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Fiber Optic Sensors Based on Nano-Films Kapitel lesen Erstes Kapitel lesen

2017 | OriginalPaper | Buchkapitel

Trends in Fibre-Optic Uses for Personal Healthcare and Clinical Diagnostics

verfasst von : A. B. Socorro, S. Díaz

Erschienen in: Fiber Optic Sensors

Verlag: Springer International Publishing

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Abstract

Along this chapter, a different point of view on the sensing uses of optical fibre is shown, focusing on its applicability to medical diagnostics. A wide majority of the fibre-optic-based structures described in this book can be used in medicine. But there are some challenges for fibre-optics to be fulfilled in the future when talking about healthcare. First, current society strongly demands day-by-day applications. This means, technologies that permit their use ‘on the go’ such as wearables or their integration in our smartphones. Second, due to the reduced dimensions of the optical fibre, there is an increasing interest in introducing it into the body, as it occurs when using catheters or fibrescopes. Moreover, the need for analysing biological substances makes it crucial to use reduced size devices that permit their interaction with the biomolecules, once the samples have been extracted from the patient. And of course, all the addressed applications must be achieved in order to search for cheap devices that work under exigent conditions. The main goal of this chapter is to search for those applications that will lead us to use fibre-optics for self-healthcare and diagnose patients in the next times.

