Embodiments described herein relate to an apparatus for positioning and securing an excised biological tissue specimen for imaging and analysis. In some embodiments, an apparatus includes a sample bag defining an inner volume configured to receive a biological tissue sample, and a sealing member coupled to the sample bag. An imaging window is disposed and configured to be placed in contact with at least a portion of the biological tissue sample, and a positioning member is coupled to the imaging window and is configured to be disposed against the sealing member to substantially seal the inner volume. The positioning member includes a vacuum port disposed and configured to be aligned with a vacuum source to withdraw air from the inner volume of the sample bag.

A microfluidic device comprising a channel within a substrate and a condenser or a hydrodynamic focusing chamber along the channel, configured to focus a fluid containing particles of a plurality of sizes. A negative angle deterministic lateral displacement (DLD) array is configured to receive the focused fluid and separate the particles in the focused fluid into three sizes ranges. The negative angle DLD array comprises a plurality of rows of pillars, wherein the rows of pillars are positioned to repeat a pattern every N rows with a shift of M columns, N and M are relatively coprime, and N is greater than 1.

The present disclosure provides systems and methods for sample analysis. The system comprises a container. The container comprises a sample receptacle and a cap, and the cap comprises a reservoir for retaining a composition, a first piercing member and a first pierceable barrier for sealing said composition within said reservoir. There is also provided a method for sample analysis.

The device comprises a nib (12) having a working surface (16) exposed or exposable for acquiring a biological sample and a porous structure to absorb the sample thus acquired. A reservoir (28) provides fluid under pressure to the nib via a valve (29), conveying and dispensing the sample into a reaction chamber (14), where it reconstitutes a dried-down reagent (43) to perform an analytic reaction on the sample, for example, an isothermal amplification of nucleic acid released from the sample by a membrane-disrupting agent pre-functionalised in the porous nib. The nib may be initially mounted (A) in the outlet of the reservoir or (B) in the inlet to the reaction chamber, in either case with its working surface (16) initially exposed to acquire the sample before the components of the device are assembled for performing the analytical procedure.

A system for collecting a sample of a liquid, the system including a liquid storage vessel including an opening, and a capping element configured to seal the opening of the storage vessel is provided. The capping element includes a chamber configured to store a sample of the liquid separate to the liquid storage vessel. The capping element includes a pipette element defining the chamber that is configured to store the sample of liquid taken from the storage vessel.

A biopsy container assembly having a container with a lower chamber suitable for containing a buffer liquid, and a cap coupled with the container. The cap being provided with a chamber that contains a biopsy liquid sealed by a membrane, and a crown with a toothing-suitable for tearing off the membrane of the cap. The crown is also suitable for being disposed in the container in an initial position, wherein the toothing is directed downwards in order not to interfere with the membrane of the cap when the cap is closed on the container, and in an operating position, wherein the toothing is directed upwards in order to tear off the membrane of the cap when the cap is closed on the container.

A test container includes an inlet, a first storage portion, a second storage portion, a first flow channel that connects the first storage portion to the second storage portion, a first cylinder of which one end is connected to the first storage portion via a second flow channel and the other end is open to an outside, a second cylinder of which one end is connected to the second storage portion via a third flow channel and the other end is open to an outside, a first plug provided in the first cylinder, and a second plug provided in the second cylinder. An internal space including the first storage portion, the second storage portion, the first flow channel, the second flow channel, and the third flow channel is capable of being pressurized in a case where the first plug and the second plug are pressed and moved from the outside.

A specimen sample collection device is disclosed, the device including: a base having a neck extending therefrom, a film-puncture element disposed within the neck, and one or more fluid ports extending through the base within the neck; a cap engaged with the neck, the cap comprising a film attached about an inner cylinder of the cap along a periphery thereof; wherein the film defines a buffer-containing cavity within the cap, and wherein the buffer-containing cavity is configured to hold a preservation buffer for preserving a sample stored within a collection reservoir of the device.

A biological sample collection system can include (i) a sample collection vessel having an opening for receiving a biological sample, (ii) a selectively movable valve comprising a core and a collar disposed about the core, and (iii) a sealing cap coupled to the collar and comprising a reagent chamber for storing a measure of sample preservation reagent. The sealing cap is configured to associate—and form a fluid tight connection—with the sample collection vessel such that associating the sealing cap with the sample collection vessel causes a physical rearrangement of the core relative to the collar such that a fluid vent associated with the core is moved into fluid communication with the reagent chamber, thereby permitting sample preservation reagent to pass from the regent chamber to the sample collection vessel.

A sample processing assembly for treatment of a sample on a substrate includes a mounting surface for the substrate and a closure body configured to releasably retain a cover member. The closure body is movable between an open position and a substantially closed position. When a substrate is placed in the assembly and the closure body is in the substantially closed position while retaining a cover member, a reaction chamber is formed for processing a sample. A cover member for use with the sample processing assembly is also provided.