There is disclosed a method for whole genome amplification and analysis of multiple target molecules in a biological sample including genomic DNA and target molecules comprising the steps of contacting the biological sample with at least one binding agent, directed to at least one of the target molecules, conjugated with a tagged oligonucleotide, which comprises a binding-agent barcode sequence (BAB) and a unique molecular identifier sequence (UMI); carrying out a separating step to selectively remove unbound binding agent thus obtaining a labeled biological sample; simultaneously carrying out on the labeled biological sample a whole genome amplification and an amplification of the tagged oligonucleotide; preparing a massively parallel sequencing library from the amplified tagged oligonucleotide; sequencing the massively parallel sequencing library; retrieving the sequences of the BAB and UMI from each sequencing read; counting the number of distinct UMI for each binding agent.

There is disclosed a method for whole genome amplification and analysis of multiple target molecules in a biological sample including genomic DNA and target molecules comprising the steps of contacting the biological sample with at least one binding agent, directed to at least one of the target molecules, conjugated with a tagged oligonucleotide, which comprises a binding-agent barcode sequence (BAB) and a unique molecular identifier sequence (UMI); carrying out a separating step to selectively remove unbound binding agent thus obtaining a labeled biological sample; simultaneously carrying out on the labeled biological sample a whole genome amplification and an amplification of the tagged oligonucleotide; preparing a massively parallel sequencing library from the amplified tagged oligonucleotide; sequencing the massively parallel sequencing library; retrieving the sequences of the BAB and UMI from each sequencing read; counting the number of distinct UMI for each binding agent.

Sized-based detection techniques for detection of bio-nanoparticles are described. Detection nanoparticles and methods of forming the detection nanoparticles that can be utilized in the techniques are described. Detection nanoparticles can include modified bacteriophage that express a linking agent for a specific binding agent. Detection nanoparticles can bind a functional bio-nanoparticle with high specificity through specific binding of one or more entities unique to the functional bio-nanoparticle of interest. A detection nanoparticle can target an entity of a bio-nanoparticle that is relevant to its function, and as such, the methods can provide improvements in detection of complete and functional bio-nanoparticles. Size-based detection regimes can include particle displacement measurement techniques based upon Brownian motion.

Sized-based detection techniques for detection of bio-nanoparticles are described. Detection nanoparticles and methods of forming the detection nanoparticles that can be utilized in the techniques are described. Detection nanoparticles can include modified bacteriophage that express a linking agent for a specific binding agent. Detection nanoparticles can bind a functional bio-nanoparticle with high specificity through specific binding of one or more entities unique to the functional bio-nanoparticle of interest. A detection nanoparticle can target an entity of a bio-nanoparticle that is relevant to its function, and as such, the methods can provide improvements in detection of complete and functional bio-nanoparticles. Size-based detection regimes can include particle displacement measurement techniques based upon Brownian motion.

Integrated devices that include a sample preparation component integrated with a detection component are disclosed. The sample preparation component may be a digital microfluidics module or a surface acoustic wave module which modules are used for combing a sample droplet with a reagent droplet and for performing additional sample preparation step leading to a droplet that contains beads/particles/labels that indicate presence or absence of an analyte of interest in the sample. The beads/particles/labels may be detected by moving the droplet to the detection component of the device, which detection component includes an array of wells. The detection modules disclosed here can be used for detecting analytes of interest which analytes may have been enriched by amplification, isolation, or other techniques.

Integrated devices that include a sample preparation component integrated with a detection component are disclosed. The sample preparation component may be a digital microfluidics module or a surface acoustic wave module which modules are used for combing a sample droplet with a reagent droplet and for performing additional sample preparation step leading to a droplet that contains beads/particles/labels that indicate presence or absence of an analyte of interest in the sample. The beads/particles/labels may be detected by moving the droplet to the detection component of the device, which detection component includes an array of wells. The detection modules disclosed here can be used for detecting analytes of interest which analytes may have been enriched by amplification, isolation, or other techniques.

Described herein are synthetic methods for producing sequence-specific RNA oligonucleotides that eliminate impurities produced in prior art methods. In one aspect, an end-protected capture DNA complementary to a portion of the product RNA is employed. In another aspect, the template DNA is covalently or noncovalently linked to the RNA polymerase, either directly or through the use of a nontemplate DNA. In a third aspect, a flow chamber is employed. All of the methods can be used in combination.

Described herein are synthetic methods for producing sequence-specific RNA oligonucleotides that eliminate impurities produced in prior art methods. In one aspect, an end-protected capture DNA complementary to a portion of the product RNA is employed. In another aspect, the template DNA is covalently or noncovalently linked to the RNA polymerase, either directly or through the use of a nontemplate DNA. In a third aspect, a flow chamber is employed. All of the methods can be used in combination.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address one or more issues associated with the stability and/or size of nucleic acid structures such as rolling circle amplification products in the biological sample.

The present disclosure in some aspects relates to methods and compositions for accurately detecting and quantifying multiple analytes present in a biological sample. In some aspects, the methods and compositions provided herein address one or more issues associated with the stability and/or size of nucleic acid structures such as rolling circle amplification products in the biological sample.