Abstract: A liquid chromatography monitoring system comprises a computer or electronic controller comprising computer-readable instructions operable to: (a) draw a fluid into a syringe pump; (b) configure a valve so as to fluidically couple the pump to either a fluidic pathway through a fluidic system or to a plug that prevents fluid flow; (c) cause the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determine a profile of the variation of the measured pressure; (e) compare the determined profile to an expected profile that depends upon the fluid; and (f) provide a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A liquid chromatography monitoring system comprises a computer or electronic controller comprising computer-readable instructions operable to: (a) draw a fluid into a syringe pump; (b) configure a valve so as to fluidically couple the pump to either a fluidic pathway through a fluidic system or to a plug that prevents fluid flow; (c) cause the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determine a profile of the variation of the measured pressure; (e) compare the determined profile to an expected profile that depends upon the fluid; and (f) provide a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A method for monitoring a fluidic system of a liquid chromatography system is characterized by: (a) drawing a fluid into a syringe pump; (b) configuring a valve so as to fluidically couple the pump to either a fluidic pathway through the fluidic system or to a plug that prevents fluid flow; (c) causing the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determining a profile of the variation of the measured pressure; (e) comparing the determined profile to an expected profile that depends upon the fluid; and (f) providing a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A method for monitoring a fluidic system of a liquid chromatography system is characterized by: (a) drawing a fluid into a syringe pump; (b) configuring a valve so as to fluidically couple the pump to either a fluidic pathway through the fluidic system or to a plug that prevents fluid flow; (c) causing the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determining a profile of the variation of the measured pressure; (e) comparing the determined profile to an expected profile that depends upon the fluid; and (f) providing a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A method for monitoring a fluidic system of a liquid chromatography system is characterized by: (a) drawing a fluid into a syringe pump; (b) configuring a valve so as to fluidically couple the pump to either a fluidic pathway through the fluidic system or to a plug that prevents fluid flow; (c) causing the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determining a profile of the variation of the measured pressure; (e) comparing the determined profile to an expected profile that depends upon the fluid; and (f) providing a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A method for coupling a tubing to a liquid chromatography column comprises: passing an end of the tubing through a coupling apparatus comprising: (i) at least one chamber; (ii) a first spring within the at least one chamber configured to transmit a spring force to the tubing; (iii) a second spring within the at least one chamber; and (iv) a deformable sealing member configured to receive a second force from the second spring; inserting the tubing end into a receptacle of an end fitting of the column; and moving the coupling apparatus towards the chromatography column such that the first spring urges the tubing into the receptacle whereby a pressure of the tubing end against the end fitting exceeds a maximum operating fluid pressure of the column and, further, whereby the second spring causes the deformable sealing member to form a fluid seal between the column and the receptacle.

Abstract: A method for analyzing a whole blood sample can include injecting whole blood into a first zone of a dual zone sample loop, applying sufficient heat or energy to the whole blood to disintegrate the cellular components of the whole blood sample to produce cell disintegrated blood, and injecting a sufficient volume of the buffer into the dual zone sample loop to move the cell disintegrated blood into a second zone of the dual zone sample loop. The method can further include switching a multiport value to an inject position, flowing the cell disintegrated blood from the dual zone sample loop into a solid phase extraction column, and eluting components of the cell disintegrated blood from the solid phase extraction column into a liquid chromatography column.

Abstract: A method for liquid chromatography comprises steps of: mixing a sample comprising a plurality of chemical constituents with a first solvent; transferring the solvent and the plurality of constituents to a first chromatographic column housed in a cartridge; chromatographically separating a sub-group of the plurality of constituents from unwanted constituents using the first chromatographic column; transferring the sub-group of the plurality of constituents from the first chromatographic column to a second column housed in the cartridge, the transferring effected by the flow of a second solvent; chromatographically separating, from one another, individual constituents of the sub-group of the plurality of constituents using the second chromatographic column; and transferring the separated individual constituents to a detector.

Abstract: A system for providing a solvent or reagent to a liquid chromatography system comprises: a valve comprising a common port and a plurality of other ports, configurable such that the common port may be fluidically coupled to any one of the other ports; a pump fluidically coupled to the common port of the valve; a plugged first one of the other ports; a container containing the solvent or reagent, said container fluidically coupled to a second one of the other ports; a fluid tubing line having a known resistance to fluid flow fluidically coupled to a third one of the other ports; and a pressure gauge configured to measure fluid pressure within the pump, wherein the solvent or reagent is provided to the liquid chromatography system by a fourth one of the other ports.

