Multi-functionalization of lithographically designed gold nanodisks by plasmon-mediated reduction of aryl diazonium salts.

Plasmon-driven surface functionalization of nanoparticles is receiving increasing attention as it allows locally tailored chemical reactivity to be generated on the nanoparticle surface. The extension to surface multi-functionalization still represents a major breakthrough in chemistry. We address this issue by triggering regiospecific surface double-functionalization under plasmon excitation, using diazonium salts as surface functionalization agents.

Photochromic-fluorescent-plasmonic nanomaterials: towards integrated three-component photoactive hybrid nanosystems.

Silica-coated gold nanorods functionalized with grafted fluorescent and photochromic derivatives were synthesized and characterized. Spectroscopic investigations demonstrated that cross-coupled interactions between plasmonic, photochromic, and fluorescence properties play a major role in such nanosystems, depending on the thickness of the silica spacer, leading to multi-signal photoswitchability.

Revisiting Surface-Enhanced Raman Scattering on Realistic Lithographic Gold Nanostripes.

In this article, we investigate the Surface-Enhanced Raman Scattering (SERS) efficiency of methylene blue (MB) molecules deposited on gold nanostripes which, due to their fabrication by electron beam lithography and thermal evaporation, present various degrees of crystallinity and nanoscale surface roughness (NSR). By comparing gold nanostructures with different degrees of roughness and crystallinity, we show that the NSR has a strong effect on the SERS intensity of MB probe molecules. In particular, the NSR features of the lithographic structures significantly enhance the Raman signal of MB molecules, even when the excitation wavelength lies far from the localized surface plasmon resonance (LSPR) of the stripes. These results are in very good agreement with numerical calculations of the SERS gain obtained using the discrete dipole approximation (DDA). The influence of NSR on the optical near-field response of lithographic structures thus appears crucial since they are widely used in the context of nano-optics or/and molecular sensing.

Multipolar surface plasmon peaks on gold nanotriangles.

In this paper, we report on the observation of multipolar surface plasmon excitation in lithographically designed gold nanotriangles, investigated by means of far-field extinction microspectroscopy in the wavelength range of 400-1000 nm. Several bands are observed in the visible and near infrared regions when increasing the side length of the triangles. The assignment of these peaks to successive in-plane multipolar plasmon modes is supported by calculations using the discrete dipole approximation method. We show that the lowest three multipolar excitations are clearly resolved in the visible and near infrared range. These new spectral features could be very promising in nanooptics or for chemosensing and biosensing applications.

Probing surface plasmon fields by far-field Raman imaging.

This article reports on the imaging of the surface plasmon fields of lithographically designed micrometre-sized gold structures. We investigate rings made of disk-shaped particles and individual crescent-shaped particles. These structures are imaged with two techniques, dark field imaging of elastically scattered light and imaging the surface-enhanced Raman scattering signal of methylene blue dye adsorbed onto the structures. Although elastically scattered light images result from the coherently summed contributions from all elementary scattering volumes, surface-enhanced Raman scattering images reflect the optical near-field intensity incoherently averaged over a surface area corresponding to the spatial resolution of the microscope objective. The combination of both imaging methods enables us to emphasize the role of plasmon coupling and antenna effect in the surface-enhanced Raman scattering enhancement.

Quantum chemical study of the photocoloration reaction in the napthoxazine series.

Ab initio and semiempirical quantum mechanical calculations were performed to study the electronic spectra of spiroxazine photochromic compounds as well as the corresponding photoisomers. Ground-state geometries were optimized based on density functional theory (DFT). Excitation energies of the different forms were calculated using the time-dependent density functional theory (TD-DFT) method. Semiempirical calculations including configuration interactions were performed to detail the mechanism of ring opening in excited states. On the basis of the obtained potential energy profile, a complete mechanism of photocoloration able to clarify some experimental findings is provided. A correlation of the experimental quantum yield of photocoloration with the calculated properties as a function of substituent effects is proposed.

SERRS study of the DNA binding by Ru(II) tris-(Bipyridyl) complexes bearing one carboxylic group.

