Abstract: A method for preparing a hydrogel composed substantially only of nucleic acids. Further. a nucleic acid sol-like composition for producing a nucleic acid gel without requiring the use of any nucleic acid ligase, wherein the composition comprises at least two nucleic acid monomers which are partly complementary to each other and are independently selected from the group consisting of a nucleic acid, a nucleic acid derivative, a modified nucleic acid, a compound capable of binding to a nucleic acid in a complementary manner and a mixture thereof, one of the nucleic acid monomers has a moiety that constitutes a cohesive protruding end and a complementary nucleotide sequence moiety that can bind to at least one of the other nucleic acid monomers to form a double strand, and the composition contains no nucleic acid ligase. Still further, a nucleic acid gel produced using the sol-like composition.
Abstract: Nanochannel arrays that enable high-throughput macromolecular analysis are disclosed. Also disclosed are methods of preparing nanochannel arrays and nanofluidic chips. Methods of analyzing macromolecules, such as entire strands of genomic DNA, are also disclosed, as well as systems for carrying out these methods.
Type:
Grant
Filed:
March 24, 2014
Date of Patent:
July 12, 2016
Assignee:
The Trustees of Princeton University
Inventors:
Robert H. Austin, Zhaoning Yu, Jonas O. Tegenfeldt, Stephen Y. Chou, Han Cao
Abstract: An apparatus comprises an antenna pattern precursor, wherein the antenna pattern precursor includes a plurality of sensitive regions; and electromagnetically functionalized DNA/nanoparticle complex(es) that individualize the ability to transition between the precursor antenna electrical and resonant frequency characteristics, and activated antenna electrical and resonant frequency characteristics through DNA hybridization of the specific sequences contained in the electromagnetically functionalized DNA/nanoparticle complex(es).
Type:
Grant
Filed:
March 13, 2014
Date of Patent:
July 5, 2016
Assignee:
NOKOMIS, INC.
Inventors:
Bogdan Amaru Pathak, Walter John Keller, III
Abstract: An arrangement for determining the concentration of nucleic acids in a sample in a microfluidic device. In at least one embodiment, the arrangement having a) a first chamber into which a the sample is introduced, b) an element in the first chamber for carrying out a number of cycles of an amplification reaction to be carried out in cycles for amplifying nucleic acids, c) a second chamber, connectable to the first chamber by way of fluidic communication, equipped with an element to determine concentrations of amplified nucleic acids, d) a control unit to introduce a defined volume of a solution containing reagents for the amplification reaction into the first chamber and to transfer a defined volume from said first chamber to the second chamber.
Type:
Grant
Filed:
March 20, 2014
Date of Patent:
May 24, 2016
Assignee:
Boehringer Ingelheim Vetmedica GmbH
Inventors:
Walter Gumbrecht, Jörn Mosner, Sebastian Schmidt
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.
Type:
Grant
Filed:
May 9, 2014
Date of Patent:
May 10, 2016
Assignee:
Keygene N.V.
Inventors:
Michael Josephus Theresia Van Eijk, Anker Preben Sørensen, Marco Gerardus Maria Van Schriek
Abstract: A protein-immobilizing solid phase is a protein-immobilizing solid phase comprising an mRNA-nucleic acid linker-protein complex, obtained by linking the mRNA and the protein encoded by that mRNA through the nucleic acid linker, immobilized on the solid phase, wherein the nucleic acid linker has a photocleavage site and a solid phase binding site.
Type:
Grant
Filed:
April 30, 2014
Date of Patent:
May 10, 2016
Assignees:
The University of Tokyo, NIKON CORPORATION
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.
Type:
Grant
Filed:
April 29, 2015
Date of Patent:
May 3, 2016
Assignee:
Keygene N.V.
Inventors:
Michael Josephus Theresia Van Eijk, Anker Preben Sørensen, Marco Gerardus Maria Van Schriek
Abstract: The present invention relates to a method for isolating cells from a complex sample comprising the steps of: a) providing a complex sample, b) incubating said sample with: at least one chaotrope, a buffer and at least one detergent, c) isolating said cells from the resulting mixture by centrifugation or filtration.
Type:
Grant
Filed:
August 10, 2007
Date of Patent:
May 3, 2016
Assignee:
MERCK PATENT GMBH
Inventors:
Peter Rossmanith, Ingeborg Hein, Martin Wagner
Abstract: A fluid identification system comprising a plurality of particles, each particle encapsulating therein at least one tracer material having an identifiable DNA, the at least one tracer material being encapsulated by an encapsulation material, wherein the particles are adapted to retain the at least one tracer material in an encapsulated form after exposure of the particles to a temperature of at least 75° C. and/or a pressure of at least 1000 psi (6.9×106 N/m2).
Type:
Grant
Filed:
April 4, 2012
Date of Patent:
April 26, 2016
Assignee:
Tracesa, Ltd.
Inventors:
Dominic Patrick Joseph McCann, Kevin John Forbes, Edyta Lam, Geoffrey Colin Maitland, Alexander Bismarck
Abstract: Disclosed is a method for in situ detection of one or more target nucleic acids based on a combination of an in situ hybridization (ISH) assay method and a general ISH signal amplification method. This new method produces high signal intensity and while keeps low background noise of signal amplification. The result can be consistently reproduced and the method can be easily adopted for routine clinic diagnostic use. Further, the invention relates to a kit, comprising the components of the ISH assay and a general ISH signal amplification assay, for sensitive detection of one or more target nucleic acids.
