The presently disclosed subject matter is directed towards electronic devices and systems suitable for use in DNA sequencers and for detecting and quantifying individual nucleotides in a polynucleotide. More particularly, the present invention relates to compensated patch-clamp amplifiers and their use in DNA sequencing systems and methods and in similar applications.
DNA was first isolated from cells by the Swiss scientist Friedrich Miescher in 1869. In 1944 Deoxyribonucleic Acid was discovered to be a chemical that comprised a tiny genetic encyclopedia in living cells. In 1953 James Watson, an American scientist, and Francis Crick, a British researcher working at the University of Cambridge in England discovered the now-famous “double helix” molecular structure of DNA for which they received a 1962 Nobel Prize.
In nanopore sequencing a DNA strand to be sequenced is passed through an ionic fluid filled sensor having a very small pore while a voltage is induced across the sensor. The resulting sensor current depends on the structure of the DNA strand. By analyzing the sensor current the DNA strand can be sequenced. While the theoretical framework of nanopore sequencing is well understood, prior art nanopore sequencing systems and devices were not fully developed. Nanopore sequencing currents are very small and any realistic nanopore sequencing system requires very high gains. Very high gains tend to create reading instabilities caused by distributed resistances and capacitances as well as internal and external noise.
Despite those problems the promise of nanopore sequencing has motivated the development of electronic devices and systems that can detect and quantify individual nucleotides in a polynucleotide. In practice a nanopore sensor has two chambers, referred to as a cis and a trans chamber. Those chambers are filled with a buffered ionic conducting solution (for example, KCl) and a voltage is applied across the nanopore chambers. As a result, a charged DNA initially placed in the cis chamber starts moving towards the trans side. As it traverses the nanopore, the ionic current momentarily decreases. The ionic current is typically in the range of tens to hundreds of picoAmperes. The resulting electric current depends on the number of ions (the charge/net charge) in the nanopore as well as on the nanopore dimensions. The number and charge of ions can be the result of the DNA nucleotide strand passing through the nanopore (or approaching the nanopore opening). It is by monitoring the resulting current that the DNA nucleotide can be sequenced.
Accurately measuring the ultra-low current variations requires a very specialized amplifier that is referred to herein as a patch-clamp. Practical patch-clamps include an input headstage current-to-voltage converter and a difference amplifier that amplifies the voltage from the headstage. A patch-clamp must meet two very challenging design requirements. First, the input-offset voltage (VOS) of the headstage must be minimized. Even the best high-gain amplifiers available have some VOS. Causes for the VOS include random process mismatches and unavoidable systematic variations. Whatever the VOS is, it is amplified by the difference amplifier. In effect the VOS limits the output dynamic range.
Secondly, patch-clamp input parasitic capacitances have to be reduced to prevent headstage saturation. When a command voltage VCMD is applied to the nanopore sensor to produce operating currents, that voltage is actually applied through a resistance to an inverting input of an op-amp. Thus a command voltage VCMD change is time delayed due to unavoidable stray system capacitances. This causes a transient difference between the inverting input and the non-inverting input which leads to output saturation until the parasitic capacitances are charged and the inverting input once again is equal to VCMD. During this interval, known as the ‘dead-time’ all incoming data is lost. Minimizing VOS and compensating for input parasitic capacitances and resistance are major design problems in nanopore sequencing.
Modern patch-clamps are rather specialized high gain, differential op-amp transimpedance amplifiers that use either resistive or capacitive feedback.
In
In theory the basic patch-clamps 6 and 8 are sound. In practice, things go wrong. Transimpedance patch-clamp amplifiers that use resistive feedback, reference
In the prior art, complicated compensation circuitry has been used to attempt to avoid, shorten, or at least minimize dead-time. Such prior art compensation circuitry not only increased the complexity of the basic patch-clamp but resulted in an increased input capacitance which not only limited the bandwidth of resistive feedback patch-clamp circuits, such as the resistive feedback patch-clamp circuit 6, but usually resulted in output voltage “ringing” in response to a step input.
