Compositions, methods, and systems for analyzing the protein corona are described herein, as well as its application in the discovery of advanced diagnostic tools as well as therapeutic targets.

Compositions, methods, and systems for analyzing the protein corona are described herein, as well as its application in the discovery of advanced diagnostic tools as well as therapeutic targets.

A processing and detection system for detecting presence of at least one gluten protein in a food sample comprises a food processor including: a reservoir containing a process liquid for processing the food sample; a body that comprises a chamber configured to receive the food sample; and a pressing surface configured to press on the reservoir to cause the process liquid to exit the reservoir and mix with the food sample, thereby generating a processed food liquid; and an exit port configured to conduct the processed food liquid out of the food processor; and a cartridge including: at least one sensor configured to receive the processed food liquid and to generate an electrical signal in response to interaction with the at least one gluten protein in the processed food liquid, and an analyzer in electrical communication with the at least one sensor for detecting the electrical signal and determining the presence of the at least one gluten protein in the food sample based on the detected electrical signal.

The invention features methods and diffraction-based devices for the detection of specific analytes. The devices of the invention contain a periodic dielectric multilayer, which allows for the propagation of Bloch surface waves (BSWs) at the surface of the multilayer, thereby increasing the sensitivity of the device.

The invention provides methods of immobilizing an active agent to a substrate surface, including the steps of, providing a substrate, contacting the substrate with a solution of a compound including a trihydroxyphenyl group, thereby forming a trihydroxyphenyl-treated substrate, and contacting the trihydroxyphenyl-treated substrate with an active agent, thereby immobilizing the active agent on the substrate. Further provided are methods of immobilizing an active agent on a substrate, including the steps of providing a substrate, combining a solution of a compound including a trihydroxyphenyl group with a solution of an active agent, thereby forming a solution of an active agent-trihydroxyphenyl conjugate, and contacting the substrate with the solution of the active agent-trihydroxyphenyl conjugate, thereby immobilizing the active agent on the substrate. The invention further provides substrates and medical device or device components with active agents immobilized on the surface thereof.

The invention provides methods of immobilizing an active agent to a substrate surface, including the steps of, providing a substrate, contacting the substrate with a solution of a compound including a trihydroxyphenyl group, thereby forming a trihydroxyphenyl-treated substrate, and contacting the trihydroxyphenyl-treated substrate with an active agent, thereby immobilizing the active agent on the substrate. Further provided are methods of immobilizing an active agent on a substrate, including the steps of providing a substrate, combining a solution of a compound including a trihydroxyphenyl group with a solution of an active agent, thereby forming a solution of an active agent-trihydroxyphenyl conjugate, and contacting the substrate with the solution of the active agent-trihydroxyphenyl conjugate, thereby immobilizing the active agent on the substrate. The invention further provides substrates and medical device or device components with active agents immobilized on the surface thereof.

A diagnostic device includes a photodiode formed by a body of semiconductor material having a first surface, an integrated optical structure on the first surface and having a second surface, and at least one detection region on the second surface. The at least one detection region includes at least one receptor that binds to a corresponding target molecule that can be mated with a corresponding marker, which, when excited by radiation having a first wavelength, emits radiation having a second wavelength that can be detected by the photodiode. The integrated optical structure includes at least a first layer of a first material having a first refractive index. The first layer has a thickness substantially equal to an integer and odd multiple of one fourth of the first wavelength divided by the first refractive index.

A diagnostic device includes a photodiode formed by a body of semiconductor material having a first surface, an integrated optical structure on the first surface and having a second surface, and at least one detection region on the second surface. The at least one detection region includes at least one receptor that binds to a corresponding target molecule that can be mated with a corresponding marker, which, when excited by radiation having a first wavelength, emits radiation having a second wavelength that can be detected by the photodiode. The integrated optical structure includes at least a first layer of a first material having a first refractive index. The first layer has a thickness substantially equal to an integer and odd multiple of one fourth of the first wavelength divided by the first refractive index.

Among others, the present invention provides micro-devices for detecting or treating a disease, each comprising a first micro sensor for detecting a property of the biological sample at the microscopic level, and an interior wall defining a channel, wherein the micro sensor is located in the interior wall of the micro-device and detects the property of the biological sample in the microscopic level, and the biological sample is transported within the channel.

Devices and methods for gravimetric sensing are disclosed. A gravimetric sensor includes a piezoelectric resonator and an encapsulating layer formed on the surface of the resonator. The encapsulating layer defines a channel within the encapsulating layer on the surface of the resonator. The sensor is fabricated by forming a piezoelectric resonator, forming a sacrificial layer on a surface of the piezoelectric resonator, forming an encapsulating layer over the sacrificial layer on the resonator, and etching the sacrificial layer to remove the sacrificial layer and form a channel on the surface of the resonator. The sensor is used by supplying the liquid to the channel of the gravimetric sensor, operating the piezoelectric resonator, detecting a change in a resonant frequency of the resonator, and determining a presence of the analyte in the liquid from the change in resonant frequency of the resonator.