The present disclosure provides biochips and methods for making biochips. A biochip can comprise a nanopore in a membrane (e.g., lipid bilayer) adjacent or in proximity to an electrode. Methods are described for forming the membrane and inserting the nanopore into the membrane. The biochips and methods can be used for nucleic acid (e.g., DNA) sequencing. The present disclosure also describes methods for detecting, sorting, and binning molecules (e.g., proteins) using biochips.

The present disclosure provides systems, devices and methods for seeding cells or sets of molecules on a substrate by utilizing a seeding mesh, to obtain an essentially homogenous patterned seeding of the cells or sets of molecules on the mesh.

Methods of making a supramolecular structure of lipids. The methods include providing an ink made of an aqueous solution of lipid micelles that are deposited onto a polymer pen or an array of polymer pens, such as by an electrospray technique to achieve a homogenous coverage of single and isolated micelles. The method further comprises transferring the ink to a substrate using polymer pen lithography (PPL). Nanoconfinement of the lipid micelles associated with the disclosed method, allow the lipid micelles to rearrange and ultimately lead to a highly ordered and homogenous supramolecular lipid structure. A supramolecular assembly made using the disclosed method and nanoscale delivery system comprising the supramolecular assembly of lipids are further disclosed.

Screening assays and methods of performing such assays are provided. In certain examples, the assays and methods may be designed to determine whether or not two or more species can associate with each other. In some examples, the assays and methods may be used to determine if a known antigen binds to an unknown monoclonal antibody.

The present disclosure provides fluidic devices and fluidic device assemblies, including microfluidic devices and cartridges comprising the same, that in illustrative embodiments, can be used to make particles or protein precipitates, or to monitor precipitate formation. The fluidic devices typically include channels that connect a reaction well to an inlet port and an outlet port, and a fluidic constriction channel that is configured to help retain fluids in the reaction well and/or promote mixing within the reaction well. In some aspect, fluidic devices are interconnected into fluidic assemblies that can be used in continuous process methods.

An activity frame comprising a first or outer ring mounted between a pair of opposed bearings in a opposed pair of supports, for example upstanding members of a frame, the first bearings having a having a first common axis; a second or middle ring mounted between opposed bearings on the first ring, the bearings having a second common axis orthogonal to the first common axis; a third or inner ring mounted between opposed bearings on the second ring, the bearings having a third common axis orthogonal to the second axis provided with demountable restraining means to limit the movement of two or more of the rings and demountable bars to fix one or more of the rings to the frame or other fixed object.

An array of membranes comprising amphipathic molecules is formed using an apparatus comprising a support defining an array of compartments. Volumes comprising polar medium are provided within respective compartments and a layer comprising apolar medium is provided extending across the openings with the volumes. Polar medium is flowed across the support to displace apolar medium and form a layer in contact with the volumes, forming membranes comprising amphipathic molecules at the interfaces. In one construction of the apparatus, the support that comprises partitions which comprise inner portions and outer portions. The inner portions define inner recesses without gaps therebetween that are capable of constraining the volumes comprising polar medium contained in neighbouring inner recesses from contacting each other. The outer portions extend outwardly from the inner portions and have gaps allowing the flow of an apolar medium across the substrate.

The present disclosure provides biochips and methods for making biochips. A biochip can comprise a nanopore in a membrane (e.g., lipid bilayer) adjacent or in proximity to an electrode. Methods are described for forming the membrane and inserting the nanopore into the membrane. The biochips and methods can be used for nucleic acid (e.g., DNA) sequencing. The present disclosure also describes methods for detecting, sorting, and binning molecules (e.g., proteins) using biochips.

The present disclosure provides biochips and methods for making biochips. A biochip can comprise a nanopore in a membrane (e.g., lipid bilayer) adjacent or in proximity to an electrode. Methods are described for forming the membrane and insert-ing the nanopore into the membrane. The biochips and methods can be used for nucleic acid (e.g., DNA) sequencing. The present disclosure also describes methods for detecting, sorting, and binning molecules (e.g., proteins) using biochips.

Screening assays and methods of performing such assays are provided. In certain examples, the assays and methods may be designed to determine whether or not two or more species can associate with each other. In some examples, the assays and methods may be used to determine if a known antigen binds to an unknown monoclonal antibody.