posted on 2020-11-15, 21:29authored byHarsimran Kaur, Rashmi Jain, Sangita Roy
We
demonstrate the formation of diverse peptide nanostructures,
which are “out of equilibrium” based on a single dipeptide
gelator. These structures represent the differential energy states
of the free energy landscape, which are accessed by differential energy
inputs provided by variable self-assembly pathways, that is, heat–cool
method or ultrasonication. A higher energy input by the heat–cool
method created a thermodynamically favored long entangled nanofibrillar
network, while twisted ribbonlike structures were prevalent by ultrasonication.
Interestingly, the nanofibrillar network representing the global thermodynamic
minima could be accessed by simply melting the kinetically trapped
structures as indicated by the thermoreversibility studies. The impact
on the material strength was remarkable; gels with an order of magnitude
difference in mechanical properties could be fabricated by simply
modulating the self-assembly pathways. Interestingly, the thermodynamically
favored nanofibrous network promoted cellular adhesion and survival,
while a significant number of cells fail to adhere on the kinetically
trapped twisted ribbons. Thus, nonequilibrium nanostructures open
up new directions to develop advanced functional materials with diverse
functions.