Abstract: Various embodiments of the teachings relate to a system or method for sample preparation or analysis in biochemical or molecular biology procedures. The sample preparation can involve small volume processed in discrete portions or segments or slugs, herein referred to as discrete volumes. A molecular biology procedure can be nucleic acid analysis. Nucleic acid analysis can be an integrated DNA amplification/DNA sequencing procedure.

Abstract: Systems and methods are provided for identifying missing product ions after demultiplexing product ion spectra produced by overlapping precursor ion transmission windows in sequential windowed acquisition tandem mass spectrometry. Overlapping sequential windowed acquisition is performed on a sample. A first precursor mass window and the corresponding first product ion spectrum are selected from a plurality of overlapping stepped precursor mass windows and their corresponding product ion spectra. A product ion spectrum is demultiplexed for each overlapped portion of the first precursor mass window producing two or more demultiplexed first product ion spectra for the first precursor mass window. The two or more demultiplexed first product ion spectra are added together producing a reconstructed summed demultiplexed first product ion spectrum.

Abstract: Systems and methods are provided for providing a DMS precursor ion survey scan. An ion source configured to receive a sample is instructed to ionize the sample using a processor. A DMS device configured to receive ions from the ion source is instructed to separate precursor ions received from the ion source and transmit precursor ions using two or more CoVs using the processor. A mass analyzer configured to receive transmitted precursor ions from the DMS device is instructed to measure the m/z intensities of the transmitted precursor ions across an m/z range at each CoV of the two or more CoVs using the processor. The measured m/z intensities of the transmitted precursor ions received from the mass analyzer are stored as a function of m/z value and CoV using the processor. This produces a stored two-dimensional mapping of m/z intensities of the precursor ions of the sample.

Abstract: MRM triggered MRM, where the triggered MRM transitions make use of mobility device parameter values for the same compound, is performed. A plurality of primary MRM transitions are received and stored together with a mobility device parameter value for each transition as an MRM cycle list. Control information instructs a mobility device and a mass spectrometer to interrogate each MRM transition on the MRM cycle list within an MRM cycle of the mass spectrometer. If a product ion intensity value of an MRM transition exceeds a threshold value for a primary MRM transition, a plurality of secondary MRM transitions of the primary MRM transition with different mobility device parameter values are added to the MRM cycle list. The intensities of the measured secondary MRM transitions provide information on the optimum mobility device parameter for each compound.

Abstract: Systems and methods identify a product ion that does not include an interference. A full product ion spectrum for a mass range of an analyte in a sample is received from a tandem mass spectrometer. A first set of one or more peak parameters is calculated for a product ion in the full product ion spectrum using a first XIC window width. A second set of one or more peak parameters is calculated for the product ion using a second XIC window width. The product ion is identified as not including an interference, if the first set of one or more peak parameters and the second set of one or more peak parameters are substantially the same. The product ion is further confirmed or determined to be from the analyte and not from a matrix of the sample by correlating the product to a precursor ion of the analyte.

Abstract: A vertical clamping device is provided that supports a flow cell component in a vertical configuration in which the flow cell is on an opposite side of the vertical support from the electronic interface. The clamp includes a vertical setting to receive the flow cell component and provides an electronic interface on a vertical surface of the vertical setting. A block supports the fluidics interface and can move in a horizontal direction bringing the fluidics interface into contact with the flow cell component.

Abstract: Methods and systems are provided for triggering an information dependent mass spectrometry scan in real time. A mass spectrometry scan of a separating sample mixture is performed by a mass spectrometer at each time interval of a time period. The mass spectrometer receives the separating sample mixture from a separation device. It is determined at a certain time interval that a received mass spectrometry scan at the time interval and one or more preceding received mass spectrometry scans include two or more time-varying ion signals that represent two or more fragment ion transitions of a known compound. If a characteristic of the two or more time-varying ion signals meets a selection criterion, the mass spectrometer is instructed to perform a dependent mass spectrometry scan of the separating sample mixture for a precursor ion of the known compound at the time interval.

Abstract: MRM triggered MRM, where the triggered MRM transitions make use of mobility device parameter values for the same compound, is performed. A plurality of primary MRM transitions are received and stored together with a mobility device parameter value for each transition as an MRM cycle list. Control information instructs a mobility device and a mass spectrometer to interrogate each MRM transition on the MRM cycle list within an MRM cycle of the mass spectrometer. If a product ion intensity value of an MRM transition exceeds a threshold value for a primary MRM transition, a plurality of secondary MRM transitions of the primary MRM transition with different mobility device parameter values are added to the MRM cycle list. The intensities of the measured secondary MRM transitions provide information on the optimum mobility device parameter for each compound.

Abstract: Compositions are provided comprising a first fluid, in the form of discrete volumes, wherein the discrete volumes are spaced apart from one another by a second fluid that is immiscible with the first fluid. According to various embodiments, the composition can comprise a surface active agent, for example, a surfactant, that lowers, minimizes, and/or eliminates coalescence between two adjacent discrete volumes of the first fluid, in the absence of an applied electric potential or field. In some embodiments, the first fluid can comprise an aqueous solution, for example, containing biological material and/or reagents, and the second fluid can comprise an oil. Systems are also provided that can comprise a conduit system for flowing compositions such as those described above, and circuitry configured to supply an electric potential and/or electric field at, near, and/or adjacent, a junction in the conduit system.

