Abstract: The present invention generally relates to spatial and structural genomic analysis compositions, which can be used for the mapping of chromosomes and structural analyses of chromosomal rearrangements, including the entire chromosome, as well as specific portions or regions of interest of the chromosomes. In some embodiments, multiple portions of the genome can be distinguished, for instance, using a first detection entity and a second detection entity different from the first detection entity. The detection entities may be immobilized relative to oligonucleotides, which may be selected to bind to different locations within the chromosome. For instance, the oligonucleotides may be at least substantially complementary to the chromosome, e.g., substantially complementary to a specific location of the chromosome.

Abstract: The present invention generally relates to spatial and structural genomic analysis compositions, which can be used for the mapping of chromosomes and structural analyses of chromosomal rearrangements, including the entire chromosome, as well as specific portions or regions of interest of the chromosomes. In some embodiments, multiple portions of the genome can be distinguished, for instance, using a first detection entity and a second detection entity different from the first detection entity. The detection entities may be immobilized relative to oligonucleotides, which may be selected to bind to different locations within the chromosome. For instance, the oligonucleotides may be at least substantially complementary to the chromosome, e.g., substantially complementary to a specific location of the chromosome.

Abstract: A computer-implemented method for viewing experimental data is provided. In certain embodiments the method comprises: a) inputting genomic array data and cytogenetic data into a computer memory; and b) producing a graphical user interface comprising: i) a chromosomal map of the genomic array data comprising a first positional indicator that indicates a position on the chromosomal map; and ii) a cytogenetic map of the cytogenetic data comprising a second positional indicator that indicates a position on the cytogenetic map.

Abstract: The present invention generally relates to spatial and structural genomic analysis compositions, which can be used for the mapping of chromosomes and structural analyses of chromosomal rearrangements, including the entire chromosome, as well as specific portions or regions of interest of the chromosomes. In some embodiments, multiple portions of the genome can be distinguished, for instance, using a first detection entity and a second detection entity different from the first detection entity. The detection entities may be immobilized relative to oligonucleotides, which may be selected to bind to different locations within the chromosome. For instance, the oligonucleotides may be at least substantially complementary to the chromosome, e.g., substantially complementary to a specific location of the chromosome.

Abstract: A computer-implemented method for viewing experimental data is provided. In certain embodiments the method comprises: a) inputting genomic array data and cytogenetic data into a computer memory; and b) producing a graphical user interface comprising: i) a chromosomal map of the genomic array data comprising a first positional indicator that indicates a position on the chromosomal map; and ii) a cytogenetic map of the cytogenetic data comprising a second positional indicator that indicates a position on the cytogenetic map.

Abstract: The present invention generally relates to competitive oligonucleotides and, in some embodiments, to competitive oligonucleotides for use in comparative genomic hybridization (CGH) and related techniques. One aspect is generally directed to a blocking composition constructed and arranged to be used in an assay of a nucleic acid. The blocking composition may comprise oligonucleotides comprising sequences selected to hybridize to the nucleic acid used in the assay. Another aspect is generally directed to performing CGH assays and similar techniques on genomic DNA, in the absence of a Cot-1 fraction, such that the genomic DNA does not substantially cross-hybridize. Yet other aspects of the invention are directed to devices or kits for making or using competitive oligonucleotides, methods of promoting such competitive oligonucleotides, or the like.

Abstract: A multiple array substrate having multiple assay chambers, each assay chamber containing one or more arrays. The assay chambers include a form-in-place gasket between a substrate and a cover. Methods of forming such multiple array substrates are described. The assay chambers may further be associated with an analysis site for analyzing a sample solution contained within the assay chamber. Each assay chamber is in fluid communication with a port, and the ports are positioned in a spatial format adapted to interface to standard laboratory equipment for handling multiple fluids in parallel.

