An ion source for a mass spectrometer is disclosed comprising an ultrasonic transducer which focuses ultrasonic energy onto a surface of a sample fluid without directly contacting the sample fluid.

GT Systems and methods are disclosed for controlling humidity and/or temperature during chemical analysis of a sample material. Specifically, the present application relates to microfluidics systems and methods, e.g. involving ADE, open port interface (OPI) and/or mass spectrometry (MS), for controlling humidity and/or temperature during chemical analysis of a sample material. The present systems and methods allow a user to modify the temperature of a microplate during dispensing. This allows the user to study reactions that occur at temperatures different than room temperature, e.g. at body temperature. Additionally, modifying and/or controlling the temperature of a microplate during dispensing can allow a user to maintain quality of a sample through maintaining a proper temperature, e.g. a cool temperature to prevent degradation of a sample. As part of the present invention, Applicant determined how to avoid phase changes, e.g. evaporation, that are particularly concerning because of the small amounts of sample involved.

Methods of detecting at least one analyte in at least one liquid sample are described. The method includes the steps of desalting the liquid sample, acoustically ejecting the desalted sample into an open-port interface, diluting the desalted sample, and transferring the diluted sample to an ionization source, ionizing the diluted sample, and selecting ions of interest by ion mobility

A sample introduction system providing variable online dilution of a sample is described. In one or more implementations, a device includes a spectrometry analysis system that employs example techniques in accordance with the present disclosure includes an inline dilution environment, including a first valve assembly configured to prepare a sample by accepting at least one of the sample, a diluent, a carrier, or an internal standard, where the first valve assembly includes a first sample loop; and a second valve assembly configured to prepare the sample by accepting the sample from the first valve assembly, where the second valve assembly is coupled to the first valve assembly, and where the second valve assembly includes a second sample loop.

Focused acoustic radiation, referred to as tonebursts, are applied to a volume of liquid to generate a set of droplets. In one embodiment, a first toneburst is applied to temporarily raise a mound or protuberance on a free surface of the fluid. After the mound has reached a certain state, at least two additional toneburst can be applied to the protuberance to sequentially eject multiple bursts of multiple droplets. In one embodiment, the state of the mound can be maintained by a sustained acoustic signal, during which time multiple additional tonebursts can be applied to sequentially eject multiple bursts of multiple droplets from the mound.

Mass spectrometry systems and methods including ionization devices are provided. The ionization device includes either a gas pulse valve or a piezoelectric striker. The ionization device is configured to direct force to the back of a substrate, where an analyte of interest is deposited on the front of the substrate. The impact ionizes the analyte and the ions are directed into a mass spectrometer for analysis.

In one aspect, a method of extracting a target analyte from a sample for introduction into a mass spectrometer is disclosed, which includes mixing the sample with a paramagnetic medium to form a mixture, subjecting the mixture to a magnetic field gradient to form a non-homogenous distribution of at least one of the analyte and at least one interfering component of the sample, if any, thereby enhancing a concentration of the target analyte within a spatial location of said mixture, extracting at least a portion of the target analyte from that spatial location, and introducing at least a portion of the extracted target analyte into said mass spectrometer.

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 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.

According to some embodiments, systems and methods for surface impact ionization of liquid phase and aerosol samples are provided. The method includes accelerating a liquid or aerosol sample, colliding the sample with a solid collision surface thereby disintegrating the sample into both molecular ionic species (e.g., gaseous molecular ions) and molecular neutral species (e.g., gaseous sample), and transporting the disintegrated sample to an ion analyzer. Some embodiments of the method further comprise discarding the molecular neutral species. Such embodiments transport substantially only the molecular ionic species to the ion analyzer.