Aspects described herein provide blood sample purification and microfluidic nucleic acid amplification systems and methods for purifying blood samples and amplifying a target nucleic acid on the same system. The described systems and methods include a filter component and a microfluidic amplification component for amplification of nucleic acid from the blood sample, and can be used, for example, for point of care blood analysis.

The present invention provides a disposable pipette tip for dispersive solid phase extraction (SPE) that allows for rapid, automatable purification of large biomolecules, such as nucleic acids, proteins and polypeptides without the need for additional tools such as centrifuges, magnetic plates or vacuum manifolds. The pipette tip is designed for optimal biomolecule isolation while maintaining sample integrity. Optimized methods of using the dispersive pipette extraction system for isolation of large biomolecules are also provided.

The present invention relates to method for producing and purifying RNA comprising the steps of providing DNA encoding the RNA; transcription of the DNA into RNA; and conditioning and/or purifying of the solution comprising transcribed RNA by one or more steps of tangential flow filtration (TFF).

A sample processing and detection apparatus and an application thereof, capable of efficiently implementing the entire detection process of extraction and amplification of a sample such as a pathogen nucleic acid in a short time, being safe and convenient.

The present invention relates to method for producing and purifying RNA comprising the steps of providing DNA encoding the RNA; transcription of the DNA into RNA; and conditioning and/or purifying of the solution comprising transcribed RNA by one or more steps of tangential flow filtration (TFF).

A formulation for collecting a biological sample of saliva or nasal fluid and capturing nucleic acids in the collected sample has non-toxic chaotropic agents, ethanol, and coloring and/or flavoring agents. The formulation is receivable within an oral cavity or nasal cavity to collect the sample and the non-toxic chaotropic agent(s) lyse the sample cells. A device has a sample port for receiving the sample-containing formulation and a solid-state membrane in fluid communication with the sample port. A first pump causes the sample-containing formulation to flow across the solid-state membrane and into a waste chamber. The ethanol binds nucleic acids in the lysed cells of the sample to the solid-state membrane. A second pump causes the eluent to flow from an eluent chamber across the membrane, elute captured nucleic acids from the membrane, and flow with the captured nucleic acids into an eluent reservoir.

The present invention relates to method for producing and purifying RNA comprising the steps of providing DNA encoding the RNA; transcription of the DNA into RNA; and conditioning and/or purifying of the solution comprising transcribed RNA by one or more steps of tangential flow filtration (TFF).

Provided herein are methods for isolating nucleic acids from intact cells in a sample of intact cells and cell free nucleic acids. The intact cells and cell free nucleic acids are captured and concentrated within the pores of a silicate matrix in a microporous silicate filter. Within the silicate matrix the cell free nucleic acids are degraded with a nuclease, the intact cells are lysed with the released DNA binding to the silicate, the nuclease treated cell free nucleic acids and contaminants from the lysed are washed from the silicate matrix and the DNA bound to the silicate is eluted therefrom to form an isolated DNA product.

Described herein are instruments for excitation and detection of fluorophores in a plurality of functional regions in a biochip, using an excitation source and a steering element that directs a beam from the excitation source to a plurality of functional regions in the biochip, wherein the excitation source excites the fluorophores in the plurality of functional regions generating a signal that is detected such that said signal from at least one of the plurality of functional regions allows for nucleic acid quantification. Also described are systems for quantification and separation and detection using optical devices adapted for preliminary, simultaneous or sequential quantitation of nucleic acid in separate detection positions, and for the excitation and detection of multiple samples to steer both the excitation and detection beam paths to separately image each lane of a biochip.

The present invention provides, among other things, methods of purifying messenger RNA (mRNA) including the steps of (a) precipitating mRNA from an impure preparation; (b) subjecting the impure preparation comprising precipitated mRNA to a purification process involving membrane filtration such that the precipitated mRNA is captured by a membrane; and (c) eluting the captured precipitated mRNA from the membrane by re-solubilizing the mRNA, thereby resulting in a purified mRNA solution. In some embodiments, a purification process involving membrane filtration suitable for the present invention is tangential flow filtration.