Abstract: A computer-implemented method for viewing experimental data is provided. In certain embodiments the method comprises: a) inputting genomic array data and cytogenetic data into a computer memory; and b) producing a graphical user interface comprising: i) a chromosomal map of the genomic array data comprising a first positional indicator that indicates a position on the chromosomal map; and ii) a cytogenetic map of the cytogenetic data comprising a second positional indicator that indicates a position on the cytogenetic map.

Abstract: Methods and articles for analyzing nucleotide sequences of nucleic acid molecules, e.g., using multiple probes per spot of an array, are described. In some embodiments, the methods and articles can reduce the numbers of arrays necessary to probe regions of interest in a biological sample, and/or increase the resolution at which biological events are probed. In some cases, these methods exploit the vertical aspect of an array in order to decrease the number of arrays or spots required for an assay. These probes may be in the form of compound probes, which comprise at least first and second probes, including first and second nucleotide sequences capable of hybridizing to first and second target nucleotide sequences, respectively, in a nucleic acid molecule of interest.

Abstract: A method and apparatus for fabricating an array of biopolymers on a substrate using a biopolymer or biomonomer fluid, and using a dispensing head. The head has a reservoir chamber and at least one jet which can dispense droplets onto a substrate. The jet includes a capillary delivery chamber communicating with the reservoir chamber, which delivery chamber has an orifice. The jet further includes an ejector which, when activated, causes a droplet to be ejected from the orifice. The method includes loading the head by positioning the head with the orifice adjacent and facing a biomonomer or biopolymer fluid, and providing a load pressure to the reservoir chamber. The load pressure is sufficiently negative such that the fluid is drawn into the reservoir chamber through the orifice and delivery chamber, while simultaneously being insufficient to result in ambient atmosphere entering the delivery chamber through the orifice once the head has been loaded and no further fluid is facing and adjacent the orifice.

Abstract: The present invention generally relates to competitive oligonucleotides and, in some embodiments, to competitive oligonucleotides for use in comparative genomic hybridization (CGH) and related techniques. One aspect is generally directed to a blocking composition constructed and arranged to be used in an assay of a nucleic acid. The blocking composition may comprise oligonucleotides comprising sequences selected to hybridize to the nucleic acid used in the assay. Another aspect is generally directed to performing CGH assays and similar techniques on genomic DNA, in the absence of a Cot-1 fraction, such that the genomic DNA does not substantially cross-hybridize. Yet other aspects of the invention are directed to devices or kits for making or using competitive oligonucleotides, methods of promoting such competitive oligonucleotides, or the like.

Abstract: A method of fabricating an addressable array of biopolymer probes on a substrate according to a target array pattern using a deposition apparatus, and a deposition apparatus which can execute the method and computer program products for the apparatus. The deposition apparatus which, when operated according to a target drive pattern based on nominal operating parameters of the apparatus, provides the probes on the substrate in the target array pattern. The method includes examining at least one operating parameter for an error from a nominal value which error will result in use of the target drive pattern producing a discrepancy between the target array pattern and an actual array pattern deposited. When an error is detected deriving, based on the error, a corrected drive pattern different from the target drive pattern such that use of the corrected drive pattern results in a reduced discrepancy between the target and actual array patterns.

Abstract: An apparatus for mixing fluids comprises a housing having at least a portion of its interior, for example, a channel, with capillary dimensions and at least one structural member in the interior adjacent an end of the channel. The dimensions of and placement of the structural member are sufficient such that intermittent application of centrifugal force to the interior of the housing causes movement of the fluid therein. The housing may comprise a mixing chamber or area that is in fluid communication with the interior. The apparatus may comprise a mechanism adapted to generate centrifugal force within the housing to cause movement of fluid in the interior of the housing without exit of fluid therefrom.

Abstract: A method, apparatus, and computer program products for fabricating multiple chemical arrays on a substrate, each array having multiple rows of feature locations with arrays of different sets being arranged in a sideways orientation with respect to the rows. The method includes dispensing drops from a drop dispensing head onto the substrate while maintaining a gap between the head and substrate and moving them relative to one another along a path so as to fabricate the arrays. The path for the relative moving includes moving the head in a direction along the rows of a first array set then moving the head in an opposite direction along the rows of a second array set. This pattern is repeated with the second array set of an earlier cycle being the first array set of a later cycle.

