WO2018093896A1 - Embout de pipette avec guides de lumière intégrés dans le corps et procédé d'analyse spectroscopique l'utilisant - Google Patents

Embout de pipette avec guides de lumière intégrés dans le corps et procédé d'analyse spectroscopique l'utilisant Download PDF

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Publication number
WO2018093896A1
WO2018093896A1 PCT/US2017/061794 US2017061794W WO2018093896A1 WO 2018093896 A1 WO2018093896 A1 WO 2018093896A1 US 2017061794 W US2017061794 W US 2017061794W WO 2018093896 A1 WO2018093896 A1 WO 2018093896A1
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WIPO (PCT)
Prior art keywords
light
pipette tip
microspectrometer
sample
tip
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PCT/US2017/061794
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English (en)
Inventor
Bradley Lynn Postier
Thomas Michael SPUDICH
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SPECTRUM PERCEPTION LLC
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SPECTRUM PERCEPTION LLC
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Classifications

    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L3/00Containers or dishes for laboratory use, e.g. laboratory glassware; Droppers
    • B01L3/02Burettes; Pipettes
    • B01L3/0275Interchangeable or disposable dispensing tips
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
    • G01N21/00Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
    • G01N21/01Arrangements or apparatus for facilitating the optical investigation
    • G01N21/03Cuvette constructions
    • G01N21/0303Optical path conditioning in cuvettes, e.g. windows; adapted optical elements or systems; path modifying or adjustment
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L2200/00Solutions for specific problems relating to chemical or physical laboratory apparatus
    • B01L2200/02Adapting objects or devices to another
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L2300/00Additional constructional details
    • B01L2300/06Auxiliary integrated devices, integrated components
    • B01L2300/0627Sensor or part of a sensor is integrated
    • B01L2300/0654Lenses; Optical fibres
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B01PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
    • B01LCHEMICAL OR PHYSICAL LABORATORY APPARATUS FOR GENERAL USE
    • B01L2300/00Additional constructional details
    • B01L2300/08Geometry, shape and general structure
    • B01L2300/0848Specific forms of parts of containers
    • B01L2300/0858Side walls

Definitions

  • the present disclosure relates to disposable pipette tips that enable spectroscopic analysis of analytes within the tip and specifically disposable pipette tips that provide for an integral light guide to interface with a microspectrometer to provide spectroscopic analysis.
  • Spectrometers are utilized to measure the light or radiation altering properties of solutes or their surrogate analytes in solution for this purpose.
  • Spectrophotometers or spectrometers can be multipurpose or designed and built for specific purposes. Multipurpose instruments have a common design mechanism as discussed below while those with specific purpose may have alternative components and potentially simplified formats. Specific purpose instruments are less common but are advantageous for differing reasons including expense, size, data quality, environmental factors, mobility, ease of use, and sample concerns. Often the multipurpose instruments, while providing flexibility, have reduced sensitivity than when compared to the single purpose instruments which have been optimized for a single purpose.
  • Standard multipurpose spectrophotometers require that the sample in question be obtained and then placed in a specific sampling cuvette which is then placed into the spectrophotometer directly in the path of a beam of light.
  • a sensor is present in the light path downstream for detection of the light altering properties of the sample.
  • the relationship of the light source, sample, and sensor is important for consistency of measured results.
  • the light altering properties of the sample are typically compared against a reference sample (typically the same solvent without the target solute) to provide data regarding differences in light absorption, transmittance, scatter or emission. These differences are then associated with the solute of interest.
  • spectrophotometers are for the determination of solute concentration in solution and they are very common in determining the concentration of certain biological components, often which have been tagged with markers specifically designed to assist in spectrophotometry. For example, measuring the absorbance of light by a sample at 260 nm (A 26 o) can determine the concentration of nucleic acids in the sample solution after extraction of those nucleic acids from biological samples.
  • a 26 o the concentration of nucleic acids in the sample solution after extraction of those nucleic acids from biological samples.
  • the presence of contaminant molecules such as protein, guanidinium salts, and phenol in a sample can increase the A 26 o absorbance as well and this can provide an inaccurate reading.
  • these are common contaminants from nucleic acid preparations they originally needed to be removed before accurate measurements of the extracted nucleic acids could be relied upon.
  • A260:28o ratios are used to determine the level of protein contamination in a sample while A 260:2 3o ratios are used to determine the contamination due to either guanidinium salts or phenolic compounds. Further processing can reduce the contamination and this can be further confirmed by repeating the optical measurements. For these applications, the relationship of the light source, sample, and sensor must again be consistent amongst samples to obtaining reliable results.
  • Colorimetric assays are designed for indirect detection of a substance in solution.
  • the target substance may be a chemical compound, enzyme, or unknown mixture of compounds. Colorimetric assays involve chemical or physical reactions that involve a substrate/enzyme or target/ligand of interest.
