WO2004085609A2 - Nanopores, methods for using same, methods for making same and methods for characterizing biomolecules using same - Google Patents
Nanopores, methods for using same, methods for making same and methods for characterizing biomolecules using same Download PDFInfo
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- WO2004085609A2 WO2004085609A2 PCT/US2004/004138 US2004004138W WO2004085609A2 WO 2004085609 A2 WO2004085609 A2 WO 2004085609A2 US 2004004138 W US2004004138 W US 2004004138W WO 2004085609 A2 WO2004085609 A2 WO 2004085609A2
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12Q—MEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
- C12Q1/00—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
- C12Q1/68—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving nucleic acids
- C12Q1/6869—Methods for sequencing
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y15/00—Nanotechnology for interacting, sensing or actuating, e.g. quantum dots as markers in protein assays or molecular motors
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y5/00—Nanobiotechnology or nanomedicine, e.g. protein engineering or drug delivery
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12Q—MEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
- C12Q1/00—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
- C12Q1/68—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving nucleic acids
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- C—CHEMISTRY; METALLURGY
- C12—BIOCHEMISTRY; BEER; SPIRITS; WINE; VINEGAR; MICROBIOLOGY; ENZYMOLOGY; MUTATION OR GENETIC ENGINEERING
- C12Q—MEASURING OR TESTING PROCESSES INVOLVING ENZYMES, NUCLEIC ACIDS OR MICROORGANISMS; COMPOSITIONS OR TEST PAPERS THEREFOR; PROCESSES OF PREPARING SUCH COMPOSITIONS; CONDITION-RESPONSIVE CONTROL IN MICROBIOLOGICAL OR ENZYMOLOGICAL PROCESSES
- C12Q1/00—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions
- C12Q1/68—Measuring or testing processes involving enzymes, nucleic acids or microorganisms; Compositions therefor; Processes of preparing such compositions involving nucleic acids
- C12Q1/6869—Methods for sequencing
- C12Q1/6874—Methods for sequencing involving nucleic acid arrays, e.g. sequencing by hybridisation
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
- G01N33/48—Biological material, e.g. blood, urine; Haemocytometers
- G01N33/483—Physical analysis of biological material
- G01N33/487—Physical analysis of biological material of liquid biological material
- G01N33/48707—Physical analysis of biological material of liquid biological material by electrical means
- G01N33/48721—Investigating individual macromolecules, e.g. by translocation through nanopores
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S977/00—Nanotechnology
- Y10S977/70—Nanostructure
- Y10S977/701—Integrated with dissimilar structures on a common substrate
- Y10S977/72—On an electrically conducting, semi-conducting, or semi-insulating substrate
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10—TECHNICAL SUBJECTS COVERED BY FORMER USPC
- Y10S—TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y10S977/00—Nanotechnology
- Y10S977/902—Specified use of nanostructure
- Y10S977/932—Specified use of nanostructure for electronic or optoelectronic application
Definitions
- NANOPORES METHODS FOR USING SAME, METHODS FOR MAKING SAME AND METHODS FOR CHARACTERIZING BIOMOLECULES USING
- the present invention relates to devices used for characterizing biomolecules as well as sequencing DNA and RNA, and more particularly to a nanopore and/ or an array of nanopores for use in rapid characterization of biomolecules and high throughput DNA sequencing.
- DNA sequencing using nanopore ionic conductance in accordance with the KBBD method involves an insulating wall separating two reservoirs of ionic solutions, where the wall contains a hole so small that only one strand of a single- stranded DNA molecule can fit through the pore.
- the electrical potential drop should almost entirely occur at the nanopore.
- the electrical conductance or resistance between two ionic reservoirs is also the conductance or resistance of the nanopore. Because of the low mobility of the DNA molecule, the ionic conductance through the nanopore is dominated by the flux of Na and CI " flushing through the nanopore.
- the ionic conductance drops when a DNA molecule enters the nanopore.
- the amount of conductance drop will be a measure of the physical size of the part of the DNA molecule that is inside the narrowest part of the channel.
- the chemical groups (nucleotides) of a DNA molecule have slightly different sizes, one should be able to measure the genetic information of the nucleotides of a DNA molecule by measuring the time dependence of the nanopore conductance.
- the underlying assumption of the KBBD method is that the four different nucleotides composing DNA or RNA molecules may have different blockage effects in the ionic current when the molecule moves through a nanopore, because they have different atomic compositions.
- the basic concept of voltage driven DNA translocation through a nanopore is illustrated in Fig.
- the KBBD methodology uses a ⁇ -hemolysin protein ion channel embedded in a lipid bilayer membrane as a natural nanopore. It has been demonstrated that a DNA polymer consisting of 70 cytosine nucleotides and 30 adenine nucleotides does give rise to a measurable signal in the nanopore conductance. However, because the natural nanopores are long channels, typically 30 nm in length, many nucleotides are inside the channel at any time during translocation and the effect of individual nucleotides on the ionic conductance is lost.
- USP 6,428,959 describes methods for determining the presence of double stranded nucleic acids in a sample.
- nucleic acids present in a fluid sample are translocated through a nanopore, e.g., by application of an electric field to the fluid sample.
- the current amplitude through the nanopore is monitored during the translocation process and changes in the amplitude are related to the passage of single- or double-stranded molecules through the nanopore.