The capacitive feedback patch-clamp circuit 8 shown in
Unfortunately, when the reset switch 16 opens, the input capacitance at the inverting input 18 increases by Cf×(1+A0), wherein Ao is the gain of the amplifier 10, reference the well-known Miller's theorem. That rather dramatic input capacitance change subsequently restricts the bandwidth of the capacitive feedback patch-clamp circuit 8. Thus using capacitive feedback transimpedance amplifiers makes it very difficult to apply arbitrary command voltage VCMD changes because the reset frequency (fRST) is determined by Iin/(Cf×ΔV), where ΔV is the voltage difference between the inverting input 18 and the output voltage VO. That frequency is not necessarily synchronized with command voltage VCMD changes.
One solution to the reset frequency-command voltage VCMD change problem is to simply increase the reset frequency (fRST) by decreasing the capacitance Cf of the capacitance 14 so that the reset frequency is compatible with the command voltage VCMD changes. This requires multiple capacitors and their proper selection as feedback capacitor 14 capacitances whenever waveforms having different transition periods are applied as the command voltage VCMD changes. The result is a much larger and more complex patch-clamp amplifier.
Prior art compensation of patch-clamp amplifiers used additional amplifiers to estimate series resistance (RS) and parasitic capacitance (CP), a rather complex circuit resulted.
Therefore, a new patch-clamp amplifier circuit that avoids the foregoing and other limitations in the prior art would be desirable. Even more desirable would be new patch-clamp amplifier systems that incorporate compensation tailored to the particular application. Ever more beneficial would be new patch-clamp systems having compensation that can be digitally controlled.
The principles of the present invention provide for techniques for patch-clamp amplifier circuits that incorporate compensation and that can be tailored to a particular application. The new patch-clamp circuit uses digitally controlled compensation and can be used in a nanopore sequencer for sequencing polynucleotides.
Those principles are incorporated in a patch-clamp circuit having a clock that produces timing signals. The patch-clamp circuit further includes a differential amplifier circuit having a non-inverting input, an inverting input with a parasitic capacitance and an electrode resistance, and an output. A feedback resistor is connected between the output and the inverting input. A reset switch receives the timing signals and in response selectively connects the output to the inverting. A command voltage circuit receives command voltages and timing signals. The command voltage circuit produces stepped command voltages that are applied to the non-inverting input in response to the timing signals. A sensor having an input capacitance and a series resistance is operatively connected to the inverting input. The reset switch closes for a time TR in synchronization with step changes in the stepped command voltages and then opens. The time TR is sufficient to prevent saturation of the differential amplifier circuit during the step changes but without blanking out the stepped voltage. The stepped command voltages are selected to compensate for the series resistance and the electrode resistance so as to produce predetermined voltages across the sensor.
In practice the patch-clamp system uses a nanopore sensor while the differential amplifier circuit can have a current to voltage converter and a difference amplifier. The command voltage circuit may be a sample and hold circuit, a Digital-to-Analog converter or some other type of circuit that produces well defined steps. In practice the output can be applied to an Analog-to-Digital converter that produces an amplified digital version of the current in the sensor. The digital version can be applied to a field programmable array or otherwise input into a computer. Preferably that computer causes the command voltages to be applied to the command voltage circuit.
The principles of the present invention also enable methods of compensating sensors used in patch-clamp systems. Such a method involves connecting a first end of an electrode to the inverting input of a patch-clamp system, connecting the second end of the electrode to ground, and connecting a feedback resistor RF between the inverting input and the output of the patch-clamp system. This enables obtaining a steady state output from the patch-clamp system. A step voltage is then applied to the non-inverting input of the patch-clamp system. The output voltage variation of the patch-clamp system converter in response to the step voltage is then obtained and from that output voltage variation; the series resistance RE of the electrode can be determined. After the series resistance is determined a sensor is connected between the second end of the electrode and ground. The steady state output of the patch-clamp system is then found and the sensor current is measured. The sensor series resistance RS can then be determining from the measured sensor current i, the series resistance RE, and the steady state output. Once the series resistance RE is known, a predetermined voltage can be applied across the sensor by applying a compensated voltage to the non-inverting input, where the compensated voltage is equal to the predetermined voltage plus the sensor current i times the series resistance RS.
