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.

Humidification systems and methods to introduce water vapor to a laser-ablated sample prior to introduction to an ICP torch are described. A system embodiment includes, but is not limited to, a water vapor generator configured to control production of a water vapor stream and to transfer the water vapor stream to at least one of a sample chamber of a laser ablation device or a mixing chamber in fluid communication with the laser ablation device, wherein the mixing chamber is configured to receive a laser-ablated sample from the laser ablation device and direct the laser-ablated sample to an inductively coupled plasma torch.

We describe in this application systems and methods for autofocusing in imaging mass spectrometry. The present application describes improvements over current IMS and IMC apparatus and methods through an autofocus component including a plurality of apertures in the autofocus system, such as a plurality of apertures arranged in 2 dimensions. As a plurality of apertures is used, the autofocus system provides redundancy in the event that measurement of focus on the sample from the illuminating radiation passed through one or more of the apertures fails so as to reduce the number of unsuccessful autofocus attempts.

The present invention relates to a method for detecting and mapping the spatial distribution of organic compounds aiming to understand how such organic compounds are distributed on the surfaces of reservoir rocks subjected to injection fluids for oil recovery purposes. The DESI and LAESI techniques may be used in the analysis of rocks from trials of oil recovery in small or large scale. Furthermore, both techniques may be applied in the analysis of compounds present on the surfaces of minerals from aquatic environments.

A mass spectrometry imaging system includes an ionization source located at a first location configured to produce ions from a surface of a sample at the first location; a mass spectrometer located at a second location configured to perform mass spectrometry analysis by analyzing the produced ions based on mass to charge ratio of the ions; and an ion transfer device configured to transfer the ions from the first location to the second location such that the ion transfer device includes a plurality of electrodes, the plurality of electrodes configured to be flexible or flexibly connected to each other, and the ion transfer device is configured to be flexible or re-configurable while transferring the ions.

A method of ion imaging is disclosed that includes automatically sampling a plurality of different locations on a sample using a front device which is arranged and adapted to generate aerosol, smoke or vapour from the sample. Mass spectral data and/or ion mobility data corresponding to each location is obtained and the obtained mass spectral data and/or ion mobility data is used to construct, train or improved a sample classification model.

A method is disclosed comprising providing a biological sample on a swab, directing a spray of charged droplets onto a surface of the swab in order to generate a plurality of analyte ions, and analysing the analyte ions.

In an embodiment, a laser ablation system can include a laser ablation cell and at least a pair of particle-collection-to-transport-tubing interfaces. The laser ablation cell can be configured for ablating a sample or another material, and the laser ablation cell can include a laser unit. The at least a pair of particle-collection-to-transport-tubing interfaces can be configured to gather an ablated sample and direct the ablated sample to an analysis unit. A selected particle-collection-to-transport-tubing interface can be received by the laser ablation cell directly above the laser unit. The at least a pair of particle-collection-to-transport-tubing interfaces can be configured to be interchangeable with one another.

The invention generally relates to systems and methods for conducting reactions and screening for reaction products.

The invention relates to methods and devices for analysis of samples using laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS). The invention provides methods and devices in which individual ablation plumes are distinctively captured and transferred to the ICP, followed by analysis by mass cytometry.