  • the result of this chemical reaction is the production of a compound or complex that has altered light/radiation absorbing/emitting properties at a specific wavelength.
  • the change in light properties is linear in response to the concentration of the specific substrate of interest within a useful range of substrate concentration.
  • Some examples include the use of ferrozine to measure iron atoms, Coomassie blue for protein, and para-nitrophenylphosphate for phosphatase activity.
  • Fluorescent spectroscopy can be linked to enzyme assays, studies of photosynthetic activity, cell enumeration, and various other fluorescence-based assays. Fluorescent probes and substrates have expanded the potential for sensitive detection of analytes of interest and generated a broad industry focused on its exploitation.
  • luminescent assays which are at their core spectroscopy.
  • an enzyme/substrate pair are used to study analytes by generation of light within the sample and using the illuminometer (the reading spectrometer) to record the light levels.
  • the reading spectrometer the reading spectrometer
  • spectrophotometers used in most research are large and complex instruments designed for benchtop use as they often need to produce light at specific wavelength bands and detect absorbance of such light. These instruments are applicable in the chemical or biological laboratories for basic research, clinical diagnostics, biotechnology, chemical, and pharmaceutical industries, military applications, homeland security, and forensics laboratory settings where space is not at a premium and the size and bulk of a machine is a far less important consideration than its effectiveness.
  • the instruments are too bulky to be mobile as they are often attached directly to a computer to drive the instrument and extract or analyze data.
  • Instrument miniaturization generally allows for the instrument to be more portable while assay miniaturization allows for the use of spectroscopy to detect the presence of small concentrations of materials without need to concentrate them.
  • the path length of standard cuvettes is 1 centimeter and, thus, filing a cuvette typically requires comparatively significant volume of the sample for analysis. Because of this, it is often necessary to prepare a sample to concentrate an analyte of interest to make sure that it is sufficiently detectable when the sample is placed in the solvent at this volume. Similarly, particularly high percentage samples may need to be diluted. Instrument miniaturization has allowed for smaller devices to be provided, but these devices are generally still designed for benchtop use and are designed for specific purposes. For example, the single purpose NANODROP spectrophotometer provides a smaller machine than standard spectrophotometers and uses a very small sample. However, it is not easily portable and is really only useable for specific types of analysis.
  • Multi-purpose spectrophotometers have generally been bulky laboratory based devices. While they provide for very useful analysis, their physical bulk, and need for a relatively large sample size, has meant that they are only useable when samples can be prepared specifically for them. Thus, it has generally not been possible to perform spectrophotometry on particularly small samples across a wide range of analytes of interest, and it has generally not be possible to perform such spectrophotometry on samples which are not prepared and analyzed in a laboratory for the spectrophotometer. Thus, the
  • spectrophotometer has been a device which could be very useful in a variety of settings, but is confined to specific laboratory testing.
  • a microspectrometer is a micropipette with the functional capability to irradiate an attached tip with light of a defined wavelength and measure the impact of the sample within the tip on the irradiated light as the modified light is directed back to sensors on or within the instrument.
  • a pipette tip comprising: a top portion for interconnecting said pipette tip to a barrel of a microspectrometer; a middle portion including a light guide and a sample chamber; a lower portion including a hollow internal volume interconnecting with said sample chamber; wherein said light guide is configured to direct input light along a vector from said microspectrometer through said sample chamber and back to said microspectrometer, said light changing direction at least twice to return to said microspectrometer along a vector in opposing direction to said vector of said input light.
  • the middle portion is generally in the shape of a conical frustum.
  • the conical frustum has a non-circular cross sectional shape.
  • the cross sectional shape of said conical frustum is in the form of two generally half circles connected by two opposing generally parallel lines.
  • the sample chamber has a non-circular cross sectional shape.
  • the cross sectional shape of said sample chamber is in the form of two generally half circles connected by two opposing generally parallel lines.
  • the top portion is generally in the shape of a conical frustum.
  • the conical frustum has a non-circular cross sectional shape.
  • the cross sectional shape of said conical frustum is in the form of two generally half circles connected by two opposing generally parallel lines.
  • the lower portion is elongated relative to said middle portion.
  • a pipette tip comprising: a top portion for interconnecting said pipette tip to a barrel of a microspectrometer; a middle portion including a light guide; a lower portion including a sampling chamber; wherein said light guide is configured to direct input light along a vector from said microspectrometer through said sample chamber and back to said microspectrometer, said light changing direction at least twice to return to said microspectrometer along a vector in opposing direction to said vector of said input light.
  • the middle portion is generally in the shape of a conical frustum.
  • the lower portion is generally rounded at an extreme end, said light internally reflecting from said rounding into said sample chamber.
