A versatile method for decorating magnetic nanobeads (being composite materials from polymers and superparamagnetic nanoparticles) with silver nanoparticles of 3-6 nm size is presented. Control over the silver nanoparticle coverage at the nanobead surface is achieved by changing the reaction parameters. Moreover, the silver-decorated magnetic nanobeads (Ag-MNBs) are studied with respect to their in vitro cytotoxicity on two distinct tumour cell lineages under different parameters, i.e., dose, incubation time, magnetic field applied during the culturing, silver ion leakage, and colloidal stability. It is found that enhanced magnetically mediated cellular uptake and silver ion leakage from the Ag-MNBs surface are the main factors which affect the toxicity of the Ag-MNBs and allow the half-maximal inhibitory dose of silver to be reduced to only 32 μg mL(-1) . Furthermore, a synergic cytotoxicity induced by photo-activation of silver nanoparticles was also found.
Single-cell force spectroscopy is an emerging technique in the field of biomedicine because it has proved to be a unique tool to obtain mechanical and functional information on living cells, with force resolution up to single molecular bonds. This technique was applied to the study of the cytoskeleton organisation of neuroblastoma cells, a life-threatening cancer typically developing during childhood, and the results were interpreted on the basis of reference experiments on human embryonic kidney cell line. An intimate connection emerges among cellular state, cytoskeleton organisation and experimental outcome that can be potentially exploited towards a new method for cancer stadiation of neuroblastoma cells.
We
report the fabrication of aqueous multimodal imaging nanocomposites
based on superparamagnetic nanoparticles (MNPs) and two different
sizes of photoluminescent upconverting nanoparticles (UCNPs). The
controlled and simultaneous incorporation of both types of nanoparticles
(NPs) was obtained by controlling the solvent composition and the
addition rate of the destabilizing solvent. The magnetic properties
of the MNPs remained unaltered after their encapsulation into the
polymeric beads as shown by the T2 relaxivity measurements. The UCNPs
maintain photoluminescent properties even when embedded with the MNPs
into the polymer bead. Moreover, the light emitted by the magnetic
and upconverting nanobeads (MUCNBs) under NIR excitation (λexc = 980 nm) was clearly observed through different thicknesses
of agarose gel or through a mouse skin layer. The comparison with
magnetic and luminescent nanobeads based on red-emitting quantum dots
(QDs) demonstrated that while the QD-based beads show significant
autofluorescence background from the skin, the signal obtained by
the MUCNBs allows a decrease in this background. In summary, these
results indicate that MUCNBs are good magnetic and optical probes
for in vivo multimodal imaging sensors.
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