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Items: 1 to 20 of 157

1.

Understanding the contributions of NADH and collagen to cervical tissue fluorescence spectra: modeling, measurements, and implications.

Drezek R, Sokolov K, Utzinger U, Boiko I, Malpica A, Follen M, Richards-Kortum R.

J Biomed Opt. 2001 Oct;6(4):385-96.

PMID:
11728196
2.

Monte Carlo simulation of fluorescence spectra of normal and dysplastic cervical tissues for optimizing excitation/receiving arrangements.

Chu SC, Chiang HK.

Appl Spectrosc. 2010 Jul;64(7):708-13. doi: 10.1366/000370210791666336.

PMID:
20615282
3.

NAD(P)H and collagen as in vivo quantitative fluorescent biomarkers of epithelial precancerous changes.

Georgakoudi I, Jacobson BC, Müller MG, Sheets EE, Badizadegan K, Carr-Locke DL, Crum CP, Boone CW, Dasari RR, Van Dam J, Feld MS.

Cancer Res. 2002 Feb 1;62(3):682-7.

4.

Fluorescence spectroscopy of the cervix: influence of acetic acid, cervical mucus, and vaginal medications.

Agrawal A, Utzinger U, Brookner C, Pitris C, Mitchell MF, Richards-Kortum R.

Lasers Surg Med. 1999;25(3):237-49.

PMID:
10495301
5.

Spatially resolved reflectance spectroscopy for diagnosis of cervical precancer: Monte Carlo modeling and comparison to clinical measurements.

Arifler D, MacAulay C, Follen M, Richards-Kortum R.

J Biomed Opt. 2006 Nov-Dec;11(6):064027.

PMID:
17212550
6.
7.

Effects of biographical variables on cervical fluorescence emission spectra.

Brookner C, Utzinger U, Follen M, Richards-Kortum R, Cox D, Atkinson EN.

J Biomed Opt. 2003 Jul;8(3):479-83.

PMID:
12880354
8.
9.

Reconstruction of in vivo skin autofluorescence spectrum from microscopic properties by Monte Carlo simulation.

Zeng H, MacAulay C, McLean DI, Palcic B.

J Photochem Photobiol B. 1997 Apr;38(2-3):234-40.

PMID:
9203387
10.
11.

Model-based analysis of clinical fluorescence spectroscopy for in vivo detection of cervical intraepithelial dysplasia.

Chang SK, Marin N, Follen M, Richards-Kortum R.

J Biomed Opt. 2006 Mar-Apr;11(2):024008.

PMID:
16674198
12.

Spectroscopic and microscopic characteristics of human skin autofluorescence emission.

Zeng H, MacAulay C, McLean DI, Palcic B.

Photochem Photobiol. 1995 Jun;61(6):639-45.

PMID:
7568410
13.

Autofluorescence patterns in short-term cultures of normal cervical tissue.

Brookner CK, Follen M, Boiko I, Galvan J, Thomsen S, Malpica A, Suzuki S, Lotan R, Richards-Kortum R.

Photochem Photobiol. 2000 Jun;71(6):730-6.

PMID:
10857369
15.

Morphological model of human colon tissue fluorescence.

Zonios GI, Cothren RM, Arendt JT, Wu J, Van Dam J, Crawford JM, Manoharan R, Feld MS.

IEEE Trans Biomed Eng. 1996 Feb;43(2):113-22. Erratum in: IEEE Trans Biomed Eng 1996 Apr;43(4):437.

PMID:
8682522
17.

Combined reflectance and fluorescence spectroscopy for in vivo detection of cervical pre-cancer.

Chang SK, Mirabal YN, Atkinson EN, Cox D, Malpica A, Follen M, Richards-Kortum R.

J Biomed Opt. 2005 Mar-Apr;10(2):024031.

PMID:
15910104
18.

Autofluorescence microscopy of fresh cervical-tissue sections reveals alterations in tissue biochemistry with dysplasia.

Drezek R, Brookner C, Pavlova I, Boiko I, Malpica A, Lotan R, Follen M, Richards-Kortum R.

Photochem Photobiol. 2001 Jun;73(6):636-41.

PMID:
11421069
19.

Fluorescence spectroscopy for diagnostic differentiation in uteri's cervix biopsies with cervical/vaginal atypical cytology.

Rodero AB, Silveira L Jr, Rodero DA, Racanicchi R, Pacheco MT.

J Fluoresc. 2008 Sep;18(5):979-85. doi: 10.1007/s10895-008-0359-5. Epub 2008 Mar 25.

PMID:
18363079
20.

Detecting cervical cancer progression through extracted intrinsic fluorescence and principal component analysis.

Devi S, Panigrahi PK, Pradhan A.

J Biomed Opt. 2014 Dec;19(12):127003. doi: 10.1117/1.JBO.19.12.127003.

PMID:
25504494

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