An extraction cell cap assembly allows for toolless disassembly. The assembly includes a cap body having a threaded base releasably engaged with a cell vessel, a support member extending axially upward from the base, and a bore axially extending through the support member. The assembly also includes a locking cap having a plunger slidably received within the bore, a recess disposed within the plunger, and a locking portion that releasably engages the support member. Rotation of the locking cap in a first direction engages the locking portion with the support member, and rotation in an opposite direction disengages the locking portion. A filter is received in the recess and a seal member received in the bore, wherein the seal member forms a fluid-tight seal between the cell vessel and the assembly when the locking portion and the support member are engaged and the assembly is secured to the cell vessel.

The present invention provides a capping system for biological thermal reaction, which comprises at least one reaction tube, at least one suction unit, and at least one pushing rod. Each of the at least one reaction tube comprises an opening end. The at least one suction unit is used to suck at least one cap and move the at least one cap to the opening end of the at least one reaction tube. The at least one pushing rob is used to push the at least one cap into the opening end of the at least one reaction tube.

A system and method facilitates transfers of specimen containers (e.g., vials with caps) between storage cassettes and carrier cassettes. The storage cassettes are designed to be stored in cryogenic refrigerators while the carrier cassettes are designed to be temporarily stored in a portable carrier. Identification information is read from wireless transponders carried by the specimen containers. Visual mappings of the positions of the specimen container in the cassettes is provided. Presence and position of the specimen containers in the cassettes is verified, and alerts of inconsistencies provided along with corrective commands. Inventories of specimen container and even specific specimen holders are provided.

A sample analysis cup assembly, system and method for purging including a cell body, including a top end; a bottom end; a cell body wall extending axially from the top end to the bottom end; a transverse wall adjacent the top end, including a plurality of apertures extending therethrough; and a raised portion on the transverse wall including a central aperture extending therethrough; a rotatable cap, including a top surface; a bottom surface; and a series of apertures extending from the top surface through the bottom surface, the rotatable cap being structured to engage with the top end of the cell body; and a ring member structured to couple with the bottom end of the cell body are provided.

An apparatus and method for simple, low power, automated processing of biological samples through multiple preparation and assay steps. The apparatus and methods described facilitate the point-of-care implementation of diagnostic assays. The apparatus includes mechanical actuating elements using linear and/or rotational motion.

A separation container for extracting a portion of a sample for use or testing and method for preparing samples for downstream use or testing are provided. The separation container may include a body defining an internal chamber. The body may define an opening, and the body may be configured to receive the sample within the internal chamber. The separation container may further include a seal disposed across the opening, such that the seal may be configured to seal the opening of the body, and a plunger movably disposed at least partially inside the internal chamber. The plunger may be configured to be actuated to open the seal and express the portion of the sample.

A device for separating and concentrating target particles or molecules from a fibrinogen containing sample of liquid comprises a container (1) for collecting the sample and a closure (2). The container (1) comprises a first end and a second end and at least one interior wall defining a reservoir portion (5) for receiving the sample. The reservoir portion (5) comprises at least one anchor element (4) to locally catch a polymerized fibrin pellet formed upon the addition of the sample into the container. The separation and concentration process is operated by trapping the target particles or molecules into the so-formed polymerized fibrin pellet that are captured on the anchor element (4).

A receptacle distribution system includes a rotary distributor and a receptacle handoff device. The rotary distributor includes a motorized turntable with an upright wall, a distributor head for holding a receptacle, a hook configured to engage a receptacle for moving the receptacle into or out of the distributor head, and an a system for powered elevation of the distributor head. The receptacle handoff device is configured to transfer a receptacle from a first receptacle distributor to the rotary distributor and includes a receptacle yoke configured to hold a receptacle placed in the receptacle yoke with the first receptacle distributor, the receptacle yoke being rotatable between a first position to receive the receptacle and a second position to present the receptacle to the rotary distributor to enable the hook of the rotary distributor to pull the receptacle from the receptacle yoke and into the distributor head.

This disclosure is directed to methods and devices (300) associated with Point of Care medical testing and diagnostics. More specifically, methods and devices are described which provide a quick and streamlined way to prepare blood samples for analysis using flow cytometers, microscopes, and other analysis platforms. The benefits include a reduction in the time, resources, and expertise needed for preparing those blood samples without compromising the accuracy and efficacy of diagnosing diseases or identifying specific particulates from those blood samples.

The present invention provides methods and devices for simple, low power, automated processing of biological samples through multiple sample preparation and assay steps. The methods and devices described facilitate the point-of-care implementation of complex diagnostic assays in equipment-free, non-laboratory settings.