Laser-induced autofluorescence microscopy of normal and tumor human colonic tissue.

Laser-induced autofluorescence (LIAF) spectroscopy has been found to be a promising tool for early cancer diagnosis in various organs, but the reasons responsible for the spectral differences between normal and diseased tissue are still not well understood. In this study, a microspectrophotometer (MSP) system was used to identify the microscopic origins of tissue autofluorescence in the colon under the excitation of a helium-cadmium laser at 442 nm. Colonic tissue samples (normal: n=8, adenocarcinoma: n=10) were obtained from 12 patients with known or suspected malignancies of the colon. The intrinsic fluorescence spectra and images of fresh tissue sections prepared from normal and tumor colonic tissue were measured by the MSP system. Three distinct tissue layers of the colon were found for fluorescence, the mucosa, the submucosa and the muscularis propria, with submucosa being the most fluorescent. Differences in the spectral shape and intensity of the intrinsic fluorescence originating from different colonic layers indicate that fundamentally different fluorophores may be present in the respective tissue layers. There was no significant difference in the intrinsic fluorescence features of the submucosa between normal and tumor colonic tissue, but the fluorescence intensity of the submucosa in tumor tissue was significantly reduced due to the infiltration of tumor cells into the submucosa. The intrinsic fluorescence spectrum peaking at about 520 nm for tumor stroma appeared more evident than that of normal lamina propria. Limited areas of the lamina propria layer in some adenocarcinoma colon exhibited an emission band at about 635 nm, which was attributed to endogenous porphyrins in tumor. Autofluorescence microscopy revealed that differences in the clinically measured autofluorescence spectra between normal and tumor tissue were mainly due to thickening of the tumor mucosa resulting in a reduced submucosa fluorescence contribution, as well as the increased hemoglobin absorption in tumor tissue. Therefore, investigation of the microscopic origins of tissue autofluorescence and images can provide new insights into morphological structures and biochemical components of tissues, which are vital to improve the implementation of the LIAF technique for non-invasive in vivo tissue diagnostics.

[1]  E. Sevick-Muraca,et al.  Quantitative optical spectroscopy for tissue diagnosis. , 1996, Annual review of physical chemistry.

[2]  R. Marchesini,et al.  Natural fluorescence of normal and neoplastic human colon: A comprehensive “ex vivo” study , 1995, Lasers in surgery and medicine.

[3]  N Ramanujam,et al.  In vivo diagnosis of cervical intraepithelial neoplasia using 337-nm-excited laser-induced fluorescence. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[4]  T J Flotte,et al.  Ultraviolet laser‐induced fluorescence of colonic tissue: Basic biology and diagnostic potential , 1992, Lasers in surgery and medicine.

[5]  J. Arends,et al.  Patterns and composition of basement membranes in colon adenomas and adenocarcinomas , 1993, The Journal of pathology.

[6]  C. Lejeune,et al.  [The natural history of colorectal cancer revisited]. , 2002, Gastroenterologie clinique et biologique.

[7]  K Svanberg,et al.  Detection of adenocarcinoma in Barrett's oesophagus by means of laser induced fluorescence. , 1996, Gut.

[8]  R. Rava,et al.  SPECTROSCOPIC DIAGNOSIS OF COLONIC DYSPLASIA , 1991, Photochemistry and photobiology.

[9]  S L Jacques,et al.  Fluorescence spectroscopy of tissue: recovery of intrinsic fluorescence from measured fluorescence. , 1996, Applied optics.

[10]  Haishan Zeng,et al.  Novel microspectrophotometer and its biomedical applications , 1993 .

[11]  L. Deckelbaum,et al.  Laser-induced fluorescence spectroscopy of human colonic mucosa. Detection of adenomatous transformation. , 1990, Gastroenterology.

[12]  Teck-Chee Chia,et al.  Laser-induced fluorescence spectrum of human colonic tissues by Monte Carlo modeling , 2000, BiOS.

[13]  A. Zauber,et al.  The natural history of colorectal cancer. Opportunities for intervention , 1991, Cancer.

[14]  R Marchesini,et al.  Light-induced fluorescence spectroscopy of adenomas, adenocarcinomas and non-neoplastic mucosa in human colon. I. In vitro measurements. , 1992, Journal of photochemistry and photobiology. B, Biology.

[15]  Paul F. Buckley,et al.  Spectroscopic diagnosis of esophageal cancer: new classification model, improved measurement system. , 1995, Gastrointestinal endoscopy.

[16]  D. Harris,et al.  Endogenous porphyrin fluorescence in tumors , 1987, Lasers in surgery and medicine.