APS March Meeting 2017
Volume 62, Number 4
Monday–Friday, March 13–17, 2017;
New Orleans, Louisiana
Session B21: Biopolymer Physics
11:15 AM–2:15 PM,
Monday, March 13, 2017
Room: 281-282
Sponsoring
Units:
DPOLY DBIO
Chair: Brad Olsen, MIT
Abstract ID: BAPS.2017.MAR.B21.4
Abstract: B21.00004 : Structural Interplay - Tuning Mechanics in Peptide-Polyurea Hybrids*
1:03 PM–1:39 PM
Preview Abstract
Abstract
Author:
LaShanda Korley
(Case Western Reserve University)
Utilizing cues from natural materials, we have been inspired to explore the
hierarchical arrangement critical to energy absorption and mechanical
enhancement in synthetic systems. Of particular interest is the soft domain
ordering proposed as a contributing element to the observed toughness in
spider silk. Multiblock copolymers, are ideal and dynamic systems in which
to explore this approach via variations in secondary structure of nature's
building blocks -- peptides. We have designed a new class of polyurea
hybrids that incorporate peptidic copolymers as the soft segment. The impact
of hierarchical ordering on the thermal, mechanical, and morphological
behavior of these bio-inspired polyurethanes with a siloxane-based, peptide
soft segment was investigated. These peptide-polyurethane/urea hybrids were
microphase segregated, and the beta-sheet secondary structure of the soft
segment was preserved during polymerization and film casting. Toughness
enhancement at low strains was achieved, but the overall extensibility of
the peptide-incorporated systems was reduced due to the unique hard domain
organization. To decouple the secondary structure influence in the
siloxane-peptide soft segment from mechanics dominated by the hard domain,
we also developed non-chain extended peptide-polyurea hybrids in which the
secondary structure (beta sheet vs. alpha helix) was tuned via choice of
peptide and peptide length. It was shown that this structural approach
allowed tailoring of extensibility, toughness, and modulus. The
sheet-dominant hybrid materials were typically tougher and more elastic due
to intermolecular H-bonding facilitating load distribution, while the
helical-prevalent systems generally exhibited higher stiffness. Recently, we
have explored the impact of a molecular design strategy that overlays a
covalent and physically crosslinked architecture in these peptide-polyurea
hybrids, demonstrating that physical constraints in the network hybrids
influences peptide hydrogen bonding and morphology. These structural
features correlated well with systematic changes in modulus, extensibility,
and hysteresis. Complementary to this effort is the design of PEG-based
peptide-polyurea hybrids with tunable and responsive as structural and
injectable hydrogels.
*The authors acknowledge funding support from the National Science Foundation (CAREER DMR-0953236).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2017.MAR.B21.4