Quantifying and Adjusting Plasmon-Driven Nano-Localized Temperature Field around Gold Nanorods for Nucleic Acids Amplification

Fast nucleic acid (NA) amplification has found widespread biomedical applications, where high thermocycling rate is the key. The plasmon-driven nano-localized thermocycling around the gold nanorods (AuNRs) is a promising alternative, as the significantly reduced reaction volume enables a rapid temperature response. However, quantifying and adjusting the nano-localized temperature field remains challenging for now. Herein, a simple method is developed to quantify and adjust the nano-localized temperature field around AuNRs by combining experimental measurement and numerical simulation. An indirect method to measure the surface temperature of AuNRs is first developed by utilizing the temperature-dependent stability of Au-thiol bond. Meanwhile, the relationship of AuNRs ' surface temperature with the AuNRs concentration and laser intensity, is also studied. In combination with thermal diffusion simulation, the nano-localized temperature field under the laser irradiation is obtained. The results show that the restricted reaction volume (approximate to aL level) enables ultrafast thermocycling rate (>10(4) degrees C s(-1)). At last, a duplex-specific nuclease (DSN)-mediated isothermal amplification is successfully demonstrated within the nano-localized temperature field. It is envisioned that the developed method for quantifying and adjusting the nano-localized temperature field around AuNRs is adaptive for various noble metal nanostructures and will facilitate the development of the biochemical reaction in the nano-localized environment.

Automated summary

A simple method has been developed to quantify and adjust the nano-localized temperature field around AuNRs by combining experimental measurement and numerical simulation. The method first developed an indirect way to measure the surface temperature of AuNRs by utilizing the temperature-dependent stability of the Au-thiol bond. Meanwhile, the relationship of AuNRs' surface temperature with the AuNRs concentration and laser intensity is also studied.