Provided herein are sample collection devices that include a first body structure portion that comprises a drying agent compartment configured to receive a drying agent and a second body structure portion operably connected, or connectable, to the first body structure portion. The second body structure portion includes a sample collection support compartment comprising one or more segments that communicate with the drying agent compartment at least when the first and second body structure portions are operably connected to one another in a closed position. The sample collection support compartment is configured to receive a sample collection support. Related kits, systems, computer readable media, and methods are also provided.

Systems and methods for performing a plurality of nucleic acid amplification assays in an automated analyzer. A first nucleic acid amplification assay of the plurality is performed in accordance with a first set of assay parameters which consist of system-defined parameters. And a second nucleic acid amplification assay of the plurality is performed in accordance with a second set of assay parameters which includes one or more user-defined parameters.

A magazine insert for a pneumatic tube conveyor capsule for receiving sample tubes filled with bodily fluids includes a magazine drum, a fastening unit, a slider and a catch element. The magazine drum has a plurality of receiving chambers for the sample tubes. The fastening unit is pivotable about the longitudinal axis from a fastening position to a release position. The slider in the central recess of the magazine drum is slidable in axial direction from a first functional position bidirectionally to a respective second functional position relative to the magazine drum. The catch element is fastened to the slider and extends in radial direction into a control cam of the fastening unit. A pivoting of the fastening unit from the fastening position to its release position can be effected by transferring the slider to its corresponding second functional position.

Devices, systems, and methods for detecting molecules of interest within a collected sample are described herein. In certain embodiments, self-contained sample analysis systems are disclosed, which include a reusable reader component, a disposable cartridge component, and a disposable sample collection component. In some embodiments, the reader component communicates with a remote computing device for the digital transmission of test protocols and test results. In various disclosed embodiments, the systems, components, and methods are configured to identify the presence, absence, and/or quantity of particular nucleic acids, proteins, or other analytes of interest, for example, in order to test for the presence of one or more pathogens or contaminants in a sample.

There is provided a receptacle carrier unit and automated analyzer capable of suppressing generation of temperature nonuniformities among liquid aliquots received in plural receptacles without increasing the parts count. The receptacle carrier unit has a turntable, a turntable drive, a cool box, a cooling portion, and a control section. The control section controls the turntable drive, based on the number and installation locations of the receptacles installed in the cool box and on temperature distribution information, to homogenize the effects that the individual receptacles receive from the cool box.

A device for storing, incubating or manipulating biological samples, in particular incubating device or shaking device, comprising a sample chamber, an irradiation chamber, and a holder with a UV light source, wherein a sidewall of the irradiation chamber comprises a first mounting member and wherein the holder comprises a second mounting member configured to interact with the first mounting member for pre-mounting the holder to the sidewall.

The present invention relates generally to devices able to manipulate, process, treat, sort, measure and/or analyse samples at a micro level, commonly referred to as microfluidic devices. In particular, the present invention relates to a microfluidic device that can be used for the analysis of particulate samples, such as by the leaching at a micro level of a crushed rock particulate sample from a mineral ore body and the subsequent analysis of the leachate. The present invention also relates to a method for the use of a microfluidic device for the analysis of a particulate sample.

A rotary analysis apparatus and related methods are disclosed. The apparatus generally includes a rotary machine operable to rotate or spin a removable disk-type analytical cartridge. The cartridge includes a plurality of fluidly isolated processing trains for processing multiple samples simultaneously. Each process train includes an extractant mixing chamber, slurry filtration chamber, supernatant collection chamber, and reagent mixing chamber in fluid communication. In one use, soil sample slurry is prepared and added to the extractant mixing chamber. The slurry is mixed with an extractant by rotating the cartridge to separate out an analyte from the mixture. A sediment filter in the filtration chamber deliquifies and traps soil particles to produce clear supernatant. A color changing reagent or fluorescent agent may be mixed with the collected supernatant for subsequent colorimetric, fluorescent, turbidimetric, or other type of analysis.

A method includes coupling a molecular diagnostic test device to a power source. A biological sample is conveyed into a sample preparation module. The device is then actuated by only a single action to cause the device to perform the following functions without further user action. First, the device heats the sample via a heater of the sample preparation module to lyse a portion of the sample. Second, the device conveys the lysed sample to an amplification module and heats the sample within a reaction volume of the amplification module to amplify a nucleic acid thereby producing an output solution containing a target amplicon. The device then reacts, within a detection module, each of (i) the output solution and (ii) a reagent formulated to produce a signal that indicates a presence of the target amplicon within the output solution. A result associated with the signal is then read.

A container holding device for holding one or more containers includes: a base plate having an upper surface, a bottom surface, and one or more holes each extending from the upper surface to the bottom surface and having a central symmetry axis L.sub.axis orthogonal to the base plate; and two or more holding elements that are located around each hole beneath the bottom surface of the base plate. The holding elements are configured to: contact an outer surface of a container that is placed into the container holding device at a bottom edge of a top region of the container, such that the container hangs in the container holding device in a first position p1 in which the holding elements do not exert any force on the outer surface of the container that is radial; and contact the outer surface of the container in a shoulder region.