A method for measuring bilirubin concentration in a sample includes preparing a sensing element, where the sensing element may include a plurality of carbon dots, adding the sample to the sensing element, where the sample may include a plurality of bilirubin molecules, obtaining a first grayscale image of the sensing element under ultra-violet (UV) irradiation, irradiating visible light with a wavelength between 470 nm and 490 nm on the sensing element, obtaining a second grayscale image of the sensing element under ultra-violet (UV) irradiation, calculating a light intensity difference by calculating a difference between a first average light intensity of the first grayscale image and a second average light intensity of the second image, and determining the bilirubin concentration based on a correlation between the bilirubin concentration and the light intensity difference.

Disclosed herein are modified polymerase compositions exhibiting altered polymerase activity, which can be useful in a variety of biological applications. Also disclosed herein are methods of making and using such compositions. In some embodiments, the compositions exhibit altered properties that can enhance their utility in a variety of biological applications. Such altered properties, can include, for example, altered nucleotide binding affinities, altered nucleotide incorporation kinetics, altered photostability and/or altered nanoparticle tolerance, as well as a range of other properties as disclosed herein.

A method and system to decode information stored on a polymer sequence, such as a DNA strand, is described herein. The method and system use molecular probes to label sections of the polymer sequence. Each molecular probe includes a fluorophore and a quencher. The fluorophore produces light with a color and wavelength corresponding to the information stored on the section of the polymer sequence the molecular probe labels. The quencher inhibits the production of light by an adjacent fluorophore. When adjacent sections of the polymer sequence are labeled with molecular probes, the fluorophore of the leading molecular probe produces light while the trailing molecular probe's light is quenched. The method and system then sequentially unbind the molecular probes from the sections of the polymer sequence within a waveguide, producing a sequence of observable fluorescence signals. The sequence can be used to determine the information stored on a polymer sequence.

There is provided an influenza virus detection chip and a method for detecting influenza virus therewith. An influenza virus detection chip including: a graphene oxide film; a first pad disposed on one side of the graphene oxide film in a first direction; and a first electrode and a second electrode, connected to both ends of the graphene oxide film in a second direction perpendicular to the first direction, wherein a first monoclonal antibody with a fluorescent label is included in the first pad, and a second monoclonal antibody is included in the graphene oxide film, and wherein the fluorescent label includes a C═C—C═C conjugated double bond.

The present invention relates to an optical sensing element for detection of a narcotic, the optical sensing element comprising a fluorescent sensing compound provided on a substrate, wherein emission of the fluorescent sensing compound is quenched in the presence of the narcotic, and wherein the fluorescent sensing compound is non-polymeric and comprises an electron donor moiety, an electron acceptor moiety and a moiety that influences solubility of the compound in a solvent. Sensing devices incorporating the sensing element and methods of detecting narcotics are also described.

A device for base calling is provided. The device includes a receptacle configured to hold a biosensor having a sample surface holding a plurality of clusters during a sequence of sampling events, an array of sensors sensing information from clusters disposed in corresponding pixel areas of the sample surface during the sampling events and generate sequences of pixel signals and a communication port configured to output the sequences of pixel signals. The device also includes a signal processor coupled to the communication port and configured to receive and process at least one pixel signal in the sequences of pixel signals that mixes light gathered from at least two clusters in a corresponding pixel area, and to base call each of the at least two clusters using the at least one pixel signal.

The present invention relates to a method of capturing and stabilising volatile thiol malodour generated on the human skin, comprising steps of: i) contacting the human skin with a substrate, ii) absorbing said thiol into the substrate, and iii) reacting said thiol with a thiol-capture agent. The invention also relates to a method of quantifying said thiol, a method of assessing the deodorizing performance of a cosmetic composition on the human skin.

Methods of detecting a non-explosive analyte can include exposing a sensor compound to a non-explosive analyte and displaying a change in the sensor compound upon exposure of the sensor compound to the non-explosive analyte. A variety of sensor compounds for detecting a target analyte, including both explosive and non-explosive analytes, is also described. Sensor devices for detecting a target analyte can include a substrate and a sensor compound positioned on the substrate in a plurality of detection zones.

A soil sampler attachable to a vehicle for agricultural uses includes a collector configured to collect a soil sample from a field as the vehicle advances across the field. The soil sampler further includes a preprocessor connected to the collector and configured to receive the soil sample from the collector and to preprocess the soil sample to dilute the soil sample. The soil sampler also includes a sensor connected to the preprocessor and configured to determine a concentration of at least one analyte in the soil sample. The soil sampler further includes a disposer connected to the sensor and configured to dispose the soil sample after the sensor determines the concentration of the at least one analyte in the soil sample.

A device for monitoring a measurement object, comprising: an active unit having a light source emitting light with a wavelength spectrum and an optical detector. An optical link passes the emitted light to a at least one passive unit. Each passive unit comprises a sensor and a selector for diverting the emitted light to the sensor. The sensor comprises a luminescent material being directly or indirectly affected by the emitted light diverted by the selector. The sensor is sensitive to an external influence by the measurement object for producing a modulated signal, which is passed to said detector via the optical link. The luminescent material may be a fluorescent material, which is directly irradiated by the emitted light from the light source.