Molecular structure of human aortic valve by μSR- FTIR microscopy

Aortic valve is a part of the heart most frequently affected by pathological processes in humans what constitute a very serious health problem. Therefore, studies of morphology and molecular microstructure of the AV are needed. mu SR-FTIR spectroscopy and microscopy represent unique tools to study chemical composition of the tissue and to identify spectroscopic markers characteristic for structural and functional features. Normal AV reveals a multi-layered structure and the compositional and structural changes within particular layers may trigger degenerative processes within the valve. Thus, deep insight into the structure of the valve to understand pathological processes occurring in AV is needed. In order to identify differences between three layers of human AV, tissue sections of macroscopically normal AV were studied using mu SR-FTIR spectroscopy in combination with histological and histochemical stainings. Tissue sections deposited onto CaF2 substrates were mapped and representative set of IR spectra collected from fibrosa, spongiosa and ventricularis were analysed by Principal Component Analysis (PCA) in the spectral range between 1850-1000 cm(-1) and 3050-2750 cm(-1). PCA revealed a layered molecular structure of the valve and it was possible to identify IR bands associated to different tissue parts. Spongiosa layer was well differentiated from other two layers mainly based on IR bands characteristic for the distribution of glycosaminoglycans (GAGs) in the tissue - like 1170 cm(-1) (upsilon(as)(C-O-S)) and 1380 cm(-1) (acetyl amino group). Additionally, it was distinguished from fibrosa and ventricularis based on 1085 cm(-1) and 1240 cm(-1) bands characteristic for GAGs and for carbohydrates-v(C-O) and v(C-O-C) respectively and nucleic acids-v(syn)(PO2-) and v(asym)(PO2-) respectively, which were less specific for this layer. The use of mu SR-FTIR spectroscopy demonstrated co-localization of GAGs and lipids in spongiosa layer what may indicate their contribution in the very early phase of aortic valve calcific degeneration. (C) 2017 Elsevier B.V. All rights reserved.