posted on 2012-04-10, 00:00authored byRaj Kumar Roy, E. Bhoje Gowd, S. Ramakrishnan
We describe a novel class of periodically grafted amphiphilic
copolymers
(PGACs) that could serve as nonionic functional mimics of ionenes,
the primary difference being that the periodically occurring charged
units along the backbone of ionenes are replaced by hydrophilic oligoethylene
glycol segments. The synthesis and properties of this new class of
segmented polymers that carry a hydrophobic alkylene polyester backone
with periodically placed hydrophilic oligo(oxyethylene) pendant units
are presented. When the length of the intervening alkylene segment
is adequately long, 22-carbons in this case, and the pendant unit
is a hexaethylene glycol monomethyl ether (HEG) segment, the polymer
chain appears to adopt a folded zigzag conformation, reminiscent of
the accordion-type structure formed by cationic ionenes. This transformation
is driven by the intrinsic immiscibility of the alkylene and HEG segments
and is reinforced by the strong tendency for long chain alkylene segments
to crystallize in a paraffinic lattice. Evidence of the formation
of such structures comes from the AFM images, which reveal the formation
of remarkably flat pancake-like aggregates that are formed by the
lateral aggregation of individually collapsed polymer chains; importantly,
the heights of these structures match well with the lamellar layer-spacing
obtained from SAXS studies of bulk samples. DSC studies further confirm
the crystallization of the intervening alkylene segments, especially
when they are long (C22), suggesting the formation of the folded zigzag
structures. In a suitably designed PGAC that carries diacetylene units
symmetrically placed within the alkylene segment, attempts were made
to cross-polymerize the diacetylene units and generate PEGylated nanoparticles.
However, these attempts were unsuccessful demonstrating the very stringent
geometric requirements for the topotactic polymerization of diacetylenes.