In addition to compensating for resistances, the present invention can also be used to determine parasitic capacitances. To do so, after the sensor series resistance RS has been determined the patch-clamp system is set up to produce a steady state response. A compensation step voltage is then applied to the non-inverting input of the patch-clamp system. The time constant of the output is then found. The input parasitic capacitance is then determined using the previously obtained sensor series resistance RS and the time constant.
The principles of the present invention further enable new, useful, and non-obvious nanopore sequencers. Such a nanopore sequencer includes a nanopore sensor having an input resistance RN and an input capacitance CN. The nanopore sequencer further includes a patch-clamp circuit having a non-inverting input, an inverting input having a parasitic capacitance CP, and an output. An electrode having an electrode series resistance RE connects the nanopore sensor to the inverting input. A feedback resistor having a value RF is connected between the output and the inverting input. The reset switch receives timing signals that cause the reset switch to selectively connect the output to the inverting input. A digital-to-analog circuit receives timed digital command voltages and applies stepped command voltages to the non-inverting input in response to the timed digital command voltages. The reset switch closes for a time TR in synchronization with step changes in the stepped command voltages and then opens. TR is selected to be sufficient to prevent saturation of the patch-clamp circuit without blanking out the stepped voltage. The stepped command voltages are selected to compensate for the nanopore resistance RN and the electrode series resistance RE so as to produce a predetermined voltage across the nanopore sensor.
The nanopore sensor may comprise a semi-conductive material or it may be a cell membrane. The patch-clamp circuit may include a current-to-voltage converter and a difference amplifier. The output is beneficially applied to an analog-to-digital converter that produces an amplified digital version of the current in the nanopore sensor. That amplified digital version can be input to a field programmable array and/or as an input to a computer. Preferably the computer operatively produces the timing signals and the timed digital command voltages.
The advantages and features of the present invention will become better understood with reference to the following detailed description and claims when taken in conjunction with the accompanying drawings, in which like elements are identified with like symbols, and in which:
a) is a schematic depiction of a prior art resistive feedback patch-clamp circuit;
b) is a depiction of a prior art capacitive feedback patch-clamp circuit;
a) is a schematic depiction of the operation of the compensated patch-clamp circuit shown in
b) is a schematic depiction of the operation of the compensated patch-clamp circuit shown in
The presently disclosed subject matter now will be described more fully hereinafter with reference to the accompanying drawings in which one embodiment is shown. However, it should be understood that this invention may take many different forms and thus should not be construed as being limited to the embodiment set forth herein.
All publications mentioned herein are incorporated by reference for all purposes to the extent allowable by law. In addition, in the figures like numbers refer to like elements throughout. Additionally, the terms “a” and “an” as used herein do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items.
In what follows a generic nanopore sensor 302 (reference
Devices suitable for use with the present invention are described in, for example, U.S. Pat. No. (U.S. Pat. No.) 5,795,782, U.S. Pat. No. 6,015,714, U.S. Pat. No. 6,267,872, U.S. Pat. No. 6,627,067, U.S. Pat. No. 6,746,594, U.S. Pat. No. 6,428,959, U.S. Pat. No. 6,617,113, and International Publication Number WO 2006/028508, each of which is hereby incorporated by reference in their entirety. Essentially while any individual device described herein may not be novel, the combination of the individual devices results in a new, useful, and non-obvious nanopore patch-clamp systems, DNA sequencers, and electrochemical applications for measuring biochemical analytic concentrations such as glucose, oxygen, neurotransmitters and pathogens that can be measured using transimpedance amplifiers or current-to-voltage converters.
Nanopore sensitivity, particularly in the case of solid-state nanopores, is determined by the pore size and the thickness. To identify a single nucleotide (≈0.35 nm) of single-stranded DNA in a nanopore sensor, the nanopore sensor will have a diameter of somewhere around 0.35 nm or less. That causes a nanopore capacitance of about:
where εr, ε0, A and d indicate a relative permittivity, the electric constant (8.854×10−12 F m−1), an exposed area, and thickness, respectively. Where atomic layers, i.e. Al2O3 and graphene, are used for the nanopore sensor the nanopore capacitance is larger, which results in longer dead-times (see below) when the command voltage changes. Such atomic layer sensors particularly benefit by the principles of the present invention.