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Vorheriges Kapitel Plasma-Based Deposition and Processing Techniques for Optical Fiber Sensing
Nächstes Kapitel Optical Fibres for Radiation Dosimetry
Literatur
1.
M.R.N. Monton, E.M. Forsberg, J.D. Brennan, Tailoring sol-gel-derived silica materials for optical biosensing. Chem. Mater. 24, 796–811 (2012). doi:10.​1021/​cm202798e CrossRef
2.
3.
A. Rosenthal, S. Kellnberger, D. Bozhko, A. Chekkoury, M. Omar, D. Razansky et al., Sensitive interferometric detection of ultrasound for minimally invasive clinical imaging applications. Laser Photon. Rev. 8, 450–457 (2014). doi:10.​1002/​lpor.​201300204 CrossRef
4.
5.
R. Sroka, K. Weick, M. Sadeghi-Azandaryani, B. Steckmeier, C.-G. Schmedt, Endovenous laser therapy–application studies and latest investigations. J. Biophoton. 3, 269–276 (2010). doi:10.​1002/​jbio.​200900097 CrossRef
6.
G. Cheymol, B. Brichard, J.F. Villard, Fiber optics for metrology in nuclear research reactors—applications to dimensional measurements. IEEE Trans. Nucl. Sci. 58, 1895–1902 (2011). doi:10.​1109/​TNS.​2011.​2160356 CrossRef
7.
W. Hou, G. Liu, M. Han, A novel, high-resolution, high-speed fiber-optic temperature sensor for oceanographic applications, in IEEE 2015 IEEE/OES Eleveth Current, Waves and Turbulence Measurement (CWTM), 2015, pp. 1–4. doi:10.​1109/​CWTM.​2015.​7098149
8.
M. Pospíšilová, G Kuncová, J Trögl, Fiber-optic chemical sensors and fiber-optic bio-sensors. Sensors (Switzerland) 15, 25208–25259 (2015). doi:10.​3390/​s151025208
9.
C.R. Zamarreño, A.B. Socorro, P. Sanchez, I.R. Matias, F.J. Arregui, Fiber-Optic Biosensors. Book chapter in Encyclopedia of Optical and Photonic Engineering, Second Edition (Print)–Five Volume Set (Taylor & Francis, CRC Press, 2015) p. 3858
10.
11.
C. Massaroni, P. Saccomandi, E. Schena, Medical smart textiles based on fiber optic technology: an overview. J. Funct. Biomater. 6, 204–221 (2015). doi:10.​3390/​jfb6020204 CrossRef
12.
13.
14.
15.
16.
17.
K. Krebber, S. Liehr, J. Witt, Smart technical textiles based on fibre optic sensors. in OFS 2012 22 International Conference on Optical Fiber Sensors, Invited Paper. 8421 (2012) 84212A–10. doi:10.​1117/​12.​981342
18.
Novel Sensors and Sensing (Series in Sensors): Roger G. Jackson, ISBN 9780750309899 (Taylor & Francis Group, 2004), p. 512
19.
K. Krebber, P. Lenke, S. Liehr, J. Witt, M. Schukar, Smart technical textiles with integrated POF sensors, in The 15 International Symposium on: Smart Structures and Materials and Nondestructive Evaluation and Health Monitoring, International Society for Optics and Photonics, ed. by W. Ecke, K.J. Peters, N.G. Meyendorf (2008), pp. 69330V–69330V–15. doi:10.​1117/​12.​776758
20.
M.R. Voet, A. Nancey, J. Vlekken, Geodetect: a new step for the use of fibre Bragg grating technology in soil engineering, in International Society for Optics and Photonics, ed. by M. Voet, R. Willsch, W. Ecke, J. Jones, B. Culshaw (Bruges, Belgium—Deadline Past, 2005), pp. 214–217. doi:10.​1117/​12.​623799
21.
22.
23.
Manhattan Research, Physicians in 2012: The Outlook for On Demand, Mobile, and Social Digital Media: A Physician Module Report (Manhattan Research, New York, 2009)
24.
25.
G. Ferriero, S. Vercelli, F. Sartorio, S. Muñoz Lasa, E. Ilieva, E. Brigatti, et al., Reliability of a smartphone-based goniometer for knee joint goniometry. Int. J. Rehabil. Res. Internationale Zeitschrift Für Rehabilitationsforschung. Revue Internationale de Recherches de Réadaptation. 36, 146–51 (2013). doi:10.​1097/​MRR.​0b013e32835b8269​
26.
27.
