Systems and methods are described for controlling flow of a purge gas introduced to an ablation cell between samples to remove atmospheric gas. A system embodiment includes, but is not limited to, a spray chamber including a spray chamber body, a transfer gas inlet configured to receive gas from a laser ablation sample cell, a first outlet line configured to transfer gas from the spray chamber to an inductively-coupled plasma torch, and a second outlet line coupled to the spray chamber body, the second gas outlet having a larger internal cross-sectional area than an internal cross-sectional area of the first outlet line; and a valve fluidically coupled to the second outlet line, the valve configured to transition between at least an open configuration configured to permit transfer gas through the second outlet line and a closed configuration configured to prevent transfer of gas through the second outlet line.

A method of analysis using mass spectrometry and/or ion mobility spectrometry is disclosed. The method comprises: using a first device to generate smoke, aerosol or vapour from a target comprising or consisting of a microbial population; mass analysing and/or ion mobility analysing said smoke, aerosol or vapour, or ions derived therefrom, in order to obtain spectrometric data; and analysing said spectrometric data in order to analyse said microbial population.

Systems and methods for atmospheric pressure chemical ionization are provided herein. In various aspects, the APCI apparatus, systems, and methods can provide an asymmetric sample spray into a vaporization chamber asymmetrically (e.g., off axis from the longitudinal axis of the vaporization chamber) so as to increase the interaction of the molecules in the sample spray with the vaporization chamber's sidewalls (and expose more of the molecules to the heat generated thereby), which can thereby result in improved consistency and/or efficiency of ion formation, and/or increased sensitivity relative to conventional APCI techniques.

Methods and systems for delivering liquid sample to an ion source and subsequent analysis by mass spectrometry. In accordance with various aspects of the present teachings, MS-based systems and methods are provided in which desorption solvent is used in sampling interface to desorb analyte species from an SPME device that is coupled to an ion source to ionize analyte species desorbed into the desorption solvent for MS analysis (e.g., without a liquid chromatography (LC) column between the sampling interface and the ion source). In various aspects of the methods and systems described herein, configuring the sampling interface can be optimized so as to reduce the fluid volume dead space about the fluid inlet so as to concentrate the one or more analyte species desorbed at optimized conditions from the SPME substrate in a decreased volume of the desorption solvent when the SPME device is inserted into sampling interface.

In a laser assisted spectroscopy system, an apparatus for bypassing the fluid conduit and a method of bypassing the fluid conduit, opening the sample chamber and replacing the sample, closing and purging the sample chamber, and removing the fluid conduit bypass and returning to online status is addressed by the present disclosure.

A method for analyzing biological samples using mass spectrometry or ion mobility spectrometry that includes producing gas-phase ions and neutrals from the sample in a proximity of the sample; transferring the produced ions from the sample to a distance via a flexible or re-configurable ion transfer device such that the flexible or re-configurable ion transfer device includes a plurality of electrodes configured to be flexible or flexibly connected to each other, and the ion transfer device is configured to be flexible while transferring the ions to allow the ion transfer device to form one or more curvatures; and separating the produced ions with a mass spectrometer or a mobility analyzer located at the distance to provide spectrometric results.

The invention generally relates to ion generation using modified wetted porous materials. In certain aspects, the invention generally relates to systems and methods for ion generation using a wetted porous substrate that substantially prevents diffusion of sample into the substrate. In other aspects, the invention generally relate to ion generation using a wetted porous material and a drying agent. In other aspects, the invention generally relates to ion generation using a modified wetted porous substrate in which at least a portion of the porous substrate includes a material that modifies an interaction between a sample and the substrate.

A system for sampling a sample material includes a probe which can have an outer probe housing with an open end. A liquid supply conduit within the housing has an outlet positioned to deliver liquid to the open end of the housing. The liquid supply conduit can be connectable to a liquid supply for delivering liquid at a first volumetric flow rate to the open end of the housing. A liquid exhaust conduit within the housing is provided for removing liquid from the open end of the housing. A liquid exhaust system can be provided for removing liquid from the liquid exhaust conduit at a second volumetric flow rate. A droplet dispenser can dispense drops of a sample or a sample-containing solvent into the open end of the housing. A sensor and a processor can be provided to monitor and maintain a liquid dome present at the open end.

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.

A coated capillary tube having a tunable resistance in an ion transfer device, including an inlet end in communication with an atmospheric-pressure ion source, an outlet end in communication with a vacuum region of a mass spectrometer, a body elongated along an axis from the inlet end to the outlet end, and an inside surface defining a bore having an inner diameter is disclosed. The coated capillary tube also includes a resistive coating on the inside surface of the capillary tube, in which the resistive coating includes at least one layer comprising oxides or nitrides of a metal and discrete metal particles of a different metal embedded therein.