A new electrochemical DNA sensor providing detection capabilities down to 100 attomol of target DNA has been developed. The method applies CdS, ZnS, and PbS nanoparticles conjugated with short DNA sequences which are immobilized via hybridization with complementary sequences on a gold surface. When the DNA target is added, it can be identified by ousting the existing hybridization between one of the DNA-nanoparticle conjugates and the surface DNA. The nanoparticles remaining at the surface are detected by stripping voltammetry. The setup is constructed to give a signal-off response with a build-in control signal as only one of two different metal sulfide signaling probes on the surface is removed by hybridization with the DNA target. The competition assay is, in principle, label-free since no labels are required for detection after addition of DNA target. The dissociation of PbS nanoparticles from the surface after addition of the DNA target has been imaged by fluid phase AFM.
A microfabricated cantilever with an internal piezoresistive component has been sensitized with thiol tethered ss-DNA strands and utilized for an in situ, label-free, highly specific, and rapid DNA detection assay. The generation of a differential surface stress onto the functionalized cantilever surface upon target recognition has allowed nanomechanical identification of 12-nucleotide complementary DNA probes with single base mismatch discrimination (sensitivity of 0.2 microM). Interestingly, utilization of an overhang extension distal to the surface enhanced the sensitivity to the 0.01 microM level. The cantilever was functionalized by inkjet printing technology. Replacing the capture probe with locked nucleic acid (LNA) resulted in a faster target probe capture kinetics compared to DNA-DNA hybridization. The capabilities of the piezoresistive cantilever indicate future ergonomic convenience via miniaturization alternative to the conventional laser-based detection method for portable on-site applications.
A fast, label-free, and multiplexed method based on piezoresistive cantilevers is reported for the detection of specific protein conformations at the nanoscale level. The ligand-binding domain of the human oestrogen receptor (ERalpha-LBD) is used as the experimental model system, and ERalpha-LBD with or without oestradiol (E2) is detected using the conformation-specific peptides alpha/betaI (Ser-Ser-Asn-His-Gln-Ser-Ser-Arg-Leu-Ile-Glu-Leu-Leu-Ser-Arg, which recognizes E2-bound ER) and alpha/betaII (Ser-Ala-Pro-Arg-Ala-Thr-Ile-Ser-His-Tyr-Leu-Met-Gly-Gly, which recognizes E2-free ER). Target-specific signals are obtained in situ at protein concentrations of 2.5-20 nM. The in-build electrical readout of the piezoresistive cantilevers provides a convenient alternative to the conventional optical detection, and the presented method offers the possibility of detecting protein conformational changes using miniaturized microarrays.
Fischer carbene complex anchored on glass or silicon surface using a Cu-free 'click' reaction allows facile and swift covalent grafting of protein molecules like Bovine Serum Albumin (BSA).
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