Abstract: A thermal cycling device for thermally cycling samples of biological material contained in a microcard having a top and bottom surface. The thermal cycling device can include a sample block having an upper surface configured for engaging the bottom surface of a microcard, a vacuum device, and a temperature control system operatively connected with the sample block. The upper surface of the sample block may include a plurality of channels, the channels defining spaces between the sample block and the bottom surface of a microcard that may be positioned thereon. The vacuum device may be in fluid communication with the sample block for drawing gas out of the spaces defined by the channels in the sample block. The vacuum device may be configured for substantially maintaining a vacuum between the sample block and microcard so that a retention force is imparted on the microcard to urge the microcard toward the sample block.
Abstract: Compositions, methods, and kits for detecting one or more species of RNA molecules are disclosed. In one embodiment, a first adaptor and a second adaptor are ligated to the RNA molecule using a polypeptide comprising double-strand specific RNA ligase activity, without an intervening purification step. The ligated product is reverse transcribed, then at least some of the ribonucleosides in the reverse transcription product are removed. Primers are added and amplified products are generated. In certain embodiments, the sequence of at least part of at least one species of amplified product is determined and at least part of the corresponding RNA molecule is determined. In some embodiments, at least some of the amplified product species are detected, directly or indirectly, allowing the presence and/or quantity of the RNA molecule of interest to be determined.
Abstract: The invention relates to methods for the detection of a specific sequence of RNA in a cell or tissue sample. The invention also relates to methods to enzymatically manipulate the RNA in a crude cell lysate in a number of applications.
Abstract: The invention provides compositions, methods and kits for high speed, high resolution of analytes by capillary electrophoresis starting with uncoated capillaries. The compositions comprise a sieving component, comprising a non-crosslinked acrylamide polymer, and a surface interaction component, comprising at least one uncharged and non-crosslinked water-soluble silica-adsorbing polymer. Methods for employing the novel compositions in capillary electrophoresis are provided. Kits comprising the novel compositions for use in the novel methods are also provided.
Abstract: A method for dispensing liquid for use in biological analysis may comprise positioning liquid to be dispensed via electrowetting. The positioning may comprise aligning the liquid with a plurality of predetermined locations. The method may further comprise dispensing the aligned liquid from the plurality of predetermined locations through a plurality of openings respectively aligned with the predetermined locations. The dispensing may be via electrowetting.
Type:
Grant
Filed:
June 5, 2017
Date of Patent:
February 26, 2019
Assignee:
APPLIED BIOSYSTEMS, LLC
Inventors:
Charles S. Vann, Debjyoti Banerjee, Timothy G. Geiser, James C. Nurse, Nigel P. Beard
Abstract: The present disclosure relates to methods of identifying target nucleic acids by using coded molecules and its analysis by translocation through a nanopore. Generally, coded molecules are subject to a target polynucleotide dependent modification. The modified coded molecule is detected by isolating the modified coded molecules from the unmodified coded molecules prior to analysis through the nanopore or by detecting a change in the signal pattern of the coded molecule when analyzed through the nanopore.
Type:
Grant
Filed:
June 5, 2017
Date of Patent:
February 5, 2019
Assignee:
APPLIED BIOSYSTEMS, LLC
Inventors:
Muhammad A. Sharaf, Timothy Woudenberg, Khairuzzaman Bashar Mullah
Abstract: A device for performing biological sample reactions may include a plurality of flow cells configured to be mounted to a common microscope translation stage, wherein each flow cell is configured to receive at least one sample holder containing biological sample. Each flow cell also may be configured to be selectively placed in an open position for positioning the at least one sample holder into the flow cell and a closed position for reacting biological sample contained in the at least one sample holder. The plurality of flow cells may be configured to be selectively placed in the open position and the closed position independently of each other.
Abstract: A genetic surveillance system comprises a communications network and at least one reader-analyzer instrument. The reader-analyzer instrument has a communication interface to communicate over the network. The reader-analyzer instrument is adapted to perform genetic assay analysis of a sample obtained from a member of a population and to generate detection-related data based upon the analysis. The reader-analyzer instrument is adapted to associate qualifying information with the detection-related data and to communicate the associated qualifying information and detection-related data over the network.
Type:
Grant
Filed:
December 10, 2014
Date of Patent:
January 15, 2019
Assignee:
APPLIED BIOSYSTEMS, LLC
Inventors:
Chirag Patel, Hans Fuernkranz, Michael Greenstein
Abstract: There is disclosed a system for electrical charge detection comprising a nanoFET device. Also disclosed is a method of electrical charge detection for single molecule sequencing. The method includes attaching a macromolecule or assemblies thereof to a gate of a nanoFET device and flowing in a solution of charge tags, where a charge tag includes a nucleotide attached to a charge complex. The method also includes incorporating one charge tag into the macromolecule or assemblies thereof and cleaving the charge tags from the macromolecule or assemblies thereof. The method further includes detecting at least one of current and voltage from the nanoFET device.
