Abstract: A method and apparatus for analyzing a response of a cellular entity to a component of interest are described. The cellular entity may be a cell or an organoid. The method includes processing a heterogeneous population of cellular entities that are combined with the component of interest. An entity flow containing the cellular entities is generated. A morphological image of a portion of the entity flow having a cellular entity is acquired and the cellular entity is identified as belonging to an entity class. The entity flow is provided to a mass spectrometer system that performs an analysis of the cellular entity. The mass spectrometer analysis of the cellular entity can be correlated with the identified entity class. Alternatively, portions of the entity flow are deposited as samples on a sample plate and the mass spectrometer analysis is performed offline, for example, using an ionization process with each sample.

Abstract: Systems, methods, and devices for detecting leaks in chromatography systems are disclosed. The leak detection system includes a sealable compartment disposed to surround at least one component of a chromatography system. The detector is in communication, e.g., fluid communication, with an interior of the sealable compartment and configured to detect the leak by various mean including the presence of liquid or the presence of vapor, or both within the sealable compartment.

Abstract: A method of ionizing a sample includes providing an aqueous liquid and directing a jet comprising carbon dioxide to interact with the provided aqueous liquid. One or both of the aqueous liquid and the jet comprise the sample. At least a portion of the sample is ionized due to the interaction.

Abstract: Embodiments of the present invention feature devices and methods for performing mass analysis. One embodiment of the device comprises an inlet housing for mounting on the first wall between the area of low pressure and the area of high pressure. The inlet housing has passages and restrictions which can be adjusted with respect to a sample plume or changed by substituting alternative inlet housings.

Abstract: An ion source is disclosed that alternates between ionizing analytes in a sample by electrospray ionization and impact ionization.

Abstract: Apparatus and methods for performing chromatography may include a chromatography column and a vacuum insulated jacket having an inner wall and an outer wall. A vacuum area may be formed between the inner wall and the outer wall. The inner wall of the vacuum insulated jacket may surround the chromatography column. A gap may be formed between an outer wall of the chromatography column and the inner wall of the vacuum insulated jacket. The vacuum insulated jacket may extend beyond one or more end frits of the column. The gap may be filled with one or more materials so as to form an insulating or thermal barrier.

Abstract: Described is a method for purging a fluid channel is a low pressure gradient formation liquid flow system. Control of the fluid channels for multiple solvents allows for one or more static volumes of solvents not intended for use in an isocratic flow to be purged from their fluid channels to avoid contamination of the isocratic solvent. Advantageously, the method avoids the need to modify equipment or to reconfigure a pumping system so that the inlet is directly coupled to a single solvent source. Thus there is no need to bypass existing valves and liquid coupling components where solvents are combined during conventional gradient operation.

Abstract: Described are techniques for use in connection with analyzing a droplet. One or more droplets of a sample are formed on a surface of a digital microfluidic device. The droplets are manipulated to perform processing using said one or more droplets generating one or more resulting droplets. The one or more resulting droplets may be transferred from the microfluidic device to another device for analysis. The one or more droplets may also be provided to the digital microfluidic device from yet another device or analysis instrument.

Abstract: An interface for a mass spectrometer system is provided. The interface can include an inner ceramic tube fabricated from a first ceramic material and an outer tube fabricated from a second ceramic material surrounding the inner ceramic tube. The inner ceramic tube can have high electrical resistivity and high thermal conductivity and the intermediate ceramic tube can have an electrical resistivity that is at least an order of magnitude higher than the electrical resistivity of the first ceramic material and a thermal conductivity that is at least an order of magnitude higher than the thermal conductivity of the first ceramic material.

Abstract: An ion inlet assembly for connecting to a mass spectrometer housing is disclosed comprising a sampling limiting body having a sampling orifice. The sampling limiting body comprises a nickel disk wherein the disk and sampling orifice are made or formed by an electroforming process.

Abstract: An ion optical element that may be used as an ion guide in a mass spectrometer, as a reflectron in a time-of-flight mass spectrometer, as an ion mobility drift tube in an ion mobility spectrometer, or as a collision cell or reaction cell in a mass spectrometer. The ion optical element has an inner tube made of a first ceramic material within an outer ceramic tube made of a second ceramic material. The electrical resistivity of the second ceramic material is two orders of magnitude or more higher than the electrical resistivity of the first ceramic material. In certain embodiments, the thermal conductivity of the second ceramic material is at least about an order of magnitude higher than the thermal conductivity of the first ceramic material.