Surface enhanced resonance Raman scattering (SERRS) is shown to be a satisfying method to study the interaction between DNA and ruthenium complexes [Ru(bpy)(2)(Hcmbpy)][PF(6)](2), where Hcmbpy = 4-carboxy-4'-methyl-2,2'-bipyridine. Such metallic complexes are known for their fluorescence properties. To validate this spectroscopic approach we have checked that i) at a given lambda(ex), silver colloidal SERRS spectra of Ru complexes closely resemble resonance Raman spectra in aqueous solutions, intensity excepted, and ii) the DNA fragments are not altered when they are adsorbed on the Ag nanoparticles surface. This investigation shows that the intensity of the Ru complexes SERRS spectra is reduced in the presence of DNA, in particular for the specific bands assigned to the Hcmbpy ligand. This collapse demonstrates that the Ru complexes bind DNA through the Hcmbpy moiety, and intercalation is suggested as the binding mode. The DNA binding by the enantiopure Ru complexes (Delta or Lambda) is more efficient than by the racemic complexes.

Grating-induced plasmon mode in gold nanoparticle arrays.

We study the dipolar coupling of gold nanoparticles arranged in regular two-dimensional arrays by extinction micro-spectroscopy. When the interparticle spacing approaches the plasmon resonance wavelength of the individual particles, an additional band of very narrow width emerges in the extinction spectrum. By systematically changing the particles dielectric environment, the particles shape, the grating constant and angle of incidence, we show how this band associated to a grating induced-resonance can be influenced in strength and spectral position. The spectral position can be qualitatively understood by considering the conditions for grazing grating orders whereas the strength can be related to the strength of dipolar scattering from the individual particles.

Imaging surface plasmon of gold nanoparticle arrays by far-field Raman scattering.

We present Raman spectra and Raman images of the methylene blue molecule adsorbed as a single layer on gold nanoparticles regularly arranged in periodic arrays. Spectra and images are recorded in the same spatial and spectral regions using an excitation under total internal reflection. Images of the Raman scattering appear as spots of circular shape located at the particle positions with size defined by the diffraction limit. It appears that all excited particles contribute equally to the Raman signal if the Gaussian intensity distribution of the laser beam is taken into account. These results demonstrate that Raman scattering can be a useful technique to study plasmon properties.

Surface enhanced Raman scattering arising from multipolar plasmon excitation.

Visible and near infrared extinction spectra of gold nanorod regular arrays exhibit several bands assigned to high multipolar order plasmon resonances. These up to ninth order multipolar resonances generate surface enhanced Raman scattering spectra with typically 5 x 10(4) enhancement which is of similar magnitude as those obtained for dipolar excitations.

Gold particle interaction in regular arrays probed by surface enhanced Raman scattering.

Lithographically designed two-dimensional arrays consisting of gold nanoparticles deposited on a smooth gold film are used as substrate to examine the SERS effect of the trans-1,2-bis (4-pyridyl) ethylene molecule. These arrays display two plasmon bands instead of the single one observed for the same arrays of particles but deposited on indium tin oxide coated glass. Laser excitation within the short wavelength band does not bring about any SERS spectrum, while excitation within the long wavelength band yields SERS spectra with a gain per molecule rising up to 10(8). The simultaneous investigation of extinction and Raman spectra of arrays exhibiting various topography parameters enables us to suggest an interpretation for both the occurrence of the two plasmon resonances and for the high Raman enhancement. We suggest to assign the short wavelength band to a plasmon wave propagating at the gold glass interface and the long wavelength one to an air/gold surface plasmon mode modified by particle-particle interaction.

Surface enhanced Raman scattering of a lipid Langmuir monolayer at the air-water interface.

Surface enhanced Raman spectra were recorded from a phospholipid monolayer directly at the air-water interface. We used an organized monolayer of negatively charged tetramyristoyl cardiolipins as a template for the electrochemical generation of silver deposits. This two-dimensional electrodeposition of silver under potentiostatic control was the substrate for enhancement of Raman spectra. We report the optimized conditions for the Raman enhancement, the microscopic observations of the deposits, and their characterization by atomic force microscopy. Laser excitation at 514.5 nm leads to intense and reproducible surface enhanced Raman scattering spectra recorded in situ from one monolayer of cardiolipin, using 0.5 mol % of 10N nonyl acridine orange or 5 mol % of acridine in the film, and demonstrates the possibility of estimating the pH at the metal/phospholipidic film interface.

Study of Langmuir-Blodgett phospholipidic films deposited on surface enhanced Raman scattering active gold nanoparticle monolayers.

