Abstract: Described is a metering pump that may be used to meter volumes of sample in a chromatography system. The metering pump has a modular configuration that allows for separation of a head pod from a drive assembly for easy serviceability. The head pod includes a pump head, cartridge housing, seal wash housing and plunger. The drive assembly can be implemented in an inline drive configuration. Alternatively, the drive assembly can be implemented in an offset drive configuration in which a stepper motor is displaced laterally from other drive assembly components but is coupled through a belt and pulley system.

Abstract: The present invention provides novel chromatographic materials, e.g., for chromatographic separations, processes for its preparation and separations devices containing the chromatographic material; separations devices, chromatographic columns and kits comprising the same; and methods for the preparation thereof. The chromatographic materials of the invention are chromatographic materials comprising having a narrow particle size distribution.

Abstract: A method of capturing human immunoglobulin Fc domains in a biofluid sample is provided. The method includes providing an affinity capture device. The affinity capture device includes a surface having an aptamer that is at least 80% identical to SEQ ID NO 1 immobilized onto the surface of the affinity capture device. The biofluid sample is diluted with a binding buffer. The binding buffer includes (A) tris(hydroxymethyl)aminomethane (Tris), trimethylamine (TES), 2-ethanesulfonic acid (MES), or 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES); (B) a magnesium cation at a concentration between about 10 µM to about 20 mM; and (C) a total monovalent cation concentration from 0 to no greater than 100 mM. The human immunoglobulin Fc domains in the biofluid sample are adsorbed to the aptamer with the binding buffer.

Abstract: Exemplary embodiments may deploy a valve that introduces a sample of a calibrant coaxially with flow exiting a source of a mobile phase flow, such as a liquid chromatography (LC) column, on a path to an ion source for the mass spectrometer (MS). The valve may be positioned remotely on a branch that has a junction with the path leading form the source of the mobile phase flow to the ion source. Alternatively, the valve may be positioned in line on the flow path from the source of the mobile phase flow to the ion source of the MS. A novel five port valve design may be employed. With this valve design, a first position of the valve allows a sample loop for the calibrant to be filled. In a second position, the calibrant is added coaxially to the flow from the source of the mobile phase to the MS. In a third position of the valve, diversion of or infusion to a post-source flow is enabled.

Abstract: The present technology relates to a method of analyzing a sample including an analyte. The method includes injecting the sample including the analyte into a mobile phase. The mobile phase includes a metal chelator additive having a concentration between about 1 ppm to about 10 ppm. The method also includes separating the analyte using liquid chromatography and analyzing the analyte using a mass spectrometer, an ultra-violet detector, or a combination thereof.

Abstract: Methods are provided for making rapid labeled dextran ladders and other calibrants useful in liquid chromatography. The methodologies include a two-step process comprising a reductive amination step of providing a reducing glycan and reacting it with a compound having a primary amine to produce an intermediate compound. The intermediate compound is then rapidly tagged with a rapid tagging reagent to produce the rapid labeled dextran ladder.

Abstract: The present disclosure relates to a method of analyzing a sample comprising a hydrophobic molecule. The method includes preparing an aqueous solution comprising the sample. The method also includes placing the solution in contact with a polypropylene substrate having a deactivated surface that reduces adsorption of the hydrophobic molecule relative to a polypropylene substrate that has not been deactivated. The method also includes analyzing the sample.

Abstract: Multidimensional liquid chromatography (MDLC) systems include valve configurations that enable a flow containing analytes in the eluent of a first dimension liquid chromatography system to be modulated such that the analytes can be captured in fluidic loops and subsequently provided to a second dimension liquid chromatography system. Optionally, a single detector is used for both first and second dimensions. In addition, the systems can enable dilution of the analytes and enable incompatible mobile phases and mobile phase flow rates to be used in the first and second dimensions.

Abstract: The present disclosure discusses a method of separating a sample (e.g., small organic acid metabolite) including coating a flow path of a chromatographic system. The coating along the flow path is vapor deposited and prevents or severely decreases metal interactions between the metallic chromatographic system and the sample.

Abstract: The present disclosure is directed to methods for performing size exclusion chromatographic (SEC) separations. Embodiments of the present disclosure feature methods for improved separations of biomolecule analytes, such as CRISPR-related proteins, nucleotides, and ribonucleoprotein complexes, in SEC, for example, by using hydroxy-terminated polyethylene glycol surface modified stationary phase materials and/or C2/PEG surface modified column hardware.

Abstract: Thermally modulated variable restrictors used in chromatography systems enable independent control of system pressure and linear velocity of a compressible mobile phase passing through a chromatography column. A method for configuring a chromatography system with independent control of system pressure and mass flow rate of a compressible mobile phase includes determining a type of chromatography separation column to be used in the chromatography system, matching a thermally modulated variable restrictor to the type of chromatography separation column for use together during operation of the chromatography system, and bundling the chromatography column with its matching thermally modulated variable restrictor for distribution as a single package.