  • the pipette tip is formed from two halves, each of said halves including generally half of each of said portions, bonded together [034] In an embodiment of the pipette tip, the bonding is ultrasonic welding.
  • the halves are molded as strip containing a plurality of said halves.
  • a pipette tip comprising: a top portion for interconnecting said pipette tip to a barrel of a microspectrometer; a bottom portion comprising two light guide arms separated by a sample region at a terminal end spaced from said top portion; wherein said light guide arms are configured to direct input light along a vector from said microspectrometer through said sample region and back to said microspectrometer, said light changing direction at least twice to return to said
  • microspectrometer along a different arm from an arm guiding said input light to said sample region.
  • FIGS. 1-4 provide four views of an embodiment of a disposable microspectrometer tip as described herein.
  • FIG. 1 shows a perspective view
  • FIG. 2 shows a front view
  • FIG. 3 shows a top view
  • FIG. 4 shows a side view.
  • FIG. 5 shows a general indication of how light can be directed through the tip of FIGS. 1-4.
  • FIG. 6 shows a cross section of the tip of FIGS. 1-4 showing alignment of the channels for the light guides in the pipette barrel to the tip.
  • FIG. 7 shows an alternative embodiment of a disposable microspectrometer tip which uses an elongated guide to reduce necessary sample volume.
  • FIGS. 8 A, 8B, and 8C show various views of each half tip of FIG. 7.
  • FIG. 8A shows a perspective view
  • FIG. 8B shows a front view
  • FIG. 8C shows a side view.
  • FIG. 9 shows a front view of a single molding comprising eight half tips of FIGS. 8A-
  • FIG. 10 shows how two moldings of FIG. 9 can be combined together.
  • FIG. 1 1 shows a detail view of the breakable joint connecting the various half tips in the molding of FIG. 9 together.
  • FIGS. 12A and 12B show details of the light guides through a half tip of FIG. 7.
  • FIG. 12A shows a rear view of a half tip of FIG. 7 and
  • FIG. 12B shows a detail of the end of tip.
  • FIGS 13A, 13B, 14A, 14B, 15A and 15B show various views of alternative tips which do not draw a sample but are submerged in a sample.
  • FIGS. 13A and 13B show a perspective view and front view respectively of a first alternative tip
  • FIGS. 14A and 14B show a perspective view and front view respectively of a second alternative tip
  • FIGS. 15A and 15B show a perspective view and front view respectively of a third alternative tip.
  • the present invention relates to novel disposable pipette tips that enable spectroscopic analysis of analytes held within the tip while attached to a microspectrometer.
  • microspectrometer is a micropipette with the functional capability to irradiate an attached tip with light of at least one defined wavelength (or wavelength band) and measure the absorption of the light (or other characteristic) by the sample within the tip as the modified light is directed back to sensors on or within the microspectrometer.
  • the instrument is lightweight, portable, and capable of data display and or transmission to other electronic devices.
  • the described tips have design features that ensure attachment to the instrument, alignment with the optics, and allow samples to be drawn within and positioned within the light path of the instrument.
  • microspectrometer it will generally be referring to a device such as one constructed in accordance with the teaching of the above referenced patent documents and this includes both microspectrometers and microspectrophotometers.
  • the tips described herein may be useable with other types of devices as would be understood by one of ordinary skill in the art.
  • the pipettes contemplated herein generally add design features of the tip that enable the tip to alter the light path of the microspectrometer by directing it to a sample that is not positioned immediately between the light source and the detector within the instrument, but through a sample within the tip. This light direction is accomplished through the use of internal reflection within the body of the tip.
  • the body of the tip includes structures to enable it to act as a light guide. The advantage of redirecting the light path into the tip is that it allows the manufacture of tips through existing technology at low costs while reducing the minimum sample volume requirements needed for measurement.
  • FIGS. 1-7 and 8-12B Two different embodiments of pipette tips (100) and (200) utilizing an internal sample are provided in FIGS. 1-7 and 8-12B.
  • These pipette tips (100) and (200) are different from traditional pipette tips in that tips (100) and (200) are used to draw up a sample and direct light from a microspectrometer (600) through a sample held within the body of the tip (100) and (200). This is achieved by making the walls of the pipette tip (100) and (200) act as a light guide.
  • These tips (100) and (200) thus, alter the light path from the microspectrometer (600) directing it to pass through a sample held within the tip (100) or (200) and back to the microspectrometer (600) for detection.
  • the tips (100) and (200) are generally constructed utilizing transparent walls (135), (335) and (535) which allow for light to pass through the material and with a hollow internal volume (131), (331), and (531) and are designed such that light entering the walls of the tip (100) or (200) (or more particularly a portion of it) from a microspectrometer (600) is redirected using internal reflection toward and back from a sample chamber (331) which is within the tip (100) and (200) . Any modification of the light caused by the interaction of the light with the sample can then be detected, recorded, and displayed by the microspectrometer (600).
