Real-time fluorescence measurement of airborne bacterial particles using an aerosol fluorescence sensor with dual ultraviolet- and visible-fluorescence channels

Environmental Engineering Science

Volumn 29, Issue 10, 2012, Pages 987-993

  Jung, Jae Hee ^a   Lee, Jung Eun ^b   Bae, Gwi Nam ^a  

^a Korea Institute of Science and Technology   (South Korea)

^b Seoul National University   (South Korea)

Author keywords

aerosol fluorescence sensor; bioaerosol; fluorescence; real time detection

Indexed keywords

AIRBORNE BIOLOGICAL PARTICLES; AMBIENT ENVIRONMENT; BACILLUS SUBTILIS; BIO-AEROSOL DETECTIONS; BIOAEROSOLS; BIOLOGICAL AEROSOL; COEFFICIENT OF VARIANCE; DETECTION VOLUME; DYNAMIC MEASUREMENT; E. COLI; EXCITATION LIGHT; FLUORESCENCE CHARACTERISTICS; FLUORESCENCE INTENSITIES; FLUORESCENCE MEASUREMENTS; FLUORESCENCE METHOD; FLUORESCENCE SENSORS; GAIN SETTINGS; INTRINSIC FLUORESCENCE; LIGHT INDUCED FLUORESCENCE; LIVING MATTER; MONITORING DEVICE; PARTICLE CONCENTRATIONS; PHOTOMULTIPLIER DETECTORS; POLYSTYRENE LATEXES; REAL-TIME DETECTION; SUBTILIS; ULTRA-VIOLET; UV FLUORESCENCE; UV- AND;

AEROSOLS; AMINO ACIDS; ESCHERICHIA COLI; PHOTOEXCITATION; POLYSTYRENES; SENSORS; SIGNAL DETECTION;

FLUORESCENCE;

POLYSTYRENE;

AEROSOL; AEROSOL FLUORESCENCE SENSOR; AIRBORNE BACTERIUM; AIRBORNE PARTICLE; ARTICLE; BACILLUS SUBTILIS; ESCHERICHIA COLI; LIGHT; NONHUMAN; PARTICLE SIZE; SENSOR; ULTRAVIOLET RADIATION;

BACILLUS SUBTILIS; BACTERIA (MICROORGANISMS); ESCHERICHIA COLI;

EID: 84869008247     PISSN: 10928758     EISSN: 15579018     Source Type: Journal    
DOI: 10.1089/ees.2011.0449     Document Type: Article

References (47)