Abstract: A method for analyzing a whole blood sample can include injecting whole blood into a first zone of a dual zone sample loop, applying sufficient heat or energy to the whole blood to disintegrate the cellular components of the whole blood sample to produce cell disintegrated blood, and injecting a sufficient volume of the buffer into the dual zone sample loop to move the cell disintegrated blood into a second zone of the dual zone sample loop. The method can further include switching a multiport value to an inject position, flowing the cell disintegrated blood from the dual zone sample loop into a solid phase extraction column, and eluting components of the cell disintegrated blood from the solid phase extraction column into a liquid chromatography column.

Abstract: An apparatus for coupling a liquid chromatography column comprising an end fitting to a tubing comprises: at least one body member comprising at least one chamber; a first spring within the at least one chamber, the first spring configured so as to apply a first force to the tubing towards the column end fitting; a second spring within the at least one chamber, the second spring configured to apply a second force to a deformable sealing member towards the column end fitting; and a pushing and latching mechanism configured to push the at least one body member and the first and second springs towards the column end fitting.

Abstract: A method for monitoring a fluidic system of a liquid chromatography system is characterized by: (a) drawing a fluid into a syringe pump; (b) configuring a valve so as to fluidically couple the pump to either a fluidic pathway through the fluidic system or to a plug that prevents fluid flow; (c) causing the syringe pump to progressively compress the fluid therein or expel the fluid to the fluidic pathway, while measuring a pressure of the fluid; (d) determining a profile of the variation of the measured pressure; (e) comparing the determined profile to an expected profile that depends upon the fluid; and (f) providing a notification of a sub-optimal operating condition or malfunction if the determined profile varies from the expected profile by greater than a predetermined tolerance.

Abstract: A system for providing a solvent or reagent to a liquid chromatography system comprises: a valve comprising a common port and a plurality of other ports, configurable such that the common port may be fluidically coupled to any one of the other ports; a pump fluidically coupled to the common port of the valve; a plug configured to block flow through a first one of said other ports of the valve; a container containing the solvent or reagent, said container fluidically coupled to a second one of said other ports of the valve; a fluid tubing line having a known resistance to fluid flow fluidically coupled to a third one of said other ports of the valve; and a pressure gauge configured to measure fluid pressure within the pump, wherein the solvent or reagent is provided to the liquid chromatography system by a fourth one of the other ports.

Abstract: A cartridge for chromatography separations comprises a housing; at least a first and a second chromatography column at least partially passing through the housing, each chromatography column comprising a first and a second end fitting operable to connect the chromatography to external tubing of a chromatography system. Connection fittings protruding outside of the housing at each end of each column enable fluidic connection to a chromatograph plumbing system and/or mass spectrometer detector. The cartridge may comprise heaters and temperature sensors and optional sensors to monitor fluid flow rate or pH. A passive identification feature, e.g., a barcode or RFID module may identify the cartridge and its associated chromatography methods to external software.

Abstract: The present invention relates to a method and apparatus for chromatographically analyzing each of a plurality of samples in detector, comprising an autosampler to contain a plurality of samples for chromatographic analysis and a plurality of chromatographic systems, each system comprising one or more pumps and one or more chromatography columns. A detector is included for detecting compounds in the samples from each of the chromatography systems along with a valve positioned between the detector and the plurality of chromatography systems, the valve permitting each sample to reach the detector in sequence. A computer control device is included which adjusts the introduction of samples from the autosampler into the plurality of chromatography systems as well as the position of the valve to sequentially separate and deliver compounds within the samples to the detector.

Abstract: A system for separating compounds of relatively low molecular weight substantially not greater than about one kilodalton from compounds having relatively high molecular weights substantially an order of magnitude greater or more than the low molecular weight compounds in a liquid mixture. The system includes a chromatographic column packed with uniformly distributed rigid, solid, porous particles having chromatographically active, hydrophobic surfaces, average diameters of not less than about 30 .mu.m, and average pore diameters sufficiently small to substantially exclude introduction of the compounds of relatively high molecular weight into the pores. The mixture is pumped through the interstitial volume between the particles at a reduced velocity greater than about 5,000, until a band of the high molecular weight compounds exits the column. The low molecular weight compounds are then eluted and are recovered separately from the relatively high molecular weight compounds.

Abstract: A system for separating compounds of relatively low molecular weight substantially not greater than about one kilodalton from compounds having relatively high molecular weights substantially an order of magnitude greater or more than the low molecular weight compounds in a liquid mixture. The system includes a chromatographic column packed with uniformly distributed rigid, solid, porous particles having chromatographically active, hydrophobic surfaces, average diameters of not less than about 30 .mu.m, and average pore diameters sufficiently small to substantially exclude introduction of the compounds of relatively high molecular weight into the pores. The mixture is pumped through the interstitial volume between the particles at a reduced velocity greater than about 5,000, until a band of the high molecular weight compounds exits the column. The low molecular weight compounds are then eluted and are recovered separately from the relatively high molecular weight compounds.