The object of the present invention is a method for detection of a nucleic acid in a sample by nucleic acid separation and enrichment by using a bidirectional electro-hydrodynamic flow in a non-newtonian liquid medium, where the method further comprises the addition of probes intended to hybridize with a target nucleic acid so as to introduce a modification of the molecular weight of the target nucleic acid during hybridization with the probes in order to allow the separation of nucleic acid/probe complexes from the nucleic acid alone or the probes alone when the sample is subject to hydrodynamic and electrical action in order to allow the detection of the target nucleic acid.

Methods, containers, and mixtures are provided for performing PCR using molecular crowders.

Methods, containers, and mixtures are provided for performing PCR using molecular crowders.

Provided herein are methods and compositions for coating surfaces with polymers. The methods and compositions are suited for conducting biological reactions.

Provided herein are methods and compositions for coating surfaces with polymers. The methods and compositions are suited for conducting biological reactions.

The disclosure provides a label-free viscosity-based analyte detection system using paramagnetic beads as an asynchronous magnetic bead rotation (AMBR) microviscometer. It is disclosed herein that the bead rotation period is linearly proportional to the viscosity of a solution comprising analytes surrounding the paramagnetic bead. Optical measurement of asynchronous microbead motion determines solution viscosity precisely in microscale volumes, thus allowing an estimate of analyte concentration. The results demonstrate the feasibility of viscosity-based analyte detection using AMBR in microscale aqueous volumes.

The disclosure provides a label-free viscosity-based analyte detection system using paramagnetic beads as an asynchronous magnetic bead rotation (AMBR) microviscometer. It is disclosed herein that the bead rotation period is linearly proportional to the viscosity of a solution comprising analytes surrounding the paramagnetic bead. Optical measurement of asynchronous microbead motion determines solution viscosity precisely in microscale volumes, thus allowing an estimate of analyte concentration. The results demonstrate the feasibility of viscosity-based analyte detection using AMBR in microscale aqueous volumes.

The present invention describes an additive for accelerating hybridization comprising: a) an aqueous solution of sodium dextran sulphate, b) a salt, c) a buffer system, d) a strong mineral base possibly mixed with at least one polar aprotic solvent, or at least one polar aprotic solvent.

The additive described herein enables a reduction in the time required to perform the investigations with molecular probes on histological and cytological samples; the possibility of applying it to the protocol already in use in the routine practices of various laboratories in order to reduce the working time of histological and cytological samples for investigations with molecular probes, with no organisational impacts on the operators' work, enabling a more rapid diagnostic response for the patient and offering the possibility of using the additive described herein without formamide.

The present invention describes an additive for accelerating hybridization comprising: a) an aqueous solution of sodium dextran sulphate, b) a salt, c) a buffer system, d) a strong mineral base possibly mixed with at least one polar aprotic solvent, or at least one polar aprotic solvent.

The additive described herein enables a reduction in the time required to perform the investigations with molecular probes on histological and cytological samples; the possibility of applying it to the protocol already in use in the routine practices of various laboratories in order to reduce the working time of histological and cytological samples for investigations with molecular probes, with no organisational impacts on the operators' work, enabling a more rapid diagnostic response for the patient and offering the possibility of using the additive described herein without formamide.

The present disclosure provides methods, compositions, and systems for distributing polymerase compositions into array regions. In particular, the described methods, compositions, and systems utilize density differentials and/or additives to increase efficiency in the distribution of polymerase compositions to a surface as compared to methods utilizing only diffusion control.