Disclosed are novel lanthanide(III) chelates including a pyridine 4-ethynylpyrazine subunit. These chelates have an excitation wavelength which allows excitation with UV LED.

The present invention provides methods of detecting analytes using particles having different physico-chemical properties, such as buoyancy, size, density, spectral characteristics, and/or binding properties, in solution-based sandwich assays and solution-based competition assays. The methods can be performed using rotors and bench-top centrifuges and provide for rapid, qualitative and quantitative detection of analytes. The present invention also provides kits that can be used to perform the methods, and mixtures containing particles suitable for the methods.

Provided is a method of using an aptamer for detecting a glycated hemoglobin in a whole blood, the method includes that the aptamer is provided, the aptamer includes a DNA sequence selected from the group consisting of derived sequences of SEQ ID NOs: 1, 2, 3, and 4, in which the derived sequences refer to that 3′ end and/or 5′ end of the derived sequences are modified, and the derived sequences have 90% identity to the SEQ ID NOs: 1, 2, 3, and 4. The aptamer and the whole blood are contacted. A concentration of a conjugate of the aptamer and the glycated hemoglobin is estimated. Provided also is a nanoelectronic aptasensor including the above aptamer.

The present invention relates to compositions comprising magnetic particles, the methods of using these compositions in processing animal sperm, the resulting sperm and embryo products, and the methods of use of these compositions to increase the efficiency, efficacy and/or speed of cell processing and artificial insemination techniques.

A method for detecting biomarkers with shortened test time and maximized precision. A sample from the body fluid is made to flow over a sensor surface coated with a capture antibody to allow binding of a biomarker in the sample to the capture body. An optical method detects and counts the individual binding events along the sensor surface with single molecule resolution, and difference in the binding events along the sensor surface is detected in real time and analyzed to determine the biomarker concentration.

A method for measuring the concentration of a micro/nano particle, including: allowing the to-be-measured micro/nano particle to bind with one or more kinds of marker to form a new particle, the new particle having a change in at least one of particle size, charge state, and particle morphology compared with the to-be-measured micro/nano particle or the marker; measuring the particle size, charge state, or particle morphology of the new particle and the to-be-measured micro/nano particle or the marker, and counting the new particle and the to-be-measured micro/nano particle or the marker respectively to obtain their respective count results, and, on the basis of the count results, calculating the concentration of the to-be-measured micro/nano particle bound with the marker. The method of the present application has the advantages of high measurement accuracy, low measurement limit, and stability of chemical reagents.

The present invention provides a method of detecting one or more analytes in a target sample, the method comprising: a. providing a nanoparticle dimer adapted to bind the analyte; b. causing the dimer to pass through a nanopore by voltage-driven translocation; c. observing changes in the translocation current; and d. comparing the translocation current profile of the target sample to the translocation current profile of a control sample; wherein a change in the translocation current profile of the target sample versus the control sample indicates the presence of the analyte in the target sample. Also provided is a method of detecting one or more analytes in a target sample, the method comprising: a. providing a nanoparticle adapted to bind the analyte; b. providing a carrier nucleic acid molecule with at least one single-stranded region; c. contacting the carrier nucleic acid molecule and nanoparticle with the target sample, forming a carrier nucleic acid/analyte/nanoparticle complex; b. causing the carrier nucleic acid/analyte/nanoparticle complex to pass through a biological nanopore by voltage-driven translocation; c. observing changes in the translocation current; and d. comparing the translocation current profile of the target sample to the translocation current profile of a control sample; wherein a change in the translocation current profile of the target sample versus the control sample indicates the presence of the analyte in the target sample.

Provided is a method for the quantitative and/or qualitative determination of bioindicators, including the following steps: a) immobilizing capture molecules for the bioindicators on a substrate; b) bringing the bioindicators of a sample into contact with the capture molecules; c) immobilizing the bioindicators on the substrate by binding to capture molecules; d) bringing the bioindicators into contact with probes containing at least one detection molecule, and e) removing non-specifically bound molecules and particles; and f) binding the probes to the bioindicators, wherein the probes are capable of emitting a specific detection signal and steps b) and d) can take place simultaneously or d) before b), and wherein probes and capture molecules are used which have affine molecules or molecule parts that bind to at least one specific binding site of the bioindicators and these affine molecules or molecule parts of the probes and capture molecules do not overlap one another.

The invention relates to methods for detecting and/or characterising a nanovesicle in a sample or a method of detecting a target that is bound or associated with said nanovesicle, wherein the sample is brought into contact with nanoparticles that are capable of binding on the surface of nanovesicle and form, in situ, a nanoshell that surround said nanovesicle. In a preferred embodiment, the nanovesicle is exosome labelled with fluorescent probes and the nanoparticles are gold nanoparticles (AuNP). The invention also relates to a kit or microfluidic chip for performing such methods, as well as a method of determining the prognosis of a cancer in a subject by performing such methods.

Provided herein is a sensing apparatus comprising, at least one LSPR light source, at least one detector, and at least one sensor for LSPR detection of a target chemical. The sensor comprises a substantially transparent, porous membrane having nanoparticles immobilized on the surface of its pores, the nanoparticles being functionalized with one or more capture molecules. There is further provided a self-referencing sensor for distinguishing non-specific signals from analyte binding signals. The self-referencing sensor comprising one or more nanoparticles having at least two distinct LSPR signals.