1. Agranovski, V., Ristovski, Z., Hargreaves, M., Blackall, P.J., and Morawska, L. (2003a). Performance evaluation of the UVAPS: influence of physiological age of airborne bacteria and bacterial stress. J. Aerosol Sci. 34, 1711.
2. Agranovski, V., Ristovski, Z., Hargreaves, M., Blackall, P.J., and Morawska, L. (2003b). Real-time measurement of bacterial aerosols with the UVAPS: performance evaluation. J. Aerosol Sci. 34, 301.
3. Burge, H. (1990). Bioaerosols: prevalence and health effects in the indoor environment. J. Allergy Clin. Immunol. 86, 687.
4. Chadha, S., Nelson, W.H., and Sperry, J.F. (1993). Ultraviolet micro Raman spectrograph for the detection of small numbers of bacterial cells. Rev. Sci. Instrum. 64, 3088.
5. Chen, G., Nachman, P., Pinnick, R.G., Hill, S.C., and Chang, R.K. (1996). Conditional-firing aerosol-fluorescence spectrum analyzer for individual airborne particles with pulsed 266-nm laser excitation. Opt. Lett. 21, 1307.
6. Chen, P., and Li, C. (2007). Real-time monitoring for bioaerosolsflow cytometry. Analyst 132, 14.
7. Cheng, Y.S., Barr, E.B., Fan, B.J., Hargis, P.J., Rader, D.J., ÓHern, T.J., Torczynski, J.R., Tisone, G.C., Preppernau, B.L., Young, S.A., et al. (1999). Detection of bioaerosols using multiwavelength UV fluorescence spectroscopy. Aerosol Sci. Technol. 30, 186.
8. Cox, C.S., and Wathes, C.M. (1995). Bioaerosols Hand book. Boca Raton, FL: Lewis Publishers.
9. Czerwieniec, G.A., Russell, S.C., Tobias, H.J., Pitesky, M.E., Fergenson, D.P., Steele, P., Srivastava, A., Horn, J.M., Frank, M., and Gard, E.E. (2005). Stable isotope labeling of entire Bacillus atrophaeus spores and vegetative cells using bioaerosol mass spectrometry. Anal. Chem. 77, 1081.
10. Fergenson, D.P., Pitesky, M.E., Tobias, H.J., Steele, P.T., Czerwieniec, G.A., Russell, S.C., Lebrilla, C.B., Horn, J.M., Coffee, K.R., and Srivastava, A. (2004). Reagentless detection and classification of individual bioaerosol particles in seconds. Anal. Chem. 76, 373.
11. Hairston, P.P., Ho, J., and Quant, F.R. (1997). Design of an instrument for real-time detection of bioaerosols using simultaneous measurement of particle aerodynamic size and intrinsic fluorescence. J. Aerosol Sci. 28, 471.
12. Hill, S.C., Pinnick, R.G., Nachman, P., Chen, G., Chang, R.K., Mayo, M.W., and Fernand ez, G.L. (1995). Aerosol-fluorescence spectrum analyzer: Real-time measurement of emission-spectra of airborne biological particles. Appl. Opt. 34, 7149.
13. Ho, J. (2002). Future of biological aerosol detection. Anal. Chim. Acta 457, 125.
14. Ho, J., Spence, M., and Hairston, P. (1999). Measurement of biological aerosol with a fluorescent aerodynamic particle sizer (FLAPS): Correlation of optical data with biological data. Aerobiologia 15, 281.
15. Hong, S.R., Choi, S.J., Jeong, H.D., and Hong, S. (2009). Development of QCM biosensor to detect a marine derived pathogenic bacteria Edwardsiella tarda using a novel immobilisation method. Biosens. Bioelectron. 24, 1635.
16. Huang, L., and Juneja, V.K. (2001). A new kinetic model for thermal inactivation of microorganisms: Development and validation using Escherichia coli O157:H7 as a test organism. J. Food Prot. 64, 2078.
17. Jung, J.H., Hwang, G.B., Park, S.Y., Lee, J.E., Nho, C.W., Lee, B.U., and Bae, G.N. (2011a). Antimicrobial air filtration using airborne Sophora flavescens natural-product nanoparticles. Aerosol Sci. Technol. 45, 1510.
18. Jung, J.H., Lee, J.E., and Bae, G.W. (2011b). Real-time measurement of UV-inactivated Escherichia coli bacterial particles by electrospray-assisted UVAPS spectrometry. Sci. Total Environ. 409, 3249.
19. Jung, J.H., Lee, J.E., Hwang, G.B., Lee, B.U., Lee, S.B., Jurng, J.S., and Bae, G.N. (2010a). Electrospray-assisted ultraviolet aerodynamic particle sizer spectrometer for real-time characterization of bacterial particles. Anal. Chem. 82, 664.
20. Jung, J.H., Lee, J.E., and Kim, S.S. (2009). Thermal effects on bacterial bioaerosols in continuous air flow. Sci. Total Environ. 407, 301.
21. Jung, J.H., Lee, J.E., Kim, S.S., and Bae, G.N. (2010b). Size reduction of Aspergillus versicolor fungal bioaerosols during a thermal heating process in continuous-flow system. J. Aerosol Sci. 41, 602.
22. Kaye, P., Stanley, W., Hirst, E., Foot, E., Baxter, K., and Barrington, S. (2005). Single particle multichannel bio-aerosol fluorescence sensor. Opt. Express 13, 3583.
