A biomimetic tissue scaffold for repairing an elongated tissue in need of repair can comprise a plurality of coiled flexible polymeric ribbons having a surface on which is formed an array of nanofibers, the ribbons forming a tubular body defining a first open end in which a first end of the elongated tissue is receivable, a second open end in which a second end of the elongated tissue is receivable, and a lumen extending between the first and second open ends.

An imprinting apparatus includes an imprinting platform, an imprinting roller, a transfer module and a lifting and pressing mechanism. The imprinting roller is disposed above the imprinting platform. The transfer module includes a transfer film, wherein the transfer film is located between the imprinting roller and the imprinting platform. The lifting and pressing mechanism is linked with the imprinting roller, wherein the lifting and pressing mechanism drives the imprinting roller to move along a normal direction of the imprinting platform and selectively pressurizes the imprinting roller.

A biomimetic tissue scaffold for repairing an elongated tissue in need of repair can comprise a plurality of coiled flexible polymeric ribbons having a surface on which is formed an array of nanofibers, the ribbons forming a tubular body defining a first open end in which a first end of the elongated tissue is receivable, a second open end in which a second end of the elongated tissue is receivable, and a lumen extending between the first and second open ends.

Solution casting a nanostructure. Preparing a template by ablating nanoholes in a substrate using single-femtosecond laser machining. Replicating the nanoholes by applying a solution of a polymer and a solvent into the template. After the solvent has substantially dissipated, removing the replica from the substrate.

The present invention are methods for fabrication of micro- and/or nano-scale adhesive fibers and their use for movement and manipulation of objects. Further disclosed is a method of manipulating a part by providing a manipulation device with a plurality of fibers, where each fiber has a tip with a flat surface that is parallel to a backing layer, contacting the flat surfaces on an object, moving the object to a new location, then disengaging the tips from the object.

A scalable method of fabricating large area nanoparticle arrays is disclosed. The method uses a combination of nanofabrication and additive manufacturing techniques to fabricate ordered nanoparticle arrays on wide number of substrates, including flexible substrates. Nanosphere lithography may be used to form a monolayer of polymer nanospheres. A metal may be deposited on the nanospheres, using a physical vapor deposition technique. The nanoparticles may then be decomposed using intense pulsed light technique. Ordered nanoparticle arrays have several promising applications, for example, thin films with tailored light scattering signatures, sensors based on surface-enhanced Raman scattering, nanostructured electrode arrays, and ordered catalytic islands for nanostructure growth.

A blown film coextrusion line includes a support frame, a plurality of extruders each mounted to the support frame and extending upward at an angle, and a downward facing blown film coextrusion die connected to distal ends of each of the plurality of extruders and receiving individual polymer streams from them. The blown film coextrusion line is compact and sturdy and eliminates much of the floor space and towered mounting structure that was required for conventional blown film coextrusion lines. A corresponding method of making a multilayer coextruded blown film is also provided.

An imprinting apparatus includes an imprinting platform, an imprinting roller, a transfer module and a lifting and pressing mechanism. The imprinting roller is disposed above the imprinting platform. The transfer module includes a transfer film, wherein the transfer film is located between the imprinting roller and the imprinting platform. The lifting and pressing mechanism is linked with the imprinting roller, wherein the lifting and pressing mechanism drives the imprinting roller to move along a normal direction of the imprinting platform and selectively pressurizes the imprinting roller.

Solution casting a nanostructure. Preparing a template by ablating nanoholes in a substrate using single-femtosecond laser machining. Replicating the nanoholes by applying a solution of a polymer and a solvent into the template. After the solvent has substantially dissipated, removing the replica from the substrate.

A method for manufacturing a structured embossing cylinder for embossing system including the steps of providing a hard-coated embossing roller having a cylindrically-shaped core and a hard-coating layer on the cylindrically-shaped core, the hard-coating layer having a thickness in a range between 1 gm and 10 gm, and having a surface-roughness value RA of less than 100 nm, depositing a masking layer on the hard-coating layer, the masking layer having a thickness of equal or less than 100 nm, removing material from the masking layer to form at least one opening, and etching to remove material at the at least one opening of the masking layer from the hard-coating layer to form a surface cavity in the hard-coating layer at the at least one opening, the surface cavity forming a structural embossing feature into the hard-coating layer, thereby forming the structured embossing cylinder.