The present disclosure is, in one aspect, directed to a locking assembly for securing a sample tube assembly to a sample manifold of a measurement system. The locking assembly includes a ramp block having one or more slots defined therein and configured to at least partially receive a portion of the sample tube assembly. The ramp block also includes a plurality of surface features defined therealong and configured to engage and move the sample tube assembly toward and into engagement with the sample manifold. The ramp block further is movable between a plurality of positions including an open position for allowing the sample tube assembly to be received through the one or more slots or openings, and a closed position substantially sealing the sample tube assembly against or within the sample manifold. Other aspects also are described.

Provided is a specimen treatment system that can detect whether a specimen container is uncapped by using a simple mechanism. The specimen treatment system comprises: an automatic analyzer that analyzes a specimen; a pretreatment device that performs a pretreatment on the specimen; and a conveyance passage that conveys, in the automatic analyzer or in the pretreatment device, a specimen container that houses the specimen. The specimen treatment system is characterized by further comprising a single sensor that is disposed so as to be orthogonal to the longitudinal direction of the specimen container and that detects whether the specimen container is uncapped.

An optical measurement device is provided. The device includes first and second optical fibers; first and second reaction vessels, and a light guide stage coupled to the first and second optical fibers. The light guide stage is driven to simultaneously optically connect the first and second optical fibers with the first and second reaction vessels. The device includes a measurement device for receiving emissions from the first and second reaction vessels, and a connecting end arranging body that supports the first and second optical fibers along a path. The arranging body is driven along the path between a first position, in which the first optical fiber is optically connected with the measurement device so that light is transmittable from the first reaction vessel, and a second position, in which the second optical fiber is optically connected with the measurement device so that light is transmittable from the second reaction vessel.

An assembly for storing sample processing consumables that includes a cover and a tray. The cover includes a flexible panel and a cover wall that extends downward from the perimeter of the panel, where the panel and the cover wall define a cavity. The tray has a top surface that defines a plurality of wells and a side surface that extends downward from the perimeter of the top surface. The panel is situated adjacent the top surface of the tray, where a first portion of the tray is received within the cover cavity, such that a press fit is formed between the side surface of the tray and an inner surface of the cover wall, thereby releasably coupling the cover to the tray. At least a portion of the wells contain a sample processing consumable, and the cover is configured to be decoupled from the tray by applying a force to the panel to overcome the press fit.

The present disclosure is, in one aspect, directed to a locking assembly for securing a sample tube assembly to a sample manifold of a measurement system. The locking assembly includes a ramp block having one or more slots defined therein and configured to at least partially receive a portion of the sample tube assembly. The ramp block also includes a plurality of surface features defined therealong and configured to engage and move the sample tube assembly toward and into engagement with the sample manifold. The ramp block further is movable between a plurality of positions including an open position for allowing the sample tube assembly to be received through the one or more slots or openings, and a closed position substantially sealing the sample tube assembly against or within the sample manifold. Other aspects also are described.

A Reagent container cap (116) is adapted to being mounted to a reagent container and to being adjustable, at least after an initial opening of the cap (116), between an opened state and a closed state, wherein the reagent container cap (116) defines a cap interior space (109) and has a cap opening (116o) allowing access to the cap interior space (109) from above when the cap (116) is in the opened state; and wherein, in the closed state of the cap (116), the cap interior space (109) is open only towards a bottom side (116b), wherein the reagent container cap (116) comprises a main portion (116m) and an insert portion (116i) that are fixedly connected to each other and made from different materials, wherein, when the cap (116) is in the closed state, the cap interior space (109) comprises a region (109t) which is delimited circumferentially and towards the upper side of this region completely and exclusively by surfaces of the insert portion (116i).

An analysis device is described comprising a housing 12, and a carrier 14 within the housing, the carrier 14 including a plurality of individual pockets 18, each pocket 18 containing a stable assay, and a first seal member 20 operable to cover at least one of the pockets 18 to substantially seal the said pocket(s) 18.

A microplate for containing a plurality of samples includes a plurality of sample cavities, each sample cavity including at least one dividing element which divides the sample cavity into at least a donor compartment and a receiver compartment. The dividing element is configured to contain one of the samples within one of the donor or receiver compartments when the microplate is in a first orientation. The dividing element is further configured to allow the sample to be transferred at least from the donor compartment to the receiver compartment of one of the sample cavities when the microplate is in a second orientation. A method for transferring a sample between compartments of the microplate is also disclosed.

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 automated storage system for storing large quantities of samples in trays includes a storage compartment, a tray shuttle compartment abutting the storage compartment on one side and a plurality of independent modules on the other side. The modules perform processing of samples that are retrieved from the storage compartment by a tray shuttle, including extraction of selected samples from retrieved source trays and transfer of the selected samples into a separate, destination tray that can be further processed or removed from the system for use. The independent operation of the modules permits handling and processing to be performed simultaneously by different modules while the tray shuttle accesses additional samples within the storage compartment. In one embodiment, a vertical carousel is used to vertically align a desired tray with the tray shuttle, while the tray shuttle operates within a horizontal plane.