In situ infrared histopathology of keratinization in human oral/oropharyngeal squamous cell carcinoma.

Fourier transform infrared (FTIR) microspectroscopy is emerging as a promising new tool for histopathological investigations of tissue histochemistry. This study was designed to assess whether changes in tissue biochemistry induced by well-differentiated and poorly differentiated oral/oropharyngeal squamous cell carcinoma (SCC) can be detected by infrared spectroscopy. The biopsies analyzed were each proven SCC positive and compared with tissue taken from the contralateral normal site. Individual infrared spectra, recorded from specific tissue areas, were correlated with histopathological structures normally found in the oral mucosa. Infrared mapping of these areas allows the generation of biochemical images of molecular structures such as lipids, sugars, and proteins. The visualization of DNA and tissue structures containing keratin (well expressed in all epithelia) reveals distinct differences between normal and SCC-positive biopsies. Bivariate histogram analysis of cell components (e.g., DNA and keratin) indicated that cancer cells produce a relatively homogeneous and clearly abnormal cell biochemistry, whereas differentiated epithelial cells present a very heterogeneous distribution of cellular components. Using these features, tissue containing abnormal or cancer cells can easily be distinguished from normal epithelial structures. The abnormal keratin distribution in poorly differentiated SCC and in keratin pearls (present only in well-differentiated SCC) offers insight into the process of malignant tissue transformation in squamous epithelium. Applying infrared microspectroscopy in combination with bivariate statistics to histopathological tissue thin sections provides a potential diagnostic tool for detection of cell changes in epithelial cancers.