A sample processing system that may be automated and methods are disclosed where samples are arranged on a carrier element and a process operation control system automatically processes the samples perhaps robotically with an operationally-influential exteriorly-consequential information monitor or a data capture element. Significant process details as well as operationally-influential exteriorly-consequential information may be monitored and an automatic notice element may cause notification of a person at some display that may be remote. Various people may be notified, such as an administrator, a supplier, or a manufacturer of an opportunity for some action such as reagent reordering or the like. A simulated motion display may be included to watch simulated operation in real time or long after completion of the actual processing.

A heating device having a heating element patterned into a robust MEMs substrate, wherein the heating element is electrically isolated from a fluid reservoir or bulk conductive sample, but close enough in proximity to an imagable window/area having the fluid or sample thereon, such that the sample is heated through conduction. The heating device can be used in a microscope sample holder, e.g., for SEM, TEM, STEM, X-ray synchrotron, scanning probe microscopy, and optical microscopy.

The apparatus has a containing body with a flat upper functional floor for containing receptacles of reagents, diluents and samples, as well as housings for gel cards and incubators for the same; a lower floor containing receptacles for washing liquids and the collection of waste and cards and for housing the fluid control and electronic control system; a series of longitudinal and transverse guides associated with the upper part of the apparatus, suitable for carrying in suspension the moving heads of the apparatus, the heads being movable on the transverse guides; two heads, respectively for perforation and pipetting and for the transport of gel cards; two centrifuges and a gel card reader; and a folding touch screen providing information and control.

A system for the integrated and automated analysis of DNA or protein, including a single-use cartridge, with an analysis device having a control device, and devices for capturing and processing signals, the control device carrying out a completely automatic process and evaluation of molecular diagnostic analysis via single-use cartridges (Lab-on-a-Chip). Controlling of an analysis process, which occurs in the cartridge, involves the subsequent displacement and thermostatization of liquids with a first device, and with a second device the signals which are obtained during the analysis are processed. The first and the second devices are synchronized in such a manner that the analysis process of the sample can be carried out in a totally integrated manner thus producing an immediate result.

In one embodiment, a diagnostic system includes an instrument coupled to a client device and having at least one sample processing bay. The diagnostic system has a software architecture including instrument software (ISW) associated with the instrument. The ISW receives an assay definition file (ADF) that has a control file and an assay analysis module (AAM) file. The processing bay prepares and senses the sample according to parameters in the OPUS file and then generates sensor scan data. The diagnostic system then analyzes the sensor scan data and prepares a report according to the AAM file.

The present invention relates to markers for liquids that can be used to authenticate the origin and genuineness of a liquid, preferably a bulk liquid such as fuel. For this purpose, the present invention teaches the use of a polymer capable of forming a semiconducting polymer particle (pdot) in the liquid in small amounts. The invention encompasses a liquid comprising a) a polymer that is capable of forming a semiconducting polymer particle (pdot), the concentration of the polymer being 10 ppm by weight or less, and b) an organic substance in an amount of 90% by weight or more. The invention furthermore envisages the use of such a polymer as an authenticating marker in a liquid, preferably a fuel, and a method for authenticating the genuineness and/or origin of a liquid comprising a polymer capable of forming a semiconducting polymer particle (pdot), comprising the steps i. concentrating, isolating and/or extracting the polymer capable of forming a semiconducting polymer particle (pdot); ii. aggregating the polymer or the polymer obtained in Step i. to form semiconducting polymer dots (pdots); iii. irradiating the formed pdots with electromagnetic radiation capable of exciting the pdots to emit electromagnetic radiation by fluorescence and/or phosphorescence, and iv. observing the electromagnetic radiation emitted in response to the exciting irradiation of step iii.

Embodiments disclosed herein are directed to multi-test assay systems for analyzing biological material and methods of using such multi-test assay systems. For example, the multi-test assay system can detect or identify one or more biological markers representative of or corresponding to an illness or disease.

Embodiments disclosed herein are directed to multi-test assay systems for analyzing biological material and methods of using such multi-test assay systems. For example, the multi-test assay system can detect or identify one or more biological markers representative of or corresponding to an illness or disease.

Disclosed is a specimen treatment apparatus that treats a specimen by using a specimen treatment chip including a flow channel and a connecting port communicating with the flow channel, the specimen treatment apparatus including: a placement part in which the specimen treatment chip is placed; a connector provided to be engaged with the connecting port to allow a sample containing a specimen to be injected into the flow channel through the connector; and a heating unit that is pressed on the specimen treatment chip and heats the specimen treatment chip while the connector is connected to the connecting port of the specimen treatment chip placed in the placement part.

Induction heating can be used facilitate reactions within biological samples. A sample container can be placed in a magnetic field from an induction coil to generate heat. An exemplary sample container can include an electrically insulative outer wall surrounding an interior space for containing a biological sample and a heating element within the interior space, the heating element comprising an electrically conductive portion. In use, the sample container can be received within a receptacle that includes the induction coil. The induction coil is operated to induce a current in the heating element of the sample container until the biological sample reaches a target temperature.