Abstract: In one aspect, a kit for detection of genetic gene mutation is provided, which is used for detecting nine deafness gene mutations of Caucasian populations, including GJB2 (c.35delG, c.167delT, c.132G>C, and c.269T>C), GJB6 (c.del309kb), SLC26A4 (c.707T>C and c.1246A>C), 12S rRNA (m.1555A>G and m.7444G>A). In another aspect, a method is provided, which method comprises labeling a target molecule with a luminophore, coupling the target molecule to a particle, and binding to a probe molecule on microarray. In some aspects, this technology, with high sensitivity, enables the detection and interpretation of molecular interactions in an efficient way.

Abstract: The present disclosure provides a cover sheet for a microarray reaction device. In one aspect, the present cover sheet or device ensures the reaction units/volumes are stable and/or consistent among assay samples and assay runs, allowing samples (e.g., reaction solutions) to be conveniently added and distributed uniformly.

Abstract: Provided is a microfluidic chip, which comprises a substrate and a cover sheet, wherein a microreactor array is arranged on the substrate and comprises at least one main channel (401) and at least two micro cells (402) connected to the main channel (401). The microfluidic chip also comprises at least one local temperature control device, which is used for heating the main channel (401) or cooling the micro cells (402). The use of the microfluidic chip ensures uniformity and independency of the micro cells (402). Also provided is an application of the microfluidic chip in biological detection or medical inspection.

Abstract: This invention relates generally to the field of analyte assays. In particular, the invention provides a device for analyzing an analyte, which device comprises, inter alia, various means for moving analytes and other items to facilitate binding between analytes and their binding reagents immobilized on a surface and to facilitate clearance of undesirable items away from analyte-binding reagent interaction area to reduce background noise in the assay. Methods for analyzing an analyte using the devices are also disclosed.

Abstract: This invention relates generally to the field of nucleic acid detection. In particular, the invention provides a lab-on-chip system for analyzing a nucleic acid, which system comprises, inter alia, controllably closed space, and a target nucleic acid can be prepared and/or amplified, and hybridized to a nucleic acid probe, and the hybridization signal can be acquired if desirable, in the controllably closed space without any material exchange between the controllably closed space and the outside environment. Methods for analyzing a nucleic acid using the lab-on-chip system is also provided.

Abstract: The present disclosure relates to a method for camera identification and detection on color features. In some aspects, the method comprises: 1) starting the camera, the image processing unit and the display unit at the beginning of testing; 2) using the camera to capture the color characteristic value; and 3) moving the untested object to the detection area of the camera for it to be detected, wherein the image processing unit extracts the mean color characteristic value from the color pixels of the detection area.

Abstract: A microarray-based assay is provided, which is used for analyzing molecular interactions, including polynucleotides, polypeptides, antibodies, small molecule compounds, peptides and carbohydrates. Such method comprises coupling a target molecule to a particle and then binding to a probe molecule on microarray. In particular, multiplexed genetic analysis of nucleic acid fragments can be implemented. Specific genes, single nucleotide polymorphisms or gene mutations, such as deletions, insertions, and indels, can be identified. Coupled with microarray, the particles, themselves or further modified, facilitate the detection of results with non-expensive devices or even naked eyes. This technology enables the detection and interpretation of molecular interactions in an efficient and cost effective way.

Abstract: In some aspects, the present disclosure provides a biochip detecting device that comprises a first shell (2) connect to a second shell (1), and a rotatable support frame (5) of biochip possessing a detecting zone that holds one or more biochips, and a detector (7).

Abstract: In one aspect, disclosed herein are devices, systems, and methods for assessing human health states based on non-shadow imaging of sclera, or whites, of one or both eyes. In one aspect, the device is an on-body device. In one aspect, the system comprises a positioning aperture, an illuminating apparatus, an imaging apparatus, and/or a processing apparatus. In one aspect, the process only takes a short period of time to take images of the sclera without any operation of splicing multiple images. In one aspect, the device or system improves the quality of images by avoiding the formation of reflection of the illuminating apparatus on the images of the sclera. In a further aspect, the system can utilize the sclera images to obtain information of eye diseases and to predict the physiological and pathological changes in the health status of subject or diagnostic results, which can provide helpful information for medical diagnosis.

Abstract: A hybridization system is provided, which comprises a biological chip having a substrate (1) with a probe dot matrix (3) and a cover plate (2) with at least two through-holes (4), where a hybrid chamber (5) is formed between the substrate (1) and the cover plate (2), at least two fluid channels (6) are interconnected respectively with the hybrid chamber (5) by the two through-holes (4), and a fluid control device is interconnected with the fluid channels (6). The biological chip hybridization system integrates hybridizing, cleaning and drying functions, uses power provided by the fluid control device as the drive force for promoting the liquid flow for automatically reciprocation flow in the fluid channels (6) and the chamber (5) to achieve a dynamic hybridization, thus improving the hybrid efficiency and uniformity, and achieving automatic control.

Abstract: An automatic injection device comprises at least an injection unit (1). The said injection unit (1) is formed by sealing a cover plate layer (3) with hydrophilic surfaces and a microfluid layer (4). The said cover plate layer (3) is provided with at least two through holes (5). The said microfluid layer (4) is provided with a hollow-out hybridization chamber (7) and at least two hollow-out microfluid channels (6). One end of each channel (6) is connected with the hybridization chamber (7), and the other end is connected with a through hole (5) of the cover plate layer (3) respectively. Taking advantage of the hydrophilicity of the cover plate, the automatic injection device makes a solution automatically enter and fill the hybridization chamber (7) and the microfluid channels (6) by the driving force of liquid surface tension. The flow uniformity of sample solution in microarray chip is achieved by the structural design of the hybridization chamber (7) and the microfluid channels (6).