23. Kaye, P.H., Hirst, E., Foot, V., Clark, J.M., and Baxter, K. (2004). A low-cost multi-channel aerosol fluorescence sensor for networked deployment. Proc. SPIE 5617, 388.
24. Lee, B.U., Yun, S.H., Jung, J.H., and Bae, G.N. (2010). Effect of relative humidity and variation of particle number size distribution on the inactivation effectiveness of airborne silver nanoparticles against bacteria bioaerosols deposited on a filter. J. Aerosol Sci. 41, 447.
25. Li, J.K., Asali, E.C., Humphrey, A.E., Horvath, J.J. (1991). Monitoring cell concentration and activity by multiple excitation fluorometry. Biotechnol. Prog. 7, 21.
26. Li, S., Orona, L., Li, Z., and Cheng, Z.Y. (2006). Biosensor based on magnetostrictive microcantilever. Appl. Phys. Lett. 88, 073507.
27. Madigan, M.T., Martinko, J.M., and Parker, J. (2003). Brock Biology of Microorganisms. Upper Saddle River, NJ: Prentice Hall.
28. Maquelin, K., van Vreeswijk, T., Endtz, H.P., Smith, B., Bennett, R., Bruining, H.A., and Puppels, G.J. (2000). Raman spectroscopic method for identification of clinically relevant microorganisms growing on solid culture medium. Anal. Chem. 72, 12.
29. Murray, P.R., Baron, E.J., and Pfaller, M.A. (2003). Manual of Clinical Microbiology. New York: American Society for Microbiology.
30. Nachman, P., Chen, G., Pinnick, R.G., Hill, S.C., Chang, R.K., Mayo, M.W., and Fernand ez, G.L. (1996). Conditionalsampling spectrograph detection system for fluorescence measurements of individual airborne biological particles. Appl. Opt. 35, 1069.
31. Nicas, M., and Hubbard, A. (2003). A risk analysis approach to selecting respiratory protection against airborne pathogens used for bioterrorism. AIHA J. 64, 95.
32. Palaniappan, S., Sastry, S.K., and Richter, E.R. (1992). Effects of electroconductive heat treatment and electrical pretreatment on thermal death kinetics of selected microorganisms. Biotechnol. Bioeng. 39, 225.
33. Pan, Y.L., Boutou, V., Bottiger, J.R., Zhang, S.S., Wolf, J.P., and Chang, R.K. (2004). A puff of air sorts bioaerosols for pathogen identification. Aerosol Sci. Technol. 38, 598.
34. Pan, Y.L., Holler, S., Chang, R.K., Hill, S.C., Pinnick, R.G., Niles, S., and Bottiger, J.R. (1999). Single-shot fluorescence spectra of individual micrometer-sized bioaerosols illuminated by a 351- or a 266-nm ultraviolet laser. Opt. Lett. 24, 116.
35. Park, I.S., Kim, W.Y., and Kim, N. (2000). Operational characteristics of an antibody-immobilized QCM system detecting Salmonella spp. Biosens. Bioelectron. 15, 167.
36. Peters, T.M., and Leith, D. (2003). Concentration measurement and counting efficiency of the aerodynamic particle sizer 3321. J. Aerosol Sci. 34, 627.
37. Pinnick, R.G., Hill, S.C., Nachman, P., Pendleton, J.D., Fernand ez, G.L., Mayo, M.W., and Bruno, J.G. (1995). Fluorescence particle counter for detecting airborne bacteria and other biological particles. Aerosol Sci. Technol. 23, 653.
38. Pinnick, R.G., Hill, S.C., Nachman, P., Videen, G., Chen, G., and Chang, R.K. (1998). Aerosol fluorescence spectrum analyzer for rapid measurement of single micrometer-sized airborne biological particles. Aerosol Sci. Technol. 28, 95.
39. Poitras, C., and Tufenkji, N. (2009). A QCM-D-based biosensor for E. coli O157: H7 highlighting the relevance of the dissipation slope as a transduction signal. Biosens. Bioelectron. 24, 2137.
40. Roüsch, P., Harz, M., Schmitt, M., Peschke, K.D., Ronneberger, O., Burkhardt, H., Motzkus, H.W., Lankers, M., Hofer, S., Thiele, H., et al. (2005). Chemotaxonomic identification of single bacteria by micro-Raman spectroscopy: application to cleanroom- relevant biological contaminations. Appl. Environ. Microbiol. 71, 1626.
41. Roszak, D.B., and Colwell, R.R. (1987). Survival strategies of bacteria in the natural environment. Microbiol. Mol. Biol. Rev. 51, 365.
42. Seaver, M., Eversole, J.D., Hardgrove, J.J., Cary, W.K., and Roselle, D.C. (1999). Size and fluorescence measurements for field detection of biological aerosols. Aerosol Sci. Technol. 30, 174.
43. Stowers, M.A., Van Wuijckhuijse, A.L., Marijnissen, J.C.M., Scarlett, B., Van Baar, B.L.M., and Kientz, C.E. (2000). Application of matrix-assisted laser desorption/ionization to on-line aerosol time-of-flight mass spectrometry. Rapid Commun. Mass Spectrom. 14, 829.
44. Tobias, H.J., Schafer, M.P., Pitesky, M., Fergenson, D.P., Horn, J., Frank, M., and Gard, E.E. (2005). Bioaerosol mass spectrometry for rapid detection of individual airborne Mycobacterium tuberculosis H37Ra particles. Appl. Environ. Microbiol. 71, 6086.
45. