A method for manufacturing a detection device includes dispensing a plurality of reagent droplets of a detection reagent to a fiber substrate by a dispensing unit, and absorbing the plurality of reagent droplets by the fiber substrate to form the detection device having at least one detection pore. The dispensing unit includes two plastic sheets and a water retention substrate, the water retention substrate contains the detection reagent, and one of the two plastic sheets has at least one opening.

The present invention is drawn to the generation of micropatterns of biomolecules and cells on standard laboratory materials through selective ablation of a physisorbed biomolecule with oxygen plasma. In certain embodiments, oxygen plasma is able to ablate selectively physisorbed layers of biomolecules (e.g., type-I collagen, fibronectin, laminin, and Matrigel) along complex non-linear paths which are difficult or impossible to pattern using alternative methods. In addition, certain embodiments of the present invention relate to the micropatterning of multiple cell types on curved surfaces, multiwell plates, and flat bottom flasks. The invention also features kits for use with the subject methods.

The disclosure generally relates to compositions and methods for the production of nucleic acid molecules. In some aspects, the invention allows for the microscale generation of nucleic acid molecules, optionally followed by assembly of these nucleic acid molecules into larger molecules. In some aspects, the invention allows for efficient production of nucleic acid molecules (e.g., large nucleic acid molecules such as genomes).

A continuous throughput microfluidic system includes an input system configured to provide a sequential stream of sample plugs; a droplet generator arranged in fluid connection with the input system to receive the sequential stream of sample plugs and configured to provide an output stream of droplets; a droplet treatment system arranged in fluid connection with the droplet generator to receive the output stream of droplets in a sequential order and configured to provide a stream of treated droplets in the sequential order; a detection system arranged to obtain detection signals from the treated droplets in the sequential order; a control system configured to communicate with the input system, the droplet generator, and the droplet treatment system; and a data processing and storage system configured to communicate with the control system and the detection system.

In order to reduce the cost of producing a spot array substrate and reduce the cost of nucleic acid polymer analysis, a spot array substrate is used which is produced by preparing a resin substrate 402 having a surface on which an uneven pattern is formed and a plurality of bead sitting positions set in a two-dimensional array within the uneven pattern, and loading surface-modified beads onto the bead sitting positions of the resin substrate.

Paper-based single cell arrays are provided, as well as methods of making and using the arrays. The invention provides a low cost, high-throughput platform to detect and quantify different types of DNA damage at point-of-care without expensive equipment or highly trained personnel. Ordinary paper can be covered with multiple layers of common printing ink and micro-patterned to form discrete and ordered arrays capable of binding a single cell, which are then lysed and imaged. The platform allows quick and inexpensive testing of multiple anti-cancer treatment options for a particular patient. The invention can make cancer treatment personalized and more effective, even in low-resource settings.

Methods of generating a nucleic acid signature for identifying particles associated in a partition are provided. In one aspect, the method comprises: partitioning a sample into a plurality of partitions comprising a particle comprising a solid support surface, the solid support surface having a plurality of oligonucleotide primers conjugated thereon, wherein the oligonucleotide primers comprise a barcode sequence, and wherein the partitions have 0, 1, or more than 1 particles per partition; providing in a partition a substrate comprising a barcode sequence or repeating clonal barcode sequences; and in the partition, associating a first particle conjugated to oligonucleotide primers comprising a first barcode sequence and a second particle conjugated to oligonucleotide primers comprising a second barcode sequence to a barcode sequence from the substrate, thereby generating a nucleic acid signature for the particles in the partition.

Multi-stage sample-recovery systems, including automated 2-stage and 3-stage sample-recovery systems, are provided. Such systems enable the rapid screening and recovery of samples, including viable cell-based samples, from high-throughput screening systems, including systems utilizing large-scale arrays of microcapillaries. In specific screening systems, each microcapillary comprises a solution containing a variant protein, an immobilized target molecule, and a reporter element. Immobilized target molecules may include any molecule of interest, including proteins, nucleic acids, carbohydrates, and other biomolecules. The association of a variant protein with a molecular target is assessed by measuring a signal from the reporter element. The contents of microcapillaries identified in the assays as containing variant proteins of interest can be identified and recovered using the multi-stage systems disclosed herein.

The invention provides a method for preparing a compound or a product having one or more characteristics that meet or exceed a user specification, the process comprising the step of selecting a first combination of chemical inputs, optionally together with physical inputs, and supplying those inputs to a reaction space, thereby to generate a first product; analyzing one or more characteristics of the product generated; comparing the one or more characteristics against a user specification; using a genetic algorithm selecting a second combination of chemical inputs, optionally together with physical inputs, wherein the second combination differs from the first combination, and supplying those inputs to the reaction space, thereby to generate a second product; analyzing one or more characteristics of the second product generated; comparing the one or more characteristics generated against the user specification; repeating the selecting and analyzing steps for further individual combinations of chemical and/or physical inputs, to provide an array of products wherein the flow chemistry system operates continuously to provide the first, second and further products, thereby to identify one or more products meeting or exceeding the user specification.

The invention proceeds from an apparatus for analyzing reactions, comprising a starting material distributor (7) and at least two reactors (3) which are connected in parallel and are each connected via a connecting conduit (5) to an outlet of the starting material distributor (7). To set the inflow, a pressure regulator (33) and a restrictor (19) are installed in each connecting conduit (5) between the starting material distributor (7) and the reactors (3) or an outlet conduit (13) in which a restrictor (19) and a pressure regulator (33) are installed branches off from each connecting conduit (5).

The invention further relates to a method for analyzing reactions in such an apparatus.