Abstract: The present invention concerns the use of methods and compositions for the isolation of small RNA molecules (100 nucleotides or fewer), such as microRNA and siRNA molecules. Such molecules are routinely lost in commonly used isolation procedures and therefore the present invention allows for a much higher level of enrichment or isolation of these small RNA molecules.
Abstract: Systems and methods are provided for processing a melting or dissociation curve of a DNA or other sample, for example, during PCR processing. In some embodiments, detection of the melting point and melting curve behavior can be enhanced by taking a derivative of the curve, and detecting peaks in the differential dissociation curve. In some embodiments, the derivative operation can comprise the use of edge-processing, or other detection algorithms. In some embodiments, the dissociation analysis can comprise removing low-frequency (or pedestal) components of the differential dissociation curve. In some embodiments, the differential dissociation curve can exhibit a smoothed or more regular appearance than the raw detected data.
Abstract: A two-step multiplex amplification reaction includes a first step which truncates the standard initial multiplex amplification round to “boost” the sample copy number by only a 100-1000 fold increase in the target. Following the first step the product is divided into optimized secondary single amplification reactions, each containing one of the primer sets that were used previously in the first or multiplexed booster step. The booster step can occur using an aqueous target nucleic acid or using a solid phase archived nucleic acid. In particular, nucleic acid sequences that uniquely identify E. Coli were identified using the multiplex amplification method.
Type:
Grant
Filed:
October 14, 2016
Date of Patent:
October 23, 2018
Assignee:
Applied Biosystems, LLC
Inventors:
John Gerdes, Elaine Best, Jeffrey M. Marmaro
Abstract: Various embodiments of the teachings relate to a system or method for sample preparation or analysis in biochemical or molecular biology procedures. The sample preparation can involve small volume processed in discrete portions or segments or slugs, herein referred to as discrete volumes. A molecular biology procedure can be nucleic acid analysis. Nucleic acid analysis can be an integrated DNA amplification/DNA sequencing procedure.
Type:
Grant
Filed:
October 28, 2015
Date of Patent:
August 7, 2018
Assignee:
Applied Biosystems, LLC
Inventors:
Linda G. Lee, Sam L. Woo, Congcong Ma, Richard T. Reel, Mark F. Oldham, David M. Cox, Benjamin G. Schroeder, Jon M. Sorenson, Willy Wiyatno
Abstract: The invention relates to methods for the detection of a specific sequence of RNA in a cell or tissue sample. The invention also relates to methods to enzymatically manipulate the RNA in a crude cell lysate in a number of applications.
Abstract: An apparatus and method for rapid thermal cycling including a thermal diffusivity plate. The thermal diffusivity plate can provide substantial temperature uniformity throughout the thermal block assembly during thermal cycling by a thermoelectric module. An edge heater can provide substantial temperature uniformity throughout the thermal block assembly during thermal cycling.
Type:
Grant
Filed:
October 10, 2014
Date of Patent:
July 3, 2018
Assignee:
Applied Biosystems, LLC
Inventors:
Hon Siu Shin, Jew Kwee Ngui, Chee Kiong Lim, Ching Ong Lau, Lim Hi Tan, Yang Hooi Kee
Abstract: The invention discloses a system and methods for quantitating the presence of nucleic acid sequences by evaluation of amplification data generated using real-time PCR. In one aspect, the methods may be adapted to identify a threshold and threshold cycle for one or more reactions based upon evaluation of exponential and baseline regions for each amplification reaction. The methodology used in the analysis may be readily automated such that subjective user interpretation of the data is substantially reduced or eliminated.
Type:
Grant
Filed:
October 7, 2013
Date of Patent:
June 19, 2018
Assignee:
APPLIED BIOSYSTEMS, LLC
Inventors:
David C. Woo, Clinton Lewis, Nasser M. Abbasi
Abstract: Systems and methods are provided for processing a melting or dissociation curve of a DNA or other sample, for example, during PCR processing. In some embodiments, detection of the melting point and melting curve behavior can be enhanced by taking a derivative of the curve, and detecting peaks in the differential dissociation curve. In some embodiments, the derivative operation can comprise the use of edge-processing, or other detection algorithms. In some embodiments, the dissociation analysis can comprise removing low-frequency (or pedestal) components of the differential dissociation curve. In some embodiments, the differential dissociation curve can exhibit a smoothed or more regular appearance than the raw detected data.
Abstract: The invention provides compositions, methods and kits for high speed, high resolution of analytes by capillary electrophoresis starting with uncoated capillaries. The compositions comprise a sieving component, comprising a non-crosslinked acrylamide polymer, and a surface interaction component, comprising at least one uncharged and non-crosslinked water-soluble silica-adsorbing polymer. Methods for employing the novel compositions in capillary electrophoresis are provided. Kits comprising the novel compositions for use in the novel methods are also provided.
Abstract: This invention is directed to methods, kits, non-nucleotide probes as well as other compositions pertaining to the suppression of binding of detectable nucleic acid probes to undesired nucleotide sequences of genomic nucleic acid in assays designed to determine target genomic nucleic acid.