A miniaturized, automated method for controlled printing of large arrays of nano- to femtoliter droplets by actively transporting mother droplets over hydrophilic-in-hydrophobic (HIH) micropatches. The technology uses single or double-plate devices where mother droplets can be actuated and HIH micropatches on one or both plates of the device where the droplets are printed. Due to the selective wettability of the hydrophilic micropatches in a hydrophobic matrix, large nano- to femtoliter droplet arrays are created when mother droplets are transported over the arrays. The parent droplets are moved by various droplet actuation principles. Also, a method using two plates placed one top another while being separated by a spacer. One plate is dedicated to confirming and guiding parent droplets by using hydrophilic patches in a hydrophobic matrix, while the other plate contains HIH arrays for printing of the droplets. When the parent droplet guidance plate is rotated over the plate dedicated to printing of nano- to femtoliter droplets, the droplets are dispensed inside the HIH array utilizing their selective wettability. The methods allow the parent droplets to move over the HIH arrays many times, providing advantages for performing bio-assays or miniaturized materials synthesis in nano- to femtoliter sized droplets. With controlled evaporation of the dispensed droplets of solution, large arrays of printed material can be generated in seconds. The methods provide a nano- to femtoliter droplet printing technique for a wide variety of applications, e.g., protein- or cell-based bio-assays or printing of crystalline structures, suspensions of nanoparticles or microelectronic components.

A novel miniaturized and highly automated method for the controlled printing of large arrays of nano- to femtoliter droplets is presented by actively transporting mother droplets over hydrophilic-in-hydrophobic micropatches. The proposed technology consists of single plate or double-plate devices where mother droplets can be actuated and hydrophilic-in-hydrophobic micropatches on one or both plates of the device where nano- to femtoliter droplets are printed. Due to the selective wettability of the more wettable hydrophilic micropatches in a hydrophobic matrix, large nano- to femtoliter droplet arrays are created when mother droplets are transported over these arrays. The parent droplets can be moved by different droplet actuation principles, for example, by using the principle of electrowetting-on-dielectric droplet actuation. We propose another method that uses two plates that are placed on top of each other while being separated by a spacer. One plate is dedicated to confirming and guiding of parent droplets by using hydrophilic patches in a hydrophobic matrix, while the other plate contains hydrophilic-in-hydrophobic arrays dedicated to the printing of nano- to femtoliter droplets. When the plate dedicated to parent droplet guiding is rotated over the plate dedicated to printing of nano- to femtoliter droplets, nano- to femtoliter droplets are dispensed inside the hydrophilic-in-hydrophobic array due to their selective wettability. All these proposed methods allow the parent droplets to be moved over the hydrophilic-in-hydrophobic arrays many times, providing unique advantages for performing bio-assays or miniaturized materials synthesis in nano- to femtoliter sized droplets. Upon the controlled evaporation of the dispensed droplets of solution, large arrays of the printed material can be generated on an automated way in seconds of time on a very flexible way. The method disclosed herein provides a distinct nano- to femtoliter droplet printing technique for a wide variety of applications such as protein- or cell-based bio-assays or printing of crystalline structures, suspensions of nanoparticles or components for microelectronics.

A flow cell includes: a first substrate; a second substrate; a first resin layer disposed over an inner surface of the first substrate; a second resin layer disposed over an inner surface of the second substrate; a first plurality of biological capture sites located at the first resin layer; a second plurality of biological capture sites located at the second resin layer; and a polymer layer interposed between the first resin layer and the second resin layer, such that the first substrate is attached to the second substrate via at least the first resin layer, the polymer layer, and the second resin layer, wherein the polymer layer defines a plurality of microfluidic channels that extend through polymer layer.

Analyte filter arrays and methods for making an analyte filter array are provided. The arrays are formed using a dispersion of filter particles having selected moieties attached to the surface of the particles and a microarray having complementary moieties formed in an array on a substrate, such that each filter particle is attached to a selected region of the microarray. The moiety on the substrate may be RNA or DNA or other molecule. The substrate may be a surface of a detector array, a membrane that may be placed in registration with the detector array or a stamp used to transfer the filter array to a detector array.

