Abstract: An analysis apparatus is provided with a storage tank, an injection nozzle, a syringe, a collection nozzle, a test sample tank, a microchip having two or more separation channels, detectors, a waste liquid tank, a controller, and a power supply. The collection nozzle collects a specimen which becomes a test sample from a test sample container housing the specimen, and transfers the specimen to the test sample tank. The separation channels separate characteristic components contained in the test sample. The injection nozzle is distanced from the collection nozzle and injects the test sample from the test sample tank into the separation channels. The detectors detect the separated characteristic components in the separation channels.

Abstract: Microfluidic methods of assaying molecule switching are provided. Aspects of the methods include microfluidically separating a sample containing the molecule of interest and then employing the resultant separation pattern to determine a switching characteristic of the molecule. Also provided are microfluidic devices, as well as systems and kits that include the devices, which find use in practicing embodiments of the methods. The methods, devices, systems and kits find use in a variety of different applications, such as analytical and diagnostic assays.

Abstract: The invention provides microfluidic devices, systems, and methods for manipulating an object within a channel of a microfluidic device using an external electrode. The device has a channel disposed within the device, the channel having no included electrodes. The channel has a wall, at least a portion of which is penetrable by an electric field generated external to the device, the wall being penetrable such that the electric field extends through the wall portion and into a region within the channel. The system includes the microfluidic device and an electrode external to and not bonded to the device. In the method, the external electrode is placed adjacent to the device and energized to generate an electric field that extends through the wall of the device and into the channel, thereby manipulating an object within the channel.

Abstract: A mechanism is provided for manipulating a molecule. The molecule is driven into a nanochannel filed with electrically conductive fluid. A first vertical electric field is created inside the nanochannel to slow down the molecule and/or immobilize the molecule. The molecule is stretched into non-folded linear chains by the first vertical electric field and a horizontal electric field. Monomers of the molecule are sequentially read.

Abstract: An apparatus (1) for the measurement of a concentration of a charged species in a sample (10) is disclosed. The sample (10) comprises a plurality of types of charged species and at least one insoluble component. The apparatus (1) comprises a first circuit with a voltage control device (54) connectable to two first electrodes (30, 30?) arranged along a channel (12) holding the sample (10) and a second circuit with a conductivity detection device (55) connectable to two second electrodes (5, 5?) arranged in the channel (12). The first circuit and the second circuit are dc and ac electrically isolated from each other.

Abstract: Methods, structures, devices and systems are disclosed for rapid enrichment and mass transport of biomolecules (e.g., such as proteins) or other small molecules and particles using electrodeless dielectrophoresis (eDEP). In one aspect, a device to aggregate molecules includes a substrate that is electrically insulating, an electrically insulative material formed on the substrate and structured to form a channel to carry an electrically conducting fluid containing particles, a constriction structure formed of the electrically insulative material and located in the channel to narrow a channel dimension and forming an opening with a size in the nanometer range, and a circuit coupled to the substrate to apply an ac electric field and a dc bias electric field along the channel, in which the constriction structure is structured to magnify the applied ac electric field to produce forces that operate collectively to aggregate the particles.

Abstract: A mechanism is provided for capturing a molecule via an integrated system. An alternating voltage is applied to a Paul trap device in an electrically conductive solution to generate electric fields. The Paul trap device is integrated with a nanopore device to form the integrated system. Forces from the electric fields of the Paul trap device position the molecule to a nanopore in the nanopore device. A first voltage is applied to the nanopore device to capture the molecule in the nanopore of the nanopore device.

Abstract: A microfluidic device for separating, fractionating, or preconcentrating analytes contained in an electrolyte having at least two reservoirs separated by at least one microchannel and/or nanochannel. At least part of the wall of the microchannel is made of and/or coated interiorly with a conducting and polarizable material or group of materials constituting a polarizable interface or a network of polarizable interfaces. In that at least one electrode or at least one electrode network is connected at at least one point of the polarizable material or group of materials, the surface electrical conductance of said material being equal to at least 100 nS.

