Biochemical analysis and mapping of atherosclerotic human artery using FT-IR microspectroscopy.

We report the application of FT-IR microspectroscopy for in situ spectroscopic characterization of molecular constituents of human atherosclerotic lesions. Since water content in tissue affects conformation-sensitive protein vibrational bands, tissue specimens were examined under moist conditions. In all measurements, vibrational bands from water were found to dominate the spectrum. By removing these water contributions, well resolved bands due to tissue components were readily observed. Utilizing the high sensitivity and good spatial resolution of IR microspectroscopy, spectra from a sample volume of 40 x 40 x 4 microns3 were collected using unstained cryostat sections mounted on a BaF2 flat in neutral isotonic saline. Microstructures were confirmed histologically by light microscopy in stained serial sections. In the spectrum of normal intima, major bands due to amide I (1656 cm-1), amide II (1556 cm-1), and CH bending (1457 cm-1) vibrations of the proteins collagen and elastin were observed. In the spectrum of the intima of noncalcified atherosclerotic plaque, major bands due to both proteins and lipids were observed. The lipid bands at 1734, 1468, 1171 and 1058 cm-1 were assigned to the C = O (ester) stretch, CH2 bend, C--O (ester) stretch and C--O stretch, respectively. At a more detailed level, bands specific to free cholesterol, and cholesterol esters were identified. A plot of the integrated intensity ratio of these bands to the protein amide II mode versus depth from the luminal surface confirmed a heterogeneous distribution of these constituents in the atheromatous core. In the spectra of calcified atherosclerotic plaque, bands were attributed to three types of biochemical microstructures: proteins (1657, 1555, 1243 cm-1), lipids (1735, 1466, 1170, 1085, 1055 cm-1) and calcium minerals such as hydroxyapatite (1094, 1040, 962 cm-1), and carbonated apatite (1463, 1412, 872 cm-1). The results demonstrate that IR microspectroscopy can be used for in situ characterization of molecular constituents in human unstained arterial sections. The molecular information obtained from these studies could be important in understanding the pathogenesis of atherosclerosis.