- Those methods find use in a variety of applications in which the detection of the presence of double-stranded nucleic acids in a sample is desired, e.g., in hybridization assays, such as Northern blot assays, Southern blot assays, array based hybridization assays, etc.
- nanopore that can be formed using synthetic material and methods for using and making such a nanopore. It also would be desirable to provide a nanopore ⁇ 10 nm in length. It would be desirable to provide a device and method that yields a linear array of nanopores or two-dimensional array of nanopores. It also would be particularly desirable to provide such linear and 2- dimensional nanopore arrays where the nanopores are separately electrically addressable.
- the present invention features devices and systems embodying one or more solid-state nanopores that can be used to sense and/or characterize single macromolecules as well as sequencing DNA or RNA.
- Such devices and systems have a wide range of applications in molecular biology and single-molecule biophysics.
- the devices and systems of the present invention can be used in a variety of applications involving, but not limited to single-molecule biophysics, molecular biology, and biochemistry.
- nanopore devices and systems of the present invention are contemplated for use as a molecular comb to probe the secondary structure of RNA molecules, for use in detecting biological warfare agents, and contaminants/ pollutants in air and/ or water.
- a device including a member of an insulating material, wherein the insulating member is configured and arranged so as to include a through aperture comprising a nanopore therein.
- the through aperture comprises a plurality of crystals that have been cleaved to form atomically sharp edges, which crystals are arranged in fixed relation while forming the insulating material.
- the crystal edges cross each other at a predetermined angle, more particularly an angle of about 90 degrees. It is within the scope of the present invention, however, for the crystal edges to be crossed each other at an angle of less than or more than 90 degrees thereby forming nanopores having different cross-sections or different cross-sectional shapes.
- the crossing cleaved crystal edges essentially form or define an area that is small enough that the molecules making up the insulating material cannot enter into this area. In this way, the molecules of the insulating material should be oriented with respect to the cleaved edges and thus forced to make a contour around the crossing point, thereby leaving a small hole comprising the through aperture therein.
- the crystals are GaAs crystals that are well known in the art.
- the present invention can be practiced using other crystals known to those skilled in the art and having similar characteristics that lend themselves to being cleaved and being held in a fixed relation, while the insulating material comprising the insulating member is formed, such as for example NaCl crystals.
- the insulating material is a material that is characterized as being flowable and which solidifies at the end of the process for forming the nanopore as well as during normal operating conditions (e.g., room temperature).
- the insulating member is made from a curable polymer such as liquid PDMS (poly-dimethylsiloxane), polystyrene or PMMA and GaAs crystals are used to form the nanopore through aperture.
- This technique yields a nanopore having a length or channel length of 20 A (Angstrom/ 10 "10 m) or less, more particularly a channel length of 20 A or less or more particularly a channel length of about 4 A and more specifically a channel length (d) that satisfies one of the following relationships; 2 A ⁇ d ⁇ l ⁇ A or 4 A ⁇ d ⁇ l ⁇ A.
- GaAs crystals are cleaved to form atomically sharp edges.
- the cleaved crystals are then arranged so two such crystal edges are brought together to within a few angstroms distance and held fixed using standard STM electronics and use electron tunneling current as a feedback mechanism (this assumes that the GaAs crystals are doped and have finite electrical conductivity).
- the spacing of the crystal edges is in the range of from between lA and 10 A, more specifically about 2A.
- the crystal edges are spaced from each other so the distance between the crystal edges is less than the thickness (Tm) of the molecule of the insulating material.
- the spacing (Se) between the crystal edges is set so as to satisfy the following relationship Se / Tm ⁇ 0.5.
- the curable polymer liquid PDMS (poly-dimethylsiloxane) is then poured into the region of the cutting edges and cured while the two crystal edges are held fixed. As indicated herein, at the crossing point between the two edges, the distance between the edges is so small that no molecules of the polymer can enter this region.
- the molecules of the polymer also are advantageously oriented parallel to the respective cleaved edges and be forced to make a contour around the crossing point, leaving a small hole. In such a methodology, the width and the length of the nanopore are controlled by the distance between the two edges and the diameter of polymers.
- the crystals are removed, e.g., by washing,
- the crystals used to form the through aperture are NaCl crystals, which crystals are removed by washing with H 2 0.
- systems and methods utilizing the nanopore device of the present invention to perform any of a number of analytical processes including but not limited to characterizing biomolecules, sequencing DNA and determining RNA secondary structures.
- Such methods include providing an insulating member as hereinabove described including a nanopore, wherein a diameter and length of the nanopore are defined by the sharp edges of cleaved crystals that are maintained in fixed relation during the formation of the insulating member and locating the insulating member so as to be disposed between two ionic reservoirs. Such methods further include passing the biomolecules or DNA through the nanopore and characterizing the biomolecule or the DNA based on changes in ionic current or other physical parameter. As to the method for determining RNA secondary structures, the method further includes operably coupling one end of the RNA to an optical tweezer and measuring a force at said one end as the RNA molecule is pulled through the nanopore.
- an electrically-addressable nanopore array that is configured and arranged so as to allow high through-put analyses of biomolecules as well as sequencing DNA.
- the electrically addressable nanopore array includes a linear or one-dimensional array of nanopores.
