Biomedical Engineering Reference
In-Depth Information
47. Kondepati, V. R., Heise, H. M., Oszinda T., Mueller, R., Keese, M., and Backhaus,
J. 2008. Detection of structural disorders in colorectal cancer DNA with Fourier-
transform infrared spectroscopy.
Vibrational Spectroscopy
46, 150-157.
48. Dovbeshko, G. I., Gridina, N. Y., Kruglova, E. B., and Pashchuk, O. P. 2000. FTIR
spectroscopy studies of nucleic acid damage.
Talana
53, 233-246.
49. Silveira, L., Sathaiah, S., and Zangaro, R. A. 2002. Correlation between near-
infrared Raman spectroscopy and the histopathological analysis of atheroscle-
rosis in human coronary arteries.
Lasers Surg. Med.
30, 290-297.
50. Chiriboga, L., Xie, P., Yee, H., Vigorita, V., Zarou, D., Zakim, D., and Diem, M.
1998. Infrared spectroscopy of human tissue. I. Differentiation and maturation
of epithelial cells in the human cervix.
Biospectroscopy
4, 47-53.
51. Fung, M. F. K., Senterman, M. K., Mikhael, N. Z., Lacelle, S., and Wong, P. T. T.
1996. Pressure-tuning Fourier transform infrared spectroscopic study of carci-
nogenesis in human endometrium.
Biospectroscopy
2, 155-165.
52. Wood, B. R., Quinn, M. A., Burden, F. R., and McNaughton, D. 1996. An inves-
tigation into FT-IR spectroscopy as a bio-diagnostic tool for cervical cancer.
Biospectroscopy
2, 143-153.
53. Argov, S., Sahu, R. K., Bernshtain, E., Salam, A., Shohat, G., Zelig, U., and
Mordechai, S. 2004. Inflammatory bowel diseases as an intermediate stage
between normal and cancer: A FTIR-microspectroscopy approach.
Biopolymers
75, 384-392.
54. Malini, R., Venkatakrishma, K., Kurien, J., Pai, K. M., Rao, L., Kartha, V. B., and
Murali Krishna, C. 2006. Discrimination of normal, inflammatory, premalig-
nant, and malignant oral tissue: A Raman spectroscopy study.
Biopolymers
81,
179-193.
55. Gazi, E., Dwyer, J., Gardner, P., Ghanbari Siakhani, A., Wde, A. P., Lockyer, N. P.,
Vickerman, J. C., Clarke, N. W., Shanks, J. H., Scott, L. J., Hart, C. A., and Brown,
M. 2003. Applications of Fourier transform infrared microspectroscopy in stud-
ies of benign prostate and prostate cancer. A pilot study.
J. Pathol
. 201, 99-108.
56. Yoshida, S., Miyazaki, M., and Sakai, K. 1997. Fourier transform infrared spec-
troscopic analysis of rat brain microsomal membranes modified by dietary
fatty acids: Possible correlation with altered learning behavior.
Biospectroscopy
3, 281-290.
57. Alfano, R. R., Tang, G. C., Pradhan, A., Lam, W., Choy, D. S. J., and Opher, E.
1987. Optical spectroscopic diagnosis of cancer and normal breast tissues.
IEEE
J. Quantum Electronics
, QE 23, 1806-1811.
58. Onogi, C., Motoyama, M., and Hamaguchi, H. 2008. High concentration
trans
form unsaturated lipids detected in a HeLa cell by Raman microspectroscopy.
J. Raman Spectroscopy
39, 555-556.
59. Lord, R. C., and Yu, N. T. 1970. Laser-excited Raman spectroscopy of bio-
molecules. II. Native ribonuclease and alpha-chymotrypsin.
J. Mol. Biol.
51,
203-213.
60. Hu Y. G., Shen, A. G., and Jiang, T. 2008. Classification of normal and malig-
nant human gastric mucosa tissue with confocal Raman microspectroscopy
and wavelet analysis.
Pectrochemica Acta Part A Mol. Biomol. Spectroscopy
69,
378-382.
61. Bogomolny E., Argov, S., Mordechai, S., and Huleihel, M. 2008. Monitoring of
viral cancer progression using FTIR microscopy: A comparative study of intact
cells and tissues.
Biochimica et Biophysica Acta
1780, 1038-1046.
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