This review focuses on recent developments in hybrid and nanostructured substrates for SERS (surface-enhanced Raman scattering) studies. Thus substrates composed of at least two distinct types of materials, in which one is a SERS active metal, are considered here aiming at their use as platforms for chemical detection in a variety of contexts. Fundamental aspects related to the SERS effect and plasmonic behaviour of nanometals are briefly introduced. The materials described include polymer nanocomposites containing metal nanoparticles and coupled inorganic nanophases. Chemical approaches to tailor the morphological features of these substrates in order to get high SERS activity are reviewed. Finally, some perspectives for practical applications in the context of chemical detection of analytes using such hybrid platforms are presented.
Nanocomposites containing Ag nanoparticles (average diameter $11 nm) dispersed in poly(tertbutylacrylate) were prepared by in situ polymerization via miniemulsions and constitute active and versatile SERS substrates. The use of this synthetic strategy enables the dual use of the final composites as SERS substrates, both as aqueous emulsions and as cast films, shown here by several measurements using thiosalicylic acid as the testing analyte. The main advantage of these types of materials is related to the potential to scale up and the widespread use of handy substrates, using technology already available. This requires homogeneous composite substrates with SERS activity and this was demonstrated here by means of confocal Raman microscopy. Finally, a series of experiments were carried out on Ag/polymer nanocomposites submitted to temperature variations below and above the polymer glass transition temperature (T g ) in order to conclude about the effect of temperature processing conditions on the composites' SERS activity.
Magnetic hydrogel kappa-carrageenan nanospheres were successfully prepared via water-in-oil (w/o) microemulsions combined with thermally induced gelation of the polysaccharide. The size of the nanospheres (an average diameter of about 50 and 75 nm) was modulated by varying the concentration of surfactant. The nanospheres contained superparamagnetic magnetite nanoparticles (average diameter 8 nm), previously prepared by co-precipitation within the biopolymer. Carboxyl groups, at a concentration of about 4 mmol g(-1), were successfully grafted at the surface of these magnetic nanospheres via carboxymethylation of the kappa-carrageenan. The carboxylated nanospheres were shown to be thermo-sensitive in the 37-45 degrees C temperature range, indicating their potential as thermally controlled delivery systems for drugs and/or magnetic particles at physiological temperatures. Finally, preliminary results have been obtained for IgG antibody conjugation of the carboxylated nanospheres and the potential of these systems for bio-applications is discussed.
Textile fibres containing Ag nanoparticles have been widely explored for a number of antimicrobial fabrics. Moreover, it is well-known that textile dyeing is a critical stage in the manufacture thereof. This research shows that surface enhanced Raman scattering (SERS) and Raman imaging can be used with advantage in the monitoring of this process. Using Ag containing linen fibres stained with methylene blue (MB), it was possible to map the local distribution of the MB dye in the fibres by Raman imaging. MB was selected as the SERS molecular probe and as a model dye. Composites of linen fibres and Ag nanoparticles were prepared by distinct methods and used as SERS substrates in order to evaluate the effect of the preparative method on the Raman images. Our results demonstrate that by using Raman imaging associated to the presence of Ag nanoparticles, it is possible to distinguish the local distribution of the dye on the textile surface. This investigation allows to foreseeing the use of this technique in terms of quality control of Ag containing fabrics, which is a market in great expansion.
Telomerase inhibition
has been an important strategy in cancer
therapies, but for which effective drugs are still required. Here,
noncovalent hybrid nanoplatforms containing the tetracationic 5,10,15,20-tetrakis(1-methyl-pyridinium-4-yl)porphyrin
(TMPyP) and graphene oxide (GO) were prepared for promoting telomerase
inhibition through the selective detection and stabilization of DNA
guanine-quadruplex (G-Q) structures. Upon binding TMPyP to the GO
sheets, the typical absorption bands of porphyrin have been red-shifted
and the fluorescence emission was quenched. Raman mapping was used
for the first time to provide new insights into the role of the electrostatic
and π–π stacking interactions in the formation
of such hybrids. The selective recovery of fluorescence observed during
the titration of TMPyP@GO with G-Q, resembles a selective “turn-off–on”
fluorescence sensor for the detection of G-Q, paving the way for a
new class of antitumor drugs.
A series
of nanocomposites based on polyamide (NL16, PA) filter
membranes containing metal nanoparticles (NPs) have been prepared
by filtration under reduced pressure of the metal colloids. The ensuing
materials were then investigated as substrates for surface-enhanced
Raman scattering (SERS) imaging studies envisaging the spectroscopic
detection of vestigial organic pollutants dissolved in contaminated
water. The organic dye crystal violet (CV) was used here as a model
pollutant because it is a hazardous compound present in certain effluent
waters. Moreover this compound is well-known for its strong SERS activity,
which is clearly advantageous in the context of material development
for SERS. Indeed, several preparative strategies were employed to
prepare PA-based composites, and the impact on SERS detection was
investigated. These include the use of chemical and morphological
distinct plasmonic NPs (Ag, Au), a variable metal load and changing
the order of addition of the analytical specimens. These studies demonstrate
that the parameters employed in the fabrication of the SERS substrates
have a strong impact on the Raman signal enhancement. The use of Raman
imaging during the fabrication process allows establishing improvements
that translate to better performances of the substrates in the analyte
detection. The results have been interpreted by considering an integrated
set of operational parameters that include the affinity of CV molecules
to the substrate, amount and dispersion of NPs in the PA membranes,
and the detection method. Noteworthy the use of SERS analysis
assisted with Raman imaging allowed achieving a detection limit for
CV as low as 100 aM in ultrapure water and 10 fM in real samples.
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