Calculated Absorption and Scattering Properties of Gold Nanoparticles of Different Size, Shape, and Composition:  Applications in Biological Imaging and Biomedicine

Abstract: The selection of nanoparticles for achieving efficient contrast for biological and cell imaging applications, as well as for photothermal therapeutic applications, is based on the optical properties of the nanoparticles. We use Mie theory and discrete dipole approximation method to calculate absorption and scattering efficiencies and optical resonance wavelengths for three commonly used classes of nanoparticles: gold nanospheres, silica-gold nanoshells, and gold nanorods. The calculated spectra clearly reflect… Show more

“…Successful down regulation was attributed to the simultaneous structural deformation of the HGN under NIR light, which was confirmed by UV-vis spectral changes in SPR, and the breakage of the Au S bond, due to heat, which resulted in the release of siRNA to the cytosol [177]. This mechanism has been described previously in photothermal transfection experiments involving DNA and is attributed to hot electron thermalization of the nanoparticle lattice [243,260,261]. Fig.…”

“…Tuning of the LSPR properties can be achieved through synthesis by exploiting differences in nanoparticle size, geometry, surface morphology, aggregation, aspect ratio, and the dielectric constant of the surrounding media [15,33,[35][36][37][38][39][40][41][42][43][44][45]. Since each application relies on a specific set of conditions for optimized efficiency, the structural parameters of the nanoparticles employed for use must be tailored accordingly.…”

“…Both the core width and shell thickness can be tuned through synthesis to produce a range of overall diameters (20-125 nm) and aspect ratios. As a two-interface system HGNs have enhanced LSPR which is the result of strong coupling in the near-field between the plasmon modes of the inner cavity surface and the outer surface [8,9,29,38]. This coupling leads to the hybridization of the two individual plasmon modes where the plasmons interact electrostatically with one another in the same manner as a coupled harmonic oscillator [8,9].…”

“…Briefly, noble metal nanoparticles, exhibiting NIR absorption in the appropriate size regime (20-100 nm) for biological applications, are modified with either an antibody or ligand specific to an antigen or receptor, on the surface of a tumor cell [38,53,190]. NIR absorbing particles are preferred since it is well known that blood and tissue are most readily penetrated by light in this wavelength region [191][192][193].…”

“…As noble metal structures, they have enhanced EM field strength because of their plasmon resonance, and surfaces can be easily functionalized to target biomolecules. They are also resistant to photobleaching and have molar extinction coefficients (ε) that are larger than those of dyes and QDS [35,38,177,367]. For instance, Lu et al recently reported that a 40 nm HGN with a 2-3 nm shell and an SPR of 800 nm has a molar absorption coefficient of 1.4 × 10 11 M −1 cm −1 [177].…”

Controllable Cobalt Oxide/Au Hierarchically Nanostructured Electrode for Nonenzymatic Glucose Sensing

“…Successful down regulation was attributed to the simultaneous structural deformation of the HGN under NIR light, which was confirmed by UV-vis spectral changes in SPR, and the breakage of the Au S bond, due to heat, which resulted in the release of siRNA to the cytosol [177]. This mechanism has been described previously in photothermal transfection experiments involving DNA and is attributed to hot electron thermalization of the nanoparticle lattice [243,260,261]. Fig.…”

“…Tuning of the LSPR properties can be achieved through synthesis by exploiting differences in nanoparticle size, geometry, surface morphology, aggregation, aspect ratio, and the dielectric constant of the surrounding media [15,33,[35][36][37][38][39][40][41][42][43][44][45]. Since each application relies on a specific set of conditions for optimized efficiency, the structural parameters of the nanoparticles employed for use must be tailored accordingly.…”

“…Both the core width and shell thickness can be tuned through synthesis to produce a range of overall diameters (20-125 nm) and aspect ratios. As a two-interface system HGNs have enhanced LSPR which is the result of strong coupling in the near-field between the plasmon modes of the inner cavity surface and the outer surface [8,9,29,38]. This coupling leads to the hybridization of the two individual plasmon modes where the plasmons interact electrostatically with one another in the same manner as a coupled harmonic oscillator [8,9].…”

“…Briefly, noble metal nanoparticles, exhibiting NIR absorption in the appropriate size regime (20-100 nm) for biological applications, are modified with either an antibody or ligand specific to an antigen or receptor, on the surface of a tumor cell [38,53,190]. NIR absorbing particles are preferred since it is well known that blood and tissue are most readily penetrated by light in this wavelength region [191][192][193].…”

“…As noble metal structures, they have enhanced EM field strength because of their plasmon resonance, and surfaces can be easily functionalized to target biomolecules. They are also resistant to photobleaching and have molar extinction coefficients (ε) that are larger than those of dyes and QDS [35,38,177,367]. For instance, Lu et al recently reported that a 40 nm HGN with a 2-3 nm shell and an SPR of 800 nm has a molar absorption coefficient of 1.4 × 10 11 M −1 cm −1 [177].…”

Controllable Cobalt Oxide/Au Hierarchically Nanostructured Electrode for Nonenzymatic Glucose Sensing

Nanomaterials for Medical Applications

Multiscale Fabrication of Plasmonic Structures