B. Berg, B. Cortazar, D. Tseng, H. Ozkan, S. Feng, Q. Wei et al., Cellphone-based hand-held microplate reader for point-of-care testing of enzyme-linked immunosorbent assays. ACS Nano 9, 7857–7866 (2015). doi:10.​1021/​acsnano.​5b03203 CrossRef
28.
29.
30.
Y. Liu, Q. Liu, S. Chen, F. Cheng, H. Wang, W. Peng, surface plasmon resonance biosensor based on smart phone platforms. Sci. Rep. 5, 12864 (2015). doi:10.​1038/​srep12864
31.
C. Shi, S. Giannarou, S. Lee, G. Yang, Simultaneous catheter and environment modeling for trans-catheter aortic valve implantation, in IEEE/RSJ International Conference on Intelligent Robots and Systems (2014), pp. 2024–2029. doi:10.​1109/​IROS.​2014.​6942832
32.
A. Nilsson, Q. Zhang, J. Styf, Evaluation of a fiber-optic technique for recording intramuscular pressure in the human leg. J. Clin. Monit. Comput. (2015). doi:10.​1007/​s10877-015-9750-3
33.
34.
E. LifeSciences, Advanced Hemodynamic Monitoring with the Edwards Swan-Ganz Catheter, vol. 2 (Edwards LifeSciences, 2009)
35.
J. Kovaleva, F.T.M. Peters, H.C. van der Mei, J.E. Degener, Transmission of infection by flexible gastrointestinal endoscopy and bronchoscopy. Clin. Microbiol. Rev. 26, 231–254 (2013). doi:10.​1128/​CMR.​00085-12 CrossRef
36.
37.
38.
39.
P. Urquhart, R. Dacosta, N. Marcon, Endoscopic mucosal imaging of gastrointestinal neoplasia in 2013 topical collection on GI oncology. Curr. Gastroenterol. Rep. 15 (2013). doi:10.​1007/​s11894-013-0330-8
40.
41.
42.
M. Abad, J.L. Arce, Study of colonoscopic laser surgery applied to tumoral tissue resection, Santander, 2014
43.
A. Katzir, Lasers and Optical Fibers in Medicine ISBN: 9780124019409 (1993), p. 317
44.
J. Sauk, E. Coron, L. Kava, M. Suter, M. Gora, K. Gallagher et al., Interobserver agreement for the detection of barrett’s esophagus with optical frequency domain imaging. Dig. Dis. Sci. 58, 2261–2265 (2013). doi:10.​1007/​s10620-013-2625-x CrossRef
45.
46.
R. Singh, S.Y. Lee, N. Vijay, P. Sharma, N. Uedo, Update on narrow band imaging in disorders of the upper gastrointestinal tract. Dig Endosc. 26, 144–153 (2014). doi:10.​1111/​den.​12207 CrossRef
47.
48.
R. Taylor, J.S. Schultz, Handbook of Chemical and Biological Sensors, ISBN: 0750303239, IOP Publishing Ltd 1996. Reprinted in 2003, p. 607
49.
50.
M. Soler, M.C. Estevez, M. Alvarez, M.A. Otte, B. Sepulveda, L.M. Lechuga, Direct detection of protein biomarkers in human fluids using site-specific antibody immobilization strategies. Sensors (Basel, Switzerland). 14, 2239–2258 (2014). doi:10.​3390/​s140202239
51.
52.
D. Futra, L. Heng, A. Ahmad, S. Surif, T. Ling, An optical biosensor from green fluorescent escherichia coli for the evaluation of single and combined heavy metal toxicities. Sensors 15, 12668–12681 (2015). doi:10.​3390/​s150612668 CrossRef
53.
X. Lv, J. Mo, L. Xu, Z. Jia, Biochemical sensing application based on optical fiber evanescent wave sensor, Proc. SPIE 9620, 2015 International Conference on Optical Instruments and Technology: Optical Sensors and Applications, 96200T (10 August 2015); doi:10.​1117/​12.​2191430
54.
Y. Huang, Z. Tian, L.-P. Sun, D. Sun, J. Li, Y. Ran et al., High-sensitivity DNA biosensor based on optical fiber taper interferometer coated with conjugated polymer tentacle. Opt. Express 23, 26962–26968 (2015). doi:10.​1364/​OE.​23.​026962 CrossRef
55.
N. Cennamo, M. Pesavento, L. Lunelli, L. Vanzetti, C. Pederzolli, L. Zeni et al., An easy way to realize SPR aptasensor: a multimode plastic optical fiber platform for cancer biomarkers detection. Talanta 140, 88–95 (2015). doi:10.​1016/​j.​talanta.​2015.​03.​025 CrossRef
56.