- the electrically addressable nanopore array includes a two-dimensional array of nanopores.
- the two-dimensional array is in the form of a plurality or more of linear arrays.
- the linear and two dimensional nanopore arrays are formed and arranged in the insulating material so each of the nanopores can be addressed independently using an electric current provided by, for example, a standard patch-clamp arrangement.
- the electrically addressable nanopore array includes an insulating material layer.
- the insulating material layer is configured and arranged so as to have one or more of grooves extending lengthwise in a first direction in a first surface thereof and being parallel to each other.
- the insulating material layer is configured and arranged so a groove also is formed in the insulating material layer second surface that extends lengthwise in a second direction in a second surface thereof, where the first and second surfaces are opposed to each other.
- the second direction is at an angle with respect to the first direction, more particularly the first and second directions are orthogonal to each other or at about a 90 deg. angle with respect to each other.
- the grooves also are formed in each of the first and second surfaces so as to extend downwardly from one surface to the other surface, so that at an intersection of each of the grooves in the first surface and the groove in the second surface there is formed an opening that comprises a nanopore.
- a plurality of nanopores are formed in a linear or one-dimensional array in the insulating material at the intersection of each of the plurality of grooves in the first surface and the groove formed in the second surface.
- the insulating material layer is configured and arranged so as to have a plurality or more of grooves extending lengthwise in the second direction in the second first surface thereof and being parallel to each other.
- the plurality of grooves also are formed in the second surface so as to extend downwardly from one surface to the other surface such that at an intersection of each of the grooves in the first surface and each of the grooves in the second surface there is formed an opening that comprises a nanopore.
- the grooves are V-shaped.
- the insulating material layer is formed from a first sub-layer and a second sub-layer that are bonded or secured to each other using any of a number of techniques known to those skilled in the art and appropriate for the materials being used so as to form the insulating material layer.
- the first sub-layer is configured and arranged so as to include a plurality of grooves that extend between opposing surfaces, one of the opposing surfaces comprising the first surface of the insulating material surface.
- the second sub-layer is configured and arranged so as to include a groove that extends between opposing surfaces, one of the opposing surfaces comprising the second surface of the insulating material surface.
- the second sub-layer can be configured and arranged so as to include a plurality of grooves that each extend between opposing surfaces, one of the opposing surfaces comprising the second surface of the insulating material surface.
- the first and second-sublayers are oriented so that the first and second surfaces of the insulating material layer are opposed to each other and so that the grooves in the first sub-layer are at an angle with respect to the one or more grooves in the second sub-layer, more particularly the first and second sub-layers are oriented so that the grooves in the respective sub-layers are orthogonal to each other or at about a 90 deg. angle with respect to each other.
- At least portions of the tip of each groove in the first and second sub-layer is configured and arranged so as to be open and each groove is formed in each of the first and second sub-layers so as to be separate from each other.
- the open portions also are arranged such that at an intersection of each of the grooves in the first sub-layer and each of the one or more grooves in the second sub-layer, there is formed an opening that comprises a nanopore.
- a plurality of nanopores are formed in a linear or one-dimensional array in the insulating material at the intersection of each of the plurality of grooves in the first sub-layer and each groove in the second sub-layer.
- the grooves are V- shaped and portions of the tips of the V-shaped grooves are formed so as to be opened.
- the first and second sub-layers comprise a silicon wafer and the grooves are formed in the silicon wafer using an oxide or nitride mask in KOH solutions.
- Such a technique allows grooves, more particularly V-shaped grooves to be formed with high accuracy (e.g., within 20 nm) by controlling the etching rate and etching time.
- the first and second sub-layers are bonded together. After bonding, the assemblage is oxidized to form SiO 2 to insulate all silicon surfaces.
- Such methods include providing an linear or two-dimensional electrically-addressable nanopore array such as that hereinabove described and locating the insulating member so as to be disposed between two ionic reservoirs.
- Such methods further include passing the biomolecules or DNA through any one or more of the nanopores of the linear or two-dimensional array and characterizing the biomolecule or the DNA based on changes in ionic current or other physical parameter.
- the method further includes operably coupling one end of the RNA to an optical tweezer and measuring a force at said one end as the RNA molecule is pulled through any one of the nanopores comprising the linear or two- dimensional array.
- a PNA functionalized nanopore device as well as methods and systems related thereto.
- a PNA functionalized includes a nanopore device including one or more nanopores as herein described and a PNA coating that is applied so as to cover at least an interior surface of the at least one or more nanopores.
- the PNA material is synthesized so as to be characterized or constituted by one of the bases that make up a DNA or RNA molecule.
- Related methods include operably coupling one end of the DNA/RNA molecule to an optical tweezer and measuring a force at said one end as the molecule is pulled through any one of the nanopores comprising the linear or two-dimensional array.
- the method further includes sequencing the DNA/ RNA molecule by determining the fluctuations in force as a function of time and correlating the fluctuations to the bonding effect between the one basis characterizing the PNA coating and any one of the number of bases that appear in DNA or RNA.
