Systems and methods are provided herein for rapid detection, separation, purification, and quantification of viral particles in a sample. According to some embodiments, a microfluidic device is provided for receiving the sample which may contain viral particles. An electrode of the microfluidic device may be used to generate dielectrophoretic (DEP) and/or electroosmotic (EO) forces acting on the sample. The applied DEP and/or EO forces may immobilize components of the sample on the surface of the electrode, may aggregate viral particles of the sample in one region of the microfluidic device, and may separate other components of the sample from the viral particles. The techniques may be performed rapidly, for example, in eight hours or less, and may not affect infectivity of the viral particles. In some embodiments, the sample may be labeled to enhance a response of one or more of the sample components to the DEP and/or EO forces.

A kit and method for flow cytometry include a liquid dye concentrate for fluorescent staining of virus-size particles with a plurality of fluorogenic dyes in a liquid medium. The liquid dye concentrate includes a plurality of fluorogenic dyes and one or both of (i) the liquid medium comprising a liquid mixture including water and liquid phase organic material and (ii) disaccharide dissolved in the liquid medium.

Systems and methods are provided herein for rapid detection, separation, purification, and quantification of viral particles in a sample. According to some embodiments, a microfluidic device is provided for receiving the sample which may contain viral particles. An electrode of the microfluidic device may be used to generate dielectrophoretic (DEP) and/or electroosmotic (EO) forces acting on the sample. The applied DEP and/or EO forces may immobilize components of the sample on the surface of the electrode, may aggregate viral particles of the sample in one region of the microfluidic device, and may separate other components of the sample from the viral particles. The techniques may be performed rapidly, for example, in eight hours or less, and may not affect infectivity of the viral particles. In some embodiments, the sample may be labeled to enhance a response of one or more of the sample components to the DEP and/or EO forces.

The present invention provides a method for rapid, highly specific and sensitive detection and quantification of a virus by observing viral substrate binding to its host receptor protein. The invention also provides a method for rapid, highly specific and sensitive detection and quantification of a virus in an individual suspected of being infected with a virus. The invention further provides a test kit for rapid, highly specific and sensitive point-of-care detection of a virus in an individual. The viruses and their host receptor proteins that can rapidly be detected include SARS-CoV-2 and its host receptor protein ACE2. The surprisingly rapid, specific and sensitive method and kit of the invention provide a point-of care test capable of diagnosing individuals suffering from COVID-19 by observation of a color change in the assay, which color change occurs in about five minutes, and which test can be completed by a user in about 60 minutes.

The optical analyte detector is a photonic detector that uses a measured wavelength shift to determine the presence of an analyte. An open cell is formed in an optical layer for receiving a sample to be analyzed. A transition metal dichalcogenide monolayer defines a bottom wall of the open cell, and the transition metal dichalcogenide monolayer is formed directly above a microring resonator. A waveguide is positioned adjacent to the open cell, and is spaced apart therefrom by a gap. The waveguide is coupled to the microring resonator, and the transition metal dichalcogenide monolayer is functionalized with an adsorbed layer for detection of a specific analyte. Molecular binding takes place if a sample of the analyte contacts the adsorbed layer, which induces a wavelength shift in light transmitted through the waveguide. The presence of this measured wavelength shift indicates positive detection of the analyte.

A method of determining a management course for treating a subject showing symptoms of a disease is disclosed. The method comprises measuring the TRAIL protein level in a blood sample of the subject, wherein when the TRAIL level is above a predetermined amount, the subject is treated as a low-risk patient.

A system for diagnosing COVID-19 infection. The system includes a biosensor, an electrochemical stimulator-analyzer, and a processing unit. The biosensor is configured to be put in contact with a blood serum sample of a person suspected to be infected of COVID-19 virus. The processing unit is configured to apply an AC potential amplitude to the biosensor while sweeping a frequency range utilizing the electrochemical stimulator-analyzer, recording an electrochemical impedance spectroscopy (EIS) associated with the blood serum sample utilizing the electrochemical stimulator-analyzer, calculating a charge transfer resistance (R.sub.CT) of the recorded EIS, and detecting a COVID-19 infection of the person based on the calculated R.sub.CT if the calculated R.sub.CT is equal to or more than a threshold value.

A method for diagnosing COVID-19 infection. The method includes drawing a blood sample from a person suspected to be infected with COVID-19 virus, separating a blood serum sample from the blood sample by centrifuging the blood sample, recording an electrochemical impedance spectroscopy (EIS) associated with the blood serum sample, calculating a charge transfer resistance (R.sub.CT) of the recorded EIS by measuring a diameter of a semicircular curved part of the recorded EIS, and detecting a COVID-19 infection of the person based on the calculated R.sub.CT if the calculated R.sub.CT is equal to or more than a threshold value.

The instant invention describes a virus reduction neutralization test (VRNT) which is a rapid, high throughput alternative to current standard low throughput and laborious neutralization assays. The VRNT utilizes imaging cytometry to count virus-infected cells at about one day post-infection (thus eliminating the wait time other assays employ allowing for viral infection cell to cell), reducing overall assay time and increasing throughput at least 15-fold.

Antibodies that bind SARS-CoV spike protein, SARS-CoV-2 spike protein, and methods of using same for treating or preventing conditions associated with SARS or COVID-19 and for detecting SARS-CoV or SARS-CoV-2.