Nature of Saccharide-Induced F127 Micellar Dehydration:
An Insight with FDAPT (2-Formyl-5-(4′‑N,N‑dimethylaminophenyl)thiophene), a Multiparametric
Fluorescent Probe
FDAPT
(2-formyl-5-(4′-N,N-dimethylaminophenyl)thiophene)
is an efficient environment-sensitive
fluorescent probe, which senses the alteration of its microenvironment
with six different fluorescent parameters, namely, emission intensity,
wavelength, fluorescence anisotropy, and corresponding three time-dependent
parameters fluorescence lifetime, time-resolved emission spectrum,
and anisotropy decay. In the present work, the nature of saccharide-induced
dehydration of a F127 polymeric micelle is investigated in detail
with FDAPT emission. Using a multiparametric fluorescence approach,
it is observed that the saccharide molecules not only decrease the
critical micellization temperature of the F127 solution but also strongly
alter the physical properties inside the micellar structures. The
local polarity and fluidity significantly decrease in the saccharide-induced
micelle as compared to the normal F127 micelle. The probe solvation
dynamics study reveals that the water content in the core as well
as corona domain diminishes significantly in the saccharide-induced
micelle as compared to the normal micelle. More precisely, dehydration
occurs more in the core region than in the corona region. Also, the
saccharide-induced dehydration alters the relative size of the core
and corona regions. The extent of dehydration varies with different
saccharide molecules. It is also found that the dehydration efficiency
order is trisaccharide (raffinose) > disaccharide (sucrose) >
monosaccharide
(glucose and fructose).