Abstract: Devices and methods for separating sample constituents are provided. The subject devices are characterized by having a fluid flow path with at least one electrophoretic separation element positioned at a region thereof. The separation element includes an element for applying an electric field across the fluid flow path and a trapping element for trapping sample constituents that migrate out of the flow path when an electric field is applied across the fluid flow path. In using the subject devices, sample is moved past the separation element and an electric field is applied across the flow path such that constituents of the sample migrate into the trapping element. The subject devices and methods find use in a variety of applications, including protein separation applications.

Abstract: An assay method includes providing a luminescent nanocrystal; combining a solution having an adenosine triphosphate molecule; and displaying a light emission by the luminescent nanocrystal and the solution combined.

Abstract: An assay system (300) comprising providing a platform (102) having a contact surface (104); immobilizing an amino acid group (108), having an amine side group (109), on the contact surface (104); transforming the amine side group (109), in the amino acid group (108) to a ketone group (120); and reacting an indicator (122) with the ketone group (120) for displaying a light emission (128) from the indicator (122).

Abstract: An enzyme detection method includes forming a caged substrate; releasing an uncaged substrate by cleaving a caging molecules from the caged substrate; and emitting a light emission from a Bioluminescence Resonance Energy Transfer luminescent nanocrystal conjugate reacting with the uncaged substrate.

Abstract: An electrically controlled microfluidic system (1300) is provided including: providing a probe fluid (128) extending longitudinally; restricting a longitudinal movement of the probe fluid (128) by capillary effects; moving the probe fluid (128) longitudinally using an electric field, an electric field gradient, or a combination thereof; reacting a fluid under test (130) with the probe fluid (128) to start a reacting mixture; and measuring the reacting mixture over distance, time, or a combination thereof.

Abstract: A microfluidic liquid stream configuration system is provided including providing a substrate; forming a first co-planar electrode and a second co-planar electrode on the substrate; applying a dielectric layer, with a controlled surface energy, on the first co-planar electrode and the second co-planar electrode; forming an input reservoir on the first co-planar electrode and a second co-planar electrode; supplying a liquid in the input reservoir for analysis; and imposing an electric field, an electric field gradient, or a combination thereof on the liquid for respectively driving surface charge or dipole moments in the liquid for configuring a liquid stream.

Abstract: An ion source for an analytical instrument is described. The ion source comprises a capillary tip and counter-electrode interface and a feedback loop control device connected to the capillary tip and counter-electrode interface. The feedback loop control device comprises a transimpedance amplifier, a DC de-coupler, a frequency to voltage converter, a controller, and a voltage-controlled high-voltage power supply that provides a tip to counter-electrode voltage to the capillary tip and counter-electrode interface. The feedback loop control device measures the modulation frequency of ionization currents and provides a feedback adjustment of the tip-to-counter-electrode voltage to maintain ionization efficiency.

Abstract: An electrospray device for a mass spectrometry system is described. The electrospray device comprises a body portion and a tip portion extending from the body portion. The tip portion comprises a polymeric material. The electrospray device also comprises a hydrophobic coating substantially selectively covering the tip portion.

Abstract: The present invention relates to a microfluidic device for separating the components of a fluid sample. A cover plate is arranged over the first surface of a substrate, which, in combination with a microchannel formed in the first surface, defines a separation conduit for separating the components of the fluid sample. An inlet port in fluid communication with the separation conduit allows a mobile phase containing a gradient of a selected mobile-phase component to be introduced from an integrated gradient-generation means to the separation conduit. A method is also provided for separating the components of a fluid sample using a mobile phase containing a gradient of a selected mobile-phase component, wherein the gradient is generated within a small volume of mobile phase.

Abstract: A process of fabricating a memory cell that includes a substrate that has a first region and a second region with a channel therebetween by forming a gate above the channel of the substrate, forming a bitline and siliciding the bitline.

Abstract: Devices and methods for separating sample constituents are provided. The subject devices are characterized by having a fluid flow path with at least one electrophoretic separation element positioned at a region thereof. The separation element includes an element for applying an electric field across the fluid flow path and a trapping element for trapping sample constituents that migrate out of the flow path when an electric field is applied across the fluid flow path. In using the subject devices, sample is moved past the separation element and an electric field is applied across the flow path such that constituents of the sample migrate into the trapping element. The subject devices and methods find use in a variety of applications, including protein separation applications.

Abstract: An electrospray device for a mass spectrometry system is described. The electrospray device comprises a body portion and a tip portion extending from the body portion. The tip portion comprises a polymeric material. The electrospray device also comprises a hydrophobic coating substantially selectively covering the tip portion. The hydrophobic coating is electrically nonconductive.

Abstract: An ion source for an analytical instrument is described. The ion source comprises a capillary tip and counter-electrode interface and a feedback loop control device connected to the capillary tip and counter-electrode interface. The feedback loop control device comprises a transimpedance amplifier, a DC de-coupler, a frequency to voltage converter, a controller, and a voltage-controlled high-voltage power supply that provides a tip to counter-electrode voltage to the capillary tip and counter-electrode interface. The feedback loop control device measures the modulation frequency of ionization currents and provides a feedback adjustment of the tip-to-counter-electrode voltage to maintain ionization efficiency.

Abstract: A microfluidic structure having an electrostatic sealing device is disclosed. The electrostatic sealing device includes a first electrode and a second electrode opposite the first electrode. At least one of the electrodes has an elastic layer facing the other electrode. The second electrode is capable of moving toward the first electrode and forming a seal with the first electrode in response to a voltage difference between the two electrodes. The electrostatic sealing device eliminates the need for mechanical components that are traditionally used for generating a mechanical force between two components of a microfluidic structure and thus reduces complexity of the microfluidic structure and possible interference with optical interrogation of the microfluidic structure. Moreover, the seal can be established or removed simply by turning the voltage on or off.

Abstract: An electrospray device for a mass spectrometry system is described. The electrospray device comprises a body portion and a tip portion extending from the body portion. The tip portion comprises a polymeric material. The electrospray device also comprises a hydrophobic coating substantially selectively covering the tip portion. The hydrophobic coating is electrically nonconductive.

Abstract: An electrospray device for a mass spectrometry system is described. The electrospray device comprises a body portion and a tip portion extending from the body portion. The tip portion comprises a polymeric material. The electrospray device also comprises a hydrophobic coating substantially selectively covering the tip portion.

Abstract: An ion source for an analytical instrument is described. The ion source comprises a capillary tip and counter-electrode interface and a feedback loop control device connected to the capillary tip and counter-electrode interface. The feedback loop control device comprises a transimpedance amplifier, a DC de-coupler, a frequency to voltage converter, a controller, and a voltage-controlled high-voltage power supply that provides a tip to counter-electrode voltage to the capillary tip and counter-electrode interface. The feedback loop control device measures the modulation frequency of ionization currents and provides a feedback adjustment of the tip-to-counter-electrode voltage to maintain ionization efficiency.

Abstract: The present invention relates to a microfluidic device for separating the components of a fluid sample. A cover plate is arranged over the first surface of a substrate, which, in combination with a microchannel formed in the first surface, defines a separation conduit for separating the components of the fluid sample. An inlet port in fluid communication with the separation conduit allows a mobile phase containing a gradient of a selected mobile-phase component to be introduced from an integrated gradient-generation means to the separation conduit. A method is also provided for separating the components of a fluid sample using a mobile phase containing a gradient of a selected mobile-phase component, wherein the gradient is generated within a small volume of mobile phase.

Abstract: The present invention relates to a microfluidic device for separating the components of a fluid sample. A cover plate is arranged over the first surface of a substrate, which, in combination with a microchannel formed in the first surface, defines a separation conduit for separating the components of the fluid sample. An inlet port in fluid communication with the separation conduit allows a mobile phase containing a gradient of a selected mobile-phase component to be introduced from an integrated gradient-generation means to the separation conduit. A method is also provided for separating the components of a fluid sample using a mobile phase containing a gradient of a selected mobile-phase component, wherein the gradient is generated within a small volume of mobile phase.

Abstract: The fluid flow rate within a microfluidic passageway of a microfabricated device is determined by measuring the time-of-flight of a heat pulse coupled into the fluid. Since the propagation velocity of the heat trace is generally slower than the mean flow rate of the flow, additional processing provides the appropriate scaling needed to obtain an accurate fluid flow rate measurement. The scaling factor is based on the geometry of the structure and the thermal properties of the fluid and the materials used for the device.