Capture mixtures and activated capture mixtures are provided that are useful for nucleic acid separation and purification are provided. The mixtures comprise lithium lauryl sulfate, lithium hydroxide, a zwitterionic sulfonic acid buffering agent, and optionally, proteinase K, capture probes comprising a first specific binding partner (SBP), and a second specific binding partner immobilized to a solid support. Related combinations, methods, uses, and kits, are also provided.

Capture mixtures and activated capture mixtures are provided that are useful for nucleic acid separation and purification are provided. The mixtures comprise lithium lauryl sulfate, lithium hydroxide, a zwitterionic sulfonic acid buffering agent, and optionally, proteinase K, capture probes comprising a first specific binding partner (SBP), and a second specific binding partner immobilized to a solid support. Related combinations, methods, uses, and kits, are also provided.

A method for performing a magnetic separation procedure that includes transporting a receptacle containing a fluid medium to a first location of a system, where the fluid medium contains both a sample material and a suspension of magnetically-responsive solid supports. At the first location, the fluid medium is exposed to a first magnetic field for a first dwell period, thereby isolating the solid supports within the receptacle, where no portion of the fluid medium is removed from the receptacle at the first location. The receptacle is then transported from the first location to a second location of the system, where the fluid medium is exposed to a second magnetic field for a second dwell period. Following the second dwell period, at least a portion of the fluid medium is removed from the receptacle. A suspension fluid is then dispensed into the receptacle, and the contents of the receptacle are agitated to suspend the solid supports within the suspension fluid.

Methods are provided for separating magnetically responsive beads from a droplet in a droplet actuator. Droplet operations electrodes and a magnet are arranged in a droplet actuator to manipulate a bead-containing droplet and position it relative to a magnetic field region that attracts the magnetically responsive beads. The droplet operations electrodes are operated to control the droplet shape and transport it away from the magnetic field region to form a concentration of beads in the droplet. The continued transport of the droplet away from the magnetic field causes the concentration of beads to break away from the droplet to yield a small, concentrated bead-containing droplet immobilized by the magnet.

Embodiments of the disclosure are drawn to apparatuses, systems, and methods for enrichment and separation of nucleic acids by size. A sample may include a mixture of nucleic acids of various sizes, and the nucleic acids of interest may be below a particular size threshold. An example enrichment method may include mixing the sample with a first substrate (e.g., magnetic beads). The method may include separating nucleic acids above a first size threshold form a remainder of the sample using the first substrate. The method may include mixing the nucleic acids in the remainder of the sample (e.g., nucleic acids below’ the size threshold) with a second substrate and recovering the nucleic acids below the first size threshold from the second substrate.

Embodiments of the disclosure are drawn to apparatuses, systems, and methods for enrichment and separation of nucleic acids by size. A sample may include a mixture of nucleic acids of various sizes, and the nucleic acids of interest may be below a particular size threshold. An example enrichment method may include mixing the sample with a first substrate (e.g., magnetic beads). The method may include separating nucleic acids above a first size threshold form a remainder of the sample using the first substrate. The method may include mixing the nucleic acids in the remainder of the sample (e.g., nucleic acids below’ the size threshold) with a second substrate and recovering the nucleic acids below the first size threshold from the second substrate.

In some examples, a CSS-MBs includes a solid magnetic core, a first shell material which surrounds the solid magnetic core and a second shell material which surrounds the first shell material. The first shell material may be a protective layer. The first shell material may include an inert carbon material. The second shell material may be have surface chemistry which allows for selective interaction of the CSS-MB with certain biomolecules under various buffer conditions.

A method for extracting nucleic acids includes mixing a biological sample with a solid-phase substrate to produce a sample fluid. The nucleic acids in the sample fluid bind to the solid-phase substrate. The method also includes flowing the sample fluid in a fluid conduit to a trapping site. The trapping site may include a chamber. The method may further include applying a magnetic field to trap the solid-phase substrate of the sample fluid flowing through the fluid conduit at the trapping site. The method further includes flowing a wash buffer through the fluid conduit to remove impurities from the solid-phase substrate. The method further includes flowing an immiscible fluid through the fluid conduit to remove residual sample fluid and/or wash buffer. The method further includes flowing an elution buffer through the fluid conduit to elute nucleic acids from the solid-phase substrate.

The present invention provides a system and method for automatic nucleic acid extraction and qualitative analysis. The system comprises a magnetic rotary mixer which comprises a plurality of magnetic rods for generating magnetism, configured to be retractable from the magnetic rotary mixer; a plurality of spin shaft for mounting tips, and the plurality of magnetic rods extend therein; an auto stage comprises a plate holder, which allows a plate place thereon; a mixer holder to hold the magnetic rotary mixer over the plate holder; and a heat plate, disposed under the plate holder for heating the plate. The present invention provides an automated high-throughput nucleic acid extraction and qualitative diagnosis with high efficiency and high accuracy, which is easy to interpret for operators, and realize that nucleic acid extraction and molecular detection can be completed at one time in a single device.

An apparatus, vortex generator assembly and method for automated cell lysis and nucleic acid purification and processing. The vortex generator assembly includes sample holder having a lysis well, at least one wash well, and an elution well. The vortex generator assembly also includes a sample holder cover having a plurality of vibration rods for creating a vortex in the wells of the sample holder. The apparatus includes motor operating a rotating cam to cause the vibration rods to vibrate and create the vortex in a well holding fluid and magnetic beads, wherein the vortexing speed is sufficient to overcome the magnetic attraction between the beads and disperse the beads in solution, to collect nucleic acids such as DNA.