The present invention relates to a kit for detecting a virus, a composition for detecting a virus and a method for detecting a virus. According to the present invention, viruses may be detected with high efficiency at low cost within a short period of time.

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.

Disclosed herein are methods for isolating target cells from blood, involving mixing in an open container an undiluted blood sample having a volume of 10 ml or less, and binding agents, wherein each binding agent comprises (A) a primary binding agent comprising an agent capable of binding to at least one cellular epitope on target cells in the undiluted blood sample, (B) a first linker bound to the primary binding agent, to generate binding agent-attached target cells in the undiluted blood sample; contacting the binding agent-attached target cells in the undiluted blood sample with a plurality of buoyant reagents that include a second linker capable of binding to the first linker to generate an undiluted buoyant reagent-attached target cell mixture; diluting the undiluted buoyant reagent-attached target cell mixture by at least 20% to produce a diluted buoyant reagent-attached target cell mixture; applying a vectorial force, such as centrifugal force, to the diluted buoyant reagent-attached target cell mixture to generate a stratified diluted buoyant reagent-attached target cell mixture; removing the buoyant reagent-attached target cells from the stratified diluted buoyant reagent-attached target cell mixture; and isolating the target cells from the buoyant reagent-attached target cells.

The present disclosure provides a system comprising a communication interface and computer for assigning a label to the biomolecule fingerprint, wherein the label corresponds to a biological state. The present disclosure also provides a sensor arrays for detecting biomolecules and methods of use. In some embodiments, the sensor arrays are capable of determining a disease state in a subject.

Sub-millimeter scale three-dimensional (3D) structures are disclosed with customizable chemical properties and/or functionality. The 3D structures are referred to as drop-carrier particles. The drop-carrier particles allow the selective association of one solution (i.e., a dispersed phased) with an interior portion of each of the drop-carrier particles, while a second non-miscible solution (i.e., a continuous phase) associates with an exterior portion of each of the drop-carrier particles due to the specific chemical and/or physical properties of the interior and exterior regions of the drop-carrier particles. The combined drop-carrier particle with the dispersed phase contained therein is referred to as a particle-drop. The selective association results in compartmentalization of the dispersed phase solution into sub-microliter-sized volumes contained in the drop-carrier particles. The compartmentalized volumes can be used for single-molecule assays as well as single-cell, and other single-entity assays.

Provided herein are methods for capturing extracellular vesicles from a biological sample for quantification and/or characterization (e.g., size and/or shape discrimination) using an SP-IRIS system. Also provided herein are methods of detecting a biomarker on captured extracellular vesicles or inside the captured vesicles (e.g., intra-vesicular or intra-exosomal biomarkers).

Disclosed herein are methods for using modified liposomes or carrier proteins comprising (i) an acridinium ester (AE), and (ii) a first agent encapsulated by the liposomes and/or (iii) a second agent on the surface of the liposomes or the carrier proteins. Specifically, the disclosed methods provide methods of labeling a target of interest, assaying a biological sample for a target antigen, and detecting a target antigen in a biological sample. Further disclosed herein are methods for increasing the strength of a signal detected by an imaging modality.

Disclosed herein are methods for isolating target cells from blood, involving mixing in an open container an undiluted blood sample having a volume of 10 ml or less, and binding agents, wherein each binding agent comprises (A) a primary binding agent comprising an agent capable of binding to at least one cellular epitope on target cells in the undiluted blood sample, (B) a first linker bound to the primary binding agent, to generate binding agent-attached target cells in the undiluted blood sample; contacting the binding agent-attached target cells in the undiluted blood sample with a plurality of buoyant reagents that include a second linker capable of binding to the first linker to generate an undiluted buoyant reagent-attached target cell mixture; diluting the undiluted buoyant reagent-attached target cell mixture by at least 20% to produce a diluted buoyant reagent-attached target cell mixture; applying a vectorial force, such as centrifugal force, to the diluted buoyant reagent-attached target cell mixture to generate a stratified diluted buoyant reagent-attached target cell mixture; removing the buoyant reagent-attached target cells from the stratified diluted buoyant reagent-attached target cell mixture; and isolating the target cells from the buoyant reagent-attached target cells.

Methods for identifying and detecting potential disease specific biomarkers from biofluids. The methods involve in vivo administration of nanoparticles to a subject in a diseased state or incubating nanoparticles in a biofluid sample taken from a subject in a diseased state and analysis of the biomolecule corona formed on said nanoparticles. The methods distinguish between a healthy and diseased state in a subject, such as, for example, the presence of a tumor in a human subject.

Compositions comprising multiple hydrogel particles having substantially the same diameter, but with each subgrouping of particles from the multiple hydrogel particles having different associated values for one or more passive optical properties that can be deconvoluted using cytometric instrumentation. Each hydrogel particle from the multiple hydrogel particles can be functionalized with a different biochemical or chemical target from a set of targets. A method of preparing hydrogel particles includes forming droplets and polymerizing the droplets, with optional functionalization.