Abstract: A method of fabricating an addressable array of chemical probes at respective feature locations on a substrate surface. The method may use a deposition apparatus with a substrate unit which includes the substrate and with a drop deposition unit which includes a drop deposition head. Such an apparatus when operated according to a target drive pattern based on nominal operating parameters of the apparatus provides the probes on the substrate surface in the target array pattern. The method may include depositing at least one drop from the head unit onto the substrate surface. A fiducial on the substrate unit is optionally viewed from a sensor. A deposited drop on the substrate surface is viewed from a sensor. An actual position of the viewed deposited drop may be determined relative to a fiducial on the substrate unit, based on the views of the fiducial and deposited drop. An error is determined based on any difference between the actual and target positions.

Abstract: Methods are disclosed for synthesizing a plurality of compounds on the surface of supports. The synthesis comprises a series of cycles of steps in which reagents for conducting the synthesis are deposited on the surface of the support to form the chemical compounds. At least one physical parameter of the deposition varies between cycles The method comprises conducting the synthesis in at least two sets of cycles, arbitrarily designated as a first set and a second set. Each cycle comprises at least one step of depositing reagents on a surface by means of droplet dispensing elements that traverse the surface of the support. At least one, and desirably all, of the following deposition parameters are employed as indicated: The number of times of repetition for a step of depositing reagents in at least one cycle of the second set is less than the number of times of repetition for a corresponding step in at least one cycle of the first set.

Abstract: Methods and apparatus for delivering a plurality of different biological materials onto discrete locations on a receiving surface, as for example to fabricate an array of different biological materials. The apparatus and methods may include a plurality of orifices in an orifice member, at least six delivery chambers each in fluid conducting relationship with at least one of the orifices, a plurality of reservoirs each in fluid communication with at least one of the delivery chambers, means associated with each orifice for propelling fluid through the associated orifice from the delivery chamber that is in fluid conducting relationship with the orifice, and a vent for commonly venting at least two of the reservoirs. In some embodiments the chambers and reservoirs are loaded with fluids containing selected biomolecules by drawing the selected fluids into the chambers through the orifices; in other embodiments the fluids are introduced into the reservoirs.

Abstract: A method is described for removing residue from a fluid deposited on the interior surface of an inkjet printhead after the printhead has contained or dispensed the fluid at least once. The method makes use of a reverse flushing technique optionally used in combination with sonication. A cleaning station for flushing an inkjet printhead with a wash fluid, rinse fluid, and/or inert gas is provided as well.

Abstract: A drop deposition apparatus, and a method and computer program products using the drop deposition apparatus, for fabricating at least one addressable array of biopolymers on a substrate. The drop deposition apparatus has a drop dispenser unit and a sensing element. The method comprises includes for each of multiple addresses, dispensing droplets carrying the biopolymers or biopolymer precursors from a drop dispenser unit onto the sensing element, and onto the substrate so as to fabricate the array. Electrical signals resulting from dispensed droplets striking the sensing element are detected. A performance characteristic of the deposition apparatus is evaluated based on the detected signals.

Abstract: A method and apparatus for fabricating an array of biopolymers on a substrate using a biopolymer or biomonomer fluid, and using a dispensing head. The head has a reservoir chamber and at least one jet which can dispense droplets onto a substrate. The jet includes a capillary delivery chamber communicating with the reservoir chamber, which delivery chamber has an orifice. The jet further includes an ejector which, when activated, causes a droplet to be ejected from the orifice. The method includes loading the head by positioning the head with the orifice adjacent and facing a biomonomer or biopolymer fluid, and providing a load pressure to the reservoir chamber. The load pressure is sufficiently negative such that the fluid is drawn into the reservoir chamber through the orifice and delivery chamber, while simultaneously being insufficient to result in ambient atmosphere entering the delivery chamber through the orifice once the head has been loaded and no further fluid is facing and adjacent the orifice.