During operation the reset switch 16 is closed in synchronization with step transitions of the output of the sample and hold circuit 102. In practice those transitions and the reset switch 16 synchronization are controlled by timing pulses from a clock 31. For purposes of clarity of explanation those timing pulses and the clock 31 are left out of subsequent figures. However is should be understood that the reset switch 16 operates in synchronization with command voltage VCMD changes, be they from a sample and hold circuit, a digital-to-analog converter, or some other circuit, and that some type of synchronized timing is required.
The basic compensated patch-clamp circuit 100 has two modes of operation: a transient mode when the command voltage WCMD changes, depicted in
Because a feedback capacitor 14 is not used in the basic compensated patch-clamp circuit 100 periodic reset pulses are not required to remove built up charges. Furthermore, complex compensation circuitry is also not required because resistive-feedback is used. The basic compensated patch-clamp circuit 100 architecture enables the use of complex command voltage VCMD waveforms and the use of various dwell times in addition to reduced hardware complexity.
The basic compensated patch-clamp circuit 100 and its sample and hold circuit 102 represents a major change in nanopore patch-clamp circuits. One improvement to the basic compensated patch-clamp circuit 100 is shown in the improved compensated patch-clamp circuit 200 of
As noted patch-clamps have been used in prior art DNA sequencers.
While the basic patch-clamp circuits 100 and 200 are by themselves new, beneficial and useful, the preferred embodiment of the present invention is the computerized compensated DNA sequencer 300 system shown in
The nanopore sensor 302 is connected to the inverting input 18 of a patch-clamp circuit comprised of an input (I-V) converter 314 headstage and a difference amplifier 316, which is analogous to that shown in
The personal computer 326 performs data analysis on the nanopore sensor 302 reading. In addition, the personal computer PC 326 applies control signals to the field programmable gate array 324 which are subsequently used to control the operation of a digital-to-analog converter 330. The digital-to-analog converter 330 provides command voltages (VCMD) to the non-inverting inputs 17 of the input (I-V) converter 314 headstage and the difference amplifier 316. Thus the operation of the DNA sequencer 300 is computer controlled, its outputs are available for data analysis, and patch-clamp compensation is provided as described below.
The DNA sequencer 300 is well suited for automated compensation. A compensation operation 450 is shown in the flow diagram of
After some time a VCMD voltage step is applied, step 454 which, after some time delay, sets the voltage VP across the series resistance (RS) 308 and the parasitic capacitance (CP) 310 to VCMD see step 456. Next, the output voltage variation is measured, step 458. Note that the output voltage is digitized and applied to the PC 326. From the output voltage variation and from the known RF 12 the value of the electrode series resistance RS can be accurately measured (determined), step 460. The formula relating the output voltage variation and RS is shown in step 458.
Next, a nanopore sensor 302 is applied to the patch-clamp amplifier 360 and the resulting nanopore current (i) is measured, step 462, reference
In addition to resistor compensation it is possible to compensate for capacitances.
While the foregoing has described a novel resistive feedback patch-clamp system, its use in DNA sequencing, and automated compensation based on a resistive patch-clamp circuit, the principles of the present invention are also useful to capacitive patch-clamp circuits.
Additional embodiments and disclosures are as follows.
The invention herein disclosed provides for devices and methods that can detect and quantify individual nucleotides in a polynucleotide. The device can be a solid-state nanopore or a nanopore positioned at a defined site, for example, upon a substrate and/or surface.
The devices herein disclosed may be used in many applications, including, but not limited to, a nanopore system. The system can avoid ‘dead-time’ by placing a switch to a conventional transimpedance amplifier with a resistive feedback. Various discrete waveforms may be generated and applied to the voltage command by using a sample/hold circuit or DAC for the command voltage control. The voltage patch-clamp amplifier can be fully controlled by a computer interface system.
