Epitachophoresis (ETP) methods and devices that improve concentrating samples and/or separating components of samples. ETP methods and devices allow for electromigration in two dimensions. Electromigration of a sample may first occur in a first dimension along a single plane. Electromigration may then continue in a second dimension, which may be different from the first dimension. The volume where the electromigration occurs may significantly reduce from the first dimension to the second dimension. This smaller dimension may allow for increased concentration of samples or improved separation of components of a sample.

A sample separation apparatus includes a first-dimension separation unit for separating the fluidic sample, having a first-dimension outlet for outputting the fluidic sample or fractions thereof, and a second-dimension separation unit for further separating the fluidic sample or fractions thereof. The second-dimension separation unit has a second-dimension inlet fluidically coupled to the first-dimension outlet. A modulation unit, coupled between the first-dimension outlet and the second-dimension inlet at a first coupling point, is configured for withdrawing fluid from the first coupling point and for ejecting fluid into the first coupling point. A second-dimension fluid drive is coupled to a second coupling point located between the first-dimension outlet and the second-dimension inlet and downstream from the first coupling point. The second-dimension fluid drive is configured for generating a fluid flow for driving at least part of the fluidic sample after treatment by the first-dimension separation unit through the second-dimension separation unit.

Methods, systems and apparatus for automated extraction, purification, and processing of nucleic acids from biological samples are presented. In some embodiments, hydrogel supports are used to immobilize particulate biological input samples and extract nucleic acids during operations. The use of hydrogel facilitates automated sample processing on robotic liquid handling systems. Devices, methods, and systems are also provided for electrophoretic sample preparation.

Devices and methods for characterization of analyte mixtures are provided. Some methods described herein include performing enrichment steps on a device before expelling enriched analyte fractions from the device for subsequent analysis. Also included are devices for performing these enrichment steps.

The present application is directed to the use of electrophoresis with UV detection in the determination of iodine nutritional status in human biological specimens, specifically for monitoring iodine deficiency/inadequacy in large-scale epidemiological studies. In particular, the present application is directed to a method for determining iodide and iodide uptake inhibitors in a human biological sample when using sample self-stacking with capillary electrophoresis and UV detection.

Devices and methods for characterization of analyte mixtures are provided. Some methods described herein include performing enrichment steps on a device before expelling enriched analyte fractions from the device for subsequent analysis. Also included are devices for performing these enrichment steps.

A sample transfer device, an analytical system for analyzing a sample, a method for sample transfer and a method for manufacturing the sample transfer device are disclosed. The sample transfer device includes at least one first block and at least one second block, wherein the first block has at least one first port and at least one second port, wherein the second block has at least one third port and at least one fourth port. The sample transfer device also has at least one slider. The slider is located between the first block and the second block and is configured to slide from a first position to a second position and vice versa. Both in the first position and in the second position a first straight channel is formed between the first port and the third port and a second straight channel is formed between the second port and the fourth port.

Methods, systems and apparatus for automated extraction, purification, and processing of nucleic acids from biological samples are presented. In some embodiments, hydrogel supports are used to immobilize particulate biological input samples and extract nucleic acids during operations. The use of hydrogel facilitates automated sample processing on robotic liquid handling systems. Devices, methods, and systems are also provided for electrophoretic sample preparation.

A method and apparatus are provided for performing capillary isoelectric focusing followed by mobilization of the focused zones by induced hydrodynamic flow or chemical mobilization. These two dimensions of separation are integrated with real-time whole-channel electrophoresis detection and automatic sample injection to achieve a separation resolution superior to that obtainable using known orthogonal capillary two dimensional arrangements.

The present invention provides a mobility electrophoresis separation device, its operating method, and an interface between liquid chromatography and mass spectrometry. The mobility electrophoresis separation device comprises a separation capillary, a syringe pump for injecting a buffer solution, a syringe for injecting a sample solution, and two electrodes disposed apart from each other on either side of the separation capillary. A sample solution is injected by a syringe at a position of the capillary channel, and a buffer solution is injected into the capillary channel upstream the first position, and carries the sample solution to flow downstream. While the mixed liquid flows through the capillary, an electric field is applied in the direction of the flow. Different ions in the sample are thus separated in the flow due to their different velocities traveling in the flow.