The present disclosure relates to a lattice substrate adapted for use in direct ionization mass spectrometry. The substrate may have a plurality of tessellated unit cells forming an integral structure. Each tessellated unit cell may have a dimension of no more than about 1.5 mm and may include a plurality of pores arranged in an ordered pattern. The substrate may further include a form factor suitable for use with a direct ionization mass spectrometry system.

The invention generally relates to systems and methods for separating ions at about or above atmospheric pressure. In certain embodiments, the invention provides systems that include an ionization source that generates ions and an ion trap. The ion trap is maintained at about or above atmospheric pressure and includes a plurality of electrodes and at least one inlet configured to receive a gas flow and at least one outlet. The system is configured such that a combination of a gas flow and one or more electric fields produced by the electrodes separates the ions based on mass-to-charge ratio and sends the separated ions through the at least one outlet of the ion trap.

An integrated system for liquid separation and electrospray ionization includes an emitter-enabled capillary column including an emitter portion and a column portion; and a retractable protective sleeve for covering and/or supporting the emitter portion along at least a portion of its axis. The protective sleeve is mounted around the emitter-enabled capillary column. The retractable protective sleeve is moveable to an extended position wherein a tip of the emitter portion is covered by the protective sleeve. A resilient member is provided to bias the protective sleeve towards the extended position. The protective sleeve is enclosed and moveable within an outer electrically conductive sheath adapted for insertion within a holder having a high-voltage contact point. The sheath is adapted to contact the high-voltage contact point and provide an electrical connection to enable the emitter-enabled capillary column to receive a high voltage. The sheath has a recess to receive the high-voltage contact point.

A method for identifying a target component of interest in a specimen by probe electrospray ionization mass spectrometry, including: (1) adsorbing the target component of interest onto an extraction phase for adsorbing the target component of interest from the specimen by immersing a probe into the specimen, wherein the probe is at least partially coated with the extraction phase; (2) removing the probe from the specimen and optionally quick rising it by dipping in or spraying water or acetone/water mixtures; (3) adhering solvent to the extraction phase; (4) desorbing the target component of interest into the solvent from the extraction phase; (5) electrospraying the target component of interest desorbed in the solvent adhered to the probe on the ionization source at atmospheric pressure by applying a voltage to the probe to spray aerosolized ionized droplets out of the probe; and (6) identifying the target component of interest present in the aerosolized ionized droplets.

The invention generally relates to integrated synthesis and analysis systems and methods of use thereof.

Using ion mobility separation to improve a duty cycle of a mass spectrometer is described. In one aspect, a mass spectrometer can use an ion-mobility spectrometer to allow for more multiply-charged ions to transmit through than singly-charged ions. This results in a mass analyzer to perform a mass analysis with more multiply-charged ions.

A system and method for providing sample into an electrospray device such as a mass spectrometer by providing a sample at a near constant flow through a sample delivery tube with a specified dimensionality through an emitter. These dimensions and feed rates result in higher pressures than would exist in the prior art with some of these pressures being greater than 1000 psi. This system enables increased sample throughput of up to 1200 samples per day.

Provided herein, among other things, is a method of ionizing a first stream of liquid by an electrospray ion source having a nebulizer, wherein the first stream of liquid may comprise an analyte. In some embodiments, the method may comprise: a) providing the first stream of liquid to the nebulizer; b) adding a second stream of liquid to the first stream of liquid, wherein the second stream of liquid comprises a co-solvent that has a relatively high boiling point and an enhancement solvent that a relatively high boiling; and c) nebulizing and ionizing the resulting liquid.

Methods, devices, and systems for performing nebulization of a sample from a fluid channel of a microfluidic device are described. The systems or devices disclosed herein may comprise microfluidic devices that comprise a gas channel used for nebulization of the sample at a fluid outlet of the microfluidic device. In some instances, the disclosed devices may be designed to perform isoelectric focusing followed by further characterization of the separated analytes using electrospray ionization coupled with nebulization to introduce the samples into a mass spectrometer. The disclosed methods, devices, and systems provide for fast, accurate separation and characterization of protein analyte mixtures or other biological molecules by isoelectric point.

An ion analyzer including: a base member fixed to a ion outflow port and having a cylindrical concave part; a cylindrical first conductive member accommodated in the concave part; a first ion flow controller fixed to an exposed end of the first conductive member; a cylindrical insulating member inserted into the first conductive member; a rod-shaped second conductive member inserted into the insulating member; a second ion flow controller being fixed to an exposed end of the second conductive member; a first power feeding unit that, when accommodated in the concave part, comes into contact with the first conductive member; and a second power feeding unit that, when accommodated in the concave part, comes into contact with the second conductive member when the first conductive member accommodates the second conductive member and the insulating member.