  • One advantage of this design is that it eliminates the need for the sample to be placed directly in between the light source and detector within the body of a spectrophotometer (600). It also has the advantage that it reduces the minimal required volume of sample necessary for a spectrophotometer (600) to the amount which can fill a pipette sample chamber. For example, in an embodiment of tip (100) of standard size, one microliter will commonly be sufficient for analysis. In another embodiment where the tip (200) is rounded off rather than cone shaped, the volume may be substantially less than 1mm. In many cases, the sample can also be recovered after spectroscopic analysis without contamination and can be used for additional purposes.
  • the tip (100) includes a generally narrow sampling port formed in the bottom portion (521), a sampling chamber in the middle portion (321), and the pipette barrel attachment and aligning walls in the top portion (121).
  • Light from the pipette barrel connector (601) of the microspectrometer (600) (as shown in FIGS. 5 and 6) is projected onto the flat top surfaces (317) of the optical guide region which is within the middle portion (321).
  • the tip (100) When viewed from the side or front, the tip (100) is generally comprised of three functional components arranged in a vertical manner corresponding to the three functional elements discussed above which are referred to as the top portion (121), middle portion (321), and bottom portion (521).
  • the larger top portion (121) is generally used to attach the tip (100) to a microspectrometer (500) as shown in FIG. 6.
  • This top portion (121) is of generally elongated shape having a generally continuous external wall (135) enclosing a hollow volume (131).
  • the external wall (135) will commonly be formed of transparent or translucent material for ease of manufacture, but this is by no means required.
  • the external wall typically will generally include a taper with decreasing perimeter size from the top opening (103) to the flat surface (317) interconnecting with the middle portion (321) of the tip (100).
  • the top portion (121) may include one or more ribs (141) which are on the external surface of the external wall (135) and provide a structure for support when packaged in a common pipette tip box.
  • the ribs (141) in the depicted embodiment are vertically oriented but that is by no means required.
  • the top portion (121) of the tip (100) has a generally oval or "racetrack" cross-section when viewed from above as can be best seen in FIGS. 1 and 3.
  • the cross-section in FIG. 3 provide for two opposing generally parallel planar surfaces provides for two rounded ends (101) and (103) which are generally semicircular and are interconnected by two generally linear side faces (1 13) and (1 15).
  • the top portion (121) will be circular, ovular, ellipsoidal, or any other shape in cross section.
  • the element of its cross section will generally be selected so as to provide frictional engagement with the barrel (601) of the microspectrometer (600).
  • the tip (100) will be connected to the microspectrometer (600) with the tapered barrel (601) of the microspectrometer (600) being inserted into the hollow volume (131) of the tip (100) via the top opening (133).
  • the barrel (601) will generally have a similar cross sectional shape as the tip (100) providing that the tip will generally self align with the barrel (601).
  • the light channels (603) be aligned so light is reflected through the opposing parallel faces (313) and (315), a self-aligning design is generally preferred.
  • the second portion (321) of the tip (100) acts as a light guide for directing light into the sample and returning light from the sample to the microspectrometer (600).
  • the second portion (321) is generally in the shape of an inverted conical frustum.
  • the walls (335) of the frustum surround a generally tubular sample chamber (331) forming a hollow center through the frustum.
  • the sample chamber (33 1) will generally have an internal circumference which is substantially less than the circumference of the lowest portion of top portion (121). This creates a generally flat face (317) forming a partial base of the top portion (121) with the top (303) opening of the sample chamber (331) being positioned generally in the center of this base (317).
  • the structure of the second portion (321) of the tip (100) provides the means to redirect light from the microspectrometer (600) across the sample chamber (331) and back to the microspectrometer (600). This redirection is achieved through the use of internal reflection on smooth surfaces formed in the walls (335) which are designed and positioned to redirect the light through the sample chamber (331).
  • the second portion (321) of the tip (100) acts as a light guide.
  • the walls (335) of the second portion (321) will be constructed of a material which is generally transparent, at least with regards to the wavelength(s) of light being utilized in conjunction with the tip (100).
  • the sample chamber (331) is of a hollow tubular shape have at least two opposing generally flat walls (313) and (315) positioned in a generally plane parallel fashion. In the depicted embodiment, they are slightly tapered outward (slightly conical) to allow their manufacture through injection molding.
  • the hollow space internal to the walls (335) is the sampling chamber (331). A sample is drawn up through the bottom portion (521) of the tip (100) and a portion of it is held in position within the sampling chamber (331) for analysis.
  • the sampling chamber (331) may project upward into the top portion (through the surface (317)) to permit the positioning of a filter or other object to reduce exposure of the sample in the sample chamber (331) to outside air.
  • the overall body shape of this second portion (321) is preferably reduced in size to reduce the volume (and particularly the diameter) of material the light will travel through.