Type:
Grant
Filed:
January 9, 2014
Date of Patent:
April 19, 2016
Assignee:
Advanced Cell Diagnostics, Inc.
Inventors:
Xingyong Wu, Huei-Yu Fay Wang, Nan Su, Li-Chong Wang, Yuling Luo
Abstract: Methods of analyzing features such as the physical size of macromolecules or biomarkers along large genomic DNA molecules were disclosed as wen as the devices for carrying out such high throughput analysis in a massively parallel fashion. Methods of fabricating such devices are also disclosed.
Type:
Grant
Filed:
March 3, 2014
Date of Patent:
April 12, 2016
Assignee:
BIONANO GENOMICS, INC.
Inventors:
Han Cao, Parikshit A Deshpande, Michael D Austin, Michael Boyce-Jacino
Abstract: The present invention relates to method of using a microfluidic chip for rapid nucleic acid hybridization, comprising: activating a porous substrate with positive charges; injecting a mixed solution of a test nucleic acid and a nucleic acid probe into the microfluidic chip for maintaining the test nucleic acid hybridized to the nucleic acid probe being absorbed to the periphery of the substrate; continuously washing the microfluidic chip with an anionic surfactant; and detecting the hybridization signals on the substrate after washing for a predetermined time; wherein the activation of the substrate with positive charges allows the test nucleic acid hybridized to the nucleic acid probe to form a micelle during washing and the diffusion of such from the periphery toward the center of the substrate to accelerate. Thus, it is possible to accomplish detection in a very short time for application of specific DNA complementary hybridization.
Abstract: A molecular delivery system including a plurality of nanowires (e.g., Si NWs), each of the nanowires having a surface layer formed of a silicon-containing material and a covalently bound linker (e.g., silane linker) attached to the surface layer, and optionally including a substrate to which the nanowires are adhered or a molecule to be delivered attached to the linker. Also disclosed is a method of delivering into a cell an exogenous molecule.
Type:
Grant
Filed:
April 16, 2010
Date of Patent:
April 5, 2016
Assignee:
President and Fellows of Harvard College
Inventors:
Hongkun Park, EunGyeong Yang, Alexander K. Shalek, JinSeok Lee, Jacob Robinson, Amy Sutton, Myung-Han Yoon, Marsela Jorgolli
Abstract: The invention provides a nucleic acid probe for detecting a polynucleotide. The probe contains a region that base-pairs with a polynucleotide to form a duplex and a Tm enhancement domain that increases the stability of the duplex. The Tm enhancement domain may contain a nucleotide clamp and/or a hairpin structure, for example. Also provided is an array of subject nucleic acid probes bound to a surface of the solid support. Methods of using a subject probe to assess polynucleotides, e.g., small RNAs in a sample are provided, as are kits for use in practicing the subject methods.
Abstract: A microfluidic device for a confocal fluorescence detection system has an input channel defined by a body of the microfluidic device, a sample concentration section defined by the body of the microfluidic device and in fluid connection with the input channel, a mixing section defined by the body of the microfluidic device and in fluid connection with the concentration section, and a detection region that is at least partially transparent to illumination light of the confocal fluorescence detection system and at least partially transparent to fluorescent light when emitted from a sample under observation as the sample flows through the detection region.
Type:
Grant
Filed:
December 20, 2013
Date of Patent:
March 15, 2016
Assignee:
The Johns Hopkins University
Inventors:
Tza-Huei Wang, Kelvin J. Liu, Christopher M. Puleo, Tushar D. Rane
Abstract: Multifunctional probes include a substrate (e.g., a nanoparticle, polymer, antibody, protein, low molecular weight compound, drug) and a multifunctional single-attachment-point (MSAP) reagent. The MSAP reagents can include three components: (i) a peptide scaffold, (ii) a single chemically reactive group on the peptide scaffold for reaction of the MSAP with a substrate having a complementary reactive group, and (iii) multiple functional groups on the peptide scaffold. The peptide scaffold can include any number of residues; however, for ease of synthesis and reproducibility in clinical trials, it is preferred to limit the residues in the peptide to 20 or less.
Abstract: Described herein are methods for mid-infrared imaging of nucleic acid microarrays by employing mid-infrared reflective labels combined with detection in the reflection mode. The methods described herein provide intrinsic image contrast, and permit detection of DNA microarray hybridization on infrared absorbing substrates such as glass slides.
Type:
Grant
Filed:
October 14, 2011
Date of Patent:
March 8, 2016
Assignee:
THE UNITED STATES OF AMERICA, AS REPRESENTED BY THE SECRETARY, DEPARTMENT OF HEALTH AND HUMAN SERVICES
Inventors:
Magdi M. Mossoba, Sufian Al-Khaldi, Brianna Schoen, Betsy Jean Yakes
Abstract: The present invention is directed to compositions and methods for nucleic acid identification and detection. Compositions and methods of the present invention include extracting and fragmenting target nucleic acids from a sample, using the fragmented target nucleic acids to produce target nucleic acid templates and subjecting those target nucleic acid templates to amplification methods to form nucleic acid nanoballs. The invention also includes methods of detecting and identifying sequences using various sequencing applications, including sequencing by ligation methods.