Fourier-transform infrared anisotropy in cross and parallel sections of tendon and articular cartilage

BACKGROUND Fourier Transform Infrared Imaging (FTIRI) is used to investigate the amide anisotropies at different surfaces of a three-dimensional cartilage or tendon block. With the change in the polarization state of the incident infrared light, the resulting anisotropic behavior of the tissue structure is described here. METHODS Thin sections (6 mum thick) were obtained from three different surfaces of the canine tissue blocks and imaged at 6.25 microm pixel resolution. For each section, infrared imaging experiments were repeated thirteen times with the identical parameters except a 15 degrees increment of the analyzer's angle in the 0 degrees-180 degrees angular space. The anisotropies of amide I and amide II components were studied in order to probe the orientation of the collagen fibrils at different tissue surfaces. RESULTS For tendon, the anisotropy of amide I and amide II components in parallel sections is comparable to that of regular sections; and tendon's cross sections show distinct, but weak anisotropic behavior for both the amide components. For articular cartilage, parallel sections in the superficial zone have the expected infrared anisotropy that is consistent with that of regular sections. The parallel sections in the radial zone, however, have a nearly isotropic amide II absorption and a distinct amide I anisotropy. CONCLUSION From the inconsistency in amide anisotropy between superficial to radial zone in parallel section results, a schematic model is used to explain the origins of these amide anisotropies in cartilage and tendon.