Biophotonics_Concepts_to_Applications

References

1. A.R. Kherlopian, T. Song, Q. Duan, M.A. Neimark, M.J. Po, J.K. Gohagan, A.F. Laine, A
   review of imaging techniques for systems biology. BMC Syst. Biol. 2 ,74–91 (2008)


2. A.P. Dhawan, B.D. Alessandro, X. Fu, Optical imaging modalities for biomedical
   applications. IEEE Rev. Biomed. Eng. 3 ,69–92 (2010)


3. C.T. Xu, Q. Zhan, H. Liu, G. Somesfalean, J. Qian, S. He, S. Andersson-Engels, Upconverting
   nanoparticles for pre-clinical diffuse optical imaging, microscopy and sensing: current trends
   and future challenges. Laser Photonics Rev. 7 (5), 663–697 (2013)


4. J.G. Fujimoto, Optical coherence tomography for ultrahigh resolution in vivo imaging. Nat.
   Biotechnol. 21 , 1361–1367 (2003)


5. M. Wojtkowski, High-speed optical coherence tomography: basics and applications. Appl.
   Opt. 49 (16), D30–D61 (2010)


6. J.A. Izatt, M.A. Choma, Theory of optical coherence tomography, chap. 2, ed. by W. Drexler,
   J.G. Fujimoto, eds.,Optical Coherence Tomography Technology and Applications(Springer,
   2008)


7. R.L. Shelton, W. Jung, S.I. Sayegh, D.T. McCormick, J. Kim, S.A. Boppart, Optical
   coherence tomography for advanced screening in the primary care office. J. Biophotonics 7 ,
   525 – 533 (2014)


8. W. Drexler, M. Liu, A. Kumar, T. Kamali, A. Unterhuber, R.A. Leitgeb, Optical coherence
   tomography today: speed, contrast, and multimodality. J. Biomed. Opt. 19 (7), 071412 (2014)


9. Z. Hubler, N.D. Shemonski, R.L. Shelton, G.L. Monroy, R.M. Nolan, S.A. Boppart, Real time
   automated thickness measurement of the in vivo human TM using optical coherence
   tomography. Quant. Imaging Med. Surg. 5 (1), 69–77 (2015)


10. M.E. Brezinski,Optical Coherence Tomography: Principles and Applications, 2nd edn.
    (Academic, New York, 2016)


11. J. Mo, M. de Groot, J.F. de Boer, Depth-encoded synthetic aperture optical coherence
    tomography of biological tissues with extended focal depth. Opt. Express 23 (4), 4935– 4945
    (2015)


12. R. Leitgeb, C.K. Hitzenberger, A.F. Fercher, Performance of Fourier domain vs. time domain
    optical coherence tomography. Opt. Express 11 (8), 889–894 (2003)


13. Y. Zhao, H. Tu, Y. Liu, A.J. Bower, S.A. Boppart, Enhancement of optical coherence
    microscopy in turbid media by an optical parametric amplifier. J. Biophotonics 8 (6), 512– 521
    (2015)


14. I. Grulkowski, J.J. Liu, B. Potsaid, V. Jayaraman, J. Jiang, J.G. Fujimoto, A.E. Cable,
    High-precision, high-accuracy ultralong-range swept-source optical coherence tomography
    using vertical cavity surface emitting laser light source. Opt. Lett. 38 , 673–675 (2013)


15. W.J. Choi, R.K. Wang,“Swept-source optical coherence tomography powered by a 1.3-μm
    vertical cavity surface emitting laser enables 2.3-mm-deep brain imaging in mice in vivo.
    J. Biomed. Opt., 20 , article 106004 (Oct 2015)


16. R. Kiesslich, M. Goetz, A. Hoffman, P.R. Galle, Review paper: new imaging techniques and
    opportunities in endoscopy. Nat. Rev. Gastroenterol. Hepatol. 8 , 547–553 (2011)


17. S.F. Elahi, T.D. Wang, Future and advances in endoscopy. J. Biophotonics 4 (7–8), 471– 481
    (2011)


18. P.S. Thong, S.S. Tandjung, M.M. Movania, W.M. Chiew, M. Olivo, R. Bhuvaneswari, H.S.
    Seah, F. Lin, K. Qian, K.C. Soo, Toward real-time virtual biopsy of oral lesions using confocal
    laser endomicroscopy interfaced with embedded computing. J. Biomed. Opt. 17 (5), article
    0560 (May 2012)


19. V. Subramanian, K. Ragunath, Advanced endoscopic imaging: a review of commercially
    available technologies. Clin. Gastroenterol. Hepatol. 12 , 368–376 (2014)


20. M. Gu, H. Bao, H. Kang, Fibre-optical microendoscopy. J. Microsc., 254 (1), 13–18 (Apr

References 319