PEER-REVIEWED PUBLICATION

2025

Entropy-driven denaturation enables sustainable protein regeneration through rapid gel-solid transition

A tensile test divider icon

Wang Y, Liu J, et al.

Nature Communications

Harvard University, NTT Research, BirlaInstitute of Technology andScience-Pilani

RESEARCH SUMMARY
This study introduces an entropy-driven protein denaturation mechanism using concentrated inorganic salts to regenerate keratin into mechanically tunable, recyclable biomaterials. The authors demonstrate that lithium bromide disrupts the water network structure rather than directly interacting with proteins, enabling spontaneous gel formation and rapid gel–solid phase transition upon hydration. Regenerated keratin materials exhibited tunable mechanical properties, high stretchability, shape-memory behavior, and compatibility with multiple fabrication methods including molding, film casting, fiber spinning, and 3D printing, highlighting a sustainable pathway for upcycling protein-rich waste into functional biomaterials.
CellScale hexagons, without text

CELLSCALE INSTRUMENT USED

BioTester

Biaxial tensile mechanical properties of regenerated keratin films were characterized using a CellScale BioTester equipped with 2.5 N load cells. Keratin specimens were subjected to cyclic biaxial stretching at a strain rate of 5% per second up to 50% strain for 10 cycles, as well as monotonic loading to failure to determine yield strain and elastic modulus. The BioTester enabled precise, low-force biaxial loading and accurate strain-controlled testing, allowing quantitative comparison of reduced and oxidized keratin states and direct assessment of crosslinking-dependent mechanical tunability and shape-memory behavior.
AUTHORS

Yichong Wang, Junlang Liu, Michael M. Peters, Ryoma Ishii, Dianzhuo Wang, Sourav Chowdhury, Kevin Kit Parker, Eugene I. Shakhnovich.

PUBLICATION DETAILS
JOURNAL

Nature Communications

YEAR

2025

INSTITUTIONS

Harvard University, NTT Research, BirlaInstitute of Technology andScience-Pilani

COUNTRIES

India, United States

INSTRUMENT USED

BioTester

TESTING METHODS

Biaxial TestingTensile TestingViscoelastic & Time-Dependent Testing

RESEARCH APPLICATIONS

ECM & Decellularized Matrix MechanicsHydrogel Mechanical TestingInjectable & Regenerative BiomaterialsMechanotransductionPolymers and Elastomers Testing

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Product of Interest:
CellScale hexagon shapes