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I. Lynch, A. Salvati and K. A. Dawson, “Protein-Nanoparticle Interactions: What Does the Cell See?” Nature Nanotechnology, Vol. 4, No. 9, 2009, pp. 546-547.
http://dx.doi.org/10.1038/nnano.2009.248

has been cited by the following article:

  • TITLE: Physiological Fluid Specific Agglomeration Patterns Diminish Gold Nanorod Photothermal Characteristics

    AUTHORS: Kristen K. Comfort, Jared W. Speltz, Bradley M. Stacy, Larry R. Dosser, Saber M. Hussain

    KEYWORDS: Gold Nanorod; Nanophotonic; Agglomeration; Artificial Physiological Fluid; Photothermal Application

    JOURNAL NAME: Advances in Nanoparticles, Vol.2 No.4, November 5, 2013

    ABSTRACT: Investigations into the use of gold nanorods (Au-NRs) for biological applications are growing exponentially due to their distinctive physicochemical properties, which make them advantageous over other nanomaterials. Au-NRs are particularly renowned for their plasmonic characteristics, which generate a robust photothermal response when stimulated with light at a wavelength matching their surface plasmon resonance. Numerous reports have explored this nanophotonic phenomenon for temperature driven therapies; however, to date there is a significant knowledge gap pertaining to the kinetic heating profile of Au-NRs within a controlled physiological setting. In the present study, the impact of environmental composition on Au-NR behavior and degree of laser actuated thermal production was assessed. Through acellular evaluation, we identified a loss of photothermal efficiency in biologically relevant fluids and linked this response to excessive particle aggregation and an altered Au-NR spectral profile. Furthermore, to evaluate the potential impact of solution composition on the efficacy of nano-based biological applications, the degree of targeted cellular destruction was ascertained in vitro and was found to be susceptible to fluid-dependent modifications. In summary, this study identified a diminution of Au-NR nanophotonic response in artificial physiological fluids that translated to a loss of application efficiency, pinpointing a critical concern that must be considered to advance in vivo, nano-based bio-applications.