- Fig. 1 illustrates the basic concept of voltage driven DNA translocation through a nanopore and more particularly (a) is a schematic of a voltage-driven DNA translocation experiment using ⁇ -hemolysin nanopore and (b) illustrates typical translocation events using poly(dA) in buffer 1 M KC1, 1 mM Tris-EDTA (p ⁇ 8.5);
- Figs. 2A,B provides histograms illustrating (Fig.2A) the blockage current versus polymer length and (Fig. 2B) the translocation velocity versus polymer length for the same polymer;
- Fig. 3 is a diagrammatic view illustrating the cutting edges mechanism for forming a nanopore using curable polymers
- Fig. 4 is a schematic view of an exemplary feedback mechanism for controlling the distance between the two cutting edges;
- Fig. 5 is a three-dimensional view of a portion of the cured polymer after the
- GaAs crystals are removed
- Fig. 6 is a perspective view of an array of electrically-addressable nanopores according to an aspect of the present invention
- Fig. 7 is a perspective view of an electrically-addressable nanopore array device according to the present invention with a linear array of nanopores with only one groove in the upper side of the device for clarity;
- Fig. 8 is a schematic view of an electrically-addressable nanopore array according to the present invention with a two-dimensional array of nanopores;
- Fig. 8A is a top view with a partial cutaway of a two-dimensional array comprised of a plurality or more of the single nanopore assembly of the present invention;.
- Fig. 8B is a side view of the array of Fig. 8 A through a single nanopore assembly
- Fig. 9 is an illustrative view illustrating holding of a molecule stationary across a nanopore using beads and optical tweezers;
- Fig. 10 is a block-diagram view of an illustrative optics and video system and the general arrangement thereof with respect to an electrically-addressable nanopore array device of the present invention
- Fig. 11 is a schematic view illustrating the technique for obtaining information relating to the secondary structure(s) of RNA.
- Figs. 12A,B are schematic views illustrating a sequencing technique using PNA functionalized nanopores according to the present invention.
- Figs 3-5 various views to illustrate the process for making a nanopore insulating member 10, that includes a nanopore 12, according to one aspect of the present invention. More particularly, Fig. 3 is a diagrammatic view illustrating the cutting edges mechanism for forming the nanopore 12 of an insulating member 10 of the present invention using curable polymers; Fig. 4 is a schematic view of an exemplary feedback mechanism for controlling the distance between the two cutting edges of the crystals; and Fig. 5 is a three-dimensional view of a portion of the insulating member 10 after the GaAs crystals are removed.
- a nanoprobe insulating member 10 that is particularly configured and arranged so as to include a nanopore 12 therein that extends across a thickness of the member.
- the insulating member is constructed of any of a number of insulating materials known to those skilled in that art and adaptable for use in the insulating member of the present invention.
- the insulating nanoprobe member 10 is - arranged so as to separate two reservoirs of ionic solutions, where the insulating member contains a hole, i.e., the nanopore 12 dimensioned so that that preferably only one strand of a single-stranded DNA molecule can pass there through.
- the electrical potential drop advantageously occurs entirely at the nanopore.
- the following describes one technique for making the insulating member 10 of the present invention. However, other methods or techniques are contemplated that are adaptable to maintain crystals in fixed relation so as to provide a mechanism for defining a through aperture that comprises a nanopore.
- Such a methodology advantageously yields an insulating member having a nanopore whose length or channel length can be controlled so as to be about 20 A (Angstrom/ 10 "10 m) or less, more particularly a channel length of about 10 A or less or more particularly a channel length of about 4 A and more specifically a channel length (d) that satisfies one of the following relationships; 2 A ⁇ d ⁇ l ⁇ A or 4 A ⁇ d ⁇ l ⁇ A.
- conventional techniques for forming nanopores for such use result in a structure in which the nanopore has a length in excess of the length of the DNA strand to be characterized which can lead to inaccuracies in the characterization.
- crystals are cleaved to form atomically sharp edges and two of these cleaved crystals are brought together within a few angstroms distance of each other.
- the crystals are.arranged so the crystal edges are cutting each other at an angle of about 90 degrees, as shown in the diagram in Fig. 3.
- the two crystals are held in fixed relation using standard STM (scanning tunneling microscope) electronics such as that shown in Fig. 4 and using the electron tunneling current as a feedback mechanism.
- STM scanning tunneling microscope
- the distance between the edges is so small that no molecules larger than a certain size can enter into this region. Stated another way, the crossing point is established such that molecules having a width greater than a desired width cannot enter into this region.
- the edges of the crystals are spaced from each other so as be in the range of from between lA and 10 A, more specifically about 2A. In further embodiments, the crystal edges are spaced from each other so the distance between the crystal edges is less than the thickness (Tm) of the molecule of the insulating material. In more specific embodiments, the spacing (Se) between the crystal edges is set so as to satisfy the relationship Se / Tm ⁇ 0.5.
- the crystals contemplated for use in the present invention include a wide range of crystals and in a particular, exemplary illustrative embodiment the crystals include GaAs crystals, a common semiconductor material, and NaCl crystals.
- the present invention can be practiced using other crystals known to those skilled in the art and having similar characteristics that lend themselves to being cleaved and being held in a fixed relation while the insulating material comprising the insulating member is being formed.
- the crystals when so arranged use the crossing cleaved crystal edges as a mold (e.g., nano-molding).
- an insulating material e.g., a flowable insulating material
- PDMS poly-dimethylsiloxane
- the molecules of the insulating material are advantageously oriented parallel to the respective cleaved edges and are forced to make a contour around the crossing point, leaving a small hole of a given width and length.
