Abstract: The invention relates to a method for the detection of a target nucleotide sequence in a sample based on an oligonucleotide ligation assay wherein probes are used that contain (a combination of) sequence-based identifiers that can identify the sample and the target sequence (i.e. locus and/or allele combination) wherein after the ligation step, the ligated probes, or after amplification, the amplified ligated probes, are restricted using restriction enzymes to cut of part of the probes and continue with those parts (identifiers and target sequence) that contain the relevant information in the sequencing step.

Abstract: The invention relates to a method for the high throughput discovery, detection and genotyping of one or more genetic markers in one or more samples, comprising the steps of restriction endonuclease digest of DNA, adaptor-ligation, optional pre-amplification, selective amplification, pooling of the amplified products, sequencing the libraries with sufficient redundancy, clustering followed by identification of the genetic markers within the library and/or between libraries and determination of (co-)dominant genotypes of the genetic markers.

Abstract: The present invention provides a novel method to fabricate silica nanostructures on thin polymer films based on silica deposition and self-wrinkling induced by thermal shrinkage. These micro- and nano-scale structures have vastly enlarged the specific area of silica, thus the silica nanomembranes can be used for solid phase extraction of nucleic acids. The inventive silica nanomembranes are suitable for nucleic acid purification and isolation and demonstrated better performance than commercial particles in terms of DNA recovery yield and integrity. In addition, the silica nanomembranes have extremely high nucleic acid capacity due to its significantly enlarged specific surface area of silica. Methods of use and devices comprising the silica nanomembranes are also provided.

Abstract: The use of ion sensitive field effect transistor (ISFET) to detect methylated nucleotides in a DNA sample is described. A method of detecting methylated nucleotides in a DNA sample may include the steps of treating a sample of DNA with a reagent which discriminates between methylated and non-methylated nucleotides to provide treated DNA, amplifying the treated DNA and optionally sequencing the amplified DNA. An ISFET is used to monitor the addition of one or more dNTPs in the strand extension reactions during the amplification and/or sequencing step. Suitable apparatus is also provided.

Abstract: The present invention generally relates to devices and methods for collecting and stabilizing biological samples, and more particularly, for collecting and stabilizing blood or other bodily fluids from a user's fingertip, earlobe, heel or other locations. The present invention also relates to sample collection devices that simplify the process for mixing the biological samples with an additive or additives, provide for efficient storage and safe transport of the samples, and provide for easy access to the samples for subsequent processing.

Abstract: The invention relates to a new method of characterizing a target polynucleotide. The method uses a pore and a Hel308 helicase or amolecular motor which is capable of binding to the target polynucleotide at an internal nucleotide. The helicase or molecular motor controls the movement of the target polynucleotide through the pore.

Abstract: Methods and devices for the interfacing of microchips to various types of modules are disclosed. The technology disclosed can be used as sample preparation and analysis systems for various applications, such as DNA sequencing and genotyping, proteomics, pathogen detection, diagnostics and biodefense. Also disclosed in the present disclosure is a flow through, traveling-wave, bead-beating device which comprises a rotating pole piece, a flow through tube, and a magnetic piece. Rotation of the rotating pole piece may create a magnetic wave down the flow through tube, thereby producing sufficient acceleration of beads through the tube to disrupt or lyse target analytes flowing through the tube.

Abstract: The present invention relates to a method for preparing metal nanostructures using DNA, and more particularly, to a method for preparing metal nanostructures, in which a self-assembling DNA is used as a frame, and thus the orientation, shape and size of the nanostructures are easily controlled compared to conventional bottom-up methods. Metal nanostructures prepared by the method show excellent localized surface plasmon resonance properties, and thus can be used as fluorescent substances in drug delivery, biomedical imaging, and supersensitive biosensors.

Abstract: This invention relates to an assay device and a method for pretreating a specimen containing a biologically-relevant substance and then assaying the biologically-relevant substance. Biologically-relevant substances used in the assay method include microorganisms, cells, viruses, nucleic acids, polysaccharides, proteins (including antigens, antibodies, chromoproteins, and enzymes), peptides, nucleic acids, and small molecules. This pretreatment method removes contaminants from the biologically-relevant substances using supports such as magnetic particles, gels, resins, membranes, and solid-phased reagents. Therefore, in the assay method the following steps are generally carried out (i) a pretreatment step of treating a specimen using one or more first supports and then one or more second supports, and (ii) the assay step carried out after the pretreatment step. In particular, the pretreatment method reduces false positives and false negatives in the assay.

Abstract: Described herein are methods, compositions and kits for the generation of bisulfite-converted libraries useful for conducting reduced representation bisulfite sequencing (RRBS). The methods described herein can be employed to generate RRBS libraries in a manner that is easier and more cost-efficient than conventional RRBS methods, and can be efficiently sequenced with next generation sequencing (NGS) techniques without the need for genomic, higher diversity sequencing controls such as PhiX spike-ins.

