Abstract
Hyperspectral imaging has the unique ability of capturing spectral data for multiple wavelengths at each pixel in an image. This gives the ability to distinguish, with certainty, different nanomaterials and/or distinguish nanomaterials from biological materials. In this study, 4 nm and 13 nm gold nanoparticles (Au NPs) were synthesized, functionalized with complimentary oligonucleotides, and hybridized to form large networks of NPs. Scattering spectra were collected from each sample (unfunctionalized, functionalized, and hybridized) and evaluated. The spectra showed unique peaks for each size of Au NP sample and also exhibited narrowing and intensifying of the spectra as the NPs were functionalized and then subsequently hybridized. These spectra are different from normal aggregation effects where the LSPR and reflected spectrum broaden and are red-shifted. Rather, this appears to be dependent on the ability to control the interparticle distance through oligonucleotide length, which is also investigated through the incorporation of a poly-A spacer. Also, hybridized Au NPs were exposed to cells with no adverse effects and retained their unique spectral signatures. With the ability to distinguish between hybridization states at nearly individual NP levels, this could provide a new method of tracking the intracellular actions of nanomaterials as well as extracellular biosensing applications.
Highlights
Gold nanoparticles (Au NPs) have been highly popular for use in cell imaging, targeted drug delivery, cancer diagnostics, and medical therapeutic applications [1,2,3,4]
Au NPs serve as a model system for NP studies due to their large, producible size and shape ranges and their ease of functionalization with biomolecules through thiol chemistry
For the initial ssDNA functionalization work, 13 nm Au NPs were synthesized by the well-known Turkevich method with very high uniformity and reproducibility
Summary
Gold nanoparticles (Au NPs) have been highly popular for use in cell imaging, targeted drug delivery, cancer diagnostics, and medical therapeutic applications [1,2,3,4]. Au NPs serve as a model system for NP studies due to their large, producible size and shape ranges and their ease of functionalization with biomolecules through thiol chemistry. Au NP’s LSPRs are sensitive to the NP’s surrounding environment, causing a significant shift in the LSPR peak when in close proximity to other materials or when molecules interact with their surface This shift in the LSPR peak can be measured by observing the changes in the absorption spectrum; it correlates to a change in the scattered light from the particle, providing a colorimetric response which is recordable by any light scattering spectrum equipment. Chemical sensing using functionalized Au or Ag nanospheres and nanorods has been successful in detecting DNA, heavy
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