A nebuliser outlet comprises an inlet end and an outlet end, a first channel and one or more second channels arranged between the inlet end and the outlet end. The first channel is configured to receive a capillary, and the one or more second channels are configured to pass gas to the outlet end. The nebuliser outlet is a single integrated component.

A system includes an analysis system at a first location and one or more remote sampling systems at a second location remote from the first location. A sampling system can be configured to receive a remote liquid sample. The system also includes a sample transfer line configured to transport gas from the second location to the first location. The sample transfer line is configured to selectively couple with a remote sampling for supplying a continuous liquid sample segment to the sample transfer line. The system can further include a sample receiving line at the first location. The sample receiving line is configured to selectively couple with the sample transfer line and the analysis system to receive the continuous liquid sample segment and supply the sample to an analysis device.

A system and method are provided for loading a sample into an analytical instrument using acoustic droplet ejection (“ADE”) in combination with a continuous flow sampling probe. An acoustic droplet ejector is used to eject small droplets of a fluid sample containing an analyte into the sampling tip of a continuous flow sampling probe, where the acoustically ejected droplet combines with a continuous, circulating flow stream of solvent within the flow probe. Fluid circulation within the probe transports the sample through a sample transport capillary to an outlet that directs the analyte away from the probe to an analytical instrument, e.g., a device that detects the presence, concentration quantity, and/or identity of the analyte. When the analytical instrument is a mass spectrometer or other type of device requiring the analyte to be in ionized form, the exiting droplets pass through an ionization region, e.g., an electrospray ion source, prior to entering the mass spectrometer or other analytical instrument. The method employs active flow control and enables real-time kinetic measurements.

An ambient ionisation source unit (10) is provided comprising: a housing (12) containing a first device (14) for generating analyte material from a surface of a sample to be analysed and a sampling inlet (16) for receiving analyte material liberated from the surface of the sample. The position(s) of the first device and/or sampling inlet is (are) fixed relative to the housing. Thus, the first device and the sampling inlet are integrated into a single unit that can be installed onto the front-end of an ion analysis instrument with minimal or reduced user interaction.

The invention generally relates to methods and devices for synchronization of ion generation with cycling of a discontinuous atmospheric interface. In certain embodiments, the invention provides a system for analyzing a sample that includes a mass spectrometry probe that generates sample ions, a discontinuous atmospheric interface, and a mass analyzer, in which the system is configured such that ion formation is synchronized with cycling of the discontinuous atmospheric interface.

An ICP source (100) for generating ions using an inductively coupled plasma is configured to be coupled to a mass spectrometer (200). The sample is introduced into the plasma along a downwards-pointing vertical direction (G) under the action of gravity. In this manner, the sample can reach the plasma regardless of its condition, e.g., regardless of droplet or particle size. Transport efficiencies of up to 100% can be achieved. The ICP source can be supplied with a continuous stream comprising the sample.

An ultrasonic transmitter (95) and detector (e.g., integrated as an ultrasound transducer) utilized in a feedback control system automatically monitors and/or detects surface profile (e.g., shape) of the liquid-air interface and adjusts the flow rate of sampling liquid to ensure that experimental conditions remain consistent at the time of sample introduction during serial samplings. The feedback control can provide for automated adjustment of the surface profile of the liquid-air interface in accordance with changes in desired set point according to an experimental workflow (e.g., automated adjustment between an interface corresponding to a vortex sampling set point and an overflow cleaning set point). Improvements in desorption efficiency and quality of mass spectrometry data by degassing of the liquid solvent utilized within the sampling interfaces, and/or utilization in a feedback control system for generating data indicative of a surface profile of the liquid-air interface within the interface's sampling port may be realized.

A method and system for injecting a sample into a receiving LC/MS/MS system that is configured to determine a concentration of GenX within the sample, wherein the LC/MS/MS includes ESI. The sample is subjected to one or more of the following ESI conditions: i) a probe gas temperature of approximately 120° C. to approximately 160° C.; ii) a sheath gas heater setting of approximately 150° C. to approximately 275° C.; and iii) a sheath gas flow of approximately 6 L/min to approximately 11 L/min. The concentration of GenX within the sample may have a minimum reporting level of approximately 0.010 μg/L.

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.

A method of ionising a sample is disclosed comprising nebulising a sample which includes first biomolecules such as bovine insulin comprising one or more disulphide (S—S) bonds. A stream of droplet or charged droplets comprising one or more disulphide (S—S) bonds is directed so as to impact upon a target (106) or electrode so as to cause the breaking of a portion of the disulphide bonds. Alternatively, charged droplets may pass through an electric field region determined by an electrode (106) arranged downstream of a nebuliser or electrospray probe and an ion inlet (104) of a mass spectrometer so as to cause the breaking of a portion of the disulphide bonds.