Abstract: A device for electrically controlled transport of ions between a source and a target electrolyte, including: a first source electrode and a first target electrode, each capable of conducting ions and electrons, wherein the source electrode is arranged to receive ions from the source electrolyte and the target electrode is arranged to release ions to the target electrolyte.

Abstract: Individual biological micro-objects can be deterministically selected and moved into holding pens in a micro-fluidic device. A flow of a first liquid medium can be provided to the pens. Physical pens can be structured to impede a direct flow of the first medium into a second medium in the pens while allowing diffusive mixing of the first medium and the second medium. Virtual pens can allow a common flow of medium to multiple ones of the pens.

Abstract: A biopolymer optical analysis apparatus is provided with a biopolymer characteristic analysis chip including a solid substrate, nanopores provided in the substrate, and electrically conductive thin films on the substrate, at least portions of the thin films facing the nanopores, a light source and an irradiation optical system for producing Raman scattered lights from biopolymers entering the nanopores, and a detection device including a Raman scattered light collecting system, a separating component that splits collected light into transmitted light and reflected light, an image-forming optical system through which the split lights form images, and a two-dimensional detector for detecting the lights forming the images. External light from the light source and the irradiation optical system is applied to the characteristic analysis chip, and the detection device detects Raman scattered lights from biopolymers in the analysis chip.

Abstract: A method for analyzing hemoglobin by electrophoresis, capable of analyzing hemoglobin A1c (HbA1c) and modified hemoglobin with improved accuracy in a shortened analysis time is provided. The method for analyzing hemoglobin by electrophoresis includes performing electrophoresis under conditions in which an acidic substance having two or more carboxyl groups is present in an electrophoresis solution. At least two of the carboxyl groups of the acidic substance each have an acid dissociation constant (pKa) lower than the pH of the electrophoresis solution at the time of analysis.

Abstract: In one aspect, single-sided microfluidic devices are described herein. In some embodiments, a single-sided microfluidic device comprises a substrate, a photoconductive layer positioned over the substrate, electrical contacts in electrical communication with the photoconductive layer, and a dielectric assembly positioned over the photoconductive layer. The dielectric assembly comprises a hydrophobic surface for receiving a liquid. In some embodiments, the dielectric assembly has an effective capacitance of about 10 ?F/m2 to about 10,000 ?F/m2 and/or an average thickness between about 20 nm and about 2000 nm.

Abstract: The procedure of dielectric electrophoresis (dielectrophoresis or DEP) utilizes field-polarized particles that move under the application of positive (attractive) and/or negative (repulsive) applied forces. This invention uses negative dielectric electrophoresis (negative dielectrophoresis or nDEP) within a microchannel separation apparatus to make particles move (detached) or remain stationary (attached). In an embodiment of the present invention, the nDEP force generated was strong enough to detach Ag-Ab (antigen-antibody) bonds, which are in the order of 400 pN (piconewtons) while maintaining the integrity of the system components.

Abstract: The combined value of integrating optical forces and electrokinetics allows for the pooled separation vectors of each to be applied, providing for separation based on combinations of features such as size, shape, refractive index, charge, charge distribution, charge mobility, permittivity, and deformability. The interplay of these separation vectors allow for the selective manipulation of analytes with a finer degree of variation. Embodiments include methods of method of separating particles in a microfluidic channel using a device comprising a microfluidic channel, a source of laser light focused by an optic into the microfluidic channel, and a source of electrical field operationally connected to the microfluidic channel via electrodes so that the laser light and the electrical field to act jointly on the particles in the microfluidic channel. Other devices and methods are disclosed.

Abstract: The invention provides compositions, methods and kits for high speed, high resolution of analytes by capillary electrophoresis starting with uncoated capillaries. The compositions comprise a sieving component, comprising a non-crosslinked acrylamide polymer, and a surface interaction component, comprising at least one uncharged and non-crosslinked water-soluble silica-adsorbing polymer. Methods for employing the novel compositions in capillary electrophoresis are provided. Kits comprising the novel compositions for use in the novel methods are also provided.

