Solvent modulation in peptide sub-microfibers obtained by solution blow spinning

Peptides possess high chemical diversity at the amino acid sequence level, which further translates into versatile functions. Peptides with self-assembling properties can be processed into diverse formats giving rise to bio-based materials. Peptide-based spun fibers are an interesting format due to high surface-area and versatility, though the field is still in its infancy due to the challenges in applying the synthetic polymer spinning processes to protein fibers to peptides. In this work we show the use of solution blow-spinning to produce peptide fibers. Peptide fiber formation was assisted by the polymer poly (vinyl pyrrolidone) (PVP) in two solvent conditions. Peptide miscibility and further self-assembling propensity in the solvents played a major role in fiber formation. When employing acetic acid as solvent, peptide fibers (0.5 mu m) are formed around PVP fibers (0.75 mu m), whereas in isopropanol only one type of fibers are formed, consisting of mixed peptide and PVP (1 mu m). This report highlights solvent modulation as a mean to obtain different peptide submicrofibers via a single injection nozzle in solution blow spinning. We anticipate this strategy to be applied to other small peptides with self-assembly propensity to obtain multi-functional proteinaceous fibers.

Automated summary

Peptides possess high chemical diversity and versatile functions. Peptide-based spun fibers are of interest due to their high surface area and versatility, but applying synthetic polymer spinning processes to peptide fibers poses challenges. This study demonstrates the use of solution blow-spinning to produce peptide fibers and highlights the role of solvent modulation in obtaining different peptide submicrofibers.