A method for treating a solution including nucleic acid, comprising the steps of: arranging the solution on a first surface of a first base material having the first surface, which has a well defined by an electrode and a resist; and after arranging the solution on the first surface of the first base material, pressing the first base material and a second base material, which has a hydrophobic second surface, together so that the second surface of the second base material and the first surface of the first base material face each other.

A method for treating a solution including nucleic acid, comprising the steps of: arranging the solution on a first surface of a first base material having the first surface, which has a well defined by an electrode and a resist; and after arranging the solution on the first surface of the first base material, pressing the first base material and a second base material, which has a hydrophobic second surface, together so that the second surface of the second base material and the first surface of the first base material face each other.

Disclosed herein are highly multiplexed methods of detecting single target analytes, including complexes, with improved accuracy using a proximity binding assay and single molecule cycled detection.

Disclosed herein are highly multiplexed methods of detecting single target analytes, including complexes, with improved accuracy using a proximity binding assay and single molecule cycled detection.

This present disclosure provides methods and systems for measuring the concentration of multiple nucleic acid sequences in a sample. The nucleic acid sequences in the sample are simultaneously amplified, for example, using polymerase chain reaction (PCR) in the presence of an array of nucleic acid probes. The amount of amplicon corresponding to the multiple nucleic acid sequences can be measured in real-time during or after each cycle using a real-time microarray. The measured amount of amplicon produced can be used to determine the original amount of the nucleic acid sequences in the sample. Also provided herein are biosensor arrays, systems and methods for affinity based assays that are able to simultaneously obtain high quality measurements of the binding characteristics of multiple analytes, and that are able to determine the amounts of those analytes in solution. The present disclosure also provides a fully integrated bioarray for detecting real-time characteristics of affinity based assays.

This present disclosure provides methods and systems for measuring the concentration of multiple nucleic acid sequences in a sample. The nucleic acid sequences in the sample are simultaneously amplified, for example, using polymerase chain reaction (PCR) in the presence of an array of nucleic acid probes. The amount of amplicon corresponding to the multiple nucleic acid sequences can be measured in real-time during or after each cycle using a real-time microarray. The measured amount of amplicon produced can be used to determine the original amount of the nucleic acid sequences in the sample. Also provided herein are biosensor arrays, systems and methods for affinity based assays that are able to simultaneously obtain high quality measurements of the binding characteristics of multiple analytes, and that are able to determine the amounts of those analytes in solution. The present disclosure also provides a fully integrated bioarray for detecting real-time characteristics of affinity based assays.

The present disclosure provides methods and systems for sequencing nucleic acid molecules. Methods may include sequencing double-stranded nucleic acids or single-stranded nucleic acids. Sequencing may include the use of nucleotides coupled to electrostatic moieties. The electrostatic moieties may be detected by a sensor array. The electrostatic moieties may be reversible electrostatic moieties that are cleaved from the nucleic acid molecule after incorporation of the nucleotide. The electrostatic moieties may be irreversible electrostatic moieties. Nucleotides comprising irreversible electrostatic moieties may be incorporated into the nucleic acid molecule, detected by the sensor array, and exchanged for non-detectable nucleotides.

The present disclosure provides methods and systems for sequencing nucleic acid molecules. Methods may include sequencing double-stranded nucleic acids or single-stranded nucleic acids. Sequencing may include the use of nucleotides coupled to electrostatic moieties. The electrostatic moieties may be detected by a sensor array. The electrostatic moieties may be reversible electrostatic moieties that are cleaved from the nucleic acid molecule after incorporation of the nucleotide. The electrostatic moieties may be irreversible electrostatic moieties. Nucleotides comprising irreversible electrostatic moieties may be incorporated into the nucleic acid molecule, detected by the sensor array, and exchanged for non-detectable nucleotides.

The invention relates to methods of detecting a genetic variation in a genetic sample from a subject using labeled probes and counting the number of labels in the probes. The invention also relates to manufacturing and using molecular arrays and analytical approaches based on single molecule detection techniques.

The invention relates to methods of detecting a genetic variation in a genetic sample from a subject using labeled probes and counting the number of labels in the probes. The invention also relates to manufacturing and using molecular arrays and analytical approaches based on single molecule detection techniques.