Surface enhanced Raman scattering (SERS) was used to study phospholipid monolayers transferred by the Langmuir-Blodgett (LB) technique to SERS active substrates. These substrates, which were constituted of gold colloidal nanoparticles bound to polysilane films grafted onto glass plates, showed a uniform and homogeneous layer with strong interacting particles as revealed from UV-visible extinction spectra and atomic force microscopy images. Laser excitation at 632.8 nm within the red part of the localized surface plasmon resonance leads to intense and reproducible SERS spectra of trans-1,2-bis(4-pyridyl)ethylene (BPE). From SERS measurements at different pHs it was possible to determine the apparent pK(a) of BPE adsorbed on gold-coated silanized substrates in the absence and presence of one LB monomolecular layer of phospholipids. These SERS titrations allowed the estimation of the pH at the metal-LB film interface.

Absence in amphotericin B-spiked human plasma of the free monomeric drug, as detected by SERS.

Using surface enhanced Raman spectroscopy (SERS) which enables us to specifically detect traces of monomeric amphotericin B (AmB), we were able to show that in a 10(-5) M AmB suspension, the concentration of free drug was below 10(-8) M in the presence of low density lipoproteins (LDL) or plasma. The affinity constant of AmB for LDL determined from electronic absorption data, was found to be 4 x 10(6) M(-1). Therefore, since AmB appears to be in the majority bound to lipoproteins under in vivo conditions, its toxicity should not result from the induction of host-cell transmembrane permeability but rather from the internalization of the AmB-LDL complex.

Microspectrofluorometry of the protonation state of ellipticine, an antitumor alkaloid, in single cells.

The protonation state and intracellular distribution of ellipticine were investigated in single human mammary T47D cells by confocal laser microspectrofluorimetry. In the cell nucleus, only the protonated form of ellipticine was detected as a direct consequence of its apparent pK increase upon DNA binding. Both protonated and neutral forms were present in the aqueous cytoplasm, where the pH is close to the drug pK. When cells were incubated in high concentrations of K+, a condition that depolarizes the plasma membrane potential, ellipticine cellular accumulation was reduced. In the cytoplasm, ellipticine was mainly bound to mitochondria, and its protonation equilibrium was shifted toward the neutral form. The fluorescence spectrum of ellipticine bound to mitochondria was insensitive to valinomycin, whereas it was markedly shifted toward the protonated form after carbonyl cyanide p-trifluoromethoxy-phenylhydrazone or nigericin addition. Similar studies with ellipticine bound to isolated mitochondria suggest that it behaves as a fluorescent probe of mitochondrial pH in both isolated mitochondria and single living cells.

Thermodynamics of drug-DNA interactions: entropy-driven intercalation and enthalpy-driven outside binding in the ellipticine series.

Viscosimetric and kinetic results allow one to characterize three modes of DNA binding in the ellipticine series: (1) Ellipticine and its 9 methoxy derivative, which present maximal DNA lengthening properties and bind DNA through a single step mechanism, can be considered as pure intercalators. (2) Ellipticinium derivatives and short-chain substituted oxazolopyridocarbazoles, which present intermediate DNA lengthening properties, bind DNA through a two-step mechanism, one being intercalation. (3) Long-chain substituted oxazolopyridocarbazole derivatives, which display the smallest DNA lengthening properties, bind DNA through a single-step mechanism, probably resulting from an outside binding mode. The viscosimetric and kinetic results are compared with the thermodynamic results obtained from the temperature dependence of the binding constants. It appears that drugs binding on the outside of the DNA double helix tend to have large enthalpy and small entropy contributions, whereas pure intercalating drugs have contributions from both enthalpy and entropy, with entropy dominating by about 2:1. Drugs showing two binding modes exhibit a continuum between the aforementioned extremes, with no breaks in behavior. From this comparison, a correlation between thermodynamic data and DNA binding modes is proposed. Possible molecular implications of both enthalpy and entropy to DNA binding free energy are discussed.

Acid-base properties of ellipticine bound to DNA, micelles and liposomes.

We have determined the acid-base properties of the alkaloid ellipticine, bound to DNA and to micelles and liposomes, taken as models for membranes, in the prospect of characterizing the actual structure of the bound ligand, this being relevant to the mode of action of the drug. The acid-base properties of ellipticine bound to sonicated calf thymus DNA and SDS micelles are similar as regards their pK values and their dependence on NaCl concentrations. This observation is satisfactorily understood in terms of sodium ion condensation around the negative phosphate and sulphate groups. The slope of pK vs log(Na+) is -1, a value predicted by Friedman theory. The pK of ellipticine bound to cationic (CTAB, DDTAB) or to neutral (Triton X100) micelles and to neutral liposomes (PC) is significantly lower than water (7.4), and, in contrast to the situation in DNA and SDS micelles, does not vary with addition of NaCl. Interestingly, this result is good evidence for ellipticine having a specific pK when bound to a hydrophobic structure. This view is likely to hold for ellipticine bound to DNA.

