A molecular probe comprising at least one first moiety and at least one second moiety which are each covalently bound to the molecular probe, wherein: the at least one first moiety comprises at least one binding peptide or peptidomimetic for binding the molecular probe to at least one extracellular vesicle (EV) membrane, wherein the binding is mediated by EV membrane curvature sensing; and the at least one second moiety comprises at least one support binding group for binding of the molecular probe to at least one support. The molecular probe can also comprise a spacer moiety, and/or a labeling moiety, and/or a modification moiety. The molecular probe can be bound to a solid or semi-solid support including a microarray support. The molecular probe can be used in methods in which it is contacted with sample which might include the extracellular vesicle and can involve detection and isolation steps. Kits can include the molecular probe.

A device for chemiluminescence analysis includes: a reaction chamber; a first inlet opening for introducing a sample gas into the reaction chamber via a first supply line; a second inlet opening for introducing a reaction gas into the reaction chamber via a second supply line; an outlet opening for discharging a mixture of the sample gas and the reaction gas out of the reaction chamber via an outlet line; a mixer unit in which the sample gas and the reaction gas are mixed; and a sensor unit for detecting chemiluminescent radiation in the reaction chamber, wherein the mixer unit is arranged in a first end region of the reaction chamber, and the sensor unit is arranged in a second end region of the reaction chamber opposite the first end region. An elemental analyzer including the device is also disclosed.

An automated analyzer includes an analysis operation part that causes a sample and a reagent to react and based on the reaction result performs analysis of the sample, wherein: the automated analyzer includes a plurality of units constituting the analysis operation part, a temperature adjustment mechanism that heats or cools the units, a temperature sensor that measures the temperature of the units, and a control part that controls the temperature adjustment mechanism. The control part sets the measurement startable temperature range of each unit, which is the temperature range of the operation specification thereof, and the operable temperature range, which is a temperature range that is wider than the measurement startable temperature range, and starts the analysis process of the sample when the temperature of each unit has entered the operable temperature range.

The present disclosure relates to methods of collecting and testing bacteria containing samples from within the gastrointestinal (GI) tract of a subject. The methods may include disposing an ingestible device in the GI tract, collecting a bacteria-containing sample from the GI tract, selectively lysing eukaryotic cells in the sample by combining the sample with a dried reagent, exposing bacteria in the sample to resazurin in the ingestible device to produce resorufin, emitting light from the ingestible device, the emitted light being filtered through an optical filter to control for scatter so that the light interacts with the resorufin to produce fluorescence, and measuring a total fluorescence from the resorufin; or a rate of change of fluorescence from the resorufin as a function of time within the GI tract of the subject; and correlating the measured parameter to a number of viable bacterial cells in the sample.

The present disclosure relates to methods of collecting and testing bacteria containing samples from within the gastrointestinal (GI) tract of a subject. The methods may include disposing an ingestible device in the GI tract, collecting a bacteria-containing sample from the GI tract, selectively lysing eukaryotic cells in the sample by combining the sample with a dried reagent, exposing bacteria in the sample to resazurin in the ingestible device to produce resorufin, emitting light from the ingestible device, the emitted light being filtered through an optical filter to control for scatter so that the light interacts with the resorufin to produce fluorescence, and measuring a total fluorescence from the resorufin; or a rate of change of fluorescence from the resorufin as a function of time within the GI tract of the subject; and correlating the measured parameter to a number of viable bacterial cells in the sample.

A light guide includes a translucent member. The translucent member includes: a light incident surface where light is incident; a light emitting surface provided on a side of the translucent member opposite to the light incident surface and emitting light; a parabolic first mirror surface facing the light incident surface and reflecting the light incident from the light incident surface as parallel light; and a parabolic second mirror surface facing the first mirror surface and the light emitting surface and reflecting the parallel light reflected by the first mirror surface so as to be condensed toward the light emitting surface.

A compact explosive detecting system collects explosive residues in the form of vapor powder. The residues are accumulated on a desorber which is subjected to pyrolysis to release a gaseous sample. The sample is pumped to a detecting system through a metering valve. A luminol cell reacts with the gaseous sample to create chemiluminescence, the light output of which is measured by a photo multiplier tube. The light intensity is indicative of the amount of explosive present. Based on the amount of explosive present, a metering valve is adjusted to pass the gaseous sample into a highly sensitive metal oxide sensor array to detect NO.sub.2 from nitrogen containing explosive and CO/CO.sub.2 from non nitrogen containing explosive. The metal oxide sensor array reliably selects explosives from those compounds indicating chemiluminescence.

A multi-well assay plate is provided. The multi-well assay plate includes at least a top plate that defines a plurality of wells and a base plate having a substrate with well electrode structures patterned thereon. The well electrode structures are arranged in a plurality of sector electrical structures, each including a working electrode bus bar and a portion of an auxiliary electrode pattern. The substrate further includes at least one working electrode contact patterned on a bottom surface and an auxiliary electrode contact pattern disposed on the bottom surface.

Disclosed is an automated liquid-phase immunoassay apparatus used with a cuvette having a plurality of chambers containing a reagent necessary for detection of an analyte in a biological specimen. The apparatus includes a movable cuvette module equipped with the cuvette, an optical reading module for optical assaying of a material resulting from a reaction between the specimen and the reagent, and a dispenser module which is positioned on the cuvette module and which dispenses the specimen and the reagent to the plurality of chambers of the cuvette and washes the specimen and the reagent therefrom.

Disclosed is an automated liquid-phase immunoassay apparatus used with a cuvette having a plurality of chambers containing a reagent necessary for detection of an analyte in a biological specimen. The apparatus includes a movable cuvette module equipped with the cuvette, an optical reading module for optical assaying of a material resulting from a reaction between the specimen and the reagent, and a dispenser module which is positioned on the cuvette module and which dispenses the specimen and the reagent to the plurality of chambers of the cuvette and washes the specimen and the reagent therefrom.