Electrocatalytic and Analytical Response of β-Cyclodextrin Incorporated Carbon Nanotubes-Modified Electrodes Toward Guanine

Evolution of Supramolecular Systems Towards Next-Generation Biosensors

Supramolecular materials, which rely on dynamic non-covalent interactions, present a promising approach to advance the capabilities of currently available biosensors. The weak interactions between supramolecular monomers allow for adaptivity and responsiveness of supramolecular or self-assembling systems to external stimuli. In many cases, these characteristics improve the performance of recognition units, reporters, or signal transducers of biosensors. The facile methods for preparing supramolecular materials also allow for straightforward ways to combine them with other functional materials and create multicomponent sensors. To date, biosensors with supramolecular components are capable of not only detecting target analytes based on known ligand affinity or specific host-guest interactions, but can also be used for more complex structural detection such as chiral sensing. In this Review, we discuss the advancements in the area of biosensors, with a particular highlight on the designs of supramolecular materials employed in analytical applications over the years. We will first describe how different types of supramolecular components are currently used as recognition or reporter units for biosensors. The working mechanisms of detection and signal transduction by supramolecular systems will be presented, as well as the important hierarchical characteristics from the monomers to assemblies that contribute to selectivity and sensitivity. We will then examine how supramolecular materials are currently integrated in different types of biosensing platforms. Emerging trends and perspectives will be outlined, specifically for exploring new design and platforms that may bring supramolecular sensors a step closer towards practical use for multiplexed or differential sensing, higher throughput operations, real-time monitoring, reporting of biological function, as well as for environmental studies.

Rapid and cost-effective detection of sequence-specific DNA by monitoring the electrochemical response of 2'-deoxyguanosine 5'-triphosphate in a PCR sample

This study describes a novel strategy for rapid and cost-effective detection of sequence-specific DNA based upon the essential utility of the polymerase chain reaction (PCR) and electrochemical technologies. A dramatic enhancement of the anodic peak current (i(pa)) and a visible decrease of overpotential towards free 2'-deoxyguanosine 5'-triphosphate (dGTP) could be realized on a glassy carbon electrode modified with short single-walled carbon nanotubes (S-SWNT/GCE). Thereby, the concentration of the free dGTP in the PCR sample mixture could be determined sensitively. The i(pa) of the free dGTP decreased remarkably after a successful PCR amplification owing to the participation of the free dGTP as one of the reactive substrates for the PCR products, namely dsDNA. Based upon this response change of the free dGTP before and after incorporation in PCR, a novel method aiming at detecting PCR results was established. One transgenic maize sample as a model was successfully detected by employing the specific sequences of 35S promoter from cauliflower mosaic virus (CaMV35S) gene and nopaline synthase (NOS) gene as markers. The result was in good accordance with that obtained with gel electrophoresis.