SPECTROSCOPIC DIAGNOSIS OF ESOPHAGEAL CANCER - NEW CLASSIFICATION MODEL, IMPROVED MEASUREMENT SYSTEM

被引：86

作者：

PANJEHPOUR, M

OVERHOLT, BF

SCHMIDHAMMER, JL

FARRIS, C

BUCKLEY, PF

VO-DINH, T

机构：

[1] OAK RIDGE NATL LAB, OAK RIDGE, TN 37831 USA

[2] UNIV TENNESSEE, DEPT STAT, KNOXVILLE, TN 37996 USA

来源：

GASTROINTESTINAL ENDOSCOPY | 1995年 / 41卷 / 06期

关键词：

D O I：

10.1016/S0016-5107(95)70194-X

中图分类号：

R57 [消化系及腹部疾病];

学科分类号：

摘要：

Laser-induced fluorescence spectroscopy was used to measure fluorescence emission of normal and malignant tissue during endoscopy in patients with esophageal cancer and volunteers with normal esophagus. The spectroscopy system consisted of a nitrogen-pumped dye-laser tuned at 410 nm for excitation source, an optical multichannel analyzer for spectrum analysis, and a fiberoptic probe designed for both the delivery of excitation light and the collection of fluorescence emission from tissue. The fluorescence lineshape of each spectrum was determined and sampled at 15-nm intervals from 430 to 716 nm. A calibration set of spectra from normal and malignant spectra was selected. Using stepwise discriminate analysis, significant wavelengths that separated normal from malignant spectra were selected. The intensities at these wavelengths were used to formulate a classification model using linear discriminate analysis. The model was then used to classify additional tissue spectra from 26 malignant and 108 normal sites into either normal or malignant spectra. A sensitivity of 100% and specificity of 98% were obtained.

引用

页码：577 / 581

页数：5

共 11 条

[1] Alfano RR, Tang GC, Pradhan A, Lam W, Choy DSJ, Opher E, Fluorescence spectra from cancerous and normal human breast and lung tissues, IEEE Journal of Quantum Electronics, 23, pp. 1806-1811, (1987)
[2] Tang GC, Pradhan A, Alfano RR, Spectroscopic differences between human cancer and normal lung and breast tissues, Lasers Surg Med, 9, pp. 290-295, (1989)
[3] Schomacker KT, Frisoli JK, Compton CC, Et al., Ultraviolet laser-induced fluorescence of colonic tissue: basic biology and diagnostic potential, Lasers Surg Med, 12, pp. 63-78, (1992)
[4] Cothren RM, Richards-Kortum R, Sivak MV, Et al., Gastrointestinal tissue diagnosis by laser-induced fluorescence spectroscopy at endoscopy, Gastrointest Endosc, 36, pp. 105-111, (1990)
[5] Kapadia CR, Cutruzzola FW, O'Brien KM, Stetz ML, Enriquez R, Deckelbaum LI, Laser-induced fluorescence spectroscopy of human colonic mucosa—detection of adenomatous transformation, Gastroenterology, 99, pp. 150-157, (1990)
[6] Dougherty TJ, Photosensitizers: therapy and detection of malignant tumors, Photochem Photobiol, 45, pp. 879-889, (1987)
[7] Profio AE, Balchum OS, Fluorescence diagnosis of cancer, Methods in porphyrin photosensitization, pp. 43-50, (1985)
[8] Lam S, MacAulay C, Hung J, LeRiche J, Profio AE, Palcic B, Detection of dysplasia and carcinoma in situ with a lung imaging fluorescence endoscope device, J Thorac Cardiovasc Surg, 105, pp. 1035-1040, (1993)
[9] Schomacker KT, Frisoli JK, Compton CC, Et al., Ultraviolet laser-induced fluorescence of colonic polyps, Gastroenterology, 102, pp. 1155-1160, (1992)
[10] Richards-Kortum R, Rava RP, Petras RE, Fitzmaurice M, Sivak M, Feld MS, Spectroscopic diagnosis of colonic dysplasia, Photochem Photobiol, 53, pp. 777-786, (1991)

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