In one embodiment of the present invention, provided are novel biomaterial immobilizing method having excellent immobilization ability and uses thereof, the method being characterized in that: an immobilization carrier having a surface modification specific to the biomaterial to be immobilized is used; the material to be immobilized is pre-immobilized to the surface of the immobilization carrier; a surface layer for maintaining the immobilization carrier on a biomaterial immobilizing substrate is provided; and the immobilization carrier is stamped in the shape of a spot on the surface layer.

The present disclosure provides flow cells and methods of fabricating flow cells. The method includes combining three portions: a first substrate, a second substrate, and microfluidic channels between the first substrate and the second substrate having walls of a photoresist dry film. Through-holes for inlet and outlet are formed in the first substrate or the second substrate. Patterned capture sites are stamped on the first substrate and the second substrate by a nanoimprint lithography process. In other embodiments, parts of the patterned capture sites are selectively attached to a surface chemistry pattern formed of silicon oxide islands each disposed on an outcrop of a soft bottom layer.

A master tool is provided with an ink pattern on a major surface thereof. The ink pattern is formed by a screen printing process. A stamp-making material is applied to the major surface of the master tool to form a stamp having a stamping pattern being negative to the ink pattern of the master tool. The stamping pattern is inked with an ink composition and contacted with a metalized surface to form a printed pattern on a metalized surface of a substrate according to the stamping pattern. Using the printed pattern as an etching mask, the metalized surface is etched to form electrically conductive traces on the substrate.

A cell patterning material, a method of preparing the cell patterning material, a cell patterning method using the cell patterning material, and a biosensor including patterned cells obtained by using the cell patterning method are provided. According to the present disclosure, cells may be conveniently and efficiently patterned and the time for applying external stimulation for patterning may be controlled. In addition, the patterned cells may have an excellent proliferation rate and excellent differentiation efficiency, and may be re-patterned in a different direction, and High-throughput screening using the patterned cells is possible.

Analyte filter arrays and methods for making an analyte filter array are provided. The arrays are formed using a dispersion of filter particles having selected moieties attached to the surface of the particles and a microarray having complementary moieties formed in an array on a substrate, such that each filter particle is attached to a selected region of the microarray. The moiety on the substrate may be RNA or DNA or other molecule. The substrate may be a surface of a detector array, a membrane that may be placed in registration with the detector array or a stamp used to transfer the filter array to a detector array.

A novel miniaturized and highly automated method for the controlled printing of large arrays of nano- to femtoliter droplets is presented by actively transporting mother droplets over hydrophilic-in-hydrophobic micropatches. The proposed technology consists of single plate or double-plate devices where mother droplets can be actuated and hydrophilic-in-hydrophobic micropatches on one or both plates of the device where nano- to femtoliter droplets are printed. Due to the selective wettability of the more wettable hydrophilic micropatches in a hydrophobic matrix, large nano- to femtoliter droplet arrays are created when mother droplets are transported over these arrays. The parent droplets can be moved by different droplet actuation principles, for example, by using the principle of electrowetting-on-dielectric droplet actuation. We propose another method that uses two plates that are placed on top of each other while being separated by a spacer. One plate is dedicated to confirming and guiding of parent droplets by using hydrophilic patches in a hydrophobic matrix, while the other plate contains hydrophilic-in-hydrophobic arrays dedicated to the printing of nano- to femtoliter droplets. When the plate dedicated to parent droplet guiding is rotated over the plate dedicated to printing of nano- to femtoliter droplets, nano- to femtoliter droplets are dispensed inside the hydrophilic-in-hydrophobic array due to their selective wettability. All these proposed methods allow the parent droplets to be moved over the hydrophilic-in-hydrophobic arrays many times, providing unique advantages for performing bio-assays or miniaturized materials synthesis in nano- to femtoliter sized droplets. Upon the controlled evaporation of the dispensed droplets of solution, large arrays of the printed material can be generated on an automated way in seconds of time on a very flexible way. The method disclosed herein provides a distinct nano- to femtoliter droplet printing technique for a wide variety of applications such as protein- or cell-based bio-assays or printing of crystalline structures, suspensions of nanoparticles or components for microelectronics.