Abstract: The present invention relates to a method for analyzing a sample, the method comprising: (a) incubating a sample comprising an analyte with at least one enzyme to produce a digestion mixture comprising fragments of the analyte; (b) loading the digestion mixture onto a reversed-phase chromatography column; and (c) performing reversed-phase chromatography on the digestion mixture, wherein the at least one enzyme is hydrophobically modified to increase a retention time of the at least one enzyme such that the at least one enzyme elutes from the reversed-phase chromatography column later than the fragments of the analyte.

Abstract: The present invention provides the use of charged surface reversed phase chromatographic materials along with standard reversed-phase LC and mass spectrometry compatible conditions for the retention, separation, purification, and characterization of acidic, polar molecules, including, but not limited to, organic acids, ?-amino acids, phosphate sugars, nucleotides, other acidic, polar biologically relevant molecules. The chromatographic materials of the invention are high purity chromatographic materials comprising a chromatographic surface wherein the chromatographic surface comprises a hydrophobic surface group and one or more ionizable modifier.

Abstract: A liquid chromatography apparatus includes a diffusion-bonded separation column comprising a lower substrate comprising titanium, an upper substrate comprising titanium, and a titanium patterned foil disposed between the lower substrate and the upper substrate. The lower substrate, titanium patterned foil, and upper substrate are diffusion bonded together to form a fluid path extending from an inlet port to an outlet port, wherein walls defining the fluid path within the diffusion-bonded separation column include a titanium surface coating.

Abstract: A variable fluidic restrictor of a liquid chromatography system including a stator body, the stator body include a plurality of fluidic channels located within the stator body, wherein each fluidic channel of the plurality of fluidic channels includes a restrictor element, wherein a flow of a fluid through the variable fluidic restrictor is selectively restricted based on a position of an external element coupled to the stator body is provided. Furthermore, an associated method is also provided.

Abstract: Described is a method for determining a dwell volume of a liquid chromatography system and a liquid chromatography system that can determined the system dwell volume. The method includes mixing a flow of a first solvent with a flow of a second solvent to form a solvent mixture. The flows of the first and second solvents are decreased and increased, respectively, to generate a gradient composition. A system pressure of the liquid chromatography system is measured to determine a pressure trace defined as the measured system pressure as a function of time. The dwell volume of the system is determined from a time delay determined between the gradient composition at the mixing location and the pressure trace. The method can be performed with a liquid chromatography system having a chromatographic column or a flow restrictor used in place of the chromatographic column.

Abstract: A device for processing samples is disclosed. Interior surfaces of the device, which come in contact with fluids, define wetted surfaces. A portion of the wetted surfaces are coated with an alkylsilyl coating having the Formula I: R1, R2, R3, R4, R5, and R6 are each independently selected from (C1-C6)alkoxy, —NH(C1-C6)alkyl, —N((C1-C6)alkyl)2, OH, ORA, and halo. RA represents a point of attachment to the interior surfaces of the fluidic system. At least one of R1, R2, R3, R4, R5, and R6 is ORA. X is (C1-C20)alkyl, —O[(CH2)2O]1-20—, —(C1-C10)[NH(CO)NH(C1-C10)]1-20—, or —(C1-C10)[alkylphenyl(C1-C10)alkyl]1-20—.

Abstract: The present technology generally relates to devices, systems and methods for providing robust sealing between surfaces in a pressurized system, such as a chromatography system. In particular, the devices, systems and methods relate to compliant and resilient parts that can be reused and/or reinstalled while providing a pressure tight sealing surface even within a high pressure environment (e.g., 1000 psi or greater).

Abstract: A device for separating analytes is disclosed. The device has a sample injector, sample injection needle, sample reservoir container in communication with the sample injector, chromatography column downstream of the sample injector, and fluid conduits connecting the sample injector and the column. The interior surfaces of the fluid conduits, sample injector, sample reservoir container, and column form a flow path having wetted surfaces. A portion of the wetted surfaces of the flow path are coated with an alkylsilyl coating that is inert to at least one of the analytes. The alkylsilyl coating has the Formula I: R1, R2, R3, R4, R5, and R6 are each independently selected from (C1-C6)alkoxy, —NH(C1-C6)alkyl, —N((C1-C6)alkyl)2, OH, ORA, and halo. RA represents a point of attachment to the interior surfaces of the fluidic system. At least one of R1, R2, R3, R4, R5, and R6 is ORA. X is (C1-C20)alkyl, —O[(CH2)2O]1-20—, —(C1-C10)[NH(CO)NH(C1-C10)]1-20—, or —(C1-C10)[alkylphenyl(C1-C10)alkyl]1-20-.

Abstract: In various aspects, the present disclosure pertains to methods of performing a sample enrichment procedure, which comprise: adding a sample fluid that comprises at least one phospholipid and at least one target analyte to a sorbent that comprises a hydrophobic component and a cation exchange component, thereby resulting in sorbent with bound phospholipid and bound target analyte; adding an aqueous solution comprising an acidic compound and a salt; adding an organic solution to the sorbent thereby desorbing at least a portion of the bound phospholipid from the sorbent; and adding an elution solution to the sorbent, thereby desorbing at least a portion of the bound target analyte from the sorbent and forming a solution of the target analyte in the elution solution. In other aspects, the present disclosure pertains to kits, which may be used in conjunction with such methods.