Study by Raman spectromicroscopy of the effect of tensile deformation on the molecular structure of Bombyx mori silk

The effect of mechanical deformation on the polarized Raman spectra of a silk monofilament of the silkworm Bombyx mori has been studied in order to detect tensile stress-induced changes of the fibroin conformation and reorientation up to the breaking point. For this study, a motorized mechanical stretcher has been specifically designed to fit under the Raman microscope, thus allowing the simultaneous recording of the stress, strain and polarized Raman spectra. Due to its twin drive screw design, this stretcher allows to stretch the silk fiber symmetrically and thus to probe the same area of the fiber during the entire elongation procedure. The results obtained have allowed to clarify the assignment of some vibrational bands of silk. They also show that the intensity of some Raman bands is affected by tensile deformation. In particular, the amide III/amide I intensity ratio decreases as the strain increases and the variation is proportional to the stress applied on the fiber. These variations in intensity suggest that the alignment of the protein chains decreases with strain which might be due to the reorganization of the amorphous phase. The Raman spectra also show that several bands shift toward low wavenumbers as the strain applied increases indicating that the force constant and/or dihedral angles of the peptide bonds, in particular those involved in the β-sheets, are affected by drawing. Therefore, a local stress is directly applied on the β-sheets and the wavenumber shift observed is proportional to the stress applied on the fiber.