  • the short light path within the light guide part of the tip (100) permits the use of materials that are not 100% transparent to the measuring light but are sufficiently conductive to allow for light to pass through a relatively thin amount of sample.
  • the sample chamber (331) in the embodiment of FIGS. 1-4 is generally tubular in shape and has a cross section of similar shape to that of the top portion (121) but that is by no means required.
  • the sample chamber (331) of the embodiment of FIGS. 1-4 is of loosely ovular or racetrack form comprising two half-circular ends (301) and (303) connected by two generally linear sides (313) and (315). As can be best seen in FIG. 3, the linearity of the side (313) and (315) may be enhanced over that of sides (1 13) and (1 15).
  • This is generally to provide two opposing generally plane parallel surfaces which are used as the surfaces for supplying light to the sample chamber (331) and collecting light from the sample chamber (331). Light will pass through one side (313), through the sample in the sample chamber (331) and then will continue through the other side (315). To avoid distortion or reflection of light in this area, it is preferred that these surfaces be as planar and as parallel as possible given modern manufacturing techniques.
  • the sample chamber (331) generally does not have the clear taper present in the internal volume of the top portion (121) but may have some taper to allow for traditional manufacturing. It instead has generally flat walls (313) and (315) positioned in a generally plane parallel fashion however, the sample chamber (331) may be slightly tapered outward to allow manufacture through injection molding using side action draw pins.
  • the flat base (317) will generally provide for alignment of the sample chamber (331) to the microspectrometer (600). As can be best seen in FIG. 6, when the barrel (601) of the microspectrometer (600) is placed in the top portion (121), the cross sectional shape will force alignment of the light channels (603) in the microspectrometer (600) with the portion of the flat base (317) which is adjacent the sides (313) and (315) of the sample chamber (331). The barrel (601) will also generally fit snuggly against the flat base (3 13) providing for little to no gap between the base (317) and the end of the barrel (601).
  • FIG. 6 the cross section of the barrel (601) of a microspectrometer (600) is shown inserted and properly seated within an embodiment of a tip (100) corresponding to that of FIGS. 1-4.
  • the channels for light (603) included within the barrel (601) of the microspectrometer (600) that transfer light from a light source to the tip (100) and from the tip (100) to a detector are included.
  • the light in this path will pass through the sample chamber (331) which is expected to be holding the sample.
  • the light guiding portion of the tip (100) redirects light entering in a vertical orientation to a horizontal direction across the sample and then redirects it vertically to exit the tip (100) and enter the light channel (603) from the barrel (601) where it is directed.
  • the light Upon leaving the sample chamber (331), the light will hit the wall (315) again at a generally 90 degree angle passing through it with generally minimal reflectance. Again, the angle of incidence on the exterior surface (345) is angled relative to the face (315) such that the light is generally close to entirely internally reflected and directed back toward the flat base (317). As again the light intersects the face (317) at a virtually 90 degree angle, the light will pass back into the other light channel (603) of the microspectrometer (600) with generally little reflection. After entering the channel (603) the light can be collected and measured as understood by those of ordinary skill in the art. As should be apparent from FIG. 5, either light channel (603) in the microspectrometer (600) can be the source of the light and the other can act as the collector.
  • the lower portion (521) of the tip (100) also generally has a rounded rectangular conical frustum shape with cross section corresponding generally to the cross section of the top (121) or middle portion (321). This is, however, done for ease of manufacturing and is by no means required.
  • the bottom portion (521 ) may have a more traditional circular conical frustum shape.
  • the bottom portion (521) is generally elongated to allow it to extend into a microcentrifuge tube or other sample location to allow samples to be drawn from the bottom of a microcentrifuge tube or other sample source having a narrow access port.
  • the lower portion (521) is not of particularly elongate shape as the internal volume of its hollow interior (531), in addition to the volume of the sample chamber (331), directly correlates with the sample volume that is necessary to perform spectroscopy.
  • the hollow portions (531) and (331) of the two lower portions (321) and (521) of the tip (100) can be as short and narrow as reasonably possible.
  • some length is still generally necessary to allow reaching into the bottom of the sample holder with which it could be commonly used.
  • the tip (100) is also beneficial to reduce the external diameter of the top portion (121) of the tip (100) allowing it to fit within the sampling vessel without impediment even when placed on the barrel (601). This allows the tip (100) to be inserted as low as necessary into the sample holder (which is usually a microcentrifuge tube).
  • the sample is drawn up through the lower portion (521) of the tip (100) and a portion is held in position within the sampling chamber (331) for analysis.
  • Analysis is performed, and then the sample can be discarded in an embodiment.
  • the sample may also have spectroscopic analysis performed while utilizing the microspectrometer to transfer the sample to another location.
