posted on 2022-08-15, 14:08authored byLawrence
W. Honaker, Chang Chen, Floris M.H. Dautzenberg, Sylvia Brugman, Siddharth Deshpande
Biosensing using liquid crystals has a tremendous potential
by
coupling the high degree of sensitivity of their alignment to their
surroundings with clear optical feedback. Many existing set-ups use
birefringence of nematic liquid crystals, which severely limits straightforward
and frugal implementation into a sensing platform due to the sophisticated
optical set-ups required. In this work, we instead utilize chiral
nematic liquid crystal microdroplets, which show strongly reflected
structural color, as sensing platforms for surface active agents.
We systematically quantify the optical response of closely related
biological amphiphiles and find unique optical signatures for each
species. We detect signatures across a wide range of concentrations
(from micromolar to millimolar), with fast response times (from seconds
to minutes). The striking optical response is a function of the adsorption
of surfactants in a nonhomogeneous manner and the topology of the
chiral nematic liquid crystal orientation at the interface requiring
a scattering, multidomain structure. We show that the surface interactions,
in particular, the surface packing density, to be a function of both
headgroup and tail and thus unique to each surfactant species. We
show lab-on-a-chip capability of our method by drying droplets in
high-density two-dimensional arrays and simply hydrating the chip
to detect dissolved analytes. Finally, we show proof-of-principle in vivo biosensing in the healthy as well as inflamed intestinal
tracts of live zebrafish larvae, demonstrating CLC droplets show a
clear optical response specifically when exposed to the gut environment
rich in amphiphiles. Our unique approach shows clear potential in
developing on-site detection platforms and detecting biological amphiphiles
in living organisms.