The inventive subject matter provides an apparatus for reproducibly fabricating hydrogel-based organ and tumor models inside multi-well plates. For example, tumor models made using the inventive apparatus can be used for studying the progression of cancer, cancer diagnostics, and therapeutic screening. A mold controls the thickness of each hydrogel layer. A photomask controls the size and shape of each hydrogel layer, allowing the hydrogel diameter to be smaller than the diameter of each well so that liquid media can be exchanged around both the sides and top of the hydrogels. A holder aligns the photomask with the multi-well plate, and polymerization is initiated by a light source.

Methods of producing substrates having selected active chemical regions by employing elements of the substrates in assisting the localization of active chemical groups in desired regions of the substrate. The methods may include optical, chemical and/or mechanical processes for the deposition, removal, activation and/or deactivation of chemical groups in selected regions of the substrate to provide selective active regions of the substrate.

Methods of producing substrates having selected active chemical regions by employing elements of the substrates in assisting the localization of active chemical groups in desired regions of the substrate. The methods may include optical, chemical and/or mechanical processes for the deposition, removal, activation and/or deactivation of chemical groups in selected regions of the substrate to provide selective active regions of the substrate.

Provided in one example is a method of manufacturing a flowcell that includes: forming a core layer, the core layer disposed between a substrate and a nanowell layer, the nanowell layer having nanowells to receive a sample, the core layer having a higher refractive index than the substrate and the nanowell layer; and forming a grating to couple light to the core layer.

Devices, systems and methods for affinity reagent and catalyst discovery employing a library on a bead HTS platform, each bead comprising affixed non-natural polymers of a distinct bioactive monomer with sequence pre-defined branching and folding in tertiary structures, and fiber-optic array scanning technology.

Methods of producing substrates having selected active chemical regions by employing elements of the substrates in assisting the localization of active chemical groups in desired regions of the substrate. The methods may include optical, chemical and/or mechanical processes for the deposition, removal, activation and/or deactivation of chemical groups in selected regions of the substrate to provide selective active regions of the substrate.

Methods of producing substrates having selected active chemical regions by employing elements of the substrates in assisting the localization of active chemical groups in desired regions of the substrate. The methods may include optical, chemical and/or mechanical processes for the deposition, removal, activation and/or deactivation of chemical groups in selected regions of the substrate to provide selective active regions of the substrate.

The inventive subject matter provides methods for reproducibly fabricating hydrogel-based organ and tumor models inside multi-well plates. A hydrogel precursor, which can include cells, is instilled into a well. A pillar is inserted into the well to contact the hydrogel precursor with a surface that can be shaped or textured to provide a desired surface configuration or contour, for example that of a desired organoid or tumor feature. The hydrogel precursor is polymerized and the pillar removed. A second hydrogel precursor, which can contain a different cell type, is then instilled into the well and a second pillar, which can have a different configuration or texture, inserted. Subsequent polymerization generates a second hydrogel portion within the well. Polymerization can be carried out by photopolymerization. Different wells can be aligned with different, individually controlled light sources or a single, collimated light source.

The inventive subject matter provides methods for reproducibly fabricating hydrogel-based organ and tumor models inside multi-well plates. A hydrogel precursor, which can include cells, is instilled into a well. A pillar is inserted into the well to contact the hydrogel precursor with a surface that can be shaped or textured to provide a desired surface configuration or contour, for example that of a desired organoid or tumor feature. The hydrogel precursor is polymerized and the pillar removed. A second hydrogel precursor, which can contain a different cell type, is then instilled into the well and a second pillar, which can have a different configuration or texture, inserted. Subsequent polymerization generates a second hydrogel portion within the well. Polymerization can be carried out by photopolymerization. Different wells can be aligned with different, individually controlled light sources or a single, collimated light source.

The inventive subject matter provides an apparatus for reproducibly fabricating hydrogel-based organ and tumor models inside multi-well plates. For example, tumor models made using the inventive apparatus can be used for studying the progression of cancer, cancer diagnostics, and therapeutic screening. A mold controls the thickness of each hydrogel layer. A photomask controls the size and shape of each hydrogel layer, allowing the hydrogel diameter to be smaller than the diameter of each well so that liquid media can be exchanged around both the sides and top of the hydrogels. A holder aligns the photomask with the multi-well plate, and polymerization is initiated by a light source.