  • the system allows for a very small sample size to be analyzed effectively in transport between two other necessary locations of that sample.
  • the sample chamber (331) dimensions may be optimized for optical path lengths (the distance between faces (313) and (315)) between 0.1 and 10mm. Shorter path lengths are ideal for small sample volumes and for sampling concentrated analytes without dilution. Longer path lengths are ideal for cases like measuring cell density where a 1cm path length is standard and there is little concern for sample volume.
  • FIGS. 7-12B provide for another embodiment of a tip (200) which is useable on a very small sample.
  • the middle portion (321) is greatly elongated and externally tapered and the bottom portion (521) is extremely short.
  • the light guide element of the prior middle portion (321) is now positioned within the bottom portion (521). This provides for a middle portion (321) which acts as an elongated light guide directing the light from the microspectrometer (600) toward the bottom portion (521) which is shaped to act as the middle portion (321) of the prior embodiment.
  • the light is only reflected at the extreme end (703) through the hollow sampling chamber (331).
  • this embodiment uses a internal elongated light guide formed form the walls (335) of the middle portion (321) to reduce the sample volume needed for measurement when light transmission efficiency is not a concern by placing the sample chamber (331) at the extreme end (703) of the tip (200). Light from the microspectrometer (600) barrel (601) is projected onto/into the horizontal surface (317) inside the tip (200).
  • the sample only needs to be drawn up past the lowest portion (521) allowing use of an extremely small sample.
  • FIG. 12 A there is a front view of a filleted design which shows a single tip (200) with a filleted shape lower portion (521) of the tip (200) as can be seen in the magnified view of FIG. 12B.
  • a rounded end (703) on the lower portion (521) may result in more
  • the design the tip (200) may include an upper chamfer with around 3% draft to allow injection molding using a side action pin.
  • the lower chamfered region has a complimentary about 42% draft to direct the light 90 degrees from the original path of light from the instrument. The light then passes through the sample and turns another 90 degrees toward the microspectrometer (600).
  • the tip (200) may be molded using two identical halves (201 A) and (20 IB) in a manner such that two halves (201) can be joined later through sealing compounds, sonic welding, or over molding or in any manner to join two parts together. Note that while this modeling is contemplated with the embodiment of tip (200) shown in FIG. 12, this molding method may also be used on tip (100) of FIG. 1 -5. Molding the tips (200) in halves (201) eases mold design reducing side action pins, which are easily damaged and expensive to maintain.
  • FIGS 8A, 8B and 8C show various additional views of the two molded halves (201) which may be used in FIG. 7.
  • the half (201) is used as both halves (201 A) and (20 IB) in the embodiment of the FIG. 7 as the two halves (201 A) and (20 IB) are identical parts for all intents and purposed.
  • the two halves (201 A) and (20 IB) may actually be essentially identical parts made from the same mold cavity as contemplated herein, or may be nearly identical parts with differences resulting from modifications to the mating faces (705) to allow for joining the two pieces.
  • the mating faces (705) may comprise corresponding male and female connectors to allow for more secure and aligned connection.
  • Molding the tips (200) in two halves (201) instead of just one provides opportunities to make significant changes to the central geometry of the tip (200) that cannot be made using side action pin molding.
  • the overall geometry of the hollow center core and particularly the sample chamber (331) is no longer limited to the draft and pulling action of the central core pin. This means a thinner core can be made to reduce the light path of the sample and to reduce the total sample volume required.
  • the extra cost associated with a second round of processing (for example, sonic welding after injection molding) can be offset by making more than one tip (200) at a time by automated sonic welding, and by reducing the initial cost and maintenance of the mold to make the tips (200).
  • the tips (200) can be molded in two halves (201) and then sonic welded together, it is not required.
  • the tips (200) can still be made in the fashion of traditional single pipette tips or in multi-unit strips using side action pins to create the internal hollow cavity.
  • the two-halve molded tips (200) are generally rounded in cross section as the placement of the sample chamber (331) at the extreme end (703) and utilizing a rounded tip end (705) generally means that the planar faces (313) and (315) are not necessary.
  • half molding is not limited to only rounded tips and may be used on any embodiment of tips (100) or (200).
  • the same rounded rectangular shape described for tips (100) in FIGS. 1-5 can also be split in halves for molding.
  • oval, triangular, hexagonal, octagonal, or other top down profiles can be utilized as necessary for optimal efficiency at directing the light to the sample and back to the detector and for connection to specific microspectrometers (600).
  • alternate shapes may also be preferred for packaging or storage of tips or alignment with the instrument and these can also be produced as would be understood by one of ordinary skill in the art.
  • FIGS. 9-10 illustrate an embodiment which allows for multiple tip halves (201) to be co-molded as one piece (901) to simplify manufacturing.
  • Two strips (901 A) and (90 IB) of halves (201) may then be connected together using adhesives or techniques such as sonic welding as known to the art and illustrated in FIG. 10.
