prevent them from flowing into or passing through the suction device.

The cannula 15 is made of any form of plastic and the foam barrier 60 is made of polyurethane,
It can be made of polyvinyl chloride or polyvinyl alcohol. Preferably, the foam barrier 60 is made from a melamine-based open cell foam having a density in the range of 0.5-0.8 pcf, most preferably 0.7 pcf. Foams having these general properties are obtained from a number of supplies used as thermal and acoustic insulation. In particular, Willtec ™, available from Illbruck Inc. of Minneapolis, Minn., Is a flexible, lightweight, melamine-based open cell foam having a preferred density of 0.7 pcf. . In addition, Virtech ^™ foam is chemically resistant to organic solvents and a range of diluted acids and alkalis. Other physical properties of Virtech ™ foam are as follows: Physical Properties Representative Test Method Tensile Strength 8.0 psi ASTM D3574-77 Tear Strength 0.3 lb / in ASTM D3574-77 Ultimate Elongation 8.0% ASTM D3574-77 Temperature stability -60 ° C to 150 ° C constant up to 24 hours at 250 ° C Virtec ™ foam is, of course, a foam that can be used to form foam barrier 60 according to the present invention. This is an example. More importantly, as noted above, foam barrier 60 must not be made of a foam material that does not so severely restrict airflow through foam barrier 60, but blocks droplets or aerosols passing through foam barrier 60. No. An open-cell foam structure, similar to that shown in FIG. 3, satisfies this requirement, and a discontinuous, ball-like or glove-like structure, similar to that shown in FIG. 4, functions similarly. Not shown. FIG. 4 is an electron micrograph of a prior art barrier found on a conventional aerosol filter pipette tip. The barrier shown in FIG. 4 does not provide sufficient airflow to allow for airflow liquid detection performed by automated robotic suction devices. When a foam such as that shown in Figure 4 is used on a disposable pipette tip in an automated robotic suction device, determining whether this pipette tip has entered a reagent or sample using airflow detection technology is not possible with this device. Would not be possible.

The foam barrier 60 can be manufactured from Virtech® foam using conventional manufacturing techniques. For example, a cork punch can be used to punch out the "plug" shape of the foam barrier 60 from a 0.25 inch thick sheet of Virtech ™ foam. “Plug” shaped foam barrier 60
Is then inserted through the proximal end 20 of the pipette tip 10 and pressed into the passage 50 to a predetermined position. of course,
This manufacturing technique and materials and machines used are for illustration only, and various other manufacturing methods and materials may also be used.

In the foregoing description, the above embodiments are understood to be exemplary of a disposable pipette tip according to the present invention having an aerosol-adsorbing foam as a barrier to liquid flow without disturbing the air flow through the pipette tip. I want to be. Of course, other suitable variations and modifications can be made to this embodiment and are also within the scope of the present invention.

[Brief description of the drawings]

FIG. 1 is a perspective view of a pipette tip of the present invention.

FIG. 2 is a cross-sectional view of the pipette tip shown in FIG.

FIG. 3 is a copy of a micrograph of a foam barrier in the pipette tip shown in FIG.

FIG. 4 is a copy of a micrograph of a foam barrier used in a conventional pipette tip.

[Explanation of symbols]

 10 Pipette tip 15 Cannula 20 Base end 25 End 45 Rib 50 Passage 60 Foam barrier

Continuation of the front page (73) Patent holder 595117091 1 BECTON DRIVE, FR ANKLIN LAKES, NEW JERSEY 07417-1880, UNI TED STATES OF AMER ICA (72) Inventor Peter A. Burdel 17326, Glen Rock, PA, United States Roster Road (No Address), R1, Box 16 Kay (72) Inventor Allen S. Reacher, Coach House Drive, Owing Mills 21117, Maryland, USA 1 (56) References 7-289925 (JP, A) JP-A-3-1622673 (JP, A) JP-A-6-331513 (JP, A) JP-A 4-99225 (JP, U) JP-A 5-39642 (JP, A) U) Jiko 6-11102 (JP, Y2) (58) Field surveyed (Int. Cl. ⁶ , DB name) B01L 3/02 G01N 1/00 G01N 35/10

Claims (9)

(57) [Claims] 1. A cannula having an open proximal end and an open distal end, with a passage extending from the open proximal end to the open distal end; and a barrier located within the passage, wherein the barrier is located within the passage. Made of an open-cell foam having a web-like structure that can prevent aerosol from entering the distal end and passing through the passage to the proximal end without restricting the air flow through the passage Pipette tip for use in a suction device. 2. The foam according to claim 1, wherein said foam is 0.5 pcf to 0.8 p.
Density of Claim 1 wherein the pipette tip during cf. 3. The pipette tip according to claim 2 , wherein said density is 0.7 pcf. 4. The pipette tip according to claim 1, further comprising means for detachably attaching said pipette tip to said suction device. 5. The pipette tip of claim 1, wherein said foam is an aerosol-adsorbing foam . 6. The pipette tip of claim 1, wherein said foam is a non-hydrophobic open cell foam. 7. The pipette tip according to claim 1, further comprising means for vertically supporting said pipette tip when said pipette tip is attached to said suction device by a robot. 8. The means for vertically supporting the pipette tip when the pipette tip is robotically mounted on the suction device protrudes from the cannula and extends longitudinally from the proximal end to the distal end. The pipette tip according to claim 7 , comprising a plurality of ribs extending in a direction. 9. The pipette tip of claim 1, wherein said foam is made of a melamine-based open-cell foam.