Apparatuses and a method for plate-based oligonucleotide synthesis are disclosed. In one example, an apparatus used in oligonucleotide synthesis includes a machined block to receive a commercially-available synthesis plate. A keeper is used to apply pressure to the commercially-available synthesis plate, and a sealing element is used to seal the commercially-available synthesis plate to the machined block. Other methods and apparatuses are disclosed.

A fluid transfer system includes a transfer carousel capable of rotational and/or translational movement; at least one holding vessel (e.g. syringe) having a plunger, wherein the syringe is connected to the transfer carousel such that the movement of the transfer carousel results in movement of the syringe and wherein the syringe is capable of translational movement relative to the transfer carousel; a drive motor connected to the syringe that is capable of controlling the position of the plunger; and a peripheral module comprising at least one vessel that is capable of containing a fluid, wherein the vessel has an opening that can be mated with the syringe to allow fluid transfer between the vessel and the syringe. Methods for transferring a fluid are also disclosed.

Provided herein are biomolecular hybridization devices comprising a substrate with a permanently and covalently attached surface of functional groups and an adsorbed monolayer of unmodified, single-stranded oligonucleotides all of which are 10 to about 24 bases in length as a saturated film of constrained oligonucleotides on the surface via direct non-covalent phosphate-surface adsorptive contact of substantially all phosphate groups of each oligonucleotide. The constrained oligonucleotides are effective to dissociably hybridize to a complementary single-stranded nucleic acid with asymmetric, non-helical base pairing and without oligonucleotide dissociation from the surface of the device. Also, provided are methods for hybridizing solution-state target nucleic acids to probe nucleic acids and for identifying a nucleotide sequence to which a nucleotide-binding protein binds using the biomolecular hybridization devices.

The present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.

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 present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.

A method and system for heating and/or inspecting a portable microfluidic assay cartridge for performing an assay includes receiving the assay cartridge on a receiving region of a translatable table under automated control, heating the cartridge, during performance of the assay, with a planar radiant heater plate, the heater plate having an aperture through which an inspection axis extends, and/or inspecting the cartridge using an optical system constructed to inspect the cartridge along the inspection axis by reading a fluorescent light signal which passes through the aperture in the heater plate. In addition, the cartridge moves with movement of the translation table, and the heater plate and optical system may be stationary, and the inspection axis may be fixed.

The present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.

The present invention provides an automated modular system and method for production of biopolymers including DNA and RNA. The system and method automates the complete production process for biopolymers. Modular equipment is provided for performing production steps with the individual modules arrange in a linear array. Each module includes a control system and can be rack mounted. One side of the array of modules provides connections for power, gas, vacuum and reagents and is accessible to technicians. On the other side of the array of modules a robotic transport system is provided for transporting materials between module interfaces. The elimination of the requirement for human intervention at multiple steps in the production process significantly decreases the costs of biopolymer production and reduces unnecessary complexity and sources of quality variation.

A drug processing system includes a workstation, at least one deck module movably positionable within the workstation, at least one filter plate operably coupled with the at least one deck module, an agitating member, and a liquid handler member. The at least one filter plate has a plurality of wells to receive a fluid therein. The agitating member is adapted to move the at least one filter plate according to an agitation system. The liquid handler member is adapted to selectively add a fluid to at least one of the plurality of wells and/or remove a fluid from the at least one of the plurality of wells according to a liquid handling system. The agitating member is adapted to move the at least one filter plate while the liquid handler member selectively adds and/or removes the fluid from the at least one of the plurality of wells.