posted on 2020-07-09, 11:34authored byLuanda Lins, Florence Wianny, Colette Dehay, Jacques Jestin, Watson Loh
Improving
cell-material interactions of nonadhesive scaffolds is
crucial for the success of biomaterials in tissue engineering. Due
to their high surface area and open pore structure, sponges are widely
reported as absorbent materials for biomedical engineering. The biocompatibility
and biodegradability of polysaccharide sponges, coupled with the chemical
functionalities of supramolecular dimers, make them promising combinations
for the development of adhesive scaffolds. Here, a supramolecular
tactic based on (UPy)-modified polysaccharide associated with three-dimensional
structure of sponges was developed to reach enhanced cellular adhesion.
For this purpose, three approaches were examined individually in order
to accomplish this goal. In the first approach, the backbone polysaccharides
with noncell adhesive properties were modified via a modular tactic
using UPy-dimers. Hereupon, the physical–chemical characterizations
of the supramolecular sponges were performed, showing that the presence
of supramolecular dimers improved their mechanical properties and
induced different architectures. In addition, small-angle neutron
scattering (SANS) measurements and rheology experiments revealed that
the UPy-dimers into agarose backbone are able to reorganize in thinning
aggregates. It is also demonstrated that the resulted UPy-agarose
(AGA-UPy) motifs in surfaces can promote cell adhesion. Finally, the
last approach showed the great potential for use of this novel material
in bioadhesive scaffolds indicating that neural stem cells show a
spreading bias in soft materials and that cell adhesion was enhanced
for all UPy-modified sponges compared to the reference, i.e. unmodified
sponges. Therefore, by functionalizing sponge surfaces with UPy-dimers,
an adhesive supramolecular scaffold is built which opens the opportunity
its use neural tissues regeneration.