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Fluctuation-Enhanced Sensing with Organically Functionalized Gold Nanoparticle Gas Sensors Targeting Biomedical Applications

Abstract

Detection of volatile organic compounds is a useful approach to non-invasive diagnosis of diseases through breath analysis. Our experimental study presents a newly developed prototype gas sensor, based on organically-functionalized gold nanoparticles, and results on formaldehyde detection using fluctuation-enhanced gas sensing. Formaldehyde was easily detected via intense fluctuations of the gas sensor’s resistance, while the cross-influence of ethanol vapor (a confounding factor in exhaled breath, related to alcohol consumption) was negligible.

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Category:
Articles
Type:
artykuł w czasopiśmie wyróżnionym w JCR
Published in:
TALANTA.The International Journal of Pure and Applied Analytical Chemistry no. 160, pages 9 - 14,
ISSN: 0039-9140
Publication year:
2016
Bibliographic description:
Lentka Ł., Kotarski M., Smulko J., Cindemir U., Topalian Z., Granqvist C., Calavia R., Ionescu R.: Fluctuation-Enhanced Sensing with Organically Functionalized Gold Nanoparticle Gas Sensors Targeting Biomedical Applications// TALANTA. -Vol. 160, (2016), s.9-14
DOI:
Digital Object Identifier (open in new tab) 10.1016/j.talanta.2016.06.063
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  1. M. Hakim, Y.Y. Broza, O. Barash, N. Peled, M. Phillips, A. Amann, H. Haick, Volatile organic compounds of lung cancer and possible biochemical pathways, Chem. Rev. 112 (2012) 5949-5966. open in new tab
  2. P. Mazzone, Progress in the development of a diagnostic test for lung cancer through the analysis of breath volatiles, J. Breath Res. 2 (2008) 037014. open in new tab
  3. G. Peng, U. Tisch, O. Adams, M. Hakim, N. Shehada, Y.Y. Broza, S. Billan, R. Abdah-Bortnyak, A. Kuten, H. Haick, Diagnosing lung cancer in exhaled breath using gold nanoparticles, Nat. Nanotechnol. 4 (2009) 669-73. open in new tab
  4. P. Fuchs, C. Loeseken, J.K. Schubert, W. Miekisch, Breath gas aldehydes as biomarkers of lung cancer, Int. J. Cancer 126 (2010) 2663-2670. open in new tab
  5. P. Španěl, D. Smith, Quantification of trace levels of the potential cancer biomarkers formaldehyde, acetaldehyde and propanol in breath by SIFT-MS, J. Breath Res. 2 (2008) 046003. open in new tab
  6. M.K. Nakhleh, Y.Y. Broza, H. Haick, Monolayer-capped gold nanoparticles for disease detection from breath, Nanomedicine 9 (2014) 1991-2002. open in new tab
  7. E. Ozawa, Y. Kawakami, T. Seto, T. Formation and size control of tungsten nanoparticles produced by Nd: YAG laser irradiation, Scr. Mater. 44 (2001) 2279- 2283. open in new tab
  8. D. Buso, M. Post, C. Cantalini, P. Mulvaney, A. Martucci, Gold nanoparticle- doped TiO₂ semiconductor thin films: Gas sensing properties, Adv. Funct. Mater. 18 (2008) 3843-3849. open in new tab
  9. S. Vallejos, T. Stoycheva, P. Umek, C. Navio, R. Snyders, C. Bittencourt, E.
  10. Llobet, Ch. Blackman, S. Moniz, X. Correig, Au nanoparticle-functionalised WO3 11
  11. nanoneedles and their application in high sensitivity gas sensor devices, Chem. Commun. 47 (2011) 565-567. open in new tab
  12. P. Weisz, Effects of electronic charge transfer between adsorbate and solid on chemisorption and catalysis, J. Chem. Phys. 21 (1953) 1531-1538. open in new tab
  13. L. Kish, R. Vajtai, C. Granqvist, Extracting information from noise spectra of chemical sensors: single sensor electronic noses and tongues, Sens. Actuators B 71 (2000) 55-59. open in new tab
  14. M.M. Kotarski, J.M. Smulko, Hazardous gases detection by fluctuation-enhanced gas sensing, Fluct. Noise Lett. 9 (2010) 359-371. open in new tab
  15. J. Ederth, J. Smulko, L.B. Kish, P. Heszler, C.G. Granqvist, Comparison of classical and fluctuation-enhanced gas sensing with PdxWO3 nanoparticle films, Sens. Actuators B 113 (2006) 310-315. open in new tab
  16. M. Brust, J. Fink, D. Bethell, D. Schiffrin, C. Kiely, Synthesis and reactions of functionalised gold nanoparticles, J. Chem. Soc., Chem. Commun. 16 (1995) 1655- 1656. open in new tab
  17. J. Guo, P. Pang, Q. Cai, Effect of trace residual ionic impurities on the response of chemiresistor sensors with dithiol-linked monolayer-protected gold (nano) clusters as sensing interfaces, Sens. Actuators B 120 (2007) 521-528. open in new tab
  18. C. Granqvist, R. Buhrman, Ultrafine metal particles, J. Appl. Phys. 47 (1976) 2200- 2219. open in new tab
  19. J.S. Bendat, A.G. Piersol, Random data: analysis and measurement procedures, John Wiley & Sons, 2011. open in new tab
  20. J. Solis, L. Kish, R. Vajtai, C. Granqvist, J. Olsson, J. Schnürer, V. Lantto, Identifying natural and artificial odours through noise analysis with a sampling- and-hold electronic nose, Sens. Actuators B 77 (2001) 312-315. 12 open in new tab
  21. B. Ayhan, C. Kwan, J. Zhou, L.B. Kish, K.D. Benkstein, P.H. Rogers, S. Semancik, Fluctuation enhanced sensing (FES) with a nanostructured, semiconducting metal oxide film for gas detection and classification, Sens. Actuators B 188 (2013) 651- 660. open in new tab
  22. K.K. Hung, H. Chenming, Y.C. Cheng, Random telegraph noise of deep- submicrometer MOSFETs, IEEE Electron. Device Lett. 11 (1990) 90-92. open in new tab
  23. T. Otto, H. Eichenbaum, C.G. Wible, S.I. Wiener, Learning-related patterns of CA1 spike trains parallel stimulation parameters optimal for inducing hippocampal long- term potentiation, Hippocampus 1 (1991) 181-192. open in new tab
  24. Ł. Lentka, J.M. Smulko, R. Ionescu, C.G. Granqvist, L.B Kish, Determination of gas. mixture components using fluctuation enhanced sensing and the LS-SVM regression algorithm, Metrol. Meas. Syst. 22 (2015) 341-350. open in new tab
  25. R. Macku, J. Smulko, P. Koktavy, M. Trawka, P. Sedlak, Analytical fluctuation enhanced sensing by resistive gas sensors, Sens. Actuators B 213 (2015) 390-396. open in new tab
  26. Y. Kawakami, T. Seto, T. Yoshida, E. Ozawa, Gold nanoparticles and films produced by a laser ablation/gas deposition (LAGD) method, Appl. Surf. Sci. 197 (2002) 587-593. open in new tab
  27. O. Kvitek, R. Hendrych, Z. Kolska, V. Svorcik, Grafting of gold nanoparticles on glass using sputtered gold interlayers, J. Chem. 258 (2012) 8991-8995. open in new tab
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