Some polymeric devices, as described herein, can be made of a first layer and a second layer bonded together with one or more microfluidic channels defined internal to the device. The first layer and the second layer may each include a substrate and a polymer bonded to the substrate. The two layers may be bonded through a polymer network that interpenetrates the polymers in the first and second layers. This disclosure also describes methods of bonding together polymeric articles. The methods include diffusing polymerizable monomers and radical forming initiators into the surfaces of one or both of the polymers, putting the surfaces into contact, and initiating polymerization to create a polymer network that interpenetrates the polymers.

Nanofluidic passages such as nanochannels and nanopores are closed or opened in a controlled manner through the use of a feedback system. An oxide layer is grown or removed within a passage in the presence of an electrolyte until the passage reaches selected dimensions or is closed. The change in dimensions of the nanofluidic passage is measured during fabrication. The ionic current level through the passage can be used to determine passage dimensions. Fluid flow through an array of fluidic elements can be controlled by selective oxidation of fluidic passages between elements.

Techniques for localized surface modification for microfluidic applications are provided. In one aspect, a method includes: contacting at least one portion of a surface with at least one tri(m)ethoxysilane-containing solution under conditions sufficient to form at least one silane monolayer having a given contact angle on the surface thereby modifying a flow rate over the surface. The silane monolayer can include a silane derivative selected from: trimethoxysilyl-propoxypolyethyleneoxide (TMS-PPEO), hexadecyl-triethoxysilane (HD-TES), tridecafluoro-1,1,2,2-tetrahydrooctyl)triethoxysilane (TDF-THO-TES), and combinations thereof. A device modified in accordance with the present techniques is also provided.

Nanofluidic passages such as nanochannels and nanopores are closed or opened in a controlled manner through the use of a feedback system. An oxide layer is grown or removed within a passage in the presence of an electrolyte until the passage reaches selected dimensions or is closed. The change in dimensions of the nanofluidic passage is measured during fabrication. The ionic current level through the passage can be used to determine passage dimensions. Fluid flow through an array of fluidic elements can be controlled by selective oxidation of fluidic passages between elements.

In an example of a method of making a flowcell, an organic solid support including sidewalls and a top is provided. A bottom surface of the organic solid support adjacent to the sidewalls provides a laser bonding foot. In the method, the laser bonding foot is bonded to an inorganic solid support to form a channel having sidewalls and a top defined by the organic solid support.

A method of fabricating a sensing device for DNA sequencing and biomolecule characterization including the steps of fabricating a microelectrode chip having a silicon substrate and a silicon nitride diaphragm, attaching a monolayer graphene sheet to the silicon nitride diaphragm, dicing a portion of the monolayer graphene sheet to form a graphene microribbon, converting the graphene microribbon to a graphene nanoribbon, and converting the graphene nanoribbon to a carbyne. A sensing device for DNA sequencing and biomolecule characterization is also disclosed. The sensing device includes a silicon substrate, a cavity in the silicon substrate covered by a silicon nitride layer, microelectrodes attached to the silicon nitride layer, graphene covering the microelectrodes, and carbyne attached to a portion of the silicon nitride layer covering said cavity.

Example sensor apparatus for microfluidic devices and related methods are disclosed. In examples disclosed herein, a method of fabricating a sensor apparatus for a microfluidic device includes etching a portion of an intermediate layer to form a sensor chamber in a substrate assembly, where the substrate assembly has a base layer and the intermediate layer, and where the base layer comprises a first material and the intermediate layer comprises a second material different than the first material. The method includes forming a first electrode and a second electrode in the sensor chamber. The method also includes forming a fluidic transport channel in fluid communication with the sensor chamber, where the fluidic transport channel comprises a third material different than the first material and the second material.

Nanochannel arrays that enable high-throughput macromolecular analysis are disclosed. Also disclosed are methods of preparing nanochannel arrays and nanofluidic chips. Methods of analyzing macromolecules, such as entire strands of genomic DNA, are also disclosed, as well as systems for carrying out these methods.

Apparatus and methods for controlling the insertion of a membrane channel into a membrane are disclosed. In one arrangement a first bath holds a first liquid in contact with a first surface of a membrane. A second bath holds a second liquid in contact with a second surface of the membrane. The membrane separates the first and second liquids. A first electrode contacts the first liquid. A second electrode contacts the second liquid. A driving unit applies a potential difference across the membrane via the first and second electrodes to promote insertion of a membrane channel into the membrane from the first liquid or the second liquid. A membrane voltage reduction unit is connected in series with the membrane. The driving unit applies a driving voltage across the membrane voltage reduction unit and the membrane, the driving voltage providing the potential difference across the membrane. The membrane voltage reduction unit is configured such that a reduction in resistance through the membrane caused by insertion of a membrane channel intrinsically increases a potential difference across the membrane voltage reduction unit thereby lowering the potential difference across the membrane. The lowering of the potential difference across the membrane is sufficient to prevent or reduce promotion of insertion of a further membrane channel.

Integrated circuit packages (100) having electrical and optical connectivity and methods of making the same are disclosed herein. According to one embodiment, an integrated circuit package includes a structured glass article (120) including a glass substrate (122), an optical channel (132), and redistribution layers. The integrated circuit package (100) further includes an integrated circuit chip (160) positioned on the glass substrate (122) and in optical communication with the optical channel (132) and in electrical continuity with the redistribution layers (136).