Abstract: The invention provides a capillary electrophoresis apparatus which can improve the operability and measuring speed. According to the invention, a sensor for identifying the type of sample containers is fixed at the position away from a capillary anode electrode. The sensor is made to be closer to the sample containers by moving a moving stage so that the sample containers disposed on the moving stage can be identified by the sensor. A fixing apparatus for fixing at least a pair of sample containers is provided on the moving stage.

Abstract: An apparatus for capillary zone electrophoresis includes a polyelectrolyte multilayer positioned in a capillary tube for analytical separations of macromolecules. The capillary comprises a passage defined by passage walls comprising fused silica and the polyelectrolyte multilayer positioned within the passage. The polyelectrolyte multilayer comprises layers with alternating charge. The apparatus includes a power supply having a positive electrode and a negative electrode for generating an electric field therebetween and a sensor positioned adjacent the passage for sensing macromolecules.

Abstract: A method is provided for producing, in a substrate, an enclosed channel or enclosed cavity comprising at least one functional nanofiber, the method comprising the steps of providing a first substrate and a second substrate; forming a channel or cavity on the first substrate or the second substrate; electrospinning at least one functional nanofiber on the first substrate; assembling the first and second substrates, wherein the first substrate is placed over the second substrate, or the second substrate is placed over the first substrate; and bonding the first substrate and the second substrate to form the substrate, thereby forming an enclosed channel or enclosed cavity comprising the at least one functional nanofiber in the substrate. An enclosed channel or cavity comprising at least one functional electrospun nanofiber is also provided. A microfluidic device is also provided comprising an enclosed channel or cavity comprising at least one functional electrospun nanofiber.

Abstract: Methods of forming a microelectronic packaging structure and associated structures formed thereby are described. Those methods may include attaching a microfluidic die to a package structure, wherein the microfluidic die comprises a plurality of asymmetric electrodes that may be coupled with signal pads disposed within the package structure.

Abstract: The invention relates to devices and methods for nanopore sequencing. The invention provides for using the signals from n-mers to provide sequence information, for example where the system has less than single base resolution. The invention includes arrays of nanopores having incorporated electronic circuits, for example, in CMOS. In some cases, the arrays of nanopores comprise resistive openings for isolating the electronic signals for improved sequencing. Methods for controlling translocation of through the nanopore are disclosed.

Abstract: A system and method for detecting a single-molecule using an integrated circuit which includes at least one membrane having a nanopore located between first and second reservoirs and a low-noise preamplifier having an electrode formed on the surface thereof is provided. The method includes passing a target molecule through the nanopore, and measuring a current through the nanopore to detect the presence of a biomolecular entity, if any.

Abstract: The present disclosure provides devices, systems and methods for sequencing nucleic acid molecules. Nucleic acid molecules can be sequenced with a high accuracy (e.g., greater than 97% in a single pass) using a chip comprising an array of independently addressable nanopore sensors at a density of at least about 500 sites per 1 mm2. An individual nanopore sensor can include a nanopore in a membrane that is adjacent or in proximity to a sensing electrode.

Abstract: The present invention relates to a plastic capillary tube for capillary electrophoresis, in which the plastic capillary tube has an inlet opening and an outlet opening and, furthermore, has at least one hole in the capillary tube wall and the diameter of the hole on the inside of the capillary tube wall dL(innen) lies in the range from 0.5 ?m to 30 ?m.

Abstract: Described is a capillary column cartridge. The cartridge can be used to perform separations according to various techniques such as capillary gas chromatography, capillary electrophoresis and capillary liquid chromatography. The cartridge includes a capillary column secured in a cartridge body. The capillary column includes an inlet port and an outlet port that, in some embodiments, are disposed on a planar surface of the body. When the body is engaged to a separation system module, the inlet port is aligned to receive a sample to be separated and the outlet port is aligned to provide the separated sample to the separation system module. The path of the capillary through the body has a non-planar path shape such as a coil shape. Consequently, longer column lengths can be accommodated, leading to an improvement in separation resolution. The body can include a material having a high thermal conductivity to achieve improved thermal performance.

