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.

The present disclosure describes embodiments directed to a bubble based ion source system comprising an ion source configured to generate a plurality of ions, an ion channel, an electrode, and/or any other components. The ion source can include a container at least partially comprising a solvent or solution, a bubble generator coupled to the container configured to generate a plurality of bubbles within the solvent, and/or any other component. The ion channel can receive ions that are generated based on solvent from the bubbles.

The invention generally relates to systems and methods for sample analysis using swabs. In certain aspects, the invention provides systems that include a probe having a conductive proximal portion coupled to a porous material at a distal portion of the probe that is configured to retain a portion of a sample that has contacted the porous material, and a mass spectrometer having an inlet. The system is configured such that the porous material at a distal portion of the probe is aligned over the inlet of the mass spectrometer.

A method of analysis using mass spectrometry and/or ion mobility spectrometry is disclosed comprising: (a) using a first device to generate smoke, aerosol or vapour from a target in vitro or ex vivo cell population; (b) mass analysing and/or ion mobility analysing said smoke, aerosol or vapour, or ions derived therefrom, in order to obtain spectrometric data; and (c) analysing said spectrometric data in order to identify and/or characterise said target cell population or one or more cells and/or compounds present in said target cell population.

A mass spectrometer, MS, 100 is described. The MS 100 comprises: a first chamber 110, comprising a set of ports P close able by respective doors, for receiving sample plates including respective unique device identifiers, UDIs, therein and/or there through, wherein the set of ports P includes a first port P1 having a first door D1 and a second port P2 having a second door D2; a second chamber 120, fluidically couple able with the first chamber 110 via the second port P2, wherein the second chamber 120 is fluidically coupled to and/or comprises an ion source 130, an analyser 140 and an ion detector 150, for mass spectrometry of samples included on the sample plates received therein; and an imager 160, coupled to the second chamber 120, configured to image the UDIs of the sample plates; a controller 170 configured to control the imager 160; wherein the MS 100 is arrangeable in: a first arrangement, wherein a first sample plate 1A of a set of sample plates 1 is received in the first chamber 110 via the first port P1, wherein the first door D1 is open and wherein the second door D2 is closed, and wherein the first sample plate 1A includes a first UDI U1A of a set of UDIs; a second arrangement, wherein the first sample plate 1A is in the first chamber 110, wherein the first door D1 is closed and wherein the second door D2 is closed; and a third arrangement, wherein the first sample plate 1A is received in the second chamber 120 via the second port P2, wherein the second door D2 is closed; wherein the controller 170 is configured to control the imager 160 to image the first UDI U1A of the first sample plate 1A, when the MS 100 is arranged in the third arrangement.

A mass spectrometer, MS, 100 is described. A mass spectrometer comprises: a set of chambers, for receiving sample plate holders therein and/or therethrough, wherein the sample plate holders are arranged to hold respective subsets of sample plates therein and/or thereon and wherein the sample plate holders include respective identifiers, wherein the set of chambers is fluidically coupled to and/or comprises an ion source, an analyser and an ion detector, for mass spectrometry of samples included on the sample plates received therein; a reader configured to read a first identifier, of a set of identifiers, included on a first sample plate holder, of a set of sample plate holders, optionally including a first sample plate, of a set of sample plates, held therein and/or thereon, received in the set of chambers; and a controller configured to control the reader to read the first identifier of the first sample plate holder received in the set of chambers.

An ADE device identifies an identifiable sequence of one or more ejections from at least one sample using a different value or pattern of values for one or more ADE parameters. The identifiable one or more ejections are performed to produce one or more mass peaks that have a different feature value or pattern of feature values for one or more peak features than other mass peaks produced. Ejection times are stored. One or more detected peaks with the different feature values or pattern of feature values are identified as produced by the identifiable one or more ejections. A delay time is calculated from the time of the identifiable ejections and the time of the identified detected peaks and the peaks are aligned with samples using delay time, stored times, and order of the samples.

Technology for analyzing collections of substance samples. Systems in accordance with the disclosure can include one or more sample handlers, sample capture devices, mass analysis instruments, and controllers; the controllers being operative, in accordance with instructions received from at least one of an operator input device and machine-interpretable instructions stored in memory accessible by the controller, to generate signals configured to cause the sample handler to collectively retrieve from a sample source a plurality of samples of one or more substances, and deliver the plurality of collected samples to the at least one sample capture device; cause the sample capture device to independently capture at least one of the collectively retrieved samples delivered by the sample handler, and transfer the at least one captured sample to a mass analysis instrument; and cause the mass analysis instrument to ionize and detect one or more particles of the transferred treated sample.

A mass spectrometer is disclosed comprising a rotatable isolation valve 1 having a curved, spherical, cylindrical or concave portion. At least a portion of an ion guide 2 is positioned so as to extend within a swept volume of the isolation valve 1 enabling the ion guide 2 to be positioned close to a second downstream ion guide 3 and for ions to be transmitted from the first 2 ion guide to the second ion guide 3 with high ion transmission efficiency.

A mass spectrometer is disclosed comprising a rotatable isolation valve 1 having a curved, spherical, cylindrical or concave portion. At least a portion of an ion guide 2 is positioned so as to extend within a swept volume of the isolation valve 1 enabling the ion guide 2 to be positioned close to a second downstream ion guide 3 and for ions to be transmitted from the first 2 ion guide to the second ion guide 3 with high ion transmission efficiency.