DNA-programmed assembly of plasmonic nanostructures provides a powerful route to couple molecular recognition with optical signal generation. Here, we report the sequence-specific assembly of DNA-functionalized gold nanorods using a sesame allergen-derived DNA biomarker as a molecular bridge. Target-induced assembly produces concentration-dependent assembly growth, plasmon coupling, and distinct assembly kinetics that are readily monitored by absorption spectroscopy, enabling label-free detection of the target DNA in the nanomolar concentration range. The assembled nanorods further produce strong surface-enhanced Raman scattering (SERS) signals arising from plasmonic coupling within the assemblies, extending detection to the picomolar regime without the use of Raman reporters. Quantitative analysis reveals that both the extent and rate of assembly formation are governed by target DNA concentration. These results establish a direct relationship between molecular recognition, assembly growth, plasmonic coupling, and spectroscopic response, highlighting DNA-programmed gold nanorod assembly as a versatile platform for investigating hybridization-driven plasmonic self-assembly and nucleic acid detection.
Sharma, S., Singh, A. P., Pradhan, S., Goel, M., Gupta, N., Patra, S.
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