Presented herein are systems, methods, and architectures related to functionalization of the metallic gates of field-effect transistors (FETs) and the use of the functionalized FETs as biochemical sensors in liquid samples. The functionalization can either be a molecularly imprinted polymer or a probe material. The functionalized FETs can be used in devices for analyte detection/quantification. In particular, the functionalized FETs are used in devices for the detection and/or quantification of cytokines (e.g. interleukin) and/or cholesterol (LDL or HDL).

Presented herein are systems, methods, and architectures related to functionalization of the metallic gates of field-effect transistors (FETs) and the use of the functionalized FETs as biochemical sensors in liquid samples. The functionalization can either be a molecularly imprinted polymer or a probe material. The functionalized FETs can be used in devices for analyte detection/quantification. In particular, the functionalized FETs are used in devices for the detection and/or quantification of cytokines (e.g. interleukin) and/or cholesterol (LDL or HDL).

The present disclosure provides new approaches in developing templated polymer-based chemical receptors. At least some embodiments of the invention use a stimuli-responsive polymer [e.g., poly-Nisopropylacrylamide (pNIPAM)] as a polymer backbone with the incorporation of functional monomers (for analyte recognition). In at least some embodiments of the invention, vinylferrocene may be used as a redox-active label for electrochemical transduction.

A colorimetric sensor for detecting an analyte of interest in a fluid sample includes a lamellar photonic material having alternating layers of a first polymer layer and a second polymer layer. Each first polymer layer can be a molecularly imprinted polymer defining a cavity shaped to receive an analyte of interest. The photonic material is configured such that, when an analyte contacts the photonic material and becomes disposed within a cavity of the molecularly imprinted polymer, a refractive property of the photonic material changes, causing a detectable color change in the sensor.

The present disclosure provides a biosensor having improved sensitivity. The present disclosure also provides a base material for manufacturing a sensor for analyzing a detection object, said base material comprising a molecularly imprinted polymer having: a molecularly imprinted recess in which a target of the detection object is received; and a group for binding a specific bondable molecule to the target, said group being provided inside the molecularly imprinted recess. The base material is characterized in that the group for binding the specific bondable molecule is a group suited for a small substance, and/or is characterized in that the molecularly imprinted recess has a shape or structure suited for a small substance.

A colorimetric sensor for detecting an analyte of interest in a fluid sample includes a lamellar photonic material having alternating layers of a first polymer layer and a second polymer layer. Each first polymer layer can be a molecularly imprinted polymer defining a cavity shaped to receive an analyte of interest. The photonic material is configured such that, when an analyte contacts the photonic material and becomes disposed within a cavity of the molecularly imprinted polymer, a refractive property of the photonic material changes, causing a detectable color change in the sensor.

A measurement system capable of detecting a detection target such as sEVs with high specificity and rapidity, and also having both high stability and improved binding activity. A base material for producing a sensor for analysis of a detection target, including: a base material; and a polymer film provided on a surface of the base material, wherein the polymer film includes a concave that receives the detection target, and, inside the concave, a group for signal substance's binding and a polynucleotide group for nucleic acid aptamer's binding.

A device for detecting cotinine includes (a) a film that includes a plurality of molecularly-imprinted-polymer (MIP) coated conductive nanoparticles having specific affinity for binding with cotinine, and (b) two electrodes in contact with the film for passing electrical current through the film to detect binding with cotinine as a change in electrical conductivity of the film. A MIP coated conductive nanoparticle for detecting cotinine includes (a) a conductive nanoparticle, (b) a silicon dioxide coating formed on the conductive nanoparticle and forming a first shell around the conductive nanoparticle, and (c) an MIP coating formed on the silicon dioxide coating and forming the second shell, wherein the MIP coating includes a polymer molecularly imprinted with cotinine to provide specific affinity for binding of cotinine to the MIP coated conductive nanoparticle such that the cotinine is detectable as a change in electrical conductivity of the MIP coated conductive nanoparticle.

An allergen detection device that includes a sensor comprising a circuit board, an electropolymerized molecularly imprinted polymer film (MIP) that includes receptor sites imprinted in a first surface of the polymer, the receptor sites configured to accept a trace molecule of an allergen, and an electropolymerized non-imprinted polymer film. The sensor is configured to detect the presence of the trace molecule upon binding to one or more of the receptor sites on the MIP.

A polymer-based sensor for detecting agricultural analytes is disclosed, including stable polymer-based sensing films such as molecular imprinted polymers (MIPs) that can be incorporated in sensors for detecting herbicides and pesticides, as well as methods of making the sensing films.