Abstract: A probe array comprises a plurality of probes immobilized at a plurality of matrix sites on a substrate for capturing a target substance, wherein the probes are sequentially synthesized at the matrix sites on the substrate until a desired length, the probes are different from each other, and a labeling compound is coupled to each terminus of the probes in a final step of the synthesis. The probe array of the invention allows sensitive and reliable detection of the target substance. A method of evaluating the amount of the fully synthesized probes at respective matrix sites is also provided.

Abstract: Methods are disclosed for forming spatially addressable arrays of polynucleotides of known squence, by using blocking groups that prevent the incorporation of multiple nucleotides during each incorporation step.

Abstract: The invention relates to nucleic acids covalently coupled to electrodes via conductive oligomers. More particularly, the invention is directed to the site-selective modification of nucleic acids with electron transfer moieties and electrodes to produce a new class of biomaterials, and to methods of making and using them.

Abstract: The present invention provides materials and methods which may be used to evaluate one or more different probes and select probes that are optimized for sensitivity and specificity for a particular target. In particularly preferred embodiments, the methods and compositions of the invention can be used to evaluate polynucleotide probes having different nucleotide sequences. The methods and compositions thereby allow a user to select a polynucleotide probe, e.g., having a particular nucleotide sequence, that is optimized for sensitivity and/or for specificity for a particular target polynucleotide molecule. In particularly preferred embodiments, the methods and compositions can be used to evaluate a plurality of probes simultaneously, such as on a microarray. Probes evaluated according to the methods of the invention can be selected for and used to detect a variety molecules, including a variety of polynucleotides, such as genomic polynucleotides (e.g., genomic DNA) and genomic transcripts (e.g.

Abstract: There is used at least one probe array obtained by arraying particles having various probes, respectively, fixed thereon (probe particles) in a definite order in a holder. A plurality of capillaries or grooves packed with various kinds, respectively, of probe particles are arrayed in parallel, and one of particles contained in each capillary or groove is injected into another capillary or groove to produce a probe array in which the various kinds of probe particles are arrayed in a constant and definite order. Various fluorophore-labeled DNA's are measured at the same time by attaching various probes to particles, respectively, of different sizes. A probe array composed of various fixed DNA probes can easily be produced, and there can be provided a probe array for detecting various DNA's which is composed of various fixed arbitrary DNA probes.

Abstract: The present invention provides nano-scale devices, including electronic circuits, using DNA molecules as a support structure. DNA binding proteins are used to mask regions of the DNA as a material, such as a metal is coated onto the DNA. Included in the invention are DNA based transistors, capacitors, inductors and diodes. The present invention also provides methods of making integrated circuits using DNA molecules as a support structure. Methods are also included for making DNA based transistors, capacitors, inductors and diodes.

Abstract: The present invention relates to methods of identifying genes involved in memory formation. This is accomplished by performing a gene chip identification of those genes expressed during transcription-dependent memory formation but not during transcription-independent memory formation. A statistical analysis of the gene chip identification output yields a set of genes that are involved in transcription-dependent memory formation.

Abstract: The present invention relates to improved methods for probing of specific nucleic acids using circularizable probes designed such that they report the presence of a target sequence by allowing a detectable moiety to remain bound if an only if the probe has been cyclized in a target-dependent linking reaction. The invention may be used for distinction between sequence specific variations of nucleic acids.

Abstract: A method of detecting rpoB sequences of Mycobacterium tuberculosis present in a biological sample that includes steps of amplifying the M. Tuberculosis rpoB sequence in vitro in a nucleic acid amplification mixture that includes specific disclosed primer sequences, and detecting the amplified sequences by using probes that provide information by their specific hybridization to portions of the amplified nucleic acid is disclosed. Compositions for amplifying and detecting in vitro the rpoB sequences of M. Tuberculosis in a sample are disclosed.

Abstract: A system for the rapid characterization of multi-analyte fluids, in one embodiment, includes a light source, a sensor array, and a detector. The sensor array is formed from a supporting member into which a plurality of cavities may be formed. A series of chemically sensitive particles are, in one embodiment positioned within the cavities. The particles may be configured to produce a signal when a receptor coupled to the particle interacts with the analyte. Using pattern recognition techniques, the analytes within a multi-analyte fluid may be characterized.

Abstract: The present invention relates to parallel genotyping (or other sample analysis) of multiple patients by direct sample immobilization onto microspheres of an array. The patient beads can then be used in a variety of target analyte analyses.

