Paving the way for synthetic intrinsically disordered polymers for soft robotics
Künye
Coskuner-Weber, O., Yüce-Erarslan, E., Uversky, V. N. (2023). Paving the Way for Synthetic Intrinsically Disordered Polymers for Soft Robotics. Polymers, 15, 763.Özet
Nature is full of examples of processes that, through evolution, have been perfected over
the ages to effectively use matter and sustain life. Here, we present our strategies for designing intrinsically disordered smart polymers for soft robotics applications that are bio-inspired by intrinsically
disordered proteins. Bio-inspired intrinsically disordered smart and soft polymers designed using
our deep understanding of intrinsically disordered proteins have the potential to open new avenues
in soft robotics. Together with other desirable traits, such as robustness, dynamic self-organization,
and self-healing abilities, these systems possess ideal characteristics that human-made formations
strive for but often fail to achieve. Our main aim is to develop materials for soft robotics applications
bio-inspired by intrinsically disordered proteins to address what we see as the largest current barriers
in the practical deployment of future soft robotics in various areas, including defense. Much of the
current literature has focused on the de novo synthesis of tailor-made polymers to perform specific
functions. With bio-inspired polymers, the complexity of protein folding mechanisms has limited
the ability of researchers to reliably engineer specific structures. Unlike existing studies, our work is
focused on utilizing the high flexibility of intrinsically disordered proteins and their self-organization
characteristics using synthetic quasi-foldamers.