Abstract: The present invention is directed to solubilizing compounds, a device and a method for solubilizing and removing carboxylic acids and especially fatty acids from oils, fats, aqueous emulsion, aqueous media and organic solutions. Devices utilizing the inventive method shall be used for separating carboxylic acids from oils, fats, aqueous emulsion, lipophilic media or organic solutions, respectively by preparing an aqueous micro- or nanoemulsion of the carboxylic acids especially the fatty acids and the solubilizing compound which contains at least one amidino and/or gianidino group. Solubilization effects of solubilizing compounds combined with the inventive use of separation methods for carboxylic acids can be used to treat persons in need of removal of fatty acids or analyze carboxylic acids from blood or process other solutions in food, pharmacy, chemistry, bio fuel industry or other industrial processings.

Abstract: A microfluidic separation device is provided that includes a sample channel having a first sample channel region and a second sample channel region, where a cross-section of the first sample channel region is smaller than a cross-section of the second sample channel region. The invention further includes a detection region having a first detection region and a second detection region, where a cross-section of the first detection region is larger than a cross-section of the second detection region and the second sample channel region is connected to the first detection region. Additionally, the invention includes a marker input channel disposed to input markers into the second sample channel region, where the markers are larger than the cross-section of the first sample channel region and the cross-section of the second detection region, where the markers collect in the first detection region.

Abstract: Provided is a device and method of manipulating particles. The device includes: a channel for accommodating an electrolyte solution including particles to be manipulated; an anode and cathode for imposing a direct current (DC) electric field on the channel; metal strip(s) attached to an inner wall of the channel and resulting in induced-charge electroosmosis near a surface of the channel; a DC power supply unit for supplying a DC voltage to the anode and the cathode of the channel; control electrodes on both sides of the metal strip(s) to locally tune the induced-charge electroosmosis on the metal strip(s) regardless of the global electric field across the channel; and a DC power supply unit for supplying a DC voltage to the control electrodes.

Abstract: Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

Abstract: A technique for controlling the motion of one or more charged entities linked to a polymer through a nanochannel is provided. A first reservoir and a second reservoir are connected by the nanochannel. An array of electrodes is positioned along the nanochannel, where fluid fills the first reservoir, the second reservoir, and the nanochannel. A first electrode is in the first reservoir and a second electrode is in the second reservoir. The first and second electrodes are configured to direct the one or more charged entities linked to the polymer into the nanochannel. An array of electrodes is configured to trap the one or more charged entities in the nanochannel responsive to being controlled for trapping. The array of electrodes is configured to move the one or more charged entities along the nanochannel responsive to being controlled for moving.

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: A microfluidic device includes a plurality of array elements configured to manipulate one or more droplets of fluid on an array, each of the array elements including a top substrate electrode and a drive electrode between which the one or more droplets may be positioned, the top substrate electrode being formed on a top substrate, and the drive electrode being formed on a lower substrate; and active matrix drive circuitry arranged to provide drive signals to the top substrate and drive electrodes of the plurality of array elements to manipulate the one or more droplets among the plurality of array elements. With respect to one or more of the array elements the active matrix drive circuitry is configured to provide the drive signals to the top substrate and drive electrodes to selectively manipulate the one or more droplets within the array element both by Electro-wetting-on-Dielectric (EWOD) and by Dielectrophoresis (DEP).

Abstract: A molecule trapping method includes forming a fluid bridge between a first reservoir and a second reservoir, translocating a molecule from the first reservoir to the second reservoir through the fluid bridge, detecting when a segment of the molecule is in the fluid bridge, breaking the fluid bridge and forming an a gap between the first and the second reservoirs, thereby trapping a segment of the molecule in the gap and making measurements on the segment of the molecule.

Abstract: A nanopore sensor comprises second electrophoresis electrode or micropump, second fluidic reservoir, second micro-nanometer separation channel, substrate, sub-nanometer-thick functional layer, first micro-nanometer separation channel, first electrophoresis electrode or micropump, and electrophoresis electrode or micropump that are sequentially assembled. An opening and a nanopore are provided through the substrate and the sub-nanometer-thick functional layer, respectively. A first electrode for measuring ionic current is provided in the first micro-nanometer separation channel, and a second electrode for measuring ionic current is provide in the second micro-nanometer separation channel. The present invention provides a simple method to prepare a sub-nanometer functional layer having a nanopore extending through the sub-nanometer-thick functional layer. The pore size is comparable to the spacing between two adjacent bases in a DNA strand required for single-base resolution sequencing.

