We study the behavior of multicomponent giant unilamellar
vesicles
(GUVs) in the presence of AzoTAB, a photosensitive surfactant. GUVs
are made of an equimolar ratio of dioleoylphosphatidylcholine (DOPC)
and dipalmitoylphosphatidylcholine (DPPC) and various amounts of cholesterol
(Chol), where the lipid membrane shows a phase separation into a DPPC-rich
liquid-ordered (Lo) phase and a DOPC-rich liquid-disordered
(Ld) phase. We find that UV illumination at 365 nm for
1 s induces the bursting of a significant fraction of the GUV population.
The percentage of UV-induced disrupted vesicles, called bursting rate
(Yburst), increases with an increase in
[AzoTAB] and depends on [Chol] in a non-monotonous manner. Yburst decreases when [Chol] increases from 0
to 10 mol % and then increases with a further increase in [Chol],
which can be correlated with the phase composition of the membrane.
We show that Yburst increases with the
appearance of solid domains ([Chol] = 0) or with an increase in area
fraction of Lo phase (with increasing [Chol] ≥ 10
mol %). Under our conditions (UV illumination at 365 nm for 1 s),
maximal bursting efficiency (Yburst =
53%) is obtained for [AzoTAB] = 1 mM and [Chol] = 40 mol %. Finally,
by restricting the illumination area, we demonstrate the first selective
UV-induced bursting of individual target GUVs. These results show
a new method to probe biomembrane mechanical properties using light
as well as pave the way for novel strategies of light-induced drug
delivery.
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