Abstract: Systems, apparatus and methods for designing and operating a cell-electrode impedance sensor to detect chemical and biological samples, including biological cells. In one implementation, a method of designing a cell-electrode impedance sensor includes determining a cell free cell-electrode impedance and a cell covered cell-electrode impedance based on a design model for the cell-electrode impedance sensor, wherein the design model is based on one or more factors, the factors including properties and elements of a cell-electrode impedance measurement system, using the cell free cell-electrode impedance and the cell covered cell-electrode impedance to obtain a sensor sensitivity of the cell-electrode impedance measurement system, and choosing one or more design parameters of the cell-electrode impedance sensor in the cell-electrode impedance measurement system to maximize the sensor sensitivity.

Abstract: In one aspect, disclosed herein are methods for packaging biochips, including microfluidic chips. The method can comprise bonding a substrate and a cover slide, packaging the bonded chip, creating a vacuum in the package, and applying a pressure on the packaged chip. The method is particularly useful for minimizing bubble formation during low-cost and mass production of microfluidic chips.

Abstract: In one aspect, the present disclosure provides an integrated microfluidic device for nucleic acid amplification and microarray detection. In one aspect, the device comprises: (1) a microchip configured to process reagents, comprising a plurality of reservoirs, channels, valves, and/or fluid interfaces; (2) an amplification chamber for PCR, carried out in a detachable tube assembled on the microchip through a joint; and (3) a microarray chamber comprising a microarray and a reaction chamber. In some embodiments, these features are interconnected to allow transportation of reagents for nucleic acid amplification and hybridization detection functions in a closed system. In one aspect, the integrate device herein overcomes the problem of contamination during the amplification and hybridization reactions.

Abstract: A multi-index detection microfluidic chip is provided. A bottom plate (1) and a cover plate (2) that matches the bottom plate (1) and seals it are provided in the microfluidic chip. The center of the microfluidic chip has a through-hole (3). The bottom plate (1) has one or more wave-shaped main channel (s) (4), one end of each of the main channel (4) connected to a sample injection hole (9) on the bottom plate (1), and the other end connected to an exhaust hole (10) on the bottom plate (1). The valley on the main channel (1) is distal to the through-hole (3), and the peak is proximal to the through-hole (3). Each valley of the main channel (1) is connected to a reaction chamber (6) by a linking channel (5). The linking channel (5) comprises one or more buffering chambers (7). The microfluidic chip can be used in detection by fluorescence, turbidity, color, detection equipment, and/or direct observation by the naked eyes. The detection is real-time as the reaction occurs or after the reaction.

Abstract: In one aspect, provided herein are set of primers and use of the same for the detection of SNPs associated with diabetes. In certain embodiments, the primers used to detect SNP sites associated with diabetes comprise Primer Set 1 to Primer Set 47. The experiments show: the genotyping results of the SNP sites associated with diabetes can be accurately detected by the primers disclosed herein, and the risk of individuals can be comprehensively evaluated and the result is more accurate than the single site analysis. In addition, SNPs disclosed herein are verified as associated with type 2 diabetes and its complications, which are especially suitable for the prevention and individualized treatment for type 2 diabetes in East Asian, for example, in China.

Abstract: A micro fluidic device comprises one microstructure layer (5) and one cover layer (1), wherein the cover layer (1) is connected to the microstructure layer (5). The microstructure layer (5) comprises one bottom layer and a plurality of microstructures on it to position samples. The cover layer (1) comprises one top layer, one positioning well (6) and at least one inlet pool (4). The positioning well (6) is right above the microstructures and connected with each other. The inlet pools (4) and the positioning well (6) are connected by microchannels (3) which are formed between the microstructure layer (5) and the cover layer (1). The micro fluidic device can be applied in vitro fertilization, in determining how glial cells affect neurons, in constructing neural network and in detecting cell growth conditions.

Abstract: This invention provides nanometer-sized fluorescent magnetic particles and processes of making them. The nanoparticle has a core particle comprising a magnetic material and a fluorescent material, and the particle size is less than about 1 micrometer. The nanoparticles can be coated with an inorganic or organic layer and can be surface-modified. The nanoparticles can be used in many biological assays.

Abstract: A method for labeling target molecules coupled to particles for the detection of the target molecules using a microarray chip, comprises: providing a functionalized microparticle, wherein the microparticle is coated with one or more functional group; providing a modification group on each of the target molecules to be detected to form modified target molecules; contacting the functionalized microparticle with the modified target molecules; coupling a luminophore to the complex between the functionalized microparticle and the modified target molecules, thereby directly or indirectly labeling each modified target molecules with the luminophore. By directly or indirectly labeling the target molecules with the luminophore, the method reduces the cost of fluorescence detection, and avoids PCR inhibition derived from traditional fluorescence labeling molecules.

Abstract: An integrated microfluidic device and its usage are provided. The microfluidic device comprises an upper layer (1) and a lower layer (2), wherein the lower layer (2) is bound to the upper layer (1). The upper layer (1) comprises a micro-channel (3) and the lower layer (2) comprises a micro-well (7) array. The micro-channel (3) is in fluidic connection with the micro-well (7) array, and the height of the micro-channel (3) is greater than the diameter of the oocyte (4) flowing through the micro-channel (3). The integrated microfluidic device has many advantages including low cost, high integration, and convenient operation, and has application prospects in reproductive medicine and the research of fertilization and embryo early development.