Abstract: The invention is directed to articles of manufacture for constraining movement of molecules, such as polynucleotides, and methods of using the same. In some embodiments, article of manufacture of the invention comprise (i) a solid state membrane having at least one aperture extending therethrough from a first side to a second side; (ii) an annular DNA sheet having a central opening disposed on the first side of the solid state membrane such that the annular DNA sheet spans an aperture and the central opening is aligned with the aperture to provide fluid communication between the first side and the second side of the solid state membrane through the aperture; and (iii) a protein nanopore immobilized in the central opening of the annular DNA sheet spanning the aperture. Uses of such articles of manufacture include determining sequences of nucleic acids.

Abstract: In some aspects the invention is directed to methods of analyzing a polynucleotide which include steps of directing to a nanopore an excitation beam having a predetermined polarization state; translocating a polynucleotide through the nanopore, wherein nucleotides of the polynucleotide are labeled with fluorescent labels having absorption dipoles and wherein the nanopore spatially orients the fluorescent labels so that during translocation the adsorption dipoles are substantially unresponsive to the excitation beam; detecting changes in fluorescent signals generated by the fluorescent labels as nucleotides with fluorescent labels exit the nanopore and absorption dipoles thereof become responsive to excitation by the excitation beam with the predetermined polarization state; and identifying nucleotides exiting the nanopore from the changes in fluorescent signals.

Abstract: The invention is directed to methods for analyzing polymers comprising linear chains of at least two types of monomers, such as polynucleotides, including DNA, RNA, and the like, using nanopores and optical detection. In some embodiments, as few as two different kinds of nucleotide are labeled with different optical labels that generate distinguishable optical signals for the selected kinds of nucleotide in both sense strands and antisense strands of target polynucleotides. Labeled strands are translocated through nanopores where nucleotides of the strands are constrained to pass sequentially through an optical detection region where their labels generate a sequence of optical signals making up an optical signature. In some embodiments, information from optical signatures from both sense and antisense strands are combined to determine complete nucleotide sequences of target polynucleotides.

Abstract: The invention is directed to nanopore-based methods for analyzing polymers, such as polynucleotides or proteins, containing optical labels specific for different kinds of monomers. In some embodiments, methods of the invention include steps of (a) translocating a polymer through a nanopore, wherein different kinds of monomers of the polymer are labeled with different optical labels that generate distinguishable optical signals and wherein the nanopore constrains the monomers to move single file through an excitation zone that encompasses a plurality of monomers; (b) detecting a time-ordered set of optical signals from the monomers as the polymer passes through the excitation zone; (c) separating optical signals from different kinds of monomers to form monomer-specific time-ordered sets of optical signals; and (d) determining a sequence of monomers from the monomer-specific time-ordered sets of optical signals from the polymer.

Abstract: The invention provides methods for analyzing polynucleotides using nanopores that allow passage of single stranded polynucleotides but not double stranded polynucleotides. In accordance with some embodiments, a double-stranded product is produced that comprises a labeled strand with a single stranded tail or overhang. The double stranded product is exposed to one or more nanopores in the presence of an electric field across the one or more nanopores such that the single stranded tail may be captured and the labeled strand translocated by unzipping from the double stranded product. The ionic composition of the reaction mixture and electric field strength are selected so that nucleotides translocate a nanopore at a rate of less than 1000 nucleotides per second.

Abstract: The invention is directed to methods for carrying out redundant measurements on polymers by reversing translocation of the polymers through nanopores that each have a detection region, thereby permitting signals generated from the same polymer structure at different times to be collected. Such repeated measurements are combined in order to reduce noise in a final determination of the polymer structure. In some embodiments, polynucleotides whose different nucleotides have distinguishable fluorescent labels attached are repeatedly translocated through nanopores of a nanopore array to compile repeated measurements of optical signals from the same segments, which may be combined to make a determination of a nucleotide sequence.

Abstract: The invention is directed to nanopore arrays comprising opaque layers that reduce background fluorescence in optical signal collected in applications of such arrays for analyzing molecules. In some embodiments, such arrays are used to determine characteristics of polymers, such as polynucleotides, in methods comprising the steps of translocating polymers through nanopores of such arrays wherein polymers have one or more optical labels, exciting optical labels of the polymers in a signal generation region of each nanopore extending from the opaque layer toward the direction of the excitation beam, detecting optical signals from the signal generation regions of each nanopore to determine characteristics of the polymer translocating therethrough.

Abstract: The invention is directed to devices and methods for optically based nanopore analysis which employ FRET signaling wherein at least one member of a FRET pair is mobile within a lipid bilayer containing one or more nanopores. In some embodiments, mobile FRET donors are constrained to a lipid bilayer so that they may continuously diffuse into and within a FRET distance of acceptor-labeled analytes entering or exiting a nanopore so that bleached or degraded FRET donors are continuously replaced.

Abstract: The invention is directed to a method for determining a monomer sequence of a polymer that is translocated through a nanopore. Monomers of the polymer are labeled with fluorescent labels such that in free solution fluorescent labels of adjacent monomers substantially quench each other and wherein the nanopore constrains fluorescent labels within its bore into a constrained state wherein no detectable fluorescent signal can be generated. By exciting the fluorescent label of each monomer as it exits the nanopore and transitions from a constrained state to a quenched state with an adjacent fluorescent label, a fluorescent signal can be generated by the exiting fluorescent label that allows its monomer to be identified, thereby permitting a monomer sequence to be determined from a sequence of fluorescent signals as the polymer translocates through the nanopore.

