A gas analysis device suited for e.g. medical analysis of exhaled breath from a subject. A gas inlet receives a gas sample to a flow path for guiding the gas sample to two or more gas separators, e.g. gas chromatography columns, with respective molecule selectivity properties which are different. One or more detectors, each with a sensor, are arranged to generate respective responses to outputs from the two or more gas separators. A communication module generate output data in response to the respective responses from the one or more detectors, e.g. data indicative of selected molecules in the gas sample, e.g. data indicative of one or more diseases identified as a result of identified biomarkers in the gas sample. The device is suitable as a compact device, e.g. a handheld breath analysis device, since the use of a plurality of gas separators allows use of very molecule specific gas separators which can be implemented with a small size. E.g. a flow path with several parallel paths each comprising one or more gas separator may be used.

A liquid chromatograph includes a plurality of columns, fluid supply units each configured to feed a predetermined solution in parallel with inlet side flow paths of the plurality of columns, a sample injection unit capable of selectively injecting a sample into one of the inlet side flow paths of the plurality of columns, and a flow path switching unit disposed on exit sides of the plurality of columns and configured to selectively connect one of outlet side flow paths of the plurality of columns to a flow path connected to a detector arranged on a downstream side of the flow path switching unit and connect outlet side flow paths of other columns to a waste liquid flow path. The liquid chromatograph may improve a throughput by shortening a time required for a series of measurements in which a sample is measured under a plurality of conditions by alternatively using a plurality of columns.

The analysis apparatus includes a standby section which is provided between a dispensing operation of an analysis item B prior to an analysis item C and the sample analysis channel introduction. The sample analysis channel introduction is arranged prior to a data collection section of an analysis item A. The operation is started earlier but after a sample dispensing operation section of the analysis item A. A sample dispensing operation section of the analysis item C can be started earlier and the analysis time of the analysis item C can be moved to immediately after a sample analysis operation section of the analysis item B. The analysis item A in a second cycle can be started earlier by the early start time of the analysis item C in a first cycle. A total processing time Tc can be shorter than a total processing time Tb.

The analysis apparatus includes a standby section which is provided between a dispensing operation of an analysis item B prior to an analysis item C and the sample analysis channel introduction. The sample analysis channel introduction is arranged prior to a data collection section of an analysis item A. The operation is started earlier but after a sample dispensing operation section of the analysis item A. A sample dispensing operation section of the analysis item C can be started earlier and the analysis time of the analysis item C can be moved to immediately after a sample analysis operation section of the analysis item B. The analysis item A in a second cycle can be started earlier by the early start time of the analysis item C in a first cycle. A total processing time Tc can be shorter than a total processing time Tb.

A method for analyzing and quantifying a panel of drugs in a clinical sample comprises: trapping a first portion of drug parent compounds and their metabolites on a first chromatographic column; trapping a second portion of the drug parent compounds and their metabolites on a second chromatographic column; separately eluting the first and second portions of the drug parent compounds and their metabolites from the first and second chromatographic columns; detecting concentrations of each of the drug parent compounds and metabolites eluted from each of the first and second chromatographic columns with a detector; and summing the detected concentration of each drug parent compound together with the detected concentrations of all of its respective analytes so as to derive a respective total concentration of each drug in the sample.

A method of multiplexing the operation of a sample preparation and analysis system is disclosed. The system includes a sample preparation system capable of preparing a first sample in accordance with a first assay that is selected from a database containing a plurality of unique assays and preparing a second sample in accordance with a second, different assay. The method includes separately transporting the first and second prepared samples to an analysis station having first and second separation channels and an analyzer comprising a mass spectrometer. The method further includes simultaneously analyzing the first prepared sample with the analyzer in accordance with the first selected assay and separating the second prepared sample with the second separation channel in accordance with the second selected assay.

A sample preparation and analysis system. The system includes a sample preparation system and a sample analysis system. The sample preparation system prepares samples in accordance with an assay that is selected from a database containing a plurality of unique assays. The sample analysis system includes an analyzer that is dynamically reconfigurable based on the selected assay so as to analyze the prepared sample in accordance with that selected assay. A data communication link communicates data from the sample preparation system to the sample analysis system to reconfigure the analyzer in accordance with the selected assay.

A liquid chromatography-mass spectrometry (LC-MS) apparatus including an ionization source coupled to a mass spectrometer and a liquid chromatographic (LC) system coupled to the ionization source. The LC system comprises multiple fluidic streams alternately connectable to the ionization source, thereby assigning a detection time window to each fluidic stream from the multiple fluidic streams when connected to the ionization source. The LC-MS apparatus further comprises a controller configured to carry out steps of monitoring an ionization current of the ionization source for the multiple fluidic streams and identifying differences in flow conditions between the multiple fluidic streams based on the monitored ionization current. The controller is further configured to carry out adjusting detection conditions of one or more of the multiple fluidic streams responsive to the identified differences, thereby enabling eluates of interest from each fluidic stream to be detected by the mass spectrometer in the respective detection time window.

The analysis apparatus includes a standby section which is provided between a dispensing operation of an analysis item B prior to an analysis item C and the sample analysis channel introduction. The sample analysis channel introduction is arranged prior to a data collection section of an analysis item A. The operation is started earlier but after a sample dispensing operation section of the analysis item A. A sample dispensing operation section of the analysis item C can be started earlier and the analysis time of the analysis item C can be moved to immediately after a sample analysis operation section of the analysis item B. The analysis item A in a second cycle can be started earlier by the early start time of the analysis item C in a first cycle. A total processing time Tc can be shorter than a total processing time Tb.

The analysis apparatus includes a standby section which is provided between a dispensing operation of an analysis item B prior to an analysis item C and the sample analysis channel introduction. The sample analysis channel introduction is arranged prior to a data collection section of an analysis item A. The operation is started earlier but after a sample dispensing operation section of the analysis item A. A sample dispensing operation section of the analysis item C can be started earlier and the analysis time of the analysis item C can be moved to immediately after a sample analysis operation section of the analysis item B. The analysis item A in a second cycle can be started earlier by the early start time of the analysis item C in a first cycle. A total processing time Tc can be shorter than a total processing time Tb.