There is provided a chemiluminescence detector sample enclosure. The enclosure comprises a first interface member forming part of a chemiluminescence detector and having a first sealing element and a second interface member comprising a plurality of sample holders, each sample holder having a second sealing element. The first interface member is engagable with and moveable between sample holder subsets of the plurality of sample holders, engagement with a respective sample holder subset providing engagement of the first interface member with each sample holder of the respective sample holder subset and relative movement of the first and second interface members providing movement between sample holder subsets; and when the first interface member is engaged with each respective sample holder, the first sealing element and the respective second sealing element are adapted to interact so as to form a light restricting seal between the first interface member and said sample holder.

A microtiter plate comprising a first array of M?N wells and a microfluidic probe insert is provided. The microfluidic probe insert includes a second array of M?N microfluidic probe conduits, forming N columns of M conduits. The M conduits include respective orifices in a bounding plane and extend, each, perpendicularly to the bounding plane on one side. The microfluidic probe insert also includes N vacuum circuits, each comprising at least one vacuum port and M openings in the bounding plane, where 2?M, 2?N. The microfluidic probe insert is positioned on the microtiter plate and the microfluidic probe conduits are inserted in respective wells. A processing liquid is ejected from M conduits via the M orifices of the M conduits by applying a negative pressure to a corresponding set of N vacuum circuits via the respective one or more vacuum ports.

A cell accommodating chip capable of accommodating a plurality of cells includes a substrate composed of a light-transmitting material, and a plurality of wells on at least one of main faces of the substrate, the plurality of wells being capable of accommodating cells. A surface of the cell accommodating chip including the plurality of wells has a low cell adhesion property, and affinity to a specific binding material having affinity to a produced substance produced by a cell accommodated in one of the wells and/or a released substance released by the cell.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

An integrated sample analysis system is disclosed. The sample analysis system contains (1) a sample preparation/analysis module having sample purification device comprising a monolith that binds specifically to nucleic acids and a sample analysis device comprising a microarray enclosed in a reaction chamber having a hydrophilic interior surface; (2) a temperature control module comprising a thermocycler having a thermally conductive temperature-control bladder; and (3) an imaging device capable of capturing an image of the microarray in the reaction chamber.

A simple, low cost, efficient and stable micro-vial configuration for handling micro-volume of sample fluids. The interior wall geometry of the inventive vial is designed to include several axial sections of various interior diameters to provide a range of functionalities to address various design considerations. The interior wall defined in the vial has a cylindrical sample section, a wider cylindrical alignment section, a tapered or conical guide section, and a relatively large cylindrical body section, arranged in sequence in that order along the center axis of the vial. The sample section is designed to hold a small volume of a sample fluid, and to receive the tip end of a capillary tube. The alignment section has a larger diameter than the sample section, designed to receive a cylindrical support that coaxially supports the relatively fragile capillary tube. The tip of the capillary tube dips into the micro-volume of sample fluid held in the sample section. The conical section functions to guide the capillary tube and the support tube into the alignment section and the tip of the capillary tube into the sample section. The body section has the largest diameter, for holding additional fluid if desired.

A sampling device having a lower portion with a sample container. A cap is moveably attached with the lower portion and includes a cutting edge configured for cutting a leaf. When the cap is attached to the lower portion with a leaf there between, a leaf sample is deposited into the sample container of the lower portion. The cap includes a vent in fluid communication with the sample container such that the leaf sample is dried. A detachable label can extend from the lower portion.

A biological analysis system is provided. The system comprises an interchangeable assembly configured to accommodate any one of a plurality of sample holders, each respective sample holder configured to receive a plurality of samples. The system also includes a control system configured to cycle the plurality of samples through a series of temperatures. The system further includes an optical system configured to detect fluorescent signals emitted from the plurality of samples. The optical system, in particular, can comprise a single field lens, an excitation source, an optical sensor, and a plurality of filter components. The excitation source can be one or more light emitting diodes. The field lens can be a bi-convex lens.

An immunoassay-multiplexing apparatus includes a microplate having an array of cells. Each cell may have the same configuration, or different configurations. In at least one cell, there is a container within the cell. Within the container is a loading well and at least one satellite well. Each satellite well is connected to the loading well by a unique and independent interconnect channel. Each interconnect channel can taper inwardly transitioning from the associated satellite well to the loading well. Further, a sealing member is used to seal the cell.

A thin-walled microplate suitable for use in the Polymerase Chain Reaction (PCR) technique comprising a plurality of thin-walled tubes or wells arranged in a fixed array, each well having an upper portion with an open top and a lower, frustoconical portion having a substantially flat bottom.