Abstract: An ion source for a mass spectrometer and a method of ionizing a sample are disclosed. A droplet generator is configured to emit a stream of analyte droplets, which are ionized upon impact with a target, thus forming an ion stream. Preferably, the droplets have a diameter that is greater than a preset value to increase the kinetic energy of the droplets. Additionally, the droplet generator can be configured to create a gas flow that increases the kinetic energy of the droplets. In one embodiment, the target is positioned upstream of an inlet of a mass spectrometer so that the ion stream enters the inlet. In another preferred embodiment, the target is positioned downstream of the inlet so that the stream of droplets passes through the inlet of the mass spectrometer, and the inlet is provided with a pressure drop that increases the kinetic energy of the droplets.

Abstract: Described is a method for purging a fluid channel is a low pressure gradient formation liquid flow system. Control of the fluid channels for multiple solvents allows for one or more static volumes of solvents not intended for use in an isocratic flow to be purged from their fluid channels to avoid contamination of the isocratic solvent. Advantageously, the method avoids the need to modify equipment or to reconfigure a pumping system so that the inlet is directly coupled to a single solvent source. Thus there is no need to bypass existing valves and liquid coupling components where solvents are combined during conventional gradient operation.

Abstract: An ion optical element that may be used as an ion guide in a mass spectrometer, as a reflectron in a time-of-flight mass spectrometer, as an ion mobility drift tube in an ion mobility spectrometer, or as a collision cell or reaction cell in a mass spectrometer. The ion optical element has an inner tube made of a first ceramic material within an outer ceramic tube made of a second ceramic material. The electrical resistivity of the second ceramic material is two orders of magnitude or more higher than the electrical resistivity of the first ceramic material. In certain embodiments, the thermal conductivity of the second ceramic material is at least about an order of magnitude higher than the thermal conductivity of the first ceramic material.

Abstract: An apparatus for performing liquid chromatography includes a chromatography column, and an insulating member surrounding the chromatography column wherein the insulating member is formed from a vacuum chamber surrounding the chromatography column. Another apparatus for performing liquid chromatography includes a chromatography column, and an insulating member surrounding the chromatography column, wherein the insulating member includes aerogel. Also described is a method of insulating a chromatography column comprising forming a jacket surrounding the chromatography column, and creating a vacuum chamber in an area between the jacket and the chromatography column.

Abstract: A device for withdrawing heat energy from air. The device includes a layer of a substantially hydrophobic coating on a heat exchange surface. The coating has a lower surface tension than water, to repel water and prevent the formation of water condensation on the surface. For example, the coating can be a fluoropolymer such as 1,1,2,3,3,3 hexafluoropropene.

Abstract: A method of ionizing a sample includes providing an aqueous liquid and directing a jet comprising carbon dioxide to interact with the provided aqueous liquid. One or both of the aqueous liquid and the jet comprise the sample. At least a portion of the sample is ionized due to the interaction.

Abstract: Embodiments of the present invention are directed to resonating detection devices in which the sample flows through a conduit having a section in which the conduit is grouped or concentrated with the point of maximum movement. An exemplary device includes a primary conduit, at least one first flex section, at least one second flex section and at least one analysis section. The primary conduit cooperates with an energizer for inducing vibration and a programmed calculator for determining a resonant frequency to calculate a mass related parameter of the solution carried therein.

Abstract: An ion source for a mass spectrometer and a method of ionizing a sample are disclosed. A droplet generator is configured to emit a stream of analyte droplets, which are ionized upon impact with a target, thus forming an ion stream. Preferably, the droplets have a diameter that is greater than a preset value to increase the kinetic energy of the droplets. Additionally, the droplet generator can be configured to create a gas flow that increases the kinetic energy of the droplets. In one embodiment, the target is positioned upstream of an inlet of a mass spectrometer so that the ion stream enters the inlet. In another preferred embodiment, the target is positioned downstream of the inlet so that the stream of droplets passes through the inlet of the mass spectrometer, and the inlet is provided with a pressure drop that increases the kinetic energy of the droplets.

Abstract: A method includes passing a mobile phase fluid flow comprising liquefied CO2 through a separation column; then introducing a makeup fluid flow into the mobile phase fluid flow to form a mixed fluid flow; and then splitting the mixed fluid flow.