A device for use in laser optical transfection of biological targets including an optofluidic microdevice and a piece of optical glass. The optofluidic microdevice has a central vertical outlet and a microchannel network that includes a plurality of entrapping channels with narrowings. The microchannel network is fused with the optical glass. In one aspect the device is used with a petri dish having an optical window. In another aspect the device is used with a well plate having a plurality of wells and associated optical windows. In a third aspect the device is used with a barrier. Each of the aspects forms a peripheral space around the optofluidic microdevice capable of retaining a live culture of biological targets and material that is desired to be injected into those biological targets. Polymer tubing is inserted into the central vertical outlet which connects the device to an external pump. The external pump provides an inward suction force which draws the biological targets from the peripheral space into the microchannel network. The biological targets are then captured at the openings or within the narrowings in the entrapping channels of the microchannel network where they can be transfected by laser light emitting from a laser through the optical glass.

A device for use in laser optical transfection of biological targets including an optofluidic microdevice and a piece of optical glass. The optofluidic microdevice has a central vertical outlet and a microchannel network that includes a plurality of entrapping channels with narrowings. The microchannel network is fused with the optical glass. In one aspect the device is used with a petri dish having an optical window. In another aspect the device is used with a well plate having a plurality of wells and associated optical windows. In a third aspect the device is used with a barrier. Each of the aspects forms a peripheral space around the optofluidic microdevice capable of retaining a live culture of biological targets and material that is desired to be injected into those biological targets. Polymer tubing is inserted into the central vertical outlet which connects the device to an external pump. The external pump provides an inward suction force which draws the biological targets from the peripheral space into the microchannel network. The biological targets are then captured at the openings or within the narrowings in the entrapping channels of the microchannel network where they can be transfected by laser light emitting from a laser through the optical glass.

This invention relates to a method for producing a protein of interest, comprising introducing a protein expression vector which comprises a gene fragment a gene fragment comprising a DNA encoding a protein of interest and a selectable marker gene and transposon sequences at both terminals of the gene fragment, into a suspension mammalian cell; integrating the gene fragment inserted between a pair of the transposon sequences, into a chromosome of the mammalian cell to obtain a mammalian cell capable of expressing the protein of interest; and suspension-culturing the mammalian cell; and a suspension mammalian cell capable of expressing the protein of interest.

Disclosed are medical devices that incorporate siRNA. In addition to one or more siRNA constructs, devices include nanostructures fabricated on a surface to form a nanotopography. A random or non-random pattern of structures may be fabricated such as a complex pattern including structures of differing sizes and/or shapes. Microneedles may be incorporated on devices. The pattern including nanostructures may be formed on the surface of the microneedles.

Disclosed are medical devices that incorporate siRNA. In addition to one or more siRNA constructs, devices include nanostructures fabricated on a surface to form a nanotopography. A random or non-random pattern of structures may be fabricated such as a complex pattern including structures of differing sizes and/or shapes. Microneedles may be incorporated on devices. The pattern including nanostructures may be formed on the surface of the microneedles.

The present invention addresses the problem of providing a bubble ejection method based on a new principle that is different from conventional bubble ejection methods and a bubble ejecting device.

To solve the problem, provided is a bubble ejection method using a bubble ejecting device, wherein the bubble ejecting device comprises a substrate formed of a dielectric, at least one bubble ejection hole formed so as to penetrate through a first face and a second face, which is a face opposite to the first face, of the substrate, a first opening formed at a position of the first face at which the bubble ejection hole penetrates, and a second opening formed at a position of the second face at which the bubble ejection hole penetrates, the bubble ejection method comprising: a substrate-conductive liquid contact step; a conductive liquid-electrode contact step; a voltage application step; and a bubble ejection step.

A microbial oil is obtained from Labyrinthulomycetes in which a gene for fatty acid biosynthesis has been disrupted or an expression of the gene has been inhibited to highly accumulate the fatty acid. The microbial oil typically contains: (a) 1.5% or more of arachidonic acid (AA) based on a total amount of fatty acid; (b) 0.2% or more of dihomo-γ-linolenic acid (DGLA) based on the total amount of fatty acid; (c) 0.04% or more of eicosatetraenoic acid (ETA) based on the total amount of fatty acid; (d) 3.8% or more of eicosapentaenoic acid (EPA) based on the total amount of fatty acid; (e) 13.7% or less of n-6 docosapentaenoic acid (n-6DPA) based on the total amount of fatty acid; and (f) 43.9% or less of docosahexaenoic acid (DHA) based on the total amount of fatty acid.

The present invention relates to processes for transfecting cells. In particular, the present invention relates to processes for using CRISPR to incorporate a polynucleotide into the genome of an avian primordial germ cell (PGC).

The present invention relates to processes for transfecting cells. In particular, the present invention relates to processes for using CRISPR to incorporate a polynucleotide into the genome of an avian primordial germ cell (PGC).

Disclosed herein are rodents (such as, but not limited to, mice and rats) genetically modified to comprise a humanized Tslp gene, a humanized Tslpr gene, a humanized 117ra gene, or a combination thereof. Compositions and methods for making such genetically modified rodents, as well as methods of using such genetically modified rodents as an animal model for diseases such as allergic diseases and cancer are provided.