  • this form of molding provides for eight half tips (201) in a strip (901) to ease molding, and eliminating the need for side action inserts in the mold design.
  • the eight tip halves (201) may be joined by an easily breakable connection (91 1 ) as best illustrated in the detail view of FIG. 1 1.
  • tips (200) can then be separated by breaking the breakable connections (91 1) between each tip (200). This can be performed as part of manufacturing or can be performed at the time of use by an end user. Regardless, it allows for each tip (200) to be used one at a time.
  • the tip halves (201) may be molded together with a nine millimeter pitch (distance between two tip halves (201)) to allow tips formed from the entire strip (901) to be inserted into a standard 8x12 box as is common for pipette tips.
  • tips (200) can be boxed, or packed and hermetically sealed in pouches. Tips (200) may be broken off one at a time for individual use or used intact with multichannel devices. It is also possible to reduce the pitch between joined tips (200) as desired. This can cause the tips (200) to break apart when inserted into standard tip boxes for packaging. In this way, they can be used by single channel or by multichannel instruments without the user needing to break the tips apart. [081] The above referenced images and text, refer to a standard pitch being preferred between tips (200).
  • tips are packed in boxes using a nine-millimeter space or pitch between tips in a box in both orientations unless the holes or slots for the tips are offset to reduce the overall size of the box.
  • This allows standardization for multichannel pipettes and for robotic processes.
  • the use of these tips (100) or (200) is not limited to high throughput devices and may be used one tip (100) or (200) at a time. As such they may be packed in boxes other than the standard 8x12 conformation.
  • they may be packaged in paper or plastic films similar to syringes or bandages. They may be packaged as single tips, or in packages of 4, 8, 10, 12, or any other number of tips commonly used in one setting/experiment/test and convenient for the user. They may or may not be sterile, protease or nuclease free. They can also be packed in bulk within bags or other containers.
  • FIGS. 13A-15B provide for variable views of three embodiments of "pipette" tips (900) which utilize a light guide without a hollow core. These are useful for allowing the microspectrometer (600) used above to spectrographically analyze a sample, but without the need for the microspectrometer (600) to apply a positive or negative pressure to the sample to draw a sample into the sample chamber (331). Instead, the end of the tip (900) is submerged in the solution to be analyzed.
  • the tip (900) is more accurately described as a probe which is composed of two light guides (401) attached with a collar (915) or cross member (917) that serves to attach and align the tip (400) with the microspectrometer (600).
  • the collar (915) or cross member (917) also is used to control the spacing between the two light guides (401) and defines the optical path length (941) which is the equivalent of the length across a sample chamber (331).
  • the tip (900) is attached to the microspectrometer (600) without contamination of the light guides (401) by potential contaminants by simply pressing the barrel (601) of the microspectrometer (600) onto the collar (915) in the same manner that the barrel (601) connects with the top portions (121) in prior embodiments.
  • the light guides (401) are, at least in part, light transmitting to the wavelength of interest and direct light away from the microspectrometer (600) toward and across a sample located between the two arms (401). The light is again captured by the second light guide arm (401) and directed back up through internal reflection to the microspectrometer (600). In effect, the arms (401) of the
  • FIGS. 13A-15B represent the minimum structure for guiding light of the tip (200) as all remaining wall (335) and (535) structure has been removed.
  • the sample region (941) is defined as the area between the two light guide arms (401) where light exits one light guide (401), passes through the sample region (941), and back into the second light guide (401).
  • Two tip (900) versions (903) and (905) rely on a tapered top portion collar (915) allowing a snug or snap fit collar common to pipette tips and which may be of similar design to the top portion (121) of the above discussed embodiments.
  • the other embodiment (907) instead utilizes a cross member (917) that can be releaseably clamped by the microspectrometer itself.
  • Light guide legs (931) extend downward from the connector (915) or (917) and may be of various lengths appropriate to reach the solution in the bottom of a vessel based on the type of analysis they are intended for.
  • Shorter guides (903) and (907) such as shown in FIGS 13A, 13B, 14A, and 14B will commonly be used for standard microcentrifuge tubes while longer guides (905) as shown in FIGS. 15A and 15B can be used for 15 ml microbial culture tubes or altered in length for any depth of vessel.
  • longer guides (905) as shown in FIGS. 15A and 15B can be used for 15 ml microbial culture tubes or altered in length for any depth of vessel.
  • FIGS 13A-15B as the sample chamber (331) is eliminated and simply replaced by an open sample region (941) as there is no need to draw material from the current vessel into the tip (400).
  • sample region (941) which is preferably located at or near the base of the tip (400) and where light is directed between the two light guide legs (931) is simply submerged in the sample in whatever vessel currently contains it (or the sample may be placed between the arms (401) if the sample is solid).