The invention also discloses for a method of compensating for the feedback resistors as disclosed above. The invention further discloses a method for compensating for the probe input capacitance.
The invention can be used to detect the position and measure the quantity of a molecule relative to the defined site. In one example, the defined site is a nanopore. The molecule can be positioned by varying the potential difference on either side of the nanopore. The molecule can be a macromolecule and can further comprise a polyion, such as a polyanion and/or a polycation. In one a preferred embodiment, the polyion is a polynucleotide. In another preferred embodiment the polyion is a polypeptide. The substrate and/or surface can delimit two chambers and can further comprise a pore, the pore located at the substrate or surface. One of the chambers is cis to the pore and the other chamber is trans to the pore. The molecule can be positioned by varying the potential difference between the chambers. Preferably, the molecule is initially present in the cis chamber. The presence and/or absence and/or change in the molecular composition can be detected by measuring the electric current through the pore. The invention can be used as a sensor that detects molecules. The invention is of particular use in the fields of molecular biology, structural biology, cell biology, molecular switches, molecular circuits, and molecular computational devices, and the manufacture thereof.
The invention provides devices and methods for using the same. The devices may be used in a nanopore device system or another suitable system. In one exemplary embodiment, the device is a voltage patch-clamp circuit, comprising: a clock producing clock signals having clock transitions; a differential amplifier having a non-inverting input, an inverting input, and an output; a feedback resistor connected between said output and said inverting input; a reset switch receiving said clock signals, said reset switch for selectively connecting said output to said inverting input in response to clock signals; and a sample and hold circuit receiving clock signals and command voltages, said sample and hold circuit for digitizing command voltages in response to clock signals and for applying digitized command voltages to said non-inverting input; wherein said reset switch is closed during a clock transition to reduce the gain of said differential amplifier; and wherein said reset switch is opened after said clock transition to increase the gain of said differential amplifier.
In another exemplary embodiment, the system can be used for a method of amplifying small current variations in a sensor, comprising the steps of: digitizing command voltages in accord with clock signals; applying voltages derived from digitized command voltages to a sensor to induce variations in the sensor current; amplifying the variations in sensor current to produce an output; reducing the amplification applied to the variations in sensor current when clock signals change so as to limit saturation; and increasing the amplification applied to the variations in sensor current when clock signals are not changing.
In yet another exemplary embodiment the system can be used for a method of compensating the series resistance of a nanopore sensor, comprising the steps of: activating a current-to-voltage converter to achieve a steady state response; applying a step voltage to a non-inverting input of the current-to-voltage converter such that the resulting voltage applied to inverting input of the current-to-voltage converter is substantially equal to the step voltage; determining the output voltage variation of the current-to-voltage converter to the step voltage; measuring the series resistance of a nanopore sensor; connecting the nanopore sensor to the non-inverting input of the current-to-voltage converter; measuring the nanopore sensor current; and compensating the nanopore sensor by applying a voltage to the inverting input of the current-to-voltage converter equal to the step voltage plus the nanopore sensor current times the series resistance.
In a further embodiment, the system can be used for a method of compensating the series resistance of a cell membrane sensor, comprising the steps of: activating a current-to-voltage converter to achieve a steady state response; applying a step voltage to a non-inverting input of the current-to-voltage converter such that the resulting voltage applied to inverting input of the current-to-voltage converter is substantially equal to the step voltage; determining the output voltage variation of the current-to-voltage converter to the step voltage; measuring the series resistance of a cell membrane sensor; connecting the cell membrane sensor to the non-inverting input of the current-to-voltage converter; measuring the cell membrane sensor current; and compensating the cell membrane sensor by applying a voltage to the inverting input of the current-to-voltage converter equal to the step voltage plus the cell membrane sensor current times the series resistance.
Additionally, The system can also be used for a method of compensating for the input parasitic capacitance of a nanopore sensor, comprising the steps of: connecting a nanopore sensor to the non-inverting input of a current-to-voltage converter; obtaining the series resistance of the nanopore sensor; activating the current-to-voltage converter to achieve a steady state response; applying a step voltage to a non-inverting input of the current-to-voltage converter; determining the time constant of the current-to-voltage converter to the step voltage; and determining the input parasitic capacitance of the nanopore sensor from the series resistance of a nanopore sensor and the determined time constant.