Abstract: A microfluidic apparatus and method for performing electrophoretic separation of compounds. The method comprises the steps of: a) providing a separation buffer; b) providing a sample solution in fluid contact with the separation buffer; c) applying an electric field to the separation buffer; and d) producing a variable bulk flow of the separation buffer in a direction substantially aligned with said electric field. Fluid contact between the separation buffer and the sample solution is made through a separation column having a length in the range of from approximately 0.01 mm to approximately 5 mm. By the foregoing, compounds can be sequentially detected and quantified.

Abstract: Provided is a capillary electrophoresis device including a holder preventing a septum from coming off when a capillary is pulled out, and also allowing containers to be taken out in any order. In the capillary electrophoresis device for separating and analyzing a sample such as a DNA and a protein by electrophoresis, the holder includes: a septum having a capillary hole through which a capillary penetrates; a container for storing a solution; and a container-accommodation unit for accommodating the container. A hole formed in the septum engages with an engagement portion formed on the container, and thereby the septum is held to cover the container.

Abstract: Various embodiments provide an exemplary lab-on-a-chip (LOC) system that serves as an analytical tool and/or as a separation medium for an electrolyte solution including various charged molecular species. The LOC system can include an integrated nanofluidic FET device in combination with suitable analysis systems. By applying and controlling a longitudinal electric field and a transverse electric potential, the flow and the pH of the electrolyte solution in the nanofluidic channels can be controlled.

Abstract: The present invention provides a method for analyzing hemoglobin by capillary electrophoresis, that allows the apparatus to be smaller in size, allows a highly precise analysis to be obtained, and allows the analysis to be performed in a short period of time.

Abstract: Using multiple dichroics mirrors to split and redirect different wavelength regions of light in a multi-wavelength fluorescence detection system.

Abstract: An integrated capillary electrophoresis system comprising a universal interface is disclosed. The universal interface includes one or more of the following structural elements: a chip assembly that receives a capillary electrophoresis CE chip; a fluidic interface for coupling fluids between the chip assembly and external sources or destinations; a first electrical interface for coupling power from an external source to the chip assembly; a second electrical interface for coupling electrical signals from the chip assembly to external analysis electronics; an optical interface for coupling optical signals between the chip assembly and external sources or destinations; and a docking station for uniting and spatially locating the various other structural elements.

Abstract: An optically-induced dielectrophoresis chip including a substrate, a first electrode layer disposed on the substrate, and an interface modification layer disposed on the first electrode layer. A photo-conductive layer is disposed on the interface modification layer and includes an optical absorbent polymeric material. A barrier layer is disposed on the photo-conductive layer, and a compartment forming layer is disposed on the barrier layer defining a compartment. A second electrode layer covers the compartment forming layer.

Abstract: A device for selective preconcentration/detection of charged analytes contained in an electrolyte having at least two reservoirs separated by at least one rectilinear microchannel with no lengthwise axis X intersection and having at least one controllable voltage source configured to generate a potential difference between the ends of the rectilinear microchannel. The device has means for generating a controllable pressure that is associated with at least one of the reservoirs and is able to generate a pressure gradient between the two ends of the microchannel. The microchannel has, in its median part, means that are configured to generate at least one change in the surface area to volume ratio charge, the device configured to selectively concentrate the charged analytes in the median part of the microchannel upstream and/or downstream of the means configured to generate at least one change in the surface area to volume ration charge.

Abstract: A nanosensor comprising a substrate having a hole; a first insulating layer disposed on the substrate and having a first nanopore at a location corresponding to the hole in the substrate; first and second electrodes disposed on the first insulating layer, wherein the first and second electrodes are spaced apart from each other with the first nanopore positioned therebetween; a first electrode pad disposed on at least a portion of the first electrode; a second electrode pad disposed on at least a portion of the second electrode; and a protective layer disposed on at least a portion of the first and second electrode pads; as well as a method for manufacturing same.

Abstract: A technique for a nanodevice is provided that includes a reservoir filled with a conductive fluid and a membrane separating the reservoir. The membrane includes an electrode layer having a tunneling junction formed therein. A nanopore is formed through the membrane, and the nanopore is formed through other layers of the membrane such that the nanopore is aligned with the tunneling junction of the electrode layer. When a voltage is applied to the electrode layer, a tunneling current is generated by a base in the tunneling junction to be measured as a signature for distinguishing the base. When an organic coating is formed on an inside surface of the tunneling junction, transient bonds are formed between the electrode layer and the base.

