posted on 2021-10-25, 23:46authored byKarleena Rybacki, Stacy A. Love, Bailey Blessing, Abneris Morales, Emily McDermott, Kaylyn Cai, Xiao Hu, David Salas-de la Cruz
In this study, the
structural, thermal, and morphological properties
of biocomposite films composed of wool keratin mixed with cellulose
and regenerated with ionic liquids and various coagulation agents
were characterized and explored. These blended films exhibit different
physical and thermal properties based on the polymer ratio and coagulation
agent type in the fabrication process. Thus, understanding their structure
and molecular interaction will enable an understanding of how the
crystallinity of cellulose can be modified in order to understand
the formation of protein secondary structures. The thermal, morphological,
and physiochemical properties of the biocomposites were investigated
by Fourier transform infrared (FTIR) spectroscopy, scanning electron
microscopy (SEM), thermal gravimetric analysis (TGA), differential
scanning calorimetry (DSC), and X-ray scattering. Analysis of the
results suggests that both the wool keratin and the cellulose structures
can be manipulated during dissolution and regeneration. Specifically,
the β-sheet content in wool keratin increases with the increase
of the ethanol solution concentration during the coagulation process;
likewise, the cellulose crystallinity increases with the increase
of the hydrogen peroxide concentration via coagulation. These findings
suggest that the different molecular interactions in a biocomposite
can be tuned systematically. This can lead to developments in biomaterial
research including advances in natural based electrolyte batteries,
as well as implantable bionics for medical research.