A process for pre-concentration and detection of at least one single-stranded nucleic acid target molecule, the process comprising the steps of generating a flow of liquid comprising at least one magnetic nanoparticle in a micro-channel and a plurality of single-stranded nucleic acid probe molecules attached to the nanoparticle, generating an alternating magnetic field in the part of the micro-channel using an electromagnet, the magnetic field having an intensity and frequency that are suitable for causing magnetic hyperthermia of the nanoparticles so as to cause denaturing of the duplex formed by the single-stranded nucleic acid target molecule and the single-stranded nucleic acid probe molecule, and detecting the single-stranded target molecule dispersed in the liquid.

Provided herein, in some embodiments, are methods, compositions and kits for large-scale production of long single-stranded DNA in solution.

Provided herein, in some embodiments, are methods, compositions and kits for large-scale production of long single-stranded DNA in solution.

Systems and methods for light based heating of light absorbing sources for modification of nucleic acids through fast thermal cycling of polymerase chain reaction are provided. The system includes a polymeric fluidic device comprising one or more reaction wells. A first light absorbing material is disposed on a first support to define a reaction well and first and second ports are coupled to the reaction wells. The first and second ports are configured to allow input of a fluidic sample into the reaction well. A lyophilized reagent is pre-loaded in the reaction well. A light source is configured to illuminate the first light absorbing material. A first portion of light illuminated onto the first light absorbing material is absorbed into the first light absorbing material and is configured to elevate the temperature of the first light absorbing material to heat the fluidic sample within the reaction well.

Systems and methods for light based heating of light absorbing sources for modification of nucleic acids through fast thermal cycling of polymerase chain reaction are provided. The system includes a polymeric fluidic device comprising one or more reaction wells. A first light absorbing material is disposed on a first support to define a reaction well and first and second ports are coupled to the reaction wells. The first and second ports are configured to allow input of a fluidic sample into the reaction well. A lyophilized reagent is pre-loaded in the reaction well. A light source is configured to illuminate the first light absorbing material. A first portion of light illuminated onto the first light absorbing material is absorbed into the first light absorbing material and is configured to elevate the temperature of the first light absorbing material to heat the fluidic sample within the reaction well.

Some embodiments presented in this disclosure concern an Automated Tissue Dissection (ATD) System. An ATD system is a one stop, and potentially low-cost, system to perform dissections on a substrate from pathologist digital mark or pen mark on the substrate using non-contact and/or mechanical method to extract a Formalin-Fixed Paraffin-Embedded (FFPE) tissue sample with: (a) only the ROI or ROIs as area to be saved; and (b) remove or decompose nucleic acid content in the region of no interest (RONI) and collect all tissue sample from a standard microscope substrate into a specific container.

The present invention relates to methods for the identification of methylated cytosines in a population of double stranded DNA molecules. The invention also relates to adapters and kits for synthesizing said adapters as well as to double stranded DNA libraries obtained by the methods of the invention.

The present invention relates to methods for the identification of methylated cytosines in a population of double stranded DNA molecules. The invention also relates to adapters and kits for synthesizing said adapters as well as to double stranded DNA libraries obtained by the methods of the invention.

The present invention relates to methods for the identification of methylated cytosines in a population of double stranded DNA molecules. The invention also relates to adapters and kits for synthesizing said adapters as well as to double stranded DNA libraries obtained by the methods of the invention.

The present invention relates to methods for the identification of methylated cytosines in a population of double stranded DNA molecules. The invention also relates to adapters and kits for synthesizing said adapters as well as to double stranded DNA libraries obtained by the methods of the invention.