A mass spectrometry (MS) apparatus is provided. The MS apparatus includes a mass spectrometer, an ionization source coupled to the mass spectrometer, and a flow injection system (FIS) coupled to the ionization source. The ionization source is configured to provide an ionized gas flow of an analyte towards an entrance of the mass spectrometer. The ionization source is further configured to provide a second gas flow of a second gas. The MS apparatus is configured to measure a mass spectrometer (MS) signal of the analyte. The MS apparatus is further configured to analyze a dependency of the MS signal of the analyte versus a parameter of the second gas flow or a state of the second gas flow and to determine a condition of the apparatus based on the analyzed dependency.

Methods, devices, and systems for improving the quality of electrospray ionization mass spectrometer (ESI-MS) data are described, as are methods, devices, and systems for achieving improved correlation between chemical separation data and mass spectrometry data.

A process for decreasing contamination of a commercial refining process by vanadyl porphyrins and/or nickel porphyrins by allowing rapid screening of porphyrins directly from asphaltenes isolated from crude oil without enrichment by use of positive-ion electrospray ionization mass spectrometry (ESI MS). Sodium formate is utilized as a ESI spray modifier. The vanadyl porphyrins are detected predominantly as sodiated species, while nickel porphyrins are observed as both sodiated species and molecular ions. Crude oil feedstocks exceeding a defined threshold concentration of vanadyl porphyrins and/or nickel porphyrins are rejected or diluted prior to utilization as refinery feedstock. Certain embodiments additionally quantitate both deoxophylloerythroetioporphyrins and etioporphyrin content (and their ratio) to predict crude oil thermal maturity.

Provided is a method for introducing into a probe 22 an eluate eluted from a component separation unit 14 that temporally separates components contained in a liquid sample, for obtaining charged particles, and for delivering the charged particles to a charged particle analysis unit 30 provided at a subsequent stage through a charged particle introduction opening 23, comprising steps of: supplying a gasification promoting gas for promoting gasification of the eluate and applying a predetermined charged-particle obtaining voltage to the probe 22 while the eluate is being introduced into the probe 22; and hindering the eluate nebulized by the probe 22 from moving toward the ion introduction opening 2 only in a time period other than a time period in which a target-component containing eluate is introduced into the probe 22.

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: ##STR00001##
R.sup.1, R.sup.2, R.sup.3, R.sup.4, R.sup.5, and R.sup.6 are each independently selected from (C.sub.1-C.sub.6)alkoxy, —NH(C.sub.1-C.sub.6)alkyl, —N((C.sub.1-C.sub.6)alkyl).sub.2, OH, OR.sup.A, and halo. R.sup.A represents a point of attachment to the interior surfaces of the fluidic system. At least one of R.sup.1, R.sup.2, R.sup.3, R.sup.4, R.sup.5, and R.sup.6 is OR.sup.A. X is (C.sub.1-C.sub.20)alkyl, —O[(CH.sub.2).sub.2O].sub.1-20—, —(C.sub.1-C.sub.10)[NH(CO)NH(C.sub.1-C.sub.10)].sub.1-20—, or —(C.sub.1-C.sub.10)[alkylphenyl(C.sub.1-C.sub.10)alkyl].sub.1-20-.

A method of ionising a sample is disclosed comprising nebulising a sample which includes monoclonal antibody (“mAb”) molecules. A stream of monoclonal antibody droplets or charged droplets is directed so as to impact upon a target or electrode so as to form intact parent monoclonal antibody ions, intact minus light chain parent monoclonal antibody ions or light chain (“LC”) fragment monoclonal antibody ions.

A microwave microstrip resonator apparatus including a housing; a resonator within the housing; an output conductor within the housing and spaced apart from the resonator so as to define a capacitive gap therebetween; a reaction vessel configured to reside with the capacitive gap; and a power supply coupled to the resonator whereby contents within the reaction vessel are heated when energy is supplied to the resonator by the power supply. A mass spectrometer may also be coupled to an outlet end of the reaction vessel such that the contents within the reaction vessel are, simultaneously, delivered to the mass spectrometer for analysis.

A method that includes introducing at least one analyte into a gas plasma; generating neutral species from atoms of the analyte in the gas plasma; preferentially transporting the neutral species downstream of the gas plasma relative to any ions produced in the gas plasma; and reacting the neutral species of the analyte with at least one reagent ion downstream of the plasma resulting in ion species of the analyte, wherein the at least one reagent ion is supplied by an independent ion source.

An impact ionisation spray or electrospray ionisation ion source comprising a nebuliser (30) having a first conduit (11) for providing a liquid sample and a second conduit (10) for providing a nebulisation gas in order to nebulise the liquid sample is disclosed. The first conduit (11) and second conduit (10) are of unitary construction with each other and may be made from glass. The ion source can provide a consistent and/or predictable spray profile for the nebulised sample.

Methods for determining the relative abundance of intact adeno-associated virus (AAV) capsid components in a sample of recombinant AAV particles are disclosed. In embodiments, the methods include a system regeneration process that minimizes or eliminates the presence of ghost peaks to maximize analytical accuracy and ensure product quality and consistency.