In an alternative embodiment, the system can be used for a method of compensating for the input parasitic capacitance of a cell membrane sensor, comprising the steps of: connecting a cell membrane sensor to the non-inverting input of a current-to-voltage converter; obtaining the series resistance of the cell membrane sensor; activating the current-to-voltage converter to achieve a steady state response; applying a step voltage to a non-inverting input of the current-to-voltage converter; determining the time constant of the current-to-voltage converter to the step voltage; and determining the input parasitic capacitance of the cell membrane sensor from the series resistance of a cell membrane sensor and the determined time constant.
The nanopore device systems may comprise ‘cis’ and ‘trans’ chambers connected by an electrical communication means. In one embodiment the chambers comprise a medium, the medium selected from the group consisting of an aqueous medium, a non-aqueous medium, an organic medium, or the like. In one embodiment the medium is a fluid. In an alternative embodiment the medium is a gas. In one embodiment the electrical communication means is a solid state pore comprising, for example, silicon nitride, bifunctional alkyl sulfide, and/or gold or other metal or alloy. In the alternative, the cis and trans chambers are separated by a thin film comprising at least one pore or channel. In one preferred embodiment, the thin film comprises a a compound having a hydrophobic domain and a hydrophilic domain. In a more preferred embodiment, the thin film comprises a a phospholipid. The devices further comprise a means for applying an electric field between the cis and the trans chambers. In one embodiment the pore or channel accommodates a part of the polyion. In another embodiment the pore or channel accommodates a part of the molecule. In one preferred embodiment, the molecule is a macromolecule. In another preferred embodiment the polyion is selected from the group consisting of polynucleotides, polypeptides, phospholipids, polysaccharides, and polyketides.
In one embodiment the compound comprises a an enzyme. The enzyme activity can be, for example, but not limited to, enzyme activity of proteases, kinases, phosphatases, hydrolases, oxidoreductases, isomerases, transferases, methylases, acetylases, ligases, lyases, ribozyme, and the like. In a more preferred embodiment the enzyme activity can be enzyme activity of DNA polymerase, RNA polymerase, endonuclease, exonuclease, DNA ligase, DNase, uracil-DNA glycosidase, kinase, phosphatase, methylase, acetylase, glucose oxidase, ribozyme, and the like.
In still a further interesting embodiment, the pore is sized and shaped to allow passage of an activator, wherein the activator is selected from the group consisting of ATP, NAD+, NADP+, diacylglycerol, phosphatidylserine, eicosinoids, retinoic acid, calciferol, ascorbic acid, neuropeptides, enkephalins, endorphins, 4-aminobutyrate (GABA), 5-hydroxytryptamine (5-HT), catecholamines, acetyl CoA, S-adenosylmethionine, hexose sugars, pentose sugars, phospholipids, lipids, glycosyl phosphatidyl inositols (GPIs), and any other biological activator.
In certain embodiments the pore is sized and shaped to allow passage of a monomer, wherein the monomer is selected from the group consisting of dATP, dGTP, dCTP, dTTP, UTP, alanine, cysteine, aspartic acid, glutamic acid, phenylalanine, glycine, histidine, isoleucine, lysine, leucine, methionine, asparagines, proline, glutamine, arginine, serine, threonine, valine, tryptophan, tyrosine, hexose sugars, pentose sugars, phospholipids, lipds, and any other biological monomer.
In yet another embodiment the pore is sized and shaped to allow passage of a cofactor, wherein the cofactor is selected from the group consisting of Mg2+, Mn2+, Ca2+, ATP, NAD+, NADP+, and any other biological cofactor.
In one important embodiment, the pore or channel comprises a a biological molecule, or a synthetic modified or altered biological molecule. Such biological molecules are, for example, but not limited to, an ion channel, such as a-hemolysin, a nucleoside channel, a peptide channel, a sugar transporter, a synaptic channel, a transmembrane receptor, such as GPCRs, a receptor tyrosine kinase, and the like, a T-cell receptor, an MHC receptor, a nuclear receptor, such as a steroid hormone receptor, a nuclear pore, or the like.