Abstract: Microfluidic devices in which electrokinetic mechanisms move droplets of a liquid or particles in a liquid are described. The devices include at least one electrode that is optically transparent and/or flexible.

Abstract: Low molecular weight serum components (less than 10,000 m.w.), in vaccinated animals and a human subject who has been exposed to a threat agent inadvertently, bound to purified O-polysaccharide (OPS, a polymer of formamido-mannose) and a candidate of a threat agent, such as Brucella suis 145 vaccine is disclosed. These components formed a loose reversible precipitin with OPS in a high-salt borate-buffered agarose gel and bound to the candidate vaccine as observed by capillary electrophoresis. By using modified capillary electrophoresis, the invention also discloses the presence of two larger serum components, one similar in size to that of serum albumin and one resembles that of mannan-binding lectin, that bound to the vaccine. An indirect method for identifying vaccination is the presence of antibodies against Brucella-OPS-antibodies. ELISA, capillary electrophoresis and animal challenge studies showed that as high as 30% of the control animals did not require vaccination.

Abstract: This invention provides a device and methods for increasing the concentration of a charged species in solution, wherein the solution containing the concentrated species is exposed to the environment. Such solution can be formed on a surface or on a tip of a measurement device. The open-environment concentration technique overcomes the disadvantages of in-channel concentration devices, especially by eliminating flow-induced delivery processes that lead to concentration losses. Combined with direct contact dispensing, methods of this invention can be used for various applications such as immunoassay and MALDI-MS.

Abstract: Techniques are generally described that include electrokinetic pumping an emulsion comprising an ionic fluid and a nonpolar fluid to promote flow of the ionic fluid by electro-osmotic flow and drag the nonpolar fluid by viscous drag forces. In some examples, the electrokinetic pump may be utilized to deliver one or more reagents within a fluidic reactor system, such as a micro-scale reactor system. In some additional examples, a reagent may be dissolved in the nonpolar fluid of a first emulsion and pumped through the electrokinetic pump to a mixing channel to allow the reagent of the first emulsion to react with a reagent of second emulsion to form a reactive product.

Abstract: A channel device including a nanosize channel through which single molecule flows, at least one electrode pair arranged near the nanosize channel, and an AC power source that applies an AC voltage to the electrodes. This channel device is useful for identifying molecules one by one. Furthermore, a channel device including a nanosize channel through which single molecule flows, a branching portion, and a plurality of branching channels, wherein (i) an electrode pair is arranged near the nanosize channel so as to sandwich the nanosize channel between the electrodes, or (ii) one electrode of the electrode pair is located near the nanosize channel, whereas the other is arranged near the branching channels. This channel device is useful for separating single molecule. The present channel device achieves identification or separation at an accuracy of 100% in principle. A sample treatment apparatus according to present invention includes a channel device, a measurement section, and an arithmetic processing section.

Abstract: A method and apparatus for moving droplets passed a porous obstructions in microfluidic devices is presented. The invention describes the process of using of an enabling droplet to allow a droplet to pass an obstruction. The enabling droplet and the unfiltered droplet approach the obstruction from opposite sides, merge together within the obstruction, and the interface on the enabling side of the droplet is actuated to pull fluid through the obstruction. This technique was successful for filters with pore sizes between 2 ?m and 72 without the use of surfactants. This invention can (1) move droplets past physical obstructions, (2) allow fluid within a particle to pass an obstruction while limiting the motion of man-made or biological particles within the droplet, (3) sort particles based on size in droplet-based microfluidic devices, or (4) provide an interface between continuous and discrete flow regions on a microfluidic device.

Abstract: Apparatus, system, and method are provided for cutting a linear charged polymer inside a nanopore. A first voltage is applied to create an electric field in a first direction. A second voltage is applied to create an electric field in a second direction, and the first direction is opposite to the second direction. When the electric field in the first direction and the electric field in the second direction are applied to a linear charged polymer inside a nanopore, the linear charged polymer is cut at a location with predetermined accuracy.

Abstract: Device and Process for isolating, purifying, concentrating and/or enriching at least one organic compound by electrokinetic migration through liquid membranes by use of an electronic potential and chambers with a preset pH value is described in the present application. The liquid membranes contain an organic solvent capable of transporting an ionized form of said at least one organic compound.

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: The present invention relates to a droplet-based nucleic acid amplification apparatus and system. According to one embodiment, a droplet microactuator is provided made using a first substrate including a fluorescing material and including a detection region for detecting a fluorescence signal from a droplet, which detection region is coated with a light absorbing, low fluorescence or non-fluorescing material.

