An object of the present invention is to provide an analysis apparatus in which local analysis of a substrate with ICP-MS is automated. The present invention relates to an automatic analysis apparatus for a local region of a substrate, including: a nozzle for local analysis having: analysis-liquid supply means that ejects analysis liquid onto a substrate; analysis-liquid discharge means that takes the analysis liquid including an object to be analyzed from the substrate into the nozzle to feed the analysis liquid to a nebulizer; and exhaust means including an exhaust channel in the nozzle; automatic liquid-feed means that automatically feeds the collected analysis liquid to ICP-MS; flow adjustment means that adjusts the flow of the analysis liquid; and automatic control means that simultaneously performs local analysis and analysis of the object to be analyzed with the ICP-MS to perform automatic analysis to a plurality of adjacent predetermined regions, successively.

The present invention provides for a fluid transfer device for interconnecting vessels, the fluid transfer device comprising a main body with a first body part providing a first hollow interior merging into a first open end for receiving a fluid obtaining vessel, and a second body part providing a second hollow interior merging into a second open end for receiving a fluid supplying vessel, a connection assembly with a double-ended cannula for connecting the first hollow interior with the second hollow interior, and a first encasing member encasing a first cannula part arranged within the first hollow interior, and an actuating member provided inside the first hollow interior, wherein the actuating member is movably arranged along a longitudinal axis of the first body part, and wherein the actuating member is in contact with the first encasing member for piercing the first encasing member by the cannula during a movement of the actuating member towards the second body part. Furthermore, the present invention provides for the use of such fluid transfer device for venting a fluid supplying vessel and/or interconnecting vessels, as well as for a respective method.

Systems and methods are disclosed for rapid PCR testing. Example embodiments may include a PCR testing module that includes a housing having a PCR machine disposed therein; a sample input station on the housing, wherein the sample input station is configured to receive a sample collection device (SCD) comprising a biological specimen sample provided by the patient; an SCD processing mechanism configured to transfer a lysed microportion of the biological specimen sample into a PCR sample tube attached to the SCD; at least one mechanism configured to separate the PCR sample tube from the SCD and transfer the PCR sample tube to the PCR machine; and a controller configured to (i) use the PCR machine to conduct a PCR test on contents of the PCR sample tube, and (ii) generate results of the PCR test.

The present disclosure generally relates to a method and device for inactivation and dry storage, under ambient conditions, of a biological sample containing RNA virus. Methods for collecting and recovering RNA from a biological sample and subsequent analysis for a virus are also provided.

Methods, systems, and apparatuses are disclosed for a tamper-resistant collection and retention a chemical sample. In one embodiment, the tamper-resistant system comprises a container operable to collect and retain a chemical sample, a tamper-resistant mechanism operable to disengage at a first chemical sample to allow for a collection of a chemical sample, wherein the tamper-resistant mechanism is operable to record one or more of: a date, a time, and a location, of the chemical sample during the collection of the chemical sample, and wherein the tamper-resistant mechanism is further operable to re-engage and lock after the collection of the chemical sample to resist subsequent chemical samples after the first chemical sampling.

Disclosed herein are high-throughput sample processing systems and waste management systems, and methods of using the same.

Provided is a pipette device that can discharge or withdraw a liquid easily by liquid processing operation by a robot device. Provided is a pipette device held by a robot device, comprising a driving part for withdrawing and/or discharging a liquid, a signal receiving part for receiving a signal from the robot device and a control part for controlling the driving part according to the signal.

Systems and methods are provided for sample processing. A device may be provided, capable of receiving the sample, and performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing multiple assays. The device may comprise one or more modules that may be capable of performing one or more of a sample preparation, sample assay, and detection step. The device may be capable of performing the steps using a small volume of sample.

A process for the identification of genetic material in a biological liquid sample and including the steps of injecting into a reaction vessel containing freeze dried PCR reagents and labelled primers sufficient pure water to liquify the reagents and primers; injecting the biological liquid sample into the reaction vessel; subjecting the reaction vessel contents to a cell disruption process, in the said reaction vessel; conducting pathogen specific polymerase chain reaction (PCR) on the contents of the reaction vessel; and monitoring the PCR and determining therefrom the presence of a specific genetic material. A device for performing the process comprises a heat reduction module (HRM); a peltier cell (TEC) the base plate whereof is contiguous with the HRM; a reaction vessel receiving heat transfer sleeve contiguous with a working face of the TEC; retention means for holding a reaction vessel in the sleeve; and means for driving the TEC.

Reagent delivery systems, which can include a reagent trough and a pump system, are useful for delivering liquids to a laboratory workbench. Processing samples on the laboratory workbench can result in a large amount of liquid waste. Described herein are reagent troughs, pump systems, reagent delivery systems, waste management systems, and methods of using the same.