- the width and the length of the small hole are controlled by the distance between the two edges and the diameter of the insulating material (e.g., polymers).
- the crystals that were used to controllably form the nanopore or opening in the insulating member are removed using any of a number of techniques known to those skilled in the art that do not appreciably effect the insulating material about the formed hole, e.g., in the case of NaCl crystals, by washing with water. Following removal of the crystals, an opening is formed in the member such as that illustrated in Fig. 5, having a desired width and length. Because the chemical groups (nucleotides) of a DNA molecule have slightly different sizes, one can identify the nucleotides of a DNA molecule, and hence sequence the DNA molecule, by measuring the time dependence of the nanopore conductance.
- a nanopore is formed in the insulating material; having a desired width and length for purposes of characterizing the biomolecules, more particularly fast characterization of the biomolecule.
- Such an insulating member 10 is thus of great utility for a wide range of uses including forensics, rapid sequencing of DNA and research.
- the amount of the conductance drop will be a measure of the physical size of the part of the DNA molecule that is inside the narrowest part of the channel.
- FIG. 6 there is shown a perspective view of device 100 including an array of electrically-addressable nanopores 112, more particularly a linear array of nanopores according to another aspect of the present invention.
- the device 100 includes an insulating member 110 having a top surface 112 and a bottom surface 114.
- a plurality of grooves 116 are formed in the top surface using any of a number of techniques known to those skilled in the art that are appropriate for the material comprising the insulating member.
- the grooves 116 in the top surface 112 are formed in the insulating member 110 so as to generally extend downwardly towards the bottom surface 114 a predetermined distance from the top surface.
- the groove 118 in the bottom surface 114 is formed in the insulating member 110 so as to generally extend upwardly towards the top surface 112 a predetermined distance from the bottom surface.
- the insulating member is configured and arranged so an opening or nanopore 122 is provided in the insulating member 110 so as to fluidly couple each of the top surface grooves 116 with the bottom surface groove 118.
- the formation of the grooves 116, 118 and the nanopores 122 are discussed in more detail hereinafter.
- the insulating member 110 includes a first layer 120a and a second layer 120b that are bonded or otherwise secured to each other using any of a number of techniques known to those skilled in the art appropriate for the material being used to form the insulating member.
- the top surface grooves 116 are contained in the first layer 120 and the bottom surface groove is contained in the second layer.
- the nanopores 122 are formed in the insulating member or each of the first and second layers using any of a number of techniques appropriate for the material being used and appropriate for forming a nanopore having the desired width and length for e.g., rapidly characterizing a biomolecule.
- the first and second layers 120a,b are bonded or secured together and the nanopores 116 are formed at the intersections of the top and bottom surface grooves 116, 118.
- portions of the tips of the top and bottom surface grooves 116, 118 are formed so as to included an opening in each groove proximal the point of intersection such that when the first and second layers 120a,b are bonded or secured together the sharp edge openings in the grooves are aligned so as to form a nanopore.
- the grooves 116, 118 are formed in the top and bottom surfaces 112,114 so as to provide deep V-shaped grooves. This shall not be limiting as other shapes as are known to those skilled in the art that are otherwise adaptable and consistent with the function of the grooves in the present invention are contemplated for use in the present invention.
- the insulating member 110 and the first and second layers are initially formed from a silicon material, which is subsequently oxidized after further processing of the insulating member to form SiO 2 , an insulating material.
- the starting material is silicon, this shall not be considered limiting as other materials are contemplated for use with the present invention that would allow creation of the linear array of nanopores 122 as herein described using techniques that are appropriate for the material of use. More specifically, the silicon material is subjected to micromachining techniques as are known to those skilled in the art to form the grooves 116, 188 and the nanopores 122.
- the grooves and the nanopores are etched in the silicon wafer using an oxide or nitride mask, in KOH solutions with relatively high accuracy, or by use of beam lithography and wet etching techniques. It has been found that conventional or standard wet etching procedures as known in the art can produce highly uniform grooves as is illustrated in Fig. 6.
- the silicon wafers making up the first and second layers 120a,b are bonded or secured together and then material at the intersections of the top surface grooves 116 and the bottom surface groove 118 the tips of the grooves are further etched using a similar process to that used to form the grooves to form an opening there through.
- portions of the tips or valleys of the grooves in particular the portions proximal the intersections of the top and bottom surface grooves, are further etched so as to form an opening in these portions of the tips.
- the first and second layers are the bonded or secured to each other and the sharp edges of the openings form the nanopores at the intersections.
- the nanopores 122 are further examined using for example an electron microscope to determine if the nanopores that are formed have the desired width. If not, and assuming that the width of a given nanopore is less than a critical width, the nanopore is exposed to a high-energy electron beam to modify the dimensions of the nanopore. As more fully describe below, small holes shrink spontaneously due to surface tension when exposed to the electron beam and when the electron beam is switched off, the material quenches and retains its shape. The following further illustrates this modification process using for example, a commercial transmission electron microscope (TEM), operated at an accelerating voltage of 300 kV.
- TEM transmission electron microscope
- the power of this technique lies in the possibility to fine-tune the diameter of nanopores with unprecedented precision.