Abstract: The invention includes compositions, devices, and methods for analyzing a polymer and/or polymer unit. The polymer may be a homo- or hetero-polymer such as DNA, RNA, a polysaccharide, or a peptide. The device includes electrodes that form a tunnel gap through which the polymer can pass. The electrodes are functionalized with a reagent attached thereto, and the reagent is capable of forming a transient bond to a polymer unit. When the transient bond forms between the reagent and the unit, a detectable signal is generated and used to analyze the polymer.

Abstract: The present invention relates to an immunoaffinity device for capturing one or more analytes present at high or low concentrations in simple or complex matrices. The device is designed as an integrated modular unit and connected to capillary electrophoresis or liquid chromatography for the isolation, enrichment, separation and identification of polymeric macromolecules, primarily protein biomarkers. The integrated modular unit includes an analyte-concentrator-microreaction device connected to a modified cartridge-cassette.

Abstract: A filter includes a membrane having a plurality of nanochannels formed therein. A first surface charge material is deposited on an end portion of the nanochannels. The first surface charge material includes a surface charge to electrostatically influence ions in an electrolytic solution such that the nanochannels reflect ions back into the electrolytic solution while passing a fluid of the electrolytic solution. Methods for making and using the filter are also provided.

Abstract: A kit for determining for a female subject the implantation potential of embryos obtained or to be obtained by assisted fertilization is described. The kit includes at least one reagent suitable for detection of levels of FF G-CSF or FF G-CSF mRNA, such as anti-G-CSF antibody or a nucleic acid probe for detection of levels of G-CSF mRNA. The kit may also include a set of concentration standards of FF G-CSF and aspirator tips for removing an oocyte and follicular fluid.

Abstract: The presently-disclosed subject matter provides microfluidic devices comprised of two or more carbon nanotube membranes disposed at predetermined intervals within a microchannel. Further provided are methods of using the same for the electrokinetic separation of one or more molecules of interest from a sample.

Abstract: The invention provides methods and systems for ruggedizing a nucleic acid analyzing apparatus. The ruggedized apparatus can be used reliably and effectively in uncontrolled environments, such as, for example at a crime scene to collect and analyze forensic data, as well as in semi-controlled environments, such as, for example at a point of care location.

Abstract: A printed circuit board structure is coated with an encapsulant within which microfluidic channels have been formed. The microfluidic channels are formed by soldering fluidic connections to metal traces on a surface of the printed circuit board structure prior to encapsulation. The metal traces are removed by etching after encapsulation to form microchannels within the encapsulant.

Abstract: Provided are fabrication, characterization and application of a nanodisk electrode, a nanopore electrode and a nanopore membrane. These three nanostructures share common fabrication steps. In one embodiment, the fabrication of a disk electrode involves sealing a sharpened internal signal transduction element (“ISTE”) into a substrate, followed by polishing of the substrate until a nanometer-sized disk of the ISTE is exposed. The fabrication of a nanopore electrode is accomplished by etching the nanodisk electrode to create a pore in the substrate, with the remaining ISTE comprising the pore base. Complete removal of the ISTE yields a nanopore membrane, in which a conical shaped pore is embedded in a thin membrane of the substrate.

Abstract: A three-dimensional nanochannel device and a method of manufacturing the same are provided. In the device, a first substrate, a second substrate, and a channel layer sandwiched by the first and the second substrates are included. At least one channel is constituted by the first and the second substrates and the channel layer and includes a fluid inlet, a fluid outlet, and at least one condensed channel between the fluid inlet and the fluid outlet. The condensed channel at least has a first size and a second size on an X-Y plane and has a third size and a fourth size on an X-Z plane. A difference between the first size and the second size is about at least two orders in scale, and a difference between the third size and the fourth size is about at least two orders in scale.

Abstract: This technology is a method and apparatus for the semi-continuous measurement of the concentration of constituents of airborne particles which couples a laminar flow, water condensation particle collector to a microfluidic device for assay of particle chemical composition by electrophoresis. The technology has been used for the assay of sulfates, nitrates, chlorides, and organic acids contained in fine and submicrometer atmospheric particles. For these compounds the apparatus and method described is capable of one-minute time resolution at concentrations at the level of micrograms of analyte species per cubic meter of air. Extension to other analytes is possible.

