The present invention provides methods, devices, compositions (e.g., capture complexes), and kits useful for enhancing the detection of antibodies in a test sample. The methods, devices, and compositions utilize detectable Fc-binding molecules such as Protein A, Protein G, and/or an Fc-specific antibody to amplify the signal of a detected antibody in immunoassays, such as lateral flow assays.

A fluorescence immunochromatographic detection card and a preparation method therefor and usage thereof is disclosed. The fluorescence immunochromatographic detection card comprises a treatment liquid A, a treatment liquid B, and a detection card. The treatment liquid A contains an antibody 15C4 that is coupled with a fluorescent microsphere. The treatment liquid B contains an antibody 13G12 that is coupled with biotin. The detection card comprises a detection line area and a quality control line area, and a streptavidin detection T line is fixed in the detection area, and an antibody quality control C line is immobilized in the quality control line area. The preparation method comprises: (1) formulating the treatment liquid A; (2) formulating the treatment liquid B; and (3) drawing the line on the detection card. The fluorescence immunochromatographic detection card has characteristics such as high sensitivity, high specificity, and high stability, and can be applied to the rapid detection of disease markers.

Nanodiamond particles and related devices and methods, such as nanodiamond particles for the detection and/or quantification of analytes, are generally described. In some embodiments, the device comprises a plurality of nanodiamond particles and a species bound to the nanodiamond particles. In certain embodiments, the plurality of nanodiamond particles may be exposed to a sample suspected of containing an analyte. In some cases, the analyte may bind to the species such that the presence of the analyte in the sample may be detected. In some embodiments, the devices, systems, and methods described herein are useful for the detection of an analyte in a sample obtained from a subject for, for example, diagnostic purposes. In some cases, the systems, devices, and methods described herein may be useful for diagnosing, prevent, treating, and/or managing a disease or bodily condition. In an exemplary embodiment, such systems, devices, and methods described herein may be useful for detecting and/or quantifying the presence of a virus (e.g., ebola) in a subject and/120 or a sample obtained from the subject.

The present invention provides an apparatus having a sample separation unit, a Raman spectroscopy unit, and a mass spectrometry unit. The present invention further provides a method for specifying a biomolecule and a method for identifying the binding site of the biomolecule and the low-molecular-weight compound, comprising a combination of Raman spectroscopy and mass spectrometry. The present invention further provides a surface-enhanced Raman spectroscopy method with improved sensitivity.

A method for detecting an analyte reactive towards luminol, comprising the steps of: feeding into a reaction chamber an alkaline solution of luminol, noble metal nanoparticles and at least one analyte reactive towards luminol, wherein the reaction chamber is in the form of a curved channel; detecting the light emitted due to a chemiluminescence reaction taking place in said channel; and discharging a reaction mass from said channel, characterized in that the average diameter of the metal nanoparticles is greater than 25 nm. Also provided is a microfluidic device for carrying out the method.

Compositions which comprise a gold nanoparticle, dithiolated diethylenetriamine pentaacetic acid (DTDTPA), and a thioctic acid terminated peptide, wherein the DTDTPA is directly linked to the gold nanoparticle surface via an AuS bond, and wherein the thioctic acid terminated peptide is directly linked to the gold nanoparticle surface via an AuS bond.

Methods for producing high concentration protein formulations having high stability are provided. Assays for selecting proteins and formulation conditions that have high self-repulsive attributes are used as an early step in the manufacturing process. Specifically, a protein concentration-dependent self-interaction nanoparticle spectroscopy method is employed as a protein colloidal interaction assay.

A method and a system for detection of presence or absence of analytes in fluids, the method comprising the steps of: a) contacting a fluid sample and a plurality of nanoparticles, the nanoparticles being functionalized with a selective ligand, the contact of the fluid sample with the nanoparticles being under conditions such that, the nanoparticles aggregate selectively on surface of their target analyte, forming a nanoparticle-analyte complex, the aggregation promoting the concentration of the nanoparticles on the surface of the target analyte; b) subjecting a fluid mixture of the fluid sample and the plurality of nanoparticles to SERS; c) measuring at least a SERS signal associated with the fluid mixture; d) spectrally analyzing the at least one SERS signal of step c); e) recognizing at least one defined SERS spectrum of the nanoparticle-analyte complex, through a SERS signal enhanced by the at least one narrow inter-nanoparticle gap.

This invention provides a groundbreaking approach to PLNPs and their preparation. In particular, the synthetic methodology disclosed herein fundamentally differs from the traditional solid-state annealing reactions that require extreme and harsh reaction conditions. In one unique aspect of the invention, a simple, one-step mesoporous template method utilizing mesoporous silica nanoparticles (MSNs) is disclosed that affords in vivo rechargeable NIR-emitting mesoporous PLNPs with uniform size and morphology. In another unique aspect of the invention, the novel synthetic approach is based on aqueous-phase chemical reactions conducted in mild conditions, resulting in uniform and homogeneous PLNPs with desired size control (e.g., sub-10 nm).

A multicomponent nanomaterial AuNP(DTDTPA)(Ga), where DTDTPA is an amino-carboxylate ligand (diethylene triamine pentaacetic acid, DTPA) linked to the surface of the Au nanoparticle (NP) via dithiol (DT) linkage. Another embodiment is a multicomponent nanomaterial AuNP(DTDTPA)(Ga) with a biomolecule attached. In preferred embodiments, the Ga is Ga-67 or Ga-68. Preferred synthesis methods are conducted at room temperature.