Plasmonics-active nanoprobes are provided for detection of target biomolecules including nucleic acids, proteins, and small molecules. The nucleic acids that can be detected include RNA, DNA, mRNA, microRNA, and small nucleotide polymorphisms (SNPs). The nanoproprobes can be used in vito in sensitive detection methods for diagnosis of diseases and disorders including cancer. Multiplexing can be performed using the nanoprobes such that multiple targets can be detected simultaneously in a single sample. The methods of use of the nanoprobes include detection by a visible color change. The nanoprobes can be used in vivo for treatment of undesireable cells in a subject.

A device including a transparent layer defining a surface exposed to a flow volume and to secure a target polynucleotide template and a detector structure secured to the transparent layer and including a plurality of detectors to detect a signal emitted during nucleotide incorporation along the target polynucleotide template.

A device including a transparent layer defining a surface exposed to a flow volume and to secure a target polynucleotide template and a detector structure secured to the transparent layer and including a plurality of detectors to detect a signal emitted during nucleotide incorporation along the target polynucleotide template.

Provided herein are compositions and systems for use in polymerase-dependent, nucleotide transient-binding methods. The methods are useful for deducing the sequence of a template nucleic acid molecule and single nucleotide polymorphism (SNP) analyses. The methods rely on the fact that the polymerase transient-binding time for a complementary nucleotide is longer compared to that of a non-complementary nucleotide. The labeled nucleotides transiently-binds the polymerase in a template-dependent manner, but does not incorporate. The methods are conducted under any reaction condition that permits transient binding of a complementary or non-complementary nucleotide to a polymerase, and inhibits nucleotide incorporation.

Provided herein are compositions and systems for use in polymerase-dependent, nucleotide transient-binding methods. The methods are useful for deducing the sequence of a template nucleic acid molecule and single nucleotide polymorphism (SNP) analyses. The methods rely on the fact that the polymerase transient-binding time for a complementary nucleotide is longer compared to that of a non-complementary nucleotide. The labeled nucleotides transiently-binds the polymerase in a template-dependent manner, but does not incorporate. The methods are conducted under any reaction condition that permits transient binding of a complementary or non-complementary nucleotide to a polymerase, and inhibits nucleotide incorporation.

Nucleic acid sequencing methods and systems, the systems including nanochannel chip including: a nanochannel formed in an upper surface of the nanochannel chip and; a roof covering the nanochannel and comprising nanopores and a field enhancement structure; and a barrier disposed in the nanochannel. The method including: introducing a buffer solution including long-chain nucleic acids to the nanochannel chip; applying a voltage potential across the nanochannel chip to drive the nucleic acids through the nanochannel, towards the barrier, and to translocate the nucleic acids through nanopores adjacent to the barrier, such that bases of each of the nucleic acids pass through the field enhancement structure one base at a time and emerge onto an upper surface of the roof; detecting the Raman spectra of the bases of the nucleic acids as each base passes through the electromagnetic-field enhancement structure; and sequencing the nucleic acids based on the detected Raman spectra.

The present invention relates to a diagnostic kit for sepsis, comprising: a first core gold nanoparticle having a target capture oligonucleotide coupled thereto, the target capture oligonucleotide binding complementarily to a portion of a sepsis pathogen-specific genome; and a second core gold nanoparticle to which a target capture oligonucleotide having a Raman-active molecule coupled to one end thereof is coupled via the other end thereof, the target capture oligonucleotide including a sequence complementary to a portion of the sepsis pathogen-specific genome which does not overlap with, but is successive to the portion for the first gold nanoparticle, and a method for diagnosis of sepsis, using the same.

The present invention relates to a diagnostic kit for sepsis, comprising: a first core gold nanoparticle having a target capture oligonucleotide coupled thereto, the target capture oligonucleotide binding complementarily to a portion of a sepsis pathogen-specific genome; and a second core gold nanoparticle to which a target capture oligonucleotide having a Raman-active molecule coupled to one end thereof is coupled via the other end thereof, the target capture oligonucleotide including a sequence complementary to a portion of the sepsis pathogen-specific genome which does not overlap with, but is successive to the portion for the first gold nanoparticle, and a method for diagnosis of sepsis, using the same.

A method for optical super-multiplexing using polyynes to provide enhanced images from stimulated Raman microscopy is disclosed. In some exemplary embodiments, the polyynes are organelle-targeted or spectral barcoded. Imaging can be enhanced by using the polyynes to image whole live cells or specific organelles within live cells. The polyynes can also be used in optical data storage (i.e., encoding) and identification (i.e., decoding) applications.

A method for optical super-multiplexing using polyynes to provide enhanced images from stimulated Raman microscopy is disclosed. In some exemplary embodiments, the polyynes are organelle-targeted or spectral barcoded. Imaging can be enhanced by using the polyynes to image whole live cells or specific organelles within live cells. The polyynes can also be used in optical data storage (i.e., encoding) and identification (i.e., decoding) applications.