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Items: 1 to 20 of 184

1.

Near-infrared sensitivity enhancement of photorefractive polymer composites by pre-illumination.

Mecher E, Gallego-Gómez F, Tillmann H, Hörhold HH, Hummelen JC, Meerholz K.

Nature. 2002 Aug 29;418(6901):959-64.

PMID:
12198543
2.

Three-dimensional holographic imaging of living tissue using a highly sensitive photorefractive polymer device.

Salvador M, Prauzner J, Köber S, Meerholz K, Turek JJ, Jeong K, Nolte DD.

Opt Express. 2009 Jul 6;17(14):11834-49.

PMID:
19582098
3.

Optical gain by a simple photoisomerization process.

Gallego-Gómez F, del Monte F, Meerholz K.

Nat Mater. 2008 Jun;7(6):490-7. doi: 10.1038/nmat2186. Epub 2008 May 4.

PMID:
18454152
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5.
6.

Infrared photorefractive polymers and their applications for imaging.

Kippelen B, Marder SR, Hendrickx E, Maldonado JL, Guillemet G, Volodin BL, Steele DD, Enami Y, Sandalphon, Yao YJ, Wang JF, Röckel H, Erskine L, Peyghambarian N.

Science. 1998 Jan 2;279(5347):54-7.

7.

Direct-to-video holographic 3-D imaging using photorefractive multiple quantum well devices.

Jones R, Tziraki M, French P, Kwolek K, Nolte D, Melloch M.

Opt Express. 1998 May 25;2(11):439-48.

PMID:
19381213
8.

Photorefractive materials for nonvolatile volume holographic data storage

Hesselink L, Orlov SS, Liu A, Akella A, Lande D, Neurgaonkar RR.

Science. 1998 Nov 6;282(5391):1089-94.

9.

Comparative study of optical sources in the near infrared for optical coherence tomography applications.

Carrion L, Lestrade M, Xu Z, Touma G, Maciejko R, Bertrand M.

J Biomed Opt. 2007 Jan-Feb;12(1):014017.

PMID:
17343492
10.

Near-infrared laser tomographic imaging with right-angled scattered coherent light using an optical heterodyne-detection-based confocal scanning system.

Nishidate I, Goto M, Sasaki Y, Yuasa T, Devaraj B, Niizeki K, Akatsuka T.

Appl Opt. 2007 Apr 10;46(11):2123-30.

PMID:
17384729
11.

Upflow anaerobic sludge blanket reactor--a review.

Bal AS, Dhagat NN.

Indian J Environ Health. 2001 Apr;43(2):1-82. Review.

PMID:
12397675
12.

Interdigitated coplanar electrodes for enhanced sensitivity in a photorefractive polymer.

Christenson CW, Greenlee C, Lynn B, Thomas J, Blanche PA, Voorakaranam R, Hilaire PS, LaComb LJ Jr, Norwood RA, Yamamoto M, Peyghambarian N.

Opt Lett. 2011 Sep 1;36(17):3377-9. doi: 10.1364/OL.36.003377.

PMID:
21886216
13.

An updatable holographic three-dimensional display.

Tay S, Blanche PA, Voorakaranam R, Tunç AV, Lin W, Rokutanda S, Gu T, Flores D, Wang P, Li G, St Hilaire P, Thomas J, Norwood RA, Yamamoto M, Peyghambarian N.

Nature. 2008 Feb 7;451(7179):694-8. doi: 10.1038/nature06596.

PMID:
18256667
14.

Development of high-sensitivity near-infrared fluorescence imaging device for early cancer detection.

Chen Y, Intes X, Chance B.

Biomed Instrum Technol. 2005 Jan-Feb;39(1):75-85.

PMID:
15742853
15.
16.

Near-infrared dyes as contrast-enhancing agents for spectroscopic optical coherence tomography.

Xu C, Ye J, Marks DL, Boppart SA.

Opt Lett. 2004 Jul 15;29(14):1647-9.

PMID:
15309847
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18.

Current diagnostic modalities for vulnerable plaque detection.

Schaar JA, Mastik F, Regar E, den Uil CA, Gijsen FJ, Wentzel JJ, Serruys PW, van der Stehen AF.

Curr Pharm Des. 2007;13(10):995-1001. Review.

PMID:
17430163
19.

Direct-to-video holographic readout in quantum wells for three-dimensional imaging through turbid media.

Jones R, Barry NP, Hyde SC, French PM, Kwolek KW, Nolte DD, Melloch MR.

Opt Lett. 1998 Jan 15;23(2):103-5.

PMID:
18084426
20.

Spectral and temporal near-infrared imaging of ex vivo cancerous and normal human breast tissues.

Alrubaiee M, Gayen SK, Alfano RR, Koutcher JA.

Technol Cancer Res Treat. 2005 Oct;4(5):457-70.

PMID:
16173818
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