Kinetic and thermodynamic studies on drug-DNA interactions in the ellipticine series.

The temperature-jump (T-jump) method has been used to investigate the binding mechanism to calf-thymus DNA of ellipticine and some of its derivatives. The results show that the plant alkaloid, ellipticine, interacts with DNA at a unique intercalation site whereas most of its synthetic derivatives, such as ellipticinium, 9-hydroxy-ellipticinium and related alkyl-oxazolopyridocarbazoles recognize two distinct DNA sites. Parallel analysis of kinetic data and DNA lengthening abilities of these derivatives suggests that only one of these two DNA sites is an intercalation site. Owing to the determination of the genuine number of drug-DNA complexes (inferred from T-jump experiments) and with the results of thermodynamic investigations (Van't Hoff plots), further characterization of the molecular interactions involved in the binding process was proposed. Thus, the formation of the unique intercalation complex of ellipticine was found to be entropy driven whereas binding of drugs which recognize the second class of binding sites was essentially enthalpy driven. These different thermodynamic behaviors suggest that intercalation essentially results from hydrophobic solvent structure effects in contrast to the second binding mode which principally arises from hydrogen bonding interactions through DNA grooves.

The G.C base-pair preference of 2-N-methyl 9-hydroxyellipticinium.

Among the DNA-intercalating drugs in the ellipticinium series, 9-hydroxy derivatives elicit the highest antitumoral properties. In water these drugs display a very low fluorescence quantum yield. Replacement of H2O by D2O partially restores the fluorescence of the ellipticinium chromophore. The possibility that such a proton-exchange mechanism could be involved in a base-recognizing process at the DNA level (and therefore be responsible for some base preference) was examined by direct fluorescence titration in deuterated buffer and DNA/drug fluorescence energy transfer. These experimental approaches provide mutually consistent results showing that the 9-hydroxylated drug recognizes specific DNA sites that are not recognized by the non-hydroxylated drug. When compared to 2-N-methyl ellipticinium, the 2-N-methyl 9-hydroxyellipticinium presents: (1) higher binding constants for each DNA studied; (2) a base dependence of the fluorescence properties of the bound form (fluorescence increment upon DNA binding varying over 5-11); (3) a base dependence of its DNA affinity constants (1.1-3.3 x 10(6) M-1) and of its site size (exclusion parameters varying over 3.0-4.4); (4) a base dependence of its energy transfer from DNA bases. Analysis of the binding data suggests that the 9-hydroxyl group of 2-N-methyl ellipticinium is responsible for a G.C base-pair preference, the preferred binding site being a doublet sequence of two adjacent G.C which could be flanked either by a additional G.C base pair or by an A.T base pair.

Dynamics of drug-DNA interactions: a comparative temperature jump study of ellipticinium and 9-hydroxy ellipticinium.

The temperature-jump method has been used to compare the binding of 2-N methyl ellipticinium (NME) and 2-N methyl 9 hydroxy ellipticinium (NMHE) to three natural DNA's of different AT/GC composition. The relaxation signals, analyzed by the Padé-Laplace method, are characterized by two distinct relaxation times, tau 1 and tau 2, respectively in the 1-4 ms and 20-80 ms range. In the case of the NMHE/DNA interaction, the slower relaxation time tau 2 depends on the DNA composition, as follows: tau 2 (Micrococcus lysodeikticus) greater than tau 2 (Calf thymus) greater than tau 2 (Clostridium perfringens). Contrary to NMHE, NME which does not possess an OH group at the C-9 position, shows no relaxation time dependence upon DNA base composition. The observation of two relaxation times indicates that the binding equilibria are associated with at least two distinct drug/DNA complexes (probably arising from two distinct DNA binding sites). Three kinetic models, involving the formation of a weak intermediate ionic complex, are given to explain the binding reaction between these cationic drugs and the DNA. They allow the determination of the four rate constants associated with the two binding steps and lead to equilibrium association constants in agreement with those obtained from spectroscopic studies. The validity of the models is discussed and it is shown that the best kinetic scheme, for either NMHE or NME, could be that in which the ionic step is not a prerequiste to intercalation. The kinetic results show that the residence time of 9 hydroxy ellipticinium is markedly increased in GC rich DNA's and this could be related to the higher in vitro and in vivo cytotoxic properties of 9 hydroxy substituted ellipticines.