K.V. Sreekanth, S. Zeng, J. Shang, K.-T. Yong, T. Yu, Excitation of surface electromagnetic waves in a graphene-based Bragg grating. Sci. Rep. 2, 737 (2012). doi:10.​1038/​srep00737 CrossRef
57.
58.
H.-Y. Lin, W.-H. Tsai, Y.-C. Tsao, B.-C. Sheu, Side-polished multimode fiber biosensor based on surface plasmon resonance with halogen light. Appl. Opt. 46, 800–806 (2007). doi:10.​1364/​AO.​46.​000800 CrossRef
59.
60.
61.
C. Caucheteur, T. Guo, J. Albert, Review of plasmonic fiber optic biochemical sensors: improving the limit of detection. Anal. Bioanal. Chem. 3883–3897 (2015). doi:10.​1007/​s00216-014-8411-6
62.
63.
64.
65.
66.
67.
I. Del Villar, M. Hernaez, C.R. Zamarreño, P. Sánchez, C. Fernández-Valdivielso, F.J. Arregui et al., Design rules for lossy mode resonance based sensors. Appl. Opt. 51, 4298 (2012). doi:10.​1364/​AO.​51.​004298 CrossRef
68.
I. Del Villar, C.R. Zamarreño, P. Sanchez, M. Hernaez, C.F. Valdivielso, F.J. Arregui et al., Generation of lossy mode resonances by deposition of high-refractive-index coatings on uncladded multimode optical fibers. J. Opt. 12, 095503 (2010). doi:10.​1088/​2040-8978/​12/​9/​095503 CrossRef
69.
C.R. Zamarreño, M. Hernáez, I. Del Villar, I.R. Matías, F.J. Arregui, Optical fiber pH sensor based on lossy-mode resonances by means of thin polymeric coatings. Sens. Actuators, B: Chem. 155, 290–297 (2011). doi:10.​1016/​j.​snb.​2010.​12.​037 CrossRef
70.
C. Ruiz Zamarreño, P. Zubiate, M. Sagües, I.R. Matias, F.J. Arregui, Experimental demonstration of lossy mode resonance generation for transverse-magnetic and transverse-electric polarizations. Opt. Lett. 38, 2481–2483 (2013). doi:10.​1364/​OL.​38.​002481 CrossRef
71.
I. Del Villar, C.R. Zamarreno, M. Hernaez, F.J. Arregui, I.R. Matias, Lossy mode resonance generation with indium-tin-oxide-coated optical fibers for sensing applications. J. Lightwave Technol. 28, 111–117 (2010). doi:10.​1109/​JLT.​2009.​2036580 CrossRef
72.
73.
A.B. Socorro, I. Del Villar, J.M. Corres, F.J. Arregui, I.R. Matias, Spectral width reduction in lossy mode resonance-based sensors by means of tapered optical fibre structures. Sens. Actuators B: Chem. 200, 53–60 (2014). doi:10.​1016/​j.​snb.​2014.​04.​017 CrossRef
74.
L. Razquin, C.R. Zamarreno, F.J. Munoz, I.R. Matias, F.J. Arregui, Thrombin detection by means of an aptamer based sensitive coating fabricated onto LMR-based optical fiber refractometer, in 2012 IEEE Sensors (IEEE, 2012), pp. 1–4. doi:10.​1109/​ICSENS.​2012.​6411186
75.
C.R. Zamarreno, I. Ardaiz, L. Ruete, F.J. Munoz, I.R. Matias, F.J. Arregui, C-reactive protein aptasensor for early sepsis diagnosis by means of an optical fiber device, in 2013 IEEE Sensors (IEEE, 2013), pp. 1–4. doi:10.​1109/​ICSENS.​2013.​6688222
76.
P. Sanchez, P. Zubiate, F.J. Munoz, F.J. Arregui, I.R. Matias, C.R. Zamarreño, ​Lossy mode resonance-based aptasensor for CRP detection, 26th Anniversary World Congress on Biosensors. (Gothenburg, Sweden, 2016)
77.
P. Sanchez, C.R. Zamarreño, M. Hernaez, I.R. Matias, F.J. Arregui, Optical fiber refractometers based on lossy mode resonances by means of SnO2 sputtered coatings. Sens. Actuators B: Chem. 202, 154–159 (2014). doi:10.​1016/​j.​snb.​2014.​05.​065 CrossRef
78.
F.J. Arregui, I. Del Villar, C.R. Zamarreño, P. Zubiate, I.R. Matias, Giant sensitivity of optical fiber sensors by means of lossy mode resonance. Sens. Actuators B: Chem. (2016). doi:10.​1016/​j.​snb.​2016.​04.​015
79.
A.B. Socorro, J.M. Corres, I. Del Villar, F.J. Arregui, I.R. Matias, Immunoglobulin G biosensor based on lossy mode resonances generated on coated tapered optical fiber, Proc. Trends in Nanotechnology (TNT) 2012 Conference, (Phantoms Foundation, Madrid (Spain), 2012)
