Disclosed are high concentration reagents for use in preparing DNA samples in low volume reactions. Such reagents include, for example, DNA end repair buffers for use in low volume DNA blunting and phosphorylating reactions, DNA adenylating buffers for use in a low volume DNA adenylating reaction, and DNA ligation buffers for use in low volume DNA adaptor ligation reactions with adaptors. Also disclosed are customized reagent plates and kits containing one or more of these low volume buffers for use in low volume DNA blunting, phosphorylating, adenylating, and ligation reactions. Methods of using the high concentration reagents (low volume buffers) and the customized reagent plates for preparing DNA sequencing libraries in low volume reactions are also disclosed.

Methods and compositions are disclosed relating to the localization of nucleic acids to arrays such as silane-free arrays, and of sequencing the nucleic acids localized thereby.

The present disclosure provides a cover sheet for a microarray reaction device. In one aspect, the present cover sheet or device ensures the reaction units/volumes are stable and/or consistent among assay samples and assay runs, allowing samples (e.g., reaction solutions) to be conveniently added and distributed uniformly.

Presented herein are methods and compositions surface-based tagmentation. In particular embodiments, methods of preparing an immobilized library of fragmented and tagged DNA molecules on a solid surface are presented. In particular embodiments, the solid surface comprises immobilized transposomes in a dried format, suitable for reconstitution upon contact with liquid, such as a liquid sample.

The invention features methods of making devices, or platens, having a high-density array of through-holes, as well as methods of cleaning and refurbishing the surfaces of the platens. The invention further features methods of making high-density arrays of chemical, biochemical, and biological compounds, having many advantages over conventional, lower-density arrays. The invention includes methods by which many physical, chemical or biological transformations can be implemented in serial or in parallel within each addressable through-hole of the devices. Additionally, the invention includes methods of analyzing the contents of the array, including assaying of physical properties of the samples.

Methods and compositions are disclosed relating to the localization of nucleic acids to arrays such as silane-free arrays, and of sequencing the nucleic acids localized thereby.

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).

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.

An optical imaging system (100) includes a frame (102) designed to provide mechanical coupling between a first stage (104) and a second stage (106), a sample holding region (108) located on the first stage (104), a lens arrangement, and a sensor array. The lens arrangement is disposed between the first stage (104) and the second stage (106) and is designed to receive light from a sample at the sample holding region (108) on the first stage. The lens arrangement has a numerical aperture less than 0.1. The sensor array is coupled to the second stage (106) and is designed to receive light passing through the lens arrangement.

Disclosed herein are compositions, methods and systems for the processing of chemical reactions, such as the synthesis of polymers.