The present teachings are directed to compositions, methods, and kits for amplifying target nucleic acids while reducing non-specific fluorescence and undesired amplification products, sometimes referred to as secondary amplification products or spurious side-products. The enzyme inhibitors disclosed herein comprise a nucleotide sequence and at least one quencher. Complexes comprising an enzyme inhibitor associated with an enzyme, wherein at least one enzymatic activity of the enzyme is inhibited, are also provided. Methods for amplifying a target nucleic acid while reducing undesired amplification products are disclosed, as are methods for reducing non-specific fluorescence. Kits for expediting the performance of certain disclosed methods are also provided.

The present teachings are directed to compositions, methods, and kits for amplifying target nucleic acids while reducing non-specific fluorescence and undesired amplification products, sometimes referred to as secondary amplification products or spurious side-products. The enzyme inhibitors disclosed herein comprise a nucleotide sequence and at least one quencher. Complexes comprising an enzyme inhibitor associated with an enzyme, wherein at least one enzymatic activity of the enzyme is inhibited, are also provided. Methods for amplifying a target nucleic acid while reducing undesired amplification products are disclosed, as are methods for reducing non-specific fluorescence. Kits for expediting the performance of certain disclosed methods are also provided.

A polynucleotide sequencing method comprises (i) removing a label and a blocking moiety from a blocked, labeled nucleotide incorporated into a copy polynucleotide strand that is complementary to at least a portion of a template polynucleotide strand; and (ii) washing the removed label and blocking moiety away from the copy strand with a wash solution comprising a first buffer comprising a scavenger compound. Removing the label and blocking moieties may comprise chemically removing the moieties. The first buffer may also comprise an antioxidant and may be used in a scanning buffer used during a nucleotide detection step.

A polynucleotide sequencing method comprises (i) removing a label and a blocking moiety from a blocked, labeled nucleotide incorporated into a copy polynucleotide strand that is complementary to at least a portion of a template polynucleotide strand; and (ii) washing the removed label and blocking moiety away from the copy strand with a wash solution comprising a first buffer comprising a scavenger compound. Removing the label and blocking moieties may comprise chemically removing the moieties. The first buffer may also comprise an antioxidant and may be used in a scanning buffer used during a nucleotide detection step.

Provided is a composition for preserving cell-free nucleic acids and/or cells in a biological sample and methods for use thereof. The composition comprises at least one volume excluding polymer, at least one osmotic agent and at least one enzyme inhibitor. The composition optionally further comprises at least one metabolic inhibitor. Further, provided is a kit comprising the composition, preferably in a blood collection tube, or the components of the composition.

Provided is a composition for preserving cell-free nucleic acids and/or cells in a biological sample and methods for use thereof. The composition comprises at least one volume excluding polymer, at least one osmotic agent and at least one enzyme inhibitor. The composition optionally further comprises at least one metabolic inhibitor. Further, provided is a kit comprising the composition, preferably in a blood collection tube, or the components of the composition.

A method for preserving and processing cell-free nucleic acids located within a blood sample is disclosed, wherein a blood sample containing cell-free nucleic acids is treated to reduce both blood cell lysis and nuclease activity within the blood sample. The treatment of the sample aids in increasing the amount of cell-free nucleic acids that can be identified and tested while maintaining the structure and integrity of the nucleic acids.

A method for preserving and processing cell-free nucleic acids located within a blood sample is disclosed, wherein a blood sample containing cell-free nucleic acids is treated to reduce both blood cell lysis and nuclease activity within the blood sample. The treatment of the sample aids in increasing the amount of cell-free nucleic acids that can be identified and tested while maintaining the structure and integrity of the nucleic acids.

Disclosed herein are novel methods and compositions for rapidly extracting and amplifying nucleic acids from a sample where the sample is combined with an extraction reagent comprising a reducing agent to form a mixture and incubating said mixture at ambient temperature for a period of time not exceeding 30 minutes to generate a nucleic acid extract. In certain embodiments of the method, the nucleic acid extract is subjected to a nucleic acid amplification reaction. In certain aspects, oligonucleotide primers specific for nucleic acids of Chlamydia species and/or Neisseria species are added prior to initiating the amplification reaction.

Disclosed herein are novel methods and compositions for rapidly extracting and amplifying nucleic acids from a sample where the sample is combined with an extraction reagent comprising a reducing agent to form a mixture and incubating said mixture at ambient temperature for a period of time not exceeding 30 minutes to generate a nucleic acid extract. In certain embodiments of the method, the nucleic acid extract is subjected to a nucleic acid amplification reaction. In certain aspects, oligonucleotide primers specific for nucleic acids of Chlamydia species and/or Neisseria species are added prior to initiating the amplification reaction.