Biophotonics_Concepts_to_Applications

(Dana P.) #1

  1. G.T. Kanellos, G. Papaioannou, D. Tsiokos, C. Mitrogiannis, G. Nianios, N. Pleros, Two
    dimensional polymer-embedded quasi-distributed FBG pressure sensor for biomedical
    applications. Opt. Express 18 (1), 179–186 (2010)

  2. J.W. Arkwright, N.G. Blenman, I.D. Underhill, S.A. Maunder, M.M. Szczesniak, P.G.
    Dinning, I.J. Cook, In-vivo demonstration of a high resolution opticalfiber manometry
    catheter for diagnosis of in gastrointestinal motility disorder. Opt. Express 17 (6), 4500– 4508
    (2009)

  3. P.G. Dinning, L. Wiklendt, L. Maslen, V. Patton, H. Lewis, J.W. Arkwright, D.A. Wattchow,
    D.Z. Lubowski, M. Costa, P.A. Bampton, Colonic motor abnormalities in slow transit
    constipation defined by high resolution,fibre-optic manometry. Neurogastroenterol. Motil. 27
    (3), 379–388 (2015)

  4. A. Bhalla, N. Grewal, U. Tiwari, V. Mishra, N.S. Mehla, S. Raviprakash, P. Kapur, Shock
    absorption ability of laminate mouth guards in two different malocclusions usingfiber Bragg
    grating (FBG) sensor. Dent. Traumatol. 29 (3), 218–225 (2013)

  5. M. Ciocchetti, C. Massaroni, P. Saccomandi, M.A. Caponero, A. Polimadei, D. Formica, E.
    Schena, Smart textile based onfiber Bragg grating sensors for respiratory monitoring: design
    and preliminary trials. Biosensors 5 , 602–615 (2015)

  6. S. Poeggel, D. Duraibabu, K. Kalli, G. Leen, G. Dooly, E. Lewis, J. Kelly, M. Munroe, Recent
    improvement of medical opticalfibre pressure and temperature sensors. Biosensors 5 , 432– 449
    (2015)

  7. J. Homola, Surface plasmon resonance sensors for detection of chemical and biological
    species. Chem. Rev. 108 (2), 462–493 (2008)

  8. M. Bauch, K. Toma, M. Toma, Q. Zhang, J. Dostalek, Plasmon-enhancedfluorescence
    biosensors: a review. Plasmonics 9 (4), 781–799 (2014)

  9. C.L. Wong, M. Olivo, Surface plasmon resonance imaging sensors: a review. Plasmonics 9 (4),
    809 – 824 (2014)

  10. O. Tokel, F. Inci, U. Demirci, Advances in plasmonic technologies for point of care
    applications. Chem. Rev. 114 (11), 5728–5752 (2014)

  11. E. Seymour, G.G. Daaboul, X. Zhang, S.M. Scherr, N.L.Ünlü, J.H. Connor, M.S.Ünlü, DNA
    directed antibody immobilization for enhanced detection of single viral pathogens. Anal.
    Chem. 87 (20), 10505–10512 (2015)

  12. Y.T. Long, C. Jing,Localized Surface Plasmon Resonance Based Nanobiosensors(Springer,
    Berlin, 2014)

  13. M. Consales, M. Pisco, A. Cusano, Review: lab-on-fiber technology: a new avenue for optical
    nanosensors. Photonic Sens. 2 (4), 289–314 (2012)

  14. A. Ricciardi, M. Consales, G. Quero, A. Crescitelli, E. Esposito, A. Cusano, Lab-on-fiber
    devices as an all around platform for sensing. Opt. Fiber Technol. 19 (6), 772–784 (2013)

  15. J. Cao, T. Sun, K.T.V. Grattan, Gold nanorod-based localized surface plasmon resonance
    biosensors: a review. Sens. Actuators B Chem. 195 , 332–351 (2014)

  16. C.-K. Chu, Y.-C. Tu, Y.-W. Chang, C.-K. Chu, S.-Y. Chen, T.-T. Chi, Y.-W. Kiang, C.C.
    Yang, Cancer cell uptake behavior of Au nanoring and its localized surface plasmon resonance
    induced cell inactivation. Nanotechnology 26 (7), article 075102 (2015)

  17. J. Albert, A lab onfiber. IEEE Spectr. 51 ,49–53 (2014)

  18. K.Z. Kamili, A. Pandikumar, G. Sivaraman, H.N. Lim, S.P. Wren, T. Sun, N.M. Huang,
    Silver@graphene oxide nanocomposite-based optical sensor platform for biomolecules. RSC
    Adv. 5 (23), 17809–17816 (2015)

  19. N. Lebedev, I. Griva, W.J. Dressick, J. Phelps, J.E. Johnson, Y. Meshcheriakova, G.
    P. Lomonossoff, C.M. Soto, A virus-based nanoplasmonic structure as a surface-enhanced
    Raman biosensor. Biosens. Bioelectron. 77 , 306–314 (2016)


232 7 Optical Probes and Biosensors

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