Samenvatting
DNA-modified gold nanoparticles (AuNPs) play a pivotal role in bio-nanotechnology, driving advancements in bio-sensing, bio-imaging, and drug delivery. Synthetic protocols have focused on maximizing the receptor density on particles by fine-tuning chemical conditions, particularly for DNA. Despite their significance, the understanding of hybridization kinetics on functionalized AuNPs is lacking, particularly how this kinetics depends on DNA density and to what extent it varies from particle-to-particle. This study explores the molecular mechanisms of DNA hybridization on densely coated AuNPs by employing a combination of single-molecule microscopy and coarse-grained molecular dynamics simulations providing a quantification of the molecular rate constants for single particles. Our findings demonstrate that DNA receptor density and the presence of spacer strands profoundly impact association kinetics, with short spacers enhancing association rates by up to ∼15-fold. In contrast, dissociation kinetics are largely unaffected by receptor density within the studied range. Single-particle analysis directly reveals variability in hybridization kinetics, which is analyzed in terms of intra- and inter-particle heterogeneity. A coarse-grained DNA model that quantifies hybridization kinetics on densely coated surfaces further corroborates our experimental results, additionally shedding light on how transient base pairing within the DNA coating influences kinetics. This integrated approach underscores the value of single-molecule studies and simulations for understanding DNA dynamics on densely coated nanoparticle surfaces, offering guidance for designing DNA-functionalized nanoparticles in sensor applications.
Originele taal-2 | Engels |
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Pagina's (van-tot) | 4872-4879 |
Aantal pagina's | 8 |
Tijdschrift | Nanoscale |
Volume | 16 |
Nummer van het tijdschrift | 9 |
Vroegere onlinedatum | 1 feb. 2024 |
DOI's | |
Status | Gepubliceerd - 1 mrt. 2024 |
Financiering
This project has received funding from the European Research Council (ERC) under the European Union's Horizon 2020 research and innovation programme (grant agreement No 864772). R. R.-B., F. S., E. Z., and P. Z. acknowledge funding from the European Union's Horizon 2020 research and innovation program under the Marie Skłodowska-Curie program (ITN SuperCol, Grant Agreement 860914).
Financiers | Financiernummer |
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H2020 Marie Skłodowska-Curie Actions | 860914 |
European Research Council | |
Horizon 2020 | 864772 |