80.
81.
F. Chiavaioli, P. Biswas, C. Trono, A. Giannetti, S. Tombelli, S. Bandyopadhyay, et al., IgG/anti-IgG immunoassay based on a turn-around point long period grating, in SPIE BiOS, International Society for Optics and Photonics, ed. by T. Vo-Dinh, A. Mahadevan-Jansen, W.S. Grundfest (2014), p. 89350 V. doi:10.​1117/​12.​2039782
82.
F. Chiavaioli, P. Biswas, C. Trono, S. Bandyopadhyay, A. Giannetti, S. Tombelli et al., Towards sensitive label-free immunosensing by means of turn-around point long period fiber gratings. Biosens. Bioelectron. 60, 305–310 (2014). doi:10.​1016/​j.​bios.​2014.​04.​042 CrossRef
83.
L. Marques, F.U. Hernandez, S.W. James, S.P. Morgan, M. Clark, R.P. Tatam et al., Highly sensitive optical fibre long period grating biosensor anchored with silica core gold shell nanoparticles. Biosens. Bioelectron. 75, 222–231 (2016). doi:10.​1016/​j.​bios.​2015.​08.​046 CrossRef
84.
S.W. James, S. Korposh, S.W. Lee, R.P. Tatam. A long period grating-based chemical sensor insensitive to the influence of interfering parameters. Opt. Express 22(7), 8012–23 (2014). doi:10.​1364/​OE.​22.​008012. PubMed PMID: 24718176
85.
S. Korposh, R. Selyanchyn, W. Yasukochi, S.-W. Lee, S.W. James, R.P. Tatam, Optical fibre long period grating with a nanoporous coating formed from silica nanoparticles for ammonia sensing in water. Mater. Chem. Phys. 133, 784–792 (2012). doi:10.​1016/​j.​matchemphys.​2012.​01.​094 CrossRef
86.
G. Quero, S. Zuppolini, M. Consales, L. Diodato, P. Vaiano, A. Venturelli et al., Long period fiber grating working in reflection mode as valuable biosensing platform for the detection of drug resistant bacteria. Sens. Actuators B: Chem. 230, 510–520 (2016). doi:10.​1016/​j.​snb.​2016.​02.​086 CrossRef
87.
88.
89.
S. Demming, J. Vila-Planas, S. Aliasghar Zadeh, A. Edlich, E. Franco-Lara, R. Radespiel, et al., Poly(dimethylsiloxane) photonic microbioreactors based on segmented waveguides for local absorbance measurement. Electrophoresis. 32, 431–439 (2011). doi:10.​1002/​elps.​201000482
90.
H.K. Hunt, C. Soteropulos, A.M. Armani, Bioconjugation strategies for microtoroidal optical resonators. Sensors (Switzerland). 10, 9317–9336 (2010). doi:10.​3390/​s101009317 CrossRef
91.
92.
G. Quero, A. Crescitelli, D. Paladino, M. Consales, A. Buosciolo, M. Giordano et al., Evanescent wave long-period fiber grating within D-shaped optical fibers for high sensitivity refractive index detection. Sens. Actuators B: Chem. 152, 196–205 (2011). doi:10.​1016/​j.​snb.​2010.​12.​007 CrossRef
93.
A. Buosciolo, M. Consales, M. Pisco, A. Cusano, M. Giordano, Fiber-optic near-field chemical sensors based on wavelength scale tin dioxide particle layers. J. Lightwave Technol. 26, 3468–3475 (2008). doi:10.​1109/​JLT.​2008.​927792 CrossRef
94.
95.
A. Ricciardi, M. Consales, G. Quero, A. Crescitelli, E. Esposito, A. Cusano, Versatile optical fiber nanoprobes: from plasmonic biosensors to polarization-sensitive devices. ACS Photon. 1, 69–78 (2014). doi:10.​1021/​ph400075r CrossRef
96.
M. Consales, A. Ricciardi, A. Crescitelli, E. Esposito, A. Cutolo, A. Cusano, Lab-on-fiber technology: toward multifunctional optical nanoprobes. ACS Nano 6, 3163–3170 (2012). doi:10.​1021/​nn204953e CrossRef
Metadaten
Titel
Trends in Fibre-Optic Uses for Personal Healthcare and Clinical Diagnostics
verfasst von
A. B. Socorro
S. Díaz
Copyright-Jahr
2017
Buch
Fiber Optic Sensors

Print ISBN: 978-3-319-42624-2

Electronic ISBN: 978-3-319-42625-9

Copyright-Jahr: 2017

DOI
https://doi.org/10.1007/978-3-319-42625-9_6

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