Abstract: Methods and systems are provided herein for selecting an affinity reagent which binds a desired peptide epitope in a plurality of sequence contexts. The method relies on obtaining a peptide library, each peptide having the sequence ?X?, wherein X is the desired peptide epitope, wherein each of ? and ? comprise an amino acid, using the peptide library to select an affinity reagent.

Abstract: Methods and systems are provided herein for selecting an affinity reagent which binds a desired peptide epitope in a plurality of sequence contexts. The method relies on obtaining a peptide library, each peptide having the sequence ?X?, wherein X is the desired peptide epitope, wherein each of ? and ? comprise an amino acid, using the peptide library to select an affinity reagent.

Abstract: Methods and systems are provided herein for selecting an affinity reagent which binds a desired peptide epitope in a plurality of sequence contexts. The method relies on obtaining a peptide library, each peptide having the sequence ?X?, wherein X is the desired peptide epitope, wherein each of ? and ? comprise an amino acid, using the peptide library to select an affinity reagent.

Abstract: The present application relates to a method for analyzing a molecular target in a sample. The method involves providing an aptamer, wherein the aptamer is a high affinity binding partner to at least a portion of the molecular target in the sample. The aptamer is contacted with the sample containing the molecular target under conditions effective for the molecular target and aptamer to bind to each other. The molecular target is separated from the sample to form a molecular target enriched sample. The separated molecular target of the enriched sample is then analyzed.

Abstract: The present invention relates to a microcolumn device for selecting nucleic acid aptamers for single and multiple target molecules, as well as a method for making the microcolumn device. The present invention also relates to a system for selecting nucleic acid aptamers for single and multiple target molecules. The present invention further relates to methods of using the microcolumn device for selecting nucleic acid aptamers for multiple target molecules. Kits that include one or more microcolumn device and/or system of the present invention are also disclosed.

Abstract: The present invention is directed to a method for detecting an interaction between a ribonucleic acid (RNA) molecule and a second molecule. This method involves providing a nucleic acid construct that contains a promoter sequence, a nucleotide sequence encoding the RNA molecule, and an RNA polymerase blocking site. The nucleotide sequence encoding the RNA molecule is transcribed in vitro to produce an RNA transcript corresponding to the RNA molecule. Transcription is halted by the RNA polymerase blocking site under conditions effective for the RNA transcript to remain tethered to the nucleic acid construct. The tethered RNA transcript is contacted with the second molecule and any interaction between the tethered RNA transcript and the second molecule is detecting and identified based on said contacting.

Abstract: The present invention generally relates to microcolumn affinity chromatography devices, systems that include the microcolumn affinity chromatography devices of the present disclosure, methods of using the devices and the systems of the present disclosure, and methods of making the devices and the systems of the present disclosure. In certain embodiments, the microcolumn affinity chromatography device is suitable for conducting affinity chromatography in multiple microcolumns in parallel and/or in series.

Abstract: The present invention relates to a method for selecting an aptamer for a target molecule. The method involves providing a random oligonucleotide library comprising a plurality of unique random sequence oligonucleotides; providing a target mixture comprising at least one target molecule; and subjecting the random oligonucleotide library and the target mixture to at least one round of an aptamer isolation protocol to yield at least one aptamer for the target molecule, wherein a round of the aptamer isolation protocol comprises at least one selection cycle followed by an amplification cycle. The present invention also relates to systems and devices for implementing or performing the method of the present invention. The present invention further relates to using the method to isolate aptamers for high-throughput sequencing analysis and other aptamer analysis protocols.

Abstract: The present invention relates to a microcolumn device for selecting nucleic acid aptamers for single and multiple target molecules, as well as a method for making the microcolumn device. The present invention also relates to a system for selecting nucleic acid aptamers for single and multiple target molecules. The present invention further relates to methods of using the microcolumn device for selecting nucleic acid aptamers for multiple target molecules. Kits that include one or more microcolumn device and/or system of the present invention are also disclosed.

Abstract: The present invention generally relates to microcolumn affinity chromatography devices, systems that include the microcolumn affinity chromatography devices of the present disclosure, methods of using the devices and the systems of the present disclosure, and methods of making the devices and the systems of the present disclosure. In certain embodiments, the microcolumn affinity chromatography device is suitable for conducting affinity chromatography in multiple microcolumns in parallel and/or in series.

Abstract: The present invention is directed to a method for detecting an interaction between a ribonucleic acid (RNA) molecule and a second molecule. This method involves providing a nucleic acid construct that contains a promoter sequence, a nucleotide sequence encoding the RNA molecule, and an RNA polymerase blocking site. The nucleotide sequence encoding the RNA molecule is transcribed in vitro to produce an RNA transcript corresponding to the RNA molecule. Transcription is halted by the RNA polymerase blocking site under conditions effective for the RNA transcript to remain tethered to the nucleic acid construct. The tethered RNA transcript is contacted with the second molecule and any interaction between the tethered RNA transcript and the second molecule is detecting and identified based on said contacting.