Abstract: A sensor apparatus includes a substrate, a semiconductor device disposed over the substrate, the semiconductor device having a surface electrode structure, and a saccharide coating formed over the surface electrode structure. The saccharide coating can be removed prior to use. The semiconductor device can further include a well and optionally a bead disposed in the well.

Abstract: A vertical clamping device is provided that supports a flow cell component in a vertical configuration in which the flow cell is on an opposite side of the vertical support from the electronic interface. The clamp includes a vertical setting to receive the flow cell component and provides an electronic interface on a vertical surface of the vertical setting. A block supports the fluidics interface and can move in a horizontal direction bringing the fluidics interface into contact with the flow cell component.

Abstract: Various embodiments of the teachings relate to a system or method for sample preparation or analysis in biochemical or molecular biology procedures. The sample preparation can involve small volume processed in discrete portions or segments or slugs, herein referred to as discrete volumes. A molecular biology procedure can be nucleic acid analysis. Nucleic acid analysis can be an integrated DNA amplification/DNA sequencing procedure.

Abstract: Various embodiments relate to systems and/or methods for sample preparation that can be used for biochemical and/or molecular biology procedures involving small volumes, for example, micro volumes or smaller. Methods and systems that can reduce sample size requirements and increase the number of samples on a substrate are provided. Samples can be applied to a plate or other appropriate substrate and can be used for, inter alia, sequencing reactions. In some embodiments, apparatuses, systems, and/or methods for charged analyte collection are provided. Charged analytes in a sample can be electrokinetically collected or extracted from a conduit through a hole formed in a sidewall of the conduit, by application of an electric field that causes the charged analytes to migrate in a direction that is transverse to the conduit.

Abstract: A vertical clamping device is provided that supports a flow cell component in a vertical configuration in which the flow cell is on an opposite side of the vertical support from the electronic interface. The clamp includes a vertical setting to receive the flow cell component and provides an electronic interface on a vertical surface of the vertical setting. A block supports the fluidics interface and can move in a horizontal direction bringing the fluidics interface into contact with the flow cell component.

Abstract: Systems and methods of manipulating discrete volumes of a first fluid in a second fluid are provided. In some embodiments, discrete volumes can be formed in a conduit. In other embodiments, addition fluid can be added to a discrete volume in a first conduit by injecting the addition fluid at a relatively higher pressure. In some embodiments, discrete volumes that normally would not coalesce can be manipulated to be merged together.

Abstract: Systems and methods are provided for identifying missing product ions after demultiplexing product ion spectra produced by overlapping precursor ion transmission windows in sequential windowed acquisition tandem mass spectrometry. Overlapping sequential windowed acquisition is performed on a sample. A first precursor mass window and the corresponding first product ion spectrum are selected from a plurality of overlapping stepped precursor mass windows and their corresponding product ion spectra. A product ion spectrum is demultiplexed for each overlapped portion of the first precursor mass window producing two or more demultiplexed first product ion spectra for the first precursor mass window. The two or more demultiplexed first product ion spectra are added together producing a reconstructed summed demultiplexed first product ion spectrum.

Abstract: Various embodiments relate to systems and/or methods for sample preparation that can be used for biochemical and/or molecular biology procedures involving small volumes, for example, micro volumes or smaller. Methods and systems that can reduce sample size requirements and increase the number of samples on a substrate are provided. Samples can be applied to a plate or other appropriate substrate and can be used for, inter alia, sequencing reactions. In some embodiments, apparatuses, systems, and/or methods for charged analyte collection are provided. Charged analytes in a sample can be electrokinetically collected or extracted from a conduit through a hole formed in a sidewall of the conduit, by application of an electric field that causes the charged analytes to migrate in a direction that is transverse to the conduit.

Abstract: A vertical clamping device is provided that supports a flow cell component in a vertical configuration in which the flow cell is on an opposite side of the vertical support from the electronic interface. The clamp includes a vertical setting to receive the flow cell component and provides an electronic interface on a vertical surface of the vertical setting. A block supports the fluidics interface and can move in a horizontal direction bringing the fluidics interface into contact with the flow cell component.

Abstract: Systems and methods of manipulating discrete volumes of a first fluid in a second fluid are provided. In some embodiments, discrete volumes can be formed in a conduit. In other embodiments, addition fluid can be added to a discrete volume in a first conduit by injecting the addition fluid at a relatively higher pressure. In some embodiments, discrete volumes that normally would not coalesce can be manipulated to be merged together.

Abstract: A vertical clamping device is provided that supports a flow cell component in a vertical configuration in which the flow cell is on an opposite side of the vertical support from the electronic interface. The clamp includes a vertical setting to receive the flow cell component and provides an electronic interface on a vertical surface of the vertical setting. A block supports the fluidics interface and can move in a horizontal direction bringing the fluidics interface into contact with the flow cell component.