Abstract: Methods, systems, devices and apparatus for use in screening and/or selecting a library of nucleic acid molecules and/or nucleic acid tagged or encoded molecules for binding to or interaction with a target molecule or substance (e.g., for use in new compound or drug discovery) are described. In some embodiments the device comprises: (a) a spatially addressable array, said array comprising a plurality of separate and discrete locations thereon; (b) a plurality of different oligomers operably connected to said spatially addressable array at different ones of said separate and discrete locations; (c) a tag sequence which is complementary to, and is hybridized to, each of said oligomers; and (d) a candidate chemical operably connected to each of said tag sequences, wherein each of said discrete locations is a unique identifier for its corresponding oligomer; and wherein said tag sequence is a unique identifier for its connected candidate chemical.

Abstract: Disclosed is a process for retrieval of nucleotide sequence. The process includes mixing iron chloride tetrahydrate with iron (III) chloride hexahydrate in solution; adding ammonium hydroxide to the mixture and stirring to form maghemite nanoparticles; stirring the maghemite nanoparticles in a solution with an inorganic acid, a surfactant and a monomer precursor of a conducting polymer; initiating polymerization of the monomer by adding the inorganic acid and an oxidizing agent to the stirred solution and further stirring to yield Polyaniline/maghemite nanocomposites; adding the nanocomposites to an first aqueous solution of the nucleotide sequence and stirring so as to electrostatically interact the nanocomposites with the nucleotide sequence; and weakening the electrostatic interaction between the nanocomposite and the nucleotide sequence to recover the nanocomposite independently of the nucleotide sequence.

Abstract: Described herein is a device including a nanotube disposed within a support material. The nanotube has one or more sidewall electrodes, two nanomembranes, and an enzyme. One of the nanomembrane is in direct contact with at least a portion of one sidewall electrode. The other nanomembrane form a nanochannel, nanopore, or a combination thereof, and can alter one or more of a molecular composition, a dimension, or a property thereof in response to electrical stimuli.

Abstract: A chip device for manipulating an object component is described, in which multiple liquid substances such as reagents required for a series of manipulations on a sample are stably secured in separated states throughout the manipulations within the device. The chip device includes a manipulation chip, magnetic particles, and a magnetic field application means. The manipulation chip includes a substrate, a groove formed in the surface of the substrate, and a manipulation medium accommodated in the groove such that gel phases and aqueous liquid phases are alternately disposed in the longitudinal direction of the groove and are in contact with each other. The magnetic particles are for capturing and carrying the object component. The magnetic field application means is capable of moving the magnetic particles in the longitudinal direction of the groove in the substrate by the application of a magnetic field to the substrate.

Abstract: Systems, methods, and kits are disclosed for collection, labeling and analyzing biological samples containing nucleic acid in conjunction with collecting at least one ridge and valley signature of an individual. Such devices and methods are used in forensic, human identification, access control and screening technologies to rapidly process an individual's identity or determine the identity of an individual.

Abstract: The present invention relates to compositions comprising a porous nanostructure of a known characteristics and a fragment of nucleic acid having a known sequence. Methods of use of the compositions were also provided, for example in DNA amplification, detection, and DNA sequencing.

Abstract: The invention relates to a method for the high throughput discovery, detection and genotyping of one or more genetic markers in one or more samples, comprising the steps of restriction endonuclease digest of DNA, adaptor-ligation, optional pre-amplification, selective amplification, pooling of the amplified products, sequencing the libraries with sufficient redundancy, clustering followed by identification of the genetic markers within the library and/or between libraries and determination of (co-)dominant genotypes of the genetic markers.

Abstract: The disclosure provides devices, systems and methods for the generation of encapsulated reagents and the partitioning of encapsulated reagents for use in subsequent analyses and/or processing, such as in the field of biological analyses and characterization.

Abstract: This disclosure provides microwell capsule array devices. The microwell capsule array devices are generally capable of performing one or more sample preparation operations. Such sample preparation operations may be used as a prelude to one more or more analysis operations. For example, a device of this disclosure can achieve physical partitioning and discrete mixing of samples with unique molecular identifiers within a single unit in preparation for various analysis operations. The device may be useful in a variety of applications and most notably nucleic-acid-based sequencing, detection and quantification of gene expression and single-cell analysis.

Abstract: This disclosure provides microwell capsule array devices. The microwell capsule array devices are generally capable of performing one or more sample preparation operations. Such sample preparation operations may be used as a prelude to one more or more analysis operations. For example, a device of this disclosure can achieve physical partitioning and discrete mixing of samples with unique molecular identifiers within a single unit in preparation for various analysis operations. The device may be useful in a variety of applications and most notably nucleic-acid-based sequencing, detection and quantification of gene expression and single-cell analysis.