posted on 2018-03-28, 00:00authored byFrancesco Tantussi, Gabriele C. Messina, Rosario Capozza, Michele Dipalo, Laura Lovato, Francesco De Angelis
The
possibility of investigating small amounts of molecules, moieties,
or nano-objects dispersed in solution constitutes a central step for
various application areas in which high sensitivity is necessary.
Here, we show that the rapid expansion of a water bubble can act as
a fast-moving net for molecules or nano-objects, collecting the floating
objects in the surrounding medium in a range up to 100 μm. Thanks
to an engineered 3D patterning of the substrate, the collapse of the
bubble could be guided toward a designed area of the surface with
micrometric precision. Thus, a locally confined high density of particles
is obtained, ready for evaluation by most optical/spectroscopic detection
schemes. One of the main relevant strengths of the long-range capture
and delivery method is the ability to increase, by a few orders of
magnitude, the local density of particles with no changes in their
physiological environment. The bubble is generated by an ultrafast
IR laser pulse train focused on a resonant plasmonic antenna; due
to the excitation process, the technique is trustworthy and applicable
to biological samples. We have tested the reliabilities of the process
by concentrating highly dispersed fluorescence molecules and fluorescent
beads. Lastly, as an ultimate test, we have applied the bubble clustering
method on nanosized exosome vesicles dispersed in water; due to the
clustering effect, we were able to effectively perform Raman spectroscopy
on specimens that were otherwise extremely difficult to measure.