  • the optical path length which corresponds to the distance that the light guide arms (401) are apart, can be variable depending on the specific embodiment and intended use.
  • tip (903) may have a particularly small sample region (941) of about 0.5 mm while tips (905) and (907) may have a much longer sample region (941) such as about 5 mm to about 1 cm.
  • These examples were chosen to demonstrate that a variety of path lengths can be created dependent on the needs of the assay performed, but are in no way required. Shorter path lengths would generally be preferred for concentrated solutions such a nucleic acid analysis. Longer path lengths such as 1 cm would be preferred to measure microbial cell density as that is the most commonly reported path length in the literature.
  • the light guides (401) can have square, rectangular, round or any cross section profile as necessary to deliver light to the sample region (941) and back to the microspectrometer (600).
  • the light guides (401) can be molded or cut from any transparent material.
  • the guides can be coated or over molded with material to reduce stray light from entering the light guide and/or to improve internal reflection. This coating may also be incorporated into the upper portion (921) used to attach and align the tip (900) with the microspectrometer (600).
  • the collar (915) and/or coating may be molded separately and snapped over the arms (401), or sonic welded to or around the arms (401).
  • the arms (401) can be made of plastic including polyethylene, polypropylene, cyclic olefin copolymer, acrylic, polycarbonate or mixtures there of and of various densities.
  • the arms (401) can also be made of glass, quartz, or any other optically transparent material.
  • a coating or covering sleeve can be made of plastic or other material that is not transparent to the wavelength of light of interest and may be sprayed on, brushed on, over molded, snapped on, sonic welded to or around, or applied by any means necessary to reduce or prevent stray light from entering the light guides or better constrain light within the waveguide arms (401 ).
  • the probe material can be pigmented during manufacture to absorb wavelengths of light which are considered unfavorable to analysis of the analyte of interest.

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  • Chemical & Material Sciences (AREA)
  • Health & Medical Sciences (AREA)
  • General Health & Medical Sciences (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Analytical Chemistry (AREA)
  • Biochemistry (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Immunology (AREA)
  • Pathology (AREA)
  • Clinical Laboratory Science (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Optical Measuring Cells (AREA)
  • Investigating Or Analysing Materials By Optical Means (AREA)

Abstract

L'invention porte sur de nouveaux embouts de pipette jetables qui permettent une analyse spectroscopique d'analytes contenus à l'intérieur de l'embout tout en étant fixées à un microspectromètre ou à un microspectromètre qui est une micropipette ayant la capacité fonctionnelle d'irradier un embout attaché avec une lumière d'une longueur d'onde définie et de mesurer l'impact de l'échantillon à l'intérieur de l'embout sur la lumière irradiée lorsque la lumière modifiée est renvoyée vers des capteurs sur ou à l'intérieur de l'instrument. L'analyse spectroscopique d'échantillons est intégrée à une large gamme de sciences de la recherche, y compris la microbiologie, la biologie moléculaire, la chimie médicale, l'environnement, l'alimentaire et la médecine légale.
PCT/US2017/061794 2016-11-15 2017-11-15 Embout de pipette avec guides de lumière intégrés dans le corps et procédé d'analyse spectroscopique l'utilisant Ceased WO2018093896A1 (fr)

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US201662422441P 2016-11-15 2016-11-15
US62/422,441 2016-11-15

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Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20070081159A1 (en) * 2005-10-11 2007-04-12 Giffin Kristin M Apparatus and methods for evaluating an optical property of a liquid sample
US20100167412A1 (en) * 2008-12-31 2010-07-01 Caibin Xiao Sensor system for determining concentration of chemical and biological analytes
US20160245739A1 (en) * 2013-10-11 2016-08-25 National University Of Singapore Disposable photometric measurement tip
WO2016156051A1 (fr) * 2015-03-27 2016-10-06 Brian Page Pipette comprenant une source de lumière et un détecteur

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20070081159A1 (en) * 2005-10-11 2007-04-12 Giffin Kristin M Apparatus and methods for evaluating an optical property of a liquid sample
US20100167412A1 (en) * 2008-12-31 2010-07-01 Caibin Xiao Sensor system for determining concentration of chemical and biological analytes
US20160245739A1 (en) * 2013-10-11 2016-08-25 National University Of Singapore Disposable photometric measurement tip
WO2016156051A1 (fr) * 2015-03-27 2016-10-06 Brian Page Pipette comprenant une source de lumière et un détecteur

Non-Patent Citations (1)

* Cited by examiner, † Cited by third party
Title
PENA-PEREIRA, FRANCISCO ET AL.: "Advances in miniaturized UV-Vis spectrometric systems", TRENDS IN ANALYTICAL CHEMISTRY, vol. 30, no. 10, 2011, pages 1637 - 1648, XP028310104 *

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