- the shrinking process can be stopped within seconds when the desired diameter has been reached.
- changes in pore diameter can be monitored in real time using the imaging mechanism of the microscope.
- Rough shrinking can be done at least an order of magnitude faster by increasing the electron intensity, and can gradually be slowed down for ultimate control.
- the precision is ultimately limited by the resolution of the microscope. In practice the resolution is limited to about 1 nm due to the surface roughness of the silicon oxide.
- the level of control offered by this technique is at least an order of magnitude better than conventional e-beam lithography, which has an ultimate resolution of about 10 nm.
- this use of this modification technique provides a mechanism to reduce the required dimensional control in the lithographic process for forming the grooves and nanopores, because any pore with a diameter below 50 nm can be shrunk to a nanometer-sized pore.
- the advantage of this technique of the present invention is that nanometer- scale sample modifications are possible with direct visual feedback at sub-nanometer resolution.
- the process is based on standard silicon processing and commercially available TEM microscopy. A modest resolution of ⁇ 50 nm is required in the lithography defining the pore, as fine tuning in the electron beam is done as a final step. Using the SOI based process, this requirement is straightforward to obtain with e-beam lithography, and should be attainable even with optical lithography alone.
- Fig. 8 there is shown a schematic view of an electrically- addressable nanopore array 200 according to the present invention configured with a two-dimensional array of nanopores 116. In the illustrated embodiment shown in Fig.
- the two dimensional array is made up of two or more sets of linear arrays that are formed on a single insulating member 110.
- the grooves 116a,b in the top surface are formed so there is one set of grooves 116a for one of the linear arrays and so there is another set of grooves 116b for each of the other linear arrays.
- the grooves 116a,b in the top surface 112 or the first layer 120a are formed so the grooves for each linear array are separate from or not connected to the grooves of another linear array. For example, when the grooves are being etched in the top surface of a silicon wafer, material is not advantageously removed from the top surface between the ends of the grooves.
- the grooves 116 in the top surface of a two-dimensional array according to the present invention shall not be considered as limiting as it is within the scope of the present invention for the grooves 116 in the top surface of a two-dimensional array according to the present invention to be configurable so that the grooves in the top surface are interconnected, thereby forming a single set of top surface grooves.
- the two- dimensional array can be configured so that the grooves in the top surface are interconnected to form a single set of grooves.
- FIG. 7 there is shown a perspective view of an electrically- addressable nanopore array device 300 according to the present invention including an electrically-addressable nanopore array 100 further including a linear array of nanopores 122.
- an electrically-addressable nanopore array 100 further including a linear array of nanopores 122.
- the linear array 100 can include a plurality or more, for example 100 top surface grooves thereby forming 100 nanopores.
- the device to include a two-dimensional array 200 including the array shown in Fig. 8.
- Figs. 6 and 8 illustrate further details of the electrically-addressable arrays 100, 200 contemplated for use with an electrically-addressable nanopore array device 300 of the present invention.
- the electrodes and fluid ports are shown for illustration purposes. In an actual device the electrodes and the fluid ports are sealed.
- An electrically-addressable nanopore array device 300 includes cover slips 302 as are known to those skilled in the art, that seal the top and bottom surfaces of the array. Following fabrication of the electrically- addressable nanopore array 100, the cover slips 302 are secured or bonded to the top and bottom surfaces thereof using any of a number of techniques known to those skilled in the art appropriate for the materials being used. This is preferably done after the electrically-addressable nanopore array 100, 200 is determined to be in operable condition (e.g., nanopores of the desired width and length appropriate for the particular analytical technique).
- the electrically-addressable nanopore array device 300 is appropriately arranged with pumping lines and electrodes (e.g., Ag/AgCl wires) as is known to those skilled in the art.
- pumping lines and electrodes e.g., Ag/AgCl wires
- apparatuses and systems are interconnected to the electrically-addressable nanopore array device 300 for purposes of supplying samples for analysis, for collection of data and for the analysis of the collected data.
- Figs. 8A,B there is shown various views of a two- dimensional nanopore array 500 according to another aspect of the present invention.
- Fig. 8A comprises a plurality or more of single nanopore assemblies 510 of the present invention each including a nanopore 512 preferably formed using one of the techniques described herein.
- Fig. 8A a top view, with a partial cutaway, of a two-dimensional array 500 of this aspect of the present invention and there is shown in Fig. 8B a side view of the array of Fig. 8 A through a single nanopore assembly.
- Figs. 3-5 as to the techniques for making a nanopore assembly 512 according to the present invention having the desired characteristics.
- Fig. 7 as to further details, features and characteristics of electrically addressable nanopore arrays not described below.
- the two-dimensional nanopore array 500 includes a top member 520 and a bottom member 530.
- the nanopore assemblies 510 are configured and arranged in the two- dimensional array 500 such that the first volume 514 for each nanopore assembly is separate and electrically isolatable from each other.
- the top member 520 is affixed or secured to a top surface(s) of each of the nanopore assemblies 510 in such a fashion so as to also maintain the first volume 514 of each nanopore assembly separate and electrically isolatable from each other.
- the top member 520 further includes a plurality or more of through apertures 522 that are arranged in the top member so that there is one aperture in fluid communication with the first volume 514 of each nanopore assembly 510.