Abstract: An apparatus for detecting an analyte in solution that has a suspended beam containing at least one microfluidic channel containing a capture ligand that bonds to or reacts with an analyte. The apparatus also includes at least one detector for measuring a change in the beam upon binding or reaction of the analyte. A method of making the suspended microfluidic channels is disclosed, as well as, a method of integrating the microfluidic device with conventional microfluidics having larger sample fluid channels.

Abstract: Described herein are RNA-protein fusion production methods which involve a high salt post-translational incubation step.

Abstract: The present invention relates to a probe for selecting ES cells, which characteristically contains one of DNAs having base sequences depicted in SEQ ID Nos; 1, 2, 3, 4, 5, 6, 7 and 8, or DNAs having base sequences depicted in SEQ ID Nos; 9, 11, 13, 15, 17, 19, 21, 23 and 41 and a screening method of ES cell using this probe. Preparation of a probe for selecting ES cells becomes feasible by identifying plural gene with ES cell-specific expressions (ECAT genes) and using the information of the base sequences of these gene groups. Efficient selection of ES cell enables supply of a large amount of ES cell expected to be applicable to regenerative medicine.

Abstract: The invention relates to polyfunctional polymer monolayers (polymer brushes) comprising a multitude of polymer chains attached to a surface, with each polymer chain comprising a multitude of units carrying at least on functional group which allows the interaction of the polymer chain with a sample molecule.

Abstract: A molecular detection chip including a metal oxide silicon-field effect transistor (MOSFET) on sidewalls of a micro-fluid channel and a molecular detection device including the molecular detection chip are provided. A molecular detection method, particularly, qualification methods for the immobilization of molecular probes and the binding of a target sample to the molecular probes, using the molecular detection device, and a nucleic acid mutation assay device and method are also provided. The formation of the MOSFET on the sidewalls of the micro-fluid channel makes easier to highly integrate a molecular detection chip. In addition, immobilization of probes directly on the surface of a gate electrode ensures the molecular detection chip to check for the immobilization of probes and coupling of a target molecule to the probes in situ.

Abstract: The present invention provides methods for detecting and identifying sequence variations in a nucleic acid sequence of interest using a detector primer. It has been found that the reduced efficiency of primer extension by DNA polymerases when the 3? end of a primer does not hybridize perfectly with the target can be adapted for use as a means for distinguishing or identifying the nucleotide in the target which is at the site where the diagnostic mismatch between the detector primer and the target occurs. The detector primer hybridizes to the sequence of interest and is extended with polymerase. The efficiency of detector primer extension is detected as an indication of the presence and/or identity of the sequence variation in the target. The inventive methods make use of nucleotide mismatches at or near the 3? end of the detector primer to discriminate between the nucleotide sequence of interest and a second nucleotide sequence which may occur at that same site in the target.

Abstract: An analysis device includes an electrode arrangement, a current/voltage provider, and a circuit analyzer. The electrode arrangement has an interdigitated electrode pair including a first electrode and a second electrode. Coupled to the electrode arrangement is a signal generator adapted to provide a signal (e.g., an alternating current or voltage) having a selected range of frequencies. The analyzer is coupled to the electrode arrangement and is operative to analyze an electrical parameter of the circuit as the signal is applied. An analytic method includes measuring changes in one or more parameters of the circuit over the range of frequencies. By such measurement, the device can determine whether a target moiety has been bound by a probe attached to the electrode(s). The device can also specifically identify the intermolecular system detected, i.e., by “finger-printing” the electrical response of each molecule or intermolecular complex.

Abstract: A method and apparatus of interrogating an addressable array unit, which includes a substrate, a light reflecting layer on a front side of the substrate, and a plurality of features on a front side of the array. The method may include, for each of multiple features, illuminating the feature simultaneously with reflected and non-reflected interrogating light. A light emitted from respective features is detected. Either or both, constructive interference of interrogating light at the features, or constructive interference of light emitted from the features, can be obtained to allow lowering of light power from the source, enhanced signal, or reduced noise, or combinations of the foregoing. High depth discrimination may also be obtained without the need for a confocal detection system with conventional pinhole.

Abstract: A reflective substrate is used to amplify the photon signal captured from overlying analyte domains containing photon emitters. The reflective substrate provides substantial desired signal amplification of the photon emissions from each domain via interference effects induced in the incident excitation and/or emission energies. A dielectric is interposed between the domains and the reflective surface, which has a thickness such that substantial destructive interference occurs with respect to emission photons or excitation photons or both at the attachment surface. When analyte domains have a three-dimensional structure such that a significant fraction of their volume extends at least ¼ wavelength above the attachment surface provided by the dielectric, substantial constructive signal amplification can take place of signals generated within the analyte domains.