Abstract: Various methods, systems and devices for optical detection and analysis of polymers, such as polynucleotides, using nanopores, e.g., for determining sequences of nucleic acids, are provided herein. In certain variations, methods and systems for determining a nucleotide sequence of a polynucleotide, which include measuring mixed FRET signals as a polynucleotide translocates through a nanopore and determining a nucleotide sequence of the polynucleotide from the mixed FRET signals, are provided.

Abstract: The invention is directed to a method for determining a monomer sequence of a polymer that is translocated through a nanopore. Monomers of the polymer are labeled with fluorescent labels such that in free solution fluorescent labels of adjacent monomers substantially quench each other and wherein the nanopore constrains fluorescent labels within its bore into a constrained state wherein no detectable fluorescent signal can be generated. By exciting the fluorescent label of each monomer as it exits the nanopore and transitions from a constrained state to a quenched state with an adjacent fluorescent label, a fluorescent signal can be generated by the exiting fluorescent label that allows its monomer to be identified, thereby permitting a monomer sequence to be determined from a sequence of fluorescent signals as the polymer translocates through the nanopore.

Abstract: Various methods, systems and devices for optical detection and analysis of polymers, such as polynucleotides, using nanopores, e.g., for determining sequences of nucleic acids, are provided herein. In certain variations, methods and systems for determining a nucleotide sequence of a polynucleotide, which include measuring mixed FRET signals as a polynucleotide translocates through a nanopore and determining a nucleotide sequence of the polynucleotide from the mixed FRET signals, are provided.

Abstract: The invention is directed to methods and apparatus for detecting sequences of optical signals from parallel reactions on an array of nanostructures, such as nanopores, nanowells, or nanoparticles. In accordance with the invention, an array of nanostructures is provided, each nanostructure comprising a reaction site and each capable of confining a reaction that generates a sequence of optical signals, and the nanostructures of the array being arranged in clusters each comprising a number of nanostructures. Each different cluster is disposed within a different resolution limited area and the number of nanostructures in each cluster is either greater than one or a random variable with an average value greater than zero. Optical signals from reactions in the nanostructures are detected by an optical system operatively associated with the array.

Abstract: Methods for fabricating materials useful for optical detection in microfluidic and nanofluidic devices, such as those used in nanopore-based nucleic acid sequencing are described herein. In certain variations, a method of reducing background fluorescence in a MEMS material may include the step of treating a surface of the MEMS material with a low energy ion beam.

Abstract: The invention is directed to methods and apparatus for detecting sequences of optical signals from parallel reactions on an array of nanostructures, such as nanopores, nanowells, or nanoparticles. In accordance with the invention, an array of nanostructures is provided, each nanostructure comprising a reaction site and each capable of confining a reaction that generates a sequence of optical signals, and the nanostructures of the array being arranged in clusters each comprising a number of nanostructures. Each different cluster is disposed within a different resolution limited area and the number of nanostructures in each cluster is either greater than one or a random variable with an average value greater than zero. Optical signals from reactions in the nanostructures are detected by an optical system operatively associated with the array.

Abstract: Methods and systems for sequencing a biological molecule or polymer, e.g., a nucleic acid, are provided. One or more donor labels, which are attached to a pore or nanopore, may be illuminated or otherwise excited. A polymer having a monomer labeled with one or more acceptor labels, may be translocated through the pore. Either before, after or while the labeled monomer of the polymer passes through, exits or enters the pore, energy may be transferred from the excited donor label to the acceptor label of the monomer. As a result of the energy transfer, the acceptor label emits energy, and the emitted energy is detected in order to identify the labeled monomer of the translocated polymer and to thereby sequence the polymer.

Abstract: Methods for fabricating materials useful for optical detection in microfluidic and nanofluidic devices, such as those used in nanopore-based nucleic acid sequencing are described herein. In certain variations, a method of reducing background fluorescence in a MEMS material may include the step of treating a surface of the MEMS material with a low energy ion beam.

Abstract: Various methods, systems and devices for optical detection and analysis of polymers, such as polynucleotides, using nanopores, e.g., for determining sequences of nucleic acids, are provided herein. In certain variations, methods and systems for determining a nucleotide sequence of a polynucleotide, which include measuring mixed FRET signals as a polynucleotide translocates through a nanopore and determining a nucleotide sequence of the polynucleotide from the mixed FRET signals, are provided.

Abstract: Methods and systems for sequencing a biological molecule or polymer, e.g., a nucleic acid, are provided. One or more donor labels, which are attached to a pore or nanopore, may be illuminated or otherwise excited. A polymer having a monomer labeled with one or more acceptor labels, may be translocated through the pore. Either before, after or while the labeled monomer of the polymer passes through, exits or enters the pore, energy may be transferred from the excited donor label to the acceptor label of the monomer. As a result of the energy transfer, the acceptor label emits energy, and the emitted energy is detected in order to identify the labeled monomer of the translocated polymer and to thereby sequence the polymer.

Abstract: The invention is directed to a device comprising a protein nanopore immobilized in a lipid layer within an aperture of a solid phase substrate, which provides a stable platform for using first and second members of one or more FRET pairs to generate optical signals as a labeled analyte translocates through the bore of the protein nanopore. In another aspect, the invention is directed to the use of the device to determine the nucleotide sequence of a polynucleotide analyte.