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.

Protein arrays and their use to assay, in a parallel fashion, the protein products of highly homologous or related DNA coding sequences and described. By highly homologous or related it is meant those DNA coding sequences which share a common sequence and which differ only by one or more naturally occurring mutations such as single nucleotide polymorphisms, deletions or insertions, or those sequences which are considered to be haplotypes. Such highly homologous or related DNA coding sequences are generally naturally occurring variants of the same gene. Arrays according to the invention have two or more individual proteins deposited in a spatially defined pattern on a surface in a form whereby a property such as an activity or function of the proteins can be investigated or assayed in parallel by interrogation of the array.

The inventive concepts disclosed herein are generally directed to a sensor array device that has a prolonged shelf life but requires only a minimal amount of sample volume in order to test two or more analytes concurrently. In order to ensure the sensor array has a sufficient shelf life, anti-diffusion regions are positioned among the reaction wells in order to slow the processes of diffusion. The use of anti-diffusion regions, as described herein, can be used to optimize the number of sensors that can be fit into a sensor array designed for reduced sample liquid volumes (e.g., less than 100 L) as well as extending the test strip's shelf life.

The disclosure provides three-dimensional crosslinked polymer networks comprising one or more channels extending from the surface and/or near the surface of the network into the interior of the network, arrays comprising the networks, processes for making the networks, and uses of the networks and arrays.

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.

The present invention provides a system for conservation and efficient use of energy through controlling and monitoring of devices. At least one processing controller connected to a sensor and a device, the processing controller configured to receive the ambient data from the sensor and operating parameters from the device; a user module configured to IO receive input parameters from a plurality of users; a central processing module, connected to the structure, the user module, and the admin module through wired and/or wireless connection, the central processing module configured to process the data received from the processing controller adapted in the zone of the structure and generate the optimum parameters for operating the device adapted in the zone to the structure.

An embodiment of the invention relates to a wafer comprising a plurality of biochips and interconnects on the wafer, the biochip comprising a biochip pad, a synthesis electrode and a gel comprising a probe, wherein a plurality of the biochip pads of the plurality of the biochips are interconnected by the interconnects to carry out a chemical reaction on a plurality of the synthesis electrodes.

Embodiments of the present application relate to patterned polymer sheets and processes to prepare the same for sequencing applications. In particular, flexible micro- and nano-patterned polymer sheets are prepared and used as a template surface in sequencing reaction and new polish-free methods of forming isolated hydrogel plugs in nanowells are described.

The inventive concepts disclosed herein are generally directed to a sensor array device that has a prolonged shelf life but requires only a minimal amount of sample volume in order to test two or more analytes concurrently. In order to ensure the sensor array has a sufficient shelf life, anti-diffusion regions are positioned among the reaction wells in order to slow the processes of diffusion. The use of anti-diffusion regions, as described herein, can be used to optimize the number of sensors that can be fit into a sensor array designed for reduced sample liquid volumes (e.g., less than 100 L) as well as extending the test strip's shelf life.

The disclosure provides three-dimensional crosslinked polymer networks comprising one or more channels extending from the surface and/or near the surface of the network into the interior of the network, arrays comprising the networks, processes for making the networks, and uses of the networks and arrays.