- the bottom member 530 is secured to a lower surface(s) of each nanopore assembly 510 so a passage 516 in each nanopore assembly and the bottom member defines one or more volumes for receiving the material that has passed through a nanopore 512 such that the passed through material can be appropriately handled or processed further.
- the top and bottom members 520, 530 are made from any of a number of materials known to those skilled in the art that are appropriate for the intended use and being securable to the surface(s) of the nanopore assemblies (e.g., such as the cover slips 320 herein described).
- the through apertures 522 in the top member 520 are formed therein using any of a number of techniques known to those skilled in the art.
- the size and depth of such through apertures 522 are such as to allow material to easily pass there through into the first volume 514, and minimizing the potential for damage to the material as it passes through the through aperture. It should be recognized that the size or diameter of the through apertures 522 need not be set so as to meet the same desired characteristics for a nanopore 512.
- Such an arrangement and configuration yields a two-dimensional nanopore array 500 in which each nanopore 512 is separately, electrically addressable from any other of the nanopores making up the array.
- material to be analyzed, processed and/ or evaluated can be introduced into each of the nanopores 512 so the material (e.g., DNA) passing though any one nanopore can be uniquely or separately identified, characterized, analyzed, processed or evaluated.
- a two-dimensional array 500 exhibits a high through put yet maintains the capability for providing details, characteristics or features of the material passing through each of the nanopores 512.
- the nanopore assemblies 510 also are immobilized using any of a number of techniques known to those skilled in the art, including but not limited to mechanical and adhesive securing techniques, so the assemblage of the nanopore assemblies in effect forms a unitary structure.
- the nanopore assemblies can be secured to each other using an adhesive material.
- the top member 520 the bottom member 530 and the nanopore assemblies 510 are secured to each other so as to form a unitary structure.
- the two-dimensional array 500 is made up of a 4 x 4 matrix of nanopores 512 or nanopore assemblies 510.
- a two- dimensional array 500 according to the present invention can be made up of 1000 or more nanopores 512 or a 1000 or less nanopore 512 (e.g., an array comprising a matrix of 100 x 100 nanopores).
- a square array is illustrated (e.g.
- the nanopore assemblies to be arranged so the number of nanopores along one axis differs from the number of nanopores along the other axis (e.g., 100 x 75 array of nanopores). It also is contemplated that the nanopore assemblies are arrangeable so the number of nanopores 512 varies along one axis (e.g., varies between 100 and 70 nanopores) and so the number of nanopores along the other axis generally differs from those along the one axis (e.g., 75 nanopores).
- a two-dimensional array 500 comprising a plurality or more, more particularly a large number of nanopore assemblies 512
- a process for rapid DNA sequencing using the ionic current have not been realized as yet, nor has this process been useable to distinguish between adenine and guanine and between cytosine and thiamine.
- the electrically-addressable nanopore array device 300 of the present invention is further configured and arranged so as to reduce signal noise believed to be attributable to thermal motion of DNA as it passes through the nanopore.
- the electrically-addressable nanopore array device 300 is configured and arranged with an objective lens 320 on either side of the array device, so as to form two optical traps or two optical tweezers to hold the DNA molecule stationary across a nanopore 122.
- an objective lens 320 on either side of the array device, so as to form two optical traps or two optical tweezers to hold the DNA molecule stationary across a nanopore 122.
- noise in the ionic current signal being caused by the wiggling motion of the DNA molecule near and/or in the nanopore should be greatly reduced.
- signal-averaging techniques can be used to further reduce noise in the ionic current. Holding the molecule stationary can be best understood from the following illustrative example, although it well within the skill of those in the art to apply and adapt other techniques that are more appropriate for the items undergoing analysis/ characterization.
- a single-stranded DNA is attached to a double stranded DNA and then the latter is attached to a bead 400 using a streptaviding-biotin linker, which bead is to be held by optical tweezers.
- the single-stranded DNA is driven through the nanopore 122 and caught from the other side using another bead 400 also with a streptaviding-biotin linker, which also is held by optical tweezers.
- the holding of the molecule stationary across the nanopore 122 using beads 400 is shown illustratively in FIG. 9.
- the beads 400 or microspheres are polystyrene micropsheres or beads.
- Fig. 10 an illustrative optics and video system 500 and the general arrangement of the components thereof with respect to the electrically- addressable nanopore array device 300 (EANA in figure) of the present invention.
- Such an optical and video system 500 is equipped with optical tweezers and a digital video microscopy system that is based on a Zeiss Axiovert 135 inverted microscope.
- the illustrated Argon ion laser can be replaced by a semiconductor-based infra-red laser, to minimize light damage to the biomolecules on the microspheres.
- the system includes two objectives, and the condenser in the standard optical microscope is replaced by a lOOx oil-immersion objective. Also, illumination of the sample can be accomplished using a de-focused diode light source through the objectives.
- optical trapping As is generally known to in the art, a subfield within laser physics is optical trapping and an optical tweezer is an example of an optical trap.
- a strongly focused laser beam has the ability to catch and hold particles (e.g., particles of dielectric materials) in a predetermined size range. This technique makes it possible to study and manipulate particles like atoms and molecules (even large) and small dielectric spheres.
- optical tweezers can be found in A.Ashkin "Optical trapping and manipulation of neutral particles using lasers", Proc. Natl. Acad. Sci. USA, vol. 94, pp.4853-4860, May 1997.
