A gas chromatography system can include a circulatory loop, a gas inlet positioned along the circulatory loop, a gas outlet positioned along the circulatory loop, a micro column positioned in line with the circulatory loop, and an in-line population sensor positioned in line with the circulatory loop. The in-line population sensor can be configured to detect changes in gas population. The gas inlet and gas outlet can be associated with a gas inlet valve and gas outlet valve, and configured to admit or withdraw gas from the circulatory loop, respectively. A gas sample can be circulated through the circulatory loop for at least one cycle, and a component of the gas sample can be detected using the in-line population sensor.

A gas chromatography system can include a circulatory loop, a gas inlet positioned along the circulatory loop, a gas outlet positioned along the circulatory loop, a micro column positioned in line with the circulatory loop, and an in-line population sensor positioned in line with the circulatory loop. The in-line population sensor can be configured to detect changes in gas population. The gas inlet and gas outlet can be associated with a gas inlet valve and gas outlet valve, and configured to admit or withdraw gas from the circulatory loop, respectively. A gas sample can be circulated through the circulatory loop for at least one cycle, and a component of the gas sample can be detected using the in-line population sensor.

Reduced column loading of a sample onto a chromatographic column may be mitigated by excluding diffuse portions of the sample from introduction to the column. Systems and methods are provided for detecting and removing the diffuse portions from the feed solution delivered to the chromatography column. The systems and methods herein permit use of a single detector to detect and remove the diffuse portions and can accommodate a recovery/collection/recycling mechanism permitting reuse of removed sample from the diverted diffuse portions.

Reduced column loading of a sample onto a chromatographic column may be mitigated by excluding diffuse portions of the sample from introduction to the column. Systems and methods are provided for detecting and removing the diffuse portions from the feed solution delivered to the chromatography column. The systems and methods herein permit use of a single detector to detect and remove the diffuse portions and can accommodate a recovery/collection/recycling mechanism permitting reuse of removed sample from the diverted diffuse portions.

A simulated moving-bed type chromatographic separation method separating a weakly adsorptive component, a strongly adsorptive component, and an intermediately adsorptive component, with eluents by using a circulation system in which a plurality of unit packed columns packed with an adsorbent are connected in series and in an endless form via pipes in which a feed solution supply port F, two or more eluent supply ports D corresponding to the eluents, an extraction port A of a fraction containing the weakly adsorptive component, an extraction port B of a fraction containing the intermediately adsorptive component, and an extraction port C of a fraction containing the strongly adsorptive component are provided in the pipes of the circulation system, and positions of the ports F, A, B, and C are set to have a specified relationship.

A simulated moving-bed type chromatographic separation method separating a weakly adsorptive component, a strongly adsorptive component, and an intermediately adsorptive component, with eluents by using a circulation system in which a plurality of unit packed columns packed with an adsorbent are connected in series and in an endless form via pipes in which a feed solution supply port F, two or more eluent supply ports D corresponding to the eluents, an extraction port A of a fraction containing the weakly adsorptive component, an extraction port B of a fraction containing the intermediately adsorptive component, and an extraction port C of a fraction containing the strongly adsorptive component are provided in the pipes of the circulation system, and positions of the ports F, A, B, and C are set to have a specified relationship.

A chromatographic separation method for separating plural components contained in a liquid to be separated by a chromatography, with a separating device 1 including plural filling portions 10 filled with a separating agent for separating the plural components contained in the liquid to be separated, a supply portion 20 provided in each of the plural filling portions 10 to supply the liquid to be separated or an eluent for extracting any component contained in the liquid to be separated to the filling portion 10, and an extraction portion 30 to extract any component contained in the liquid to be separated from the filling portion 10, the method including: an upward supplying and extracting step of extracting any component contained in the liquid to be separated from an upward stream extraction portion while supplying the eluent to at least one filling portion 10 from an upward stream supply portion by an upward stream.

A chromatography system for separation of a biopolymer is described, comprising at least one feed tank, at least one hold tank, at least one elution buffer tank, at least one eluate tank, at least two packed bed chromatography columns and at least one pump and at least one outlet detector both fluidically connected to said each packed bed chromatography column, wherein the feed tank, the hold tank(s), the elution buffer tank and the eluate tank are each fluidically connected to the packed bed chromatography columns via a system of valves.

In a method for processing successive fluidic sample portions provided by a sample source, sample reception volumes are filled successively temporarily with at least a respective one of the sample sections, and the sample sections are emptied successively out of the sample reception volumes in such a way, that, while emptying, it is avoided to bring two respective ones of the sample sections, which have not left the sample source directly adjacent to one another, in contact with one another.

In a method for processing successive fluidic sample portions provided by a sample source, sample reception volumes are filled successively temporarily with at least a respective one of the sample sections, and the sample sections are emptied successively out of the sample reception volumes in such a way, that, while emptying, it is avoided to bring two respective ones of the sample sections, which have not left the sample source directly adjacent to one another, in contact with one another.