The claimed subject matter comprises a device to collect and preserve cells comprising of: (1) a collection container comprised of a tube having an open end and a closed end, a closure in the open end of the tube, a vacuum drawn to a predetermined level inside the container; and (2) compounds including an anticoagulant agent and a fixative agent, wherein the compounds are in a sufficient amount to preserve said cells' original morphology and antigenic sites without significant dilution of said cells, and thereby allowing said cells to be directly analyzed by a flow cytometer without further treatment. The claimed subject matter further comprises of a method of making a collection device for cells comprising of: (1) providing a tube having an open end and a closed end; (2) preloading compounds including: an anticoagulant agent, and a fixative agent into the tube, wherein the compounds are in a sufficient amount to preserve the cells' original morphology and antigenic sites without significant dilution of the cells, and thereby allowing the cells to be directly analyzed by a flow cytometer without further treatment; (3) inserting a closure into the open end of the tube; and (4) drawing a vacuum inside the tube to a predetermined level to form the collection device.

The invention relates to a sample collection kit (100) for collecting plant samples, in particular algae samples for biomedical applications, which sample collection kit comprises at least one sample container for holding plant samples, a plurality of sensors, by means of which sample data can be captured, a data-recording apparatus for recording the sample data, an arrangement of tools, which has collection tools designed for harvesting the plant samples and processing tools designed for processing the plant samples, an arrangement of devices, which has auxiliary devices that can be used in the collection, transport, and processing of the plant samples, a container apparatus (70), which is designed to hold the arrangement of tools and the arrangement of devices in isolation from the environment, and identification markings (80), which contain identification data and are applied to the at least one sample container (70) to the collection tools, and to the processing tools. The invention further relates to a sample collection method.

In embodiments there is described a method for reducing false positives and negatives in the detection of SARS-CoV-2 in suspected patients using mass spectroscopy employing the steps of mixing samples of collected saliva and nasopharyngeal secretions in a single sample container; adding universal transport medium to the mixed samples in said single sample container; transporting the single sample container at a temperature above 0 C. to a remote location; deactivation of viral content of the mixed sample; protein digestion of the mixed sample; concomitant separation of peptides, ionization by mass spectroscopy of the separated peptides, and comparison of peptide patterns to known SARS-CoV-2 peptides. Also set forth in an embodiment is a collection container for collecting saliva and/or sputum, as well as a swab member, with universal transport medium and/or virus inactivating agent housed in separate compartment communicable with sample compartment through a one-way valve.

Modular building cleanrooms having integrated mechanical rooms with removable, walkable floor panels above their ceilings are disclosed. The attic area above the sealed cleanroom ceiling and below joists of the modular building's frame provides an interstitial volume through which ducts, piping, electrical conduit, etc. run from the mechanical room to dampers, valves, and junctions boxes. The walkable floor panels can be bar grating through which maintenance people can see components below. The floor panels can have individual sections that may be removed for access to the components. Along with walkable floor panels, the modular building roofs can have foldable electrical panelboards that are pre-wired at the factory and then rotated upright once delivered to their destination.

Methods for separating cells from a sample (e.g., separating fetal red blood cells from maternal blood) include introducing a sample including cells into one or more microfluidic channels. In one embodiment, the device includes at least two processing steps. For example, a mixture of cells is introduced into a microfluidic channel that selectively allows the passage of a desired type of cell, and the population of cells enriched in the desired type is then introduced into a second microfluidic channel that allows the passage of the desired cell to produce a population of cells further enriched in the desired type. The selection of cells is based on a property of the cells in the mixture, for example, size, shape, deformability, surface characteristics (e.g., cell surface receptors or antigens and membrane permeability), or intracellular properties (e.g., expression of a particular enzyme).

The present disclosure provides devices, systems, methods for processing and/or analyzing a biological sample. An analytic device for processing and/or analyzing a biological sample may comprise a moving carriage. The analytic device may be portable. The analytic device may receive instructions for performing an assay from a mobile electronic device external to a housing of the analytic device.

The invention provides a method for digitising a method of synthesis. The method includes the steps of identifying a method of synthesis for a target product; (ii) establishing a process sequence for that method, which process sequence is a collection of chemical and/or physical steps within the method of synthesis; and subsequently (iii) translating the process sequence to a digital model of the method of synthesis, which digital model comprises a digital description of the chemical and/or physical steps within the method of synthesis.

A convenience kit for sterilizing and delivering liquids into the safety of a sterile environment inside a plastic bag (which can be disposed in a field environment) wherein a so sterilized liquid is dispensed into a vessel which is capped and sealed before removal from the bag. The convenience kit can be provided in a solitary format or, as a subkit combined with other associated items in a more inclusive convenience kit. In short, convenience kits made according to the present invention provide opportunity for accomplishing an aseptic liquid sterilizing transfer, a task which is commonly associated with on-hand capability of a laminar flow hood, in field environments and other areas which are remote from facilities having laminar flow hoods.

A sample kit includes a sealable container having a first region, a second region, and a third region. The first region is arranged to house at least one collection device. The second region is arranged to house at least one sample identification holders. The third region is configured to house a desiccant. The collection device is configured to obtain a sample, where the sample is configured to be positioned within the sample identification holder to define a completed sample. The sealable container includes a coating on at least one of an inner surface of the sealable container or an outer surface of the sealable container.

Disclosed are devices, kits, compositions, and methods for collecting, transporting, and detecting toxicants, pathogens, and biomarkers in a biological sample. The devices, kits, compositions and methods may be utilized to collect and transport dried blood samples from a skin prick and detect toxicants, pathogens, and biomarkers in the dried blood samples.