Abstract: An electrolytic system includes an analyte chamber having an access port for introducing a sample containing a molecules of interest, such as DNA. Electrodes create an electric field along a length of the analyte chamber to drive molecules toward an interaction region containing a nanopore, thereby increasing the arrival rate of molecules at the nanopore. Additional electrodes may be utilized to create an electric field through the nanopore to drive a molecule into the nanopore. A current sensor may be utilized to count, discriminate or characterize the molecules as they interact with the nanopore. Advantageously, system can be utilized for unamplified DNA sequencing.

Abstract: The present invention relates to methods and devices for separating particles according to size. More specifically, the present invention relates to a microfluidic method and device for the separation of particles according to size using an array comprising a network of gaps, wherein the field flux from each gap divides unequally into subsequent gaps. In one embodiment, the array comprises an ordered array of obstacles in a microfluidic channel, in which the obstacle array is asymmetric with respect to the direction of an applied field.

Abstract: A fluidic device (100) comprising a substrate (101) and a transport medium (103) provided on the substrate (101) to define a transport path for transporting a fluidic sample (104) driven by an electric force.

Abstract: An ion exchangeable mixture containing a polymeric compound consisting of an ion exchange resin, an acrylamide mixture containing at least one bisacrylamide and at least one acrylamide, and a copolymer obtained by reacting the polymeric compound with the acrylamide mixture, and a method of producing the same are provided. The ion exchangeable membrane produced by using the ion exchangeable mixture has significantly smaller electric resistance than conventional ion exchangeable membranes, and has excellent selective permeability because the ion exchangeable membrane is electrically charged. The ion exchangeable membrane can be produced under very mild production conditions, and thus can be produced very easily. Furthermore, the ion exchangeable membrane can be also formed into film during a crosslinking reaction in a solvent of water, and thus is advantageous in that the ion exchangeable membrane can be freely produced into desired sizes, shapes and forms.

Abstract: In order to provide a high-performance electrophoresis chip and an electrophoresis unit having the same that can restrain the diffusion of sample at an intersection between the electrophoresis groove and the sample introduction groove and prevent decrease in contrast and decrease in resolution, an electrophoresis chip is provided with a sample introduction groove, an electrophoresis groove, and a through hole. The sample introduction groove, the electrophoresis groove, and the through hole are formed on different substrates. In the electrophoresis chip, by combining the substrates, the sample introduction groove and the electrophoresis groove are located in different planes.

Abstract: In a capillary electrophoresis apparatus, a capillary array unit has a capillary array including capillaries having a capillary head and a detection unit, a frame for supporting the capillary array, and a load header for holding cathode ends of the capillaries. The frame has separators for separating and holding the capillaries. The capillary head, the detection unit, and the separators are disposed along one linear line. With this arrangement, there is provided the capillary array unit and the capillary electrophoresis apparatus which are arranged such that a job for mounting the capillary array can be executed easily.

Abstract: An electrokinetic pump and fluid delivery system is provided that may include any of a number of features. One feature of the fluid delivery system is that it can deliver a fixed volume of fluid with each stroke of the electrokinetic pump. Another feature of the fluid delivery system is that it can accurately deliver fluid at a target flow rate over time. Methods associated with use of the electrokinetic pump and fluid delivery system are also covered.

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: Disclosed herein is a micro-fluidic chip including a hollow area into which a charged droplet is introduced, and an electrode configured to be provided toward the hollow area. Movement direction of a droplet in the hollow area is controlled based on electric force acting between a charge given to the droplet and the electrode.

Abstract: The present invention relates a use of the electrocapture-based separation technology combined with mass spectrometrical fragmentation methods, e.g. sequence of polypeptides by collision-induce dissociation mass spectrometry, for the identification and/or characterization molecules of interest. It also relates the combination of the electrocapture-base separation technology with other liquid separation methods, as e.g. liquid chromatography, in order to achieve multi-dimensional separations prior mass spectrometrical analysis. In addition, it relates physical interfaces between electrocapture-based separations and different types mass spectrometers for on-line or off-line analysis, as well as the coupling of electrocapture-based separations, liquid chromatography and different types of mass spectrometrometers.

Abstract: A seamless microchannel with aligned microelectrodes structure can be prepared to include a polymeric body defining a surface of a seamless microchannel. The microchannel is seamless in that it is formed by a single body of material having a conduit that is open at one surface and extends to another opening aligned with microelectrodes in another surface of the body. The rest of the microchannel is closed and defined by the single body of material. The seamless microchannel structure can be used in methods that include biosensors, coupling waveguides, capillary electrophoresis chips, microreactors, polymerase chain reaction-chips, and solving mathematical problems.