Anisotropy analysis of bamboo and tooth using 4-angle polarization micro-spectroscopy
Abstract
To investigate the anisotropic properties of biomaterials, two distinct classes are considered: polymer-based (e.g., cellulose in plants) and crystalline-based (e.g., enamel in teeth), each demonstrating distinct structural and functional characteristics. Four-angle polarization (4-pol.) spectral mapping of sub-1 μm bamboo slices was carried out in the mid-IR spectral range (2.5-20 μm) to reveal the 3D organization of the chemical bonding of cellulose using the key characteristic absorption bands associated with C-O-C and C-N vibrational modes. The longitudinal and transverse microtome slices revealed a switch between the presence and absence of dichroism in parenchyma cell walls and vascular bundles. The cell wall showed continuous alignment of the C-O-C stretching vibrational mode (8.6 μm/1163 cm-1) down to the pixel resolution of ~ 4 μm (the step size in imaging) in the transverse slice; the cell wall thickness is ~ 1 μm. Thin microtomed slices of a tooth were measured in transmission and reflection modes. The single-point reflection measurements, performed using two perpendicular orientations, revealed orientational anisotropy in the enamel, which was absent in the dentin region. High sub-diffraction limited lateral resolution was numerically validated using a simplified-model of a Gaussian beam reading out material pixels with a defined orientation of absorption. It is shown that the orientation of small ~ λ/10 ~ 1 μm objects can be revealed using a focal spot of ~ λ/NA ~ 20 μm, defining the diffraction limit for the objective lens with a numerical aperture NA ~ 0.5.
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