In an alternative, the compound comprises a non-enzyme biological activity. The compound having non-enzyme biological activity can be, for example, but not limited to, proteins, peptides, antibodies, antigens, nucleic acids, peptide nucleic acids (PNAs), locked nucleic acids (LNAs), morpholinos, sugars, lipids, glycosyl phosphatidyl inositols, glycophosphoinositols, lipopolysaccharides, or the like. The compound can have antigenic activity. The compound can have ribozyme activity. The compound can have selective binding properties whereby the polymer binds to the compound under a particular controlled environmental condition, but not when the environmental conditions are changed. Such conditions can be, for example, but not limited to, change in [H+], change in environmental temperature, change in stringency, change in hydrophobicity, change in hydrophilicity, or the like.
In one embodiment the macromolecule comprises a enzyme activity. The enzyme activity can be, for example, but not limited to, enzyme activity of proteases, kinases, phosphatases, hydrolases, oxidoreductases, isomerases, transferases, methylases, acetylases, ligases, lyases, and the like. In a more preferred embodiment the enzyme activity can be enzyme activity of DNA polymerase, RNA polymerase, endonuclease, exonuclease, DNA ligase, DNase, uracil-DNA glycosidase, kinase, phosphatase, methylase, acetylase, glucose oxidase, or the like. In an alternative embodiment, the macromolecule can comprise more that one enzyme activity, for example, the enzyme activity of a cytochrome P450 enzyme. In another alternative embodiment, the macromolecule can comprise more than one type of enzyme activity, for example, mammalian fatty acid synthase. In another embodiment the macromolecule comprises a ribozyme activity.
In another embodiment, the invention provides a compound, wherein the compound further comprises a linker molecule, the linker molecule selected from the group consisting of a thiol group, a sulfide group, a phosphate group, a sulfate group, a cyano group, a piperidine group, an Fmoc group, and a Boc group. In another embodiment the compound is selected from the group consisting of a bifunctional alkyl sulfide and gold.
Devices that can be used to carry out the methods of the instant invention are described in for example, U.S. Pat. No. (U.S. Pat. No.) 5,795,782, U.S. Pat. No. 6,015,714, U.S. Pat. No. 6,267,872, U.S. Pat. No. 6,627,067, U.S. Pat. No. 6,746,594, U.S. Pat. No. 6,428,959, U.S. Pat. No. 6,617,113, and International Publication Number WO 2006/028508, each of which is hereby incorporated by reference in their entirety.
While the forgoing has described the inventive compensation technique in terms of patch-clamps it can also be employed in applications where excessive dead-times must be avoided. Accurate reset pulse widths can reduce the dead-times.
It is to be understood that while the figures and the above description illustrates the present invention, they are exemplary only. They are not intended to be exhaustive or to limit the invention to the precise forms disclosed, and obviously many modifications and variations are possible in light of the above teaching. Others who are skilled in the applicable arts will recognize numerous modifications and adaptations of the illustrated embodiments that remain within the principles of the present invention. Therefore, the present invention is to be limited only by the appended claims.
While the foregoing has explained the present invention using traditional two-electrode nanopore sensors the principles of the present invention are flexible enough to be used with other architectures. For example,
To the extent allowed by law this application claims priority to and the benefit of U.S. provisional patent application Ser. No. 61/572,829 filed 20 Jul. 2011, entitled “A SWITCHED VOLTAGE PATCH-CLAMP AMPLIFIER FOR DNA SEQUENCING ON SOLID-STATE NANOPORE”. That application and any publication cited therein are hereby incorporated by reference to the fullest extent allowed by law.
This invention was made partly using funds from the National Science Foundation, NSF Career grant number ECCS-0845766. The US Federal Government has certain rights to this invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2012/047231 | 7/18/2012 | WO | 00 | 9/14/2013 |
Number | Date | Country | |
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61572829 | Jul 2011 | US |