The present invention is drawn to the generation of micropatterns of biomolecules and cells on standard laboratory materials through selective ablation of a physisorbed biomolecule with oxygen plasma. In certain embodiments, oxygen plasma is able to ablate selectively physisorbed layers of biomolecules (e.g., type-I collagen, fibronectin, laminin, and Matrigel) along complex non-linear paths which are difficult or impossible to pattern using alternative methods. In addition, certain embodiments of the present invention relate to the micropatterning of multiple cell types on curved surfaces, multiwell plates, and flat bottom flasks. The invention also features kits for use with the subject methods.

An analyzing device has a main body and is configured to draw a sample liquid from a spot application section of the main body and transfer the sample liquid to a measurement chamber via a microchannel structure formed inside the main body by a centrifugal force. The spot application section has an inlet. The analyzing device includes a supplying capillary channel formed within the spot application section. The supplying capillary channel has an end connected to the inlet of the spot application section. The analyzing device also includes a holding chamber connected to another end of the supplying capillary channel and having a thickness sized to generate a capillary force to move the sample liquid. The holding chamber is formed between a first side wall and a second side wall. The first side wall and the second side wall define the holding chamber.

A microfluidic device comprising a microfluidic channel network sealed on one side by a membrane sheet, the sheet having PDMS defining at least the surface sealing the channel, the membrane sheet on its opposite side sealing one side of a pneumatic channel, the pneumatic channel arranged to enable pneumatic deflection of a deflectable portion of the membrane sheet into contact with an opposed surface to control flow in a channel of the network, the membrane sheet confining in a channel of the network at least one micro-particle, micro-length tube or glass nano reactor, functionalized with a capture agent, that has been inserted into that channel. A microfluidic device having a microfluidic channel containing at least two micro-particles, micro-length tubes or glass nano reactors, one functionalized with nucleic acid and another with antibody or antigen. A microfluidic device having a microfluidic channel containing at least one micro-length tube or glass nano reactor functionalized to capture nucleic acid, the device constructed to enable recovery of the nucleic acid captured by the device.

In an example, a method for preparing a nucleotide solution includes flowing an aqueous solution from an initial solution storage of a sequencing instrument continuously through a container fluidically coupled to the sequencing instrument, the container comprising a nucleotide concentrate; and collecting the aqueous solution with nucleotide in a storage container.

Sensors having dimensions on the order of nanometers can be arranged in an array. The sensors can detect substances found in an environment. The array of sensors can be disposed on a substrate along with circuitry to control the operation of the array of sensors.

The invention provides a nucleic acid testing cassette, including a substrate, a liquid storage component, a solid-reagent storage component, and an amplification reaction region, wherein the substrate is connected to the amplification reaction region; the liquid storage component and the solid-reagent storage component are disposed on the substrate, respectively; the liquid storage component is communicated with the solid-reagent storage component through a micro flow channel; and the solid-reagent storage component is communicated with the amplification reaction region through a micro flow channel.

A microfluidic device is disclosed which comprises: (i) at least one reaction unit having a test chamber connected to at least one microchannel, wherein a surface of at least a portion of said reaction unit is attached to an isolated nucleic acid; and (ii) a flow-through channel having at least one inlet port and at least one outlet port, said flow-through channel and said microchannel being of dimensions to allow reactant diffusion to and from said reaction unit, wherein the diffusion time of said reactant along the microchannel is shorter than the flow time along the microchannel.

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.

In general the present invention concerns 1) single cell trapping of a viable cell in separate well from a plurality of wells in an array of wells, 2) single cell analysis for the selected cell and 3) single cell lifting of the yet viable cell from the well by an optical tweezer. Furthermore resent invention concerns a cell trap and lift device for B lymphocytes, the device comprising an array of wells in in polymer matrix comprising an off-stoichiometry thiol-ene polymer of the group consisting of off-stoichiometry thiol-ene (OSTE) and off-stoichiometry thiol-ene-epoxy (OSTE+) or a combination thereof that have been grafted with methacrylated polyethylene glycol (methoxy polyethylene glycol methacrylate or (M-PEG-M)) of a number average molecular weight of Mn 2000. It furthermore concerns using the B lymphocyte trap and lift device for trapping single B lymphocyte cells in wells of the device of present invention and lifting said cell from the cell trapping well by optical tweezers, preferably single beam tweezers.

A microfluidic apparatus (100) can include a PCB (110), a biological chip (120) overlying the PCB (110), and a microfluidic housing (130) overlying the biological chip (120) and the PCB (110). The microfluidic apparatus (100) also has a first adhesive layer (141) attaching the microfluidic housing (130) to the biological chip (120) and a second adhesive layer (142) attaching the microfluidic housing (130) to the PCB (110). The second adhesive layer (142) is thicker than the first adhesive layer (141). The first adhesive layer (141) comprises a first adhesive material, and the second adhesive layer (142) comprises a second adhesive material.