This assembly includes a tubular body and a cap attached to the tubular body to define a chamber for an active material. The tubular body includes a transverse wall and a peripheral wall and the cap includes a base wall and a side wall. The chamber is delimited by a part of the tubular body including the transverse wall and is closed by the cap. The side wall of the cap on its periphery includes a plurality of longitudinal features in relief which cooperate by mutual engagement with complementary longitudinal features in relief provided on the peripheral wall of the tubular body substantially parallel to its longitudinal axis (X.sub.2).

A tissue holder assembly includes: a base comprising a bottom member, a central hub extending upwardly from the bottom member, and a circumferential sidewall extending upwardly from the bottom member radially spaced apart from the hub, the circumferential sidewall surrounding the hub and defining an interior region configured for accommodating a cylindrical tissue holder; the base further comprising a raised platform spaced upwardly apart from the bottom member, the central hub extending through a central opening of the platform and configured for supporting the tissue holder; the bottom member, the hub, and the circumferential sidewall collectively defining an annular fluid channel underlying the platform; wherein the fluid channel extends around the hub from an opening in the platform to a fluid exit port in the circumferential sidewall; the base further comprising a flow comb underlying the platform opening and extending into the fluid channel.

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.

Disclosed herein are system, method, and computer program product embodiments for adaptive specimen collection order processing. An embodiment operates by retrieving a specimen order for processing a specimen collection. The specimen order comprises a test code. The embodiment determines that the specimen order is an eligible specimen order by determining that the test code matches at least one of a plurality of qualifying test codes. The embodiment transmits, to an electronic patient system, a request to provide resource allocation information for processing the specimen collection associated with the eligible specimen order. The embodiment generates an event for performing the specimen collection that satisfies the resource allocation information. The embodiment retrieves digital evidence that the event was completed. The embodiment validates that the event was completed based on the retrieved digital evidence. The embodiment then updates the eligible specimen order with a completion test code indicating the specimen collection was completed.

A set of medical sampling parts for use with an endoscope, including: a sampling device; a sample container including a separator part located at a top of the sample container, a base located at a bottom of the sample container opposite of said top, and a container part at least partly enclosing a sample volume located at the bottom of the sample container, so that a container axis extends between said separator part and said base; and a connector for connecting the sampling device with the sample container, wherein the sample container can be detached from the sampling device by a translational movement along a detachment axis, whereby a smallest angle between said container axis and said detachment axis is equal to or greater than 45 degrees.

A storage system having racks and an outer container that receives the racks, each rack receiving a plurality of sample boxes, each box having a wireless ID tag. In certain embodiments, the storage system has reader electronics external to and distinct from the racks and that directly read the wireless ID tag of each box in at least one rack without relying on any reader electronics of any rack. In other embodiments, each rack has a set of rack reader electronics that read the wireless ID tag of each box in at least one rack, and the storage system has at least one removable reader access device removably connectable to the set of rack reader electronics of a rack in order to transmit the ID number of the wireless ID tag of each box in the rack outside of the outer container.

A sampling device adapted to cooperate with a sampling member subsequent to collection of a sample of animal tissue. The sampling device includes: a receiving tube designed for receiving the sample of animal tissue, containing at least one specific agent and comprising an inlet; a tube head removably attached to the inlet of the receiving tube and provided with a through channel ending in the receiving tube; a closing element configured to take at least two positions: a first position, in which the closing element is held into the tube head so as to plug the through channel of the tube head, and a second position, in which the closing element is released into the receiving tube.

In an embodiment of the invention, a frictional tissue sampling device for obtaining a histological sample from an epithelial layer includes a platform with an axis, an abrasive material comprising a plurality of fibers associated with the platform, where the abrasive material is adapted to abrade the epithelial layer to dislodge the histological sample, where rotation of the platform around the axis rotates the abrasive material, and a collector material comprising a plurality of loops associated with the platform, where rotation of the platform around the axis rotates the collector material, where the collector material is adapted to collect the histological sample dislodged by the abrasive material, where contacting the platform with the epithelial layer and rotation of the platform moves the abrasive material and the collector material over the epithelial layer thereby obtaining the sample.

An improved biopsy tray includes a container having bottom surface and continuous perimeter wall extending upward therefrom to form a cleaning zone which is sufficient to hold an adequate amount of fluid for cleaning a biopsy forceps, and at least one specimen bottle receiving receptacle adjacent the perimeter wall to receive and retain a specimen bottle. A method of obtaining a biopsy specimen includes employing the tray of the invention.

The present invention relates in general to the improved containment of biological fluids. In particular, a method and apparatus for collection and preservation of fluid samples in accordance with the present invention results in collection of semen having improved viability both at the time of collection and after storage. The disclosed apparatus support a wide variety of applications for containment of biological fluids related to human and veterinary medicine including, but not limited to, human reproductive medicine and animal husbandry.