- RNA Ribonucleic acid
- RNA molecules in cells can partially fold onto itself, forming secondary structures, due to local pairing of complementary bases. It is believed that these secondary structures of RNA are more important for the properties of the molecules than their primary sequences.
- messenger RNA miRNA
- tRNA transfer RNA
- buffers containing RNA attached microspheres or beads 400 are flushed through the lower surface groove 118, while the nanopores 122 are biased by an electric field. Occasionally an RNA molecule is pulled through a nanopore 122 by the electric field. One can identify this event by looking for a localized microsphere or bead 400 near a pore. Then, the electrical field is turned off to allow the RNA to form secondary structures. Now, and also with reference to Fig 11, the microsphere or bead 400 is slowly pulled away using optical tweezers and the force on the bead is measured as the RNA molecule is pulled (upward) through the nanopore 122.
- RNA base pairs at the entrance of the nanopore 122 will appear as force fluctuations as a function of time, hence revealing the information about the secondary structure of the test molecule. It should be noted that this situation is quite different from the previous RNA pulling experiments in which the RNA was pulled from the two ends, where without the prior knowledge of the secondary structure of an RNA, it would be difficult to assign the features in a force vs. time trace.
- the present invention does not require prior knowledge of the secondary structure of an RNA molecule.
- FIGs. 12A,B there is shown schematically another technique for characterizing (e.g., sequencing) DNA or RNA using nanopores or nanopore arrays of the present invention. More particularly these schematic views illustrate a sequencing technique using PNA functionalized nanopores 600 according to the present invention.
- PNA functionalized nanopores 600 according to the present invention.
- the technique and device of the present invention by referring to a single nanopore. It is within the scope of the present invention, however, for the below described technique and device to be adapted for use with a plurality or more of nanopores that are arranged so as to form a linear array or a two-dimensional array.
- peptide nucleic acid is applied so as to coat at least a portion of the nanopore, for example at least the interior surface of the nanopore 602 so as to form a PNA coating 604.
- the PNA coating 604 and the nanopore 602 so coated is herein referred to as PNA functionalized nanopore 600.
- the PNA coating 604 on the nanopore is exposed to any DNA/ RNA passing through the opening 606 in the PNA functionalized nanopore 600.
- the PNA is synthesized so that it is essentially constituted by one of the bases of DNA or RNA (e.g., adenosine, thymidine, guanine, cytosine, uracil).
- the PNA is synthesized so that the one basis characterizing or constituting the PNA is set so as to have a noticeable effect on the passage of the DNA/ RNA through the PNA functionalized nanopore 600, and more particularly different effects depending upon the different bases that can make up the DNA/ RNA.
- the PNA coating 604 is such as to be constituted or characterized as having essentially only adenosine bases (hereinafter referred to as A-PNA).
- the A-PNA will have differing effects (e.g., hydrogen bonding) on the passage of a strand of DNA/RNA through the functionalized nanopore 600 depending upon the particular bases constituting the DNA and the sequence of the bases in the DNA/RNA as well as the distance (e.g., bonding distance) between the PNA coating 604 and the DNA/RNA strand.
- the distance e.g., bonding distance
- the force retarding movement or other related parameter e.g., time to move a given distance
- the detected/ determined parameter is evaluated to determine if the parameter corresponds to that which would be exhibited if the A-PNA is bonding to a T, A, G or C bases of the DNA.
- an end of the DNA/ RNA strand is driven through the PNA functionalized nanopore 600 and caught from the other side using a bead 400 with a streptaviding- biotin linker.
- Optical tweezers as is known in the art are used to hold the bead 400.
- the beads 400 or microspheres are polystyrene micropsheres or beads.
- the microsphere or bead 400 is slowly pulled away from the PNA functionalized nanopore 600 using optical tweezers and the force on the bead is measured as the DNA/RNA molecule is pulled through the functionalized nanopore.
- the bases making up the DNA/ RNA molecule will cause differing forces to be applied to the molecule affecting the movement of the molecule through the fictionalized nanopore 600. These different effects will appear as force fluctuations as a function of time, hence revealing the information at least about the sequence of the A, T, G, C bases making up the test molecule.
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JP2006508720A JP2006526777A (en) | 2003-02-28 | 2004-02-13 | Nanopores, methods for using them, methods for making them, and methods for characterizing biomolecules using them |
AU2004223493A AU2004223493A1 (en) | 2003-02-28 | 2004-02-13 | Nanopores, methods for using same, methods for making same and methods for characterizing biomolecules using same |
US10/546,939 US20070042366A1 (en) | 2003-02-28 | 2004-02-13 | Nanopores, methods for using same, methods for making same and methods for characterizing biomolecules using same |
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US20050127035A1 (en) | 2005-06-16 |
JP2006526777A (en) | 2006-11-24 |
WO2004085609A3 (en) | 2006-06-29 |
AU2004223493A1 (en) | 2004-10-07 |
US20070042366A1 (en) | 2007-02-22 |
CA2517216A1 (en) | 2004-10-07 |
EP1601760A2 (en) | 2005-12-07 |
US7678562B2 (en) | 2010-03-16 |
EP1601760A4 (en) | 2009-08-19 |
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