Abstract: A mechanism for capturing molecules is provided. A nanopore through a membrane separates a first chamber from a second chamber, and the nanopore, the first chamber, and the second chamber are filled with ionic buffer. A narrowed neck is at a middle area of the first chamber, and the narrowed neck is aligned to an entrance of the nanopore. The narrowed neck has a high intensity electric field compared to other areas of the first chamber having low intensity electric fields. The narrowed neck having the high intensity electric field concentrates the molecules at the middle area aligned to the entrance of the nanopore. Voltage applied between the first chamber and the second chamber drives the molecules, concentrated at the entrance of the nanopore, through the nanopore.

Abstract: A method and system for analyzing biomolecules using a high concentration electrolytic solution and a low concentration electrolytic solution.

Abstract: A system and method employing at least one semiconductor device, or an arrangement of insulating and metal layers, having at least one detecting region which can include, for example, a recess or opening therein, for detecting a charge representative of a component of a polymer, such as a nucleic acid strand proximate to the detecting region, and a method for manufacturing such a semiconductor device. The system and method can thus be used for sequencing individual nucleotides or bases of ribonucleic acid (RNA) or deoxyribonucleic acid (DNA). The semiconductor device includes at least two doped regions, such as two n-typed regions implanted in a p-typed semiconductor layer or two p-typed regions implanted in an n-typed semiconductor layer. The detecting region permits a current to pass between the two doped regions in response to the presence of the component of the polymer, such as a base of a DNA or RNA strand.

Abstract: A flow cell for a microfluidic device can include a chamber, first microfluidic entry and exit channels, second microfluidic entry and exit channels, a first electrode, and a second electrode. A microfluidic device can include a microfluidic channel, a laser to excite fluorescent material, and a detector to detect fluorescence emission. Methods of merging a droplet from an emulsion in to a second stream of fluid and of detecting a content of a droplet in a stream are further disclosed.

Abstract: Techniques for characterizing a molecule are described herein. In one example, a portion of the molecule is trapped in a nanopore, a variable voltage is applied across the nanopore until the trapped portion of molecule is moved within the nanopore, and the molecule is characterized based on the electrical stimulus required to affect movement of at least a portion of the trapped portion of the molecule within the nanopore.

Abstract: Droplet actuator for conducting droplet operations, such as droplet transport and droplet dispensing, is provided. In one embodiment, the droplet actuator may include an electrode that is rotationally but not reflectively symmetrical.

Abstract: A detection method of detecting analytes of interest which are present in a liquid. The detection method including the steps of forming drops of liquid on a first surface by capillary breaking of a finger of liquid, which is initially formed by liquid dielectrophoresis. The thus formed drops each come into contact with a different detection surface, which is arranged facing the first surface. Analytes of interest which are present in each of the drops are detected at the corresponding detection surface.

Abstract: A compensated patch-clamp system for polynucleotide sequencing and other applications.

Abstract: An apparatus (11) for processing a sample, circuit board (8008) suited to use in such an apparatus and a method of processing are provided in which the apparatus (11) is provided with alignment features to assist in provided the circuit board and a sample cartridge (9) in the correct position relative to one another. In this way, the plurality of sections for processing a sample in the cartridge (9) are positioned against a plurality of elements, such as a heater (4) for heating the sample cartridge (9) or an electrical contact (EP1-EP4) for powering features on the sample cartridge (9), correctly and can operate independently of one another.

Abstract: A complete capillary electrophoresis (CE) system that is capable of providing a continuous flow of effluent at the exit of the flow-through outlet vial is provided. A self-contained capillary electrophoresis system with a flow-through outlet vial for interfacing with mass spectrometry includes a capillary having an upstream inlet end and a downstream terminus end; an electrically conductive hollow needle having an inner wall defining an internal tapered chamber, the internal tapered chamber dimensioned and configured to slidably accept the terminus end of the capillary, the capillary longitudinally inserted into and mounted within the internal tapered chamber to a distance whereby the terminus end of the capillary abuts the inner wall of the needle at the taper; and wherein a micro-reservoir is formed between the terminus end of the capillary and the downstream exit orifice.

Abstract: A quality control (“QC”) system for PET or SPECT radiopharmaceuticals is disclosed that contains a disposable, no-leakage, self-contained QC cassette, which interfaces with the QC system. The QC system may include a shield that substantially surrounds the cassette such that the area and the cassette are both shielded. The QC cassette may contain shielding also. The QC cassette contains components for conducting one or more QC tests. These components include sensor and devices for performing various QC tests on radiopharmaceuticals. The QC system may contain a number of sub-systems and devices for supporting the QC tests. The QC system may produce a QC report containing the test results.

Abstract: The ability to form and maintain gradients is essential for the study of response of cells to various stimuli. The invention includes devices and methods for the high-throughput, reproducible formation of gradients for the study of living cells. The invention includes microfluidics device with a lest chamber having a depth flanked by flow-through channels having a deeper depth. Flow of two different fluids through the flow-through channels results in the creation of a gradient by diffusion across the test chamber having essentially no flow.

Abstract: A normal person (i.e. a control) and liver diseases such as drug induced liver injury, an asymptomatic hepatitis B carrier, an asymptomatic hepatitis C carrier, chronic hepatitis B, chronic hepatitis C, liver cancer, a nonalcoholic fatty liver disease (NAFLD), nonalcoholic steatohepatitis (NASH), and simple steatosis (SS) are identified by measuring the concentrations of ?-Glu-X (X represents an amino acid or an amine) peptides or the levels of AST or ALT in blood and carrying out, for example, a multiple logistic regression based on the measured value.

Abstract: A micro-analytical platform for performing electrophoresis-based immunoassays was developed by integrating photopolymerized cross-linked polyacrylamide gels within a microfluidic device. The microfluidic immunoassays are performed by gel electrophoretic separation and quantifying analyte concentration based upon conventional polyacrylamide gel electrophoresis (PAGE). To retain biological activity of proteins and maintain intact immune complexes, native PAGE conditions were employed. Both direct (non-competitive) and competitive immunoassay formats are demonstrated in microchips for detecting toxins and biomarkers (cytokines, c-reactive protein) in bodily fluids (serum, saliva, oral fluids). Further, a description of gradient gels fabrication is included, in an effort to describe methods we have developed for further optimization of on-chip PAGE immunoassays.

Abstract: Disclosed are systems, devices, methods, and other implementations, including a device to detect at least one target species in a sample, with the device including a microfluidic channel configured to receive the sample containing the at least one target species and a biocompatible ferrofluid in which the at least one target species is suspended, a detector to determine the at least one target species in the sample, and at least two of electrodes positioned proximate the microfluidic channel, the at least two electrodes configured to generate controllable magnetic forces in the sample containing the ferrofluid when a controllable at least one electrical current is applied to the at least two electrodes. The generated controllable magnetic forces causes the at least one target species to be directed towards the detector. Also disclosed are devices for separating target species in a ferrofluid, and for focusing target species suspended in a ferrofluid.

Abstract: The invention relates to a nanowire device for manipulation of charged molecules, comprising a tubular nanowire with a through-going channel; a plurality of individually addressable wrap gate electrodes arranged around said tubular nanowire with a spacing between each two adjacent wrap gate electrodes and means for connecting the wrap gate electrodes to a voltage source. The invention further relates to a nanowire system comprising at least one nanowire device, and to a method for manipulating of charged molecules within a through-going channel of a tubular nanowire.

Abstract: A thread-based microfluidic guiding system is provided and includes a substrate, two fiber threads arranged on the substrate in a cross manner. The two fiber threads are used as physical guiding pathways to guide a sample fluid and a buffer fluid, respectively. The two fiber threads have capillary action, so that the sample fluid, the buffer fluid or a mixture fluid thereof can flow along fiber surfaces of the two fiber threads, which can be pre-treated by plasma. The thread-based microfluidic guiding system of the present invention is different from recessed microfluidic channel structures, and can simplify system structure, lower manufacture cost, accelerate detection operation and enhance detection sensitivity.

Abstract: In an apparatus for analyzing small number of samples, wasteful consumption of a polymer as a separation Medium is suppressed. The apparatus has a configuration provided with a plurality of capillary units each of which can be attached/detached to/from the apparatus, and performs analysis for capillaries after sealing of a polymer by attaching the capillaries by the number in accordance with the number of samples. Since analysis can be performed by using capillaries by the number identical with that of the samples to be analyzed, wasteful polymer is not used in the capillaries not used for the analysis. In addition, the polymer injection mechanism is unnecessary and the polymer is not necessary for maintenance and upon starting of analysis. An electrophoresis apparatus which is small in the size with no polymer injection mechanism, and with low running cost not wastefully consuming the polymer can be provided.

Abstract: The invention is an improved multiplex capillary electrophoresis instrument or module with at least four and preferably six user-accessible vertically stacked drawers. An x-z stage moves samples from the user accessible drawers to the capillary array for analysis. A computer program allows users to add capillary electrophoresis jobs to a queue corresponding to the analysis of rows or plates of samples without stopping or interrupting runs in progress.

Abstract: Devices and methods are provided for performing droplet-based solid phase processing steps on a digital microfluidic device. A solid phase material, which may be a porous solid phase material such as a porous polymer monolith is formed or located on a digital microfluidic element. The solid phase may be formed by an in-situ method in which the digital microfluidic array is actuated to transport a droplet of solid phase pre-cursor solution to a selected element on the array, and subsequently processed to form a solid phase on the array element. The integration of a solid phase material with a digital microfluidic array enables a wide range of applications including solid phase extraction and sample concentration.

Abstract: A method of actuating, comprising: filling at least a portion of a tube (21) with a liquid (19) containing electrolytes, the tube (21) having an inner surface that is electrically chargeable when in contact with the liquid (19); positioning an object (28) in fluid communication with the liquid in the tube; and applying an electrical field (46) along a lengthwise axis across the tube at said portion for producing a pressure in the liquid. The pressure in the liquid exerts a force on the object so as to actuate the object (28, 30). An actuator (20) is also disclosed.

Abstract: Digital microfluidics system manipulates samples in liquid droplets within disposable cartridges that have bottom layer, top layer, and gap between the bottom and top layers. The system has a base unit with cartridge accommodation sites and a central control unit for controlling selection of individual electrodes of electrode arrays and for providing these electrodes with individual voltage pulses for manipulating liquid droplets within the cartridges by electrowetting. The system further has board accommodation sites located at the cartridge accommodation sites that each can take up a swappable electrode board having an electrode array and electrical board contact elements individually connected to electrodes of the electrode array. Each board accommodation site has electrical base unit contact elements that are connected to the central control unit and that are configured to engage with the electrical board contact elements of a swappable electrode board that is placed at the board accommodation site.

Abstract: A system and method employing at least one semiconductor device, or an arrangement of insulating and metal layers, having at least one detecting region which can include, for example, a recess or opening therein, for detecting a charge representative of a component of a polymer, such as a nucleic acid strand proximate to the detecting region, and a method for manufacturing such a semiconductor device. The system and method can thus be used for sequencing individual nucleotides or bases of ribonucleic acid (RNA) or deoxyribonucleic acid (DNA). The semiconductor device includes at least two doped regions, such as two n-typed regions implanted in a p-typed semiconductor layer or two p-typed regions implanted in an n-typed semiconductor layer. The detecting region permits a current to pass between the two doped regions in response to the presence of the component of the polymer.

Abstract: An efficient method of processing a target material in a sample using a microfluidic device including an elastic membrane.

Abstract: Described are devices and methods for forming one or more nanomembranes including electroactive nanomembranes within a nanowell or nanotube, or combinations thereof, in a support material. Nanopores/nanochannels can be formed by the electroactive nanomembrane within corresponding nanowells. The electroactive nanomembrane is capable of controllably altering a dimension, a composition, and/or a variety of properties in response to electrical stimuli. Various embodiments also include devices/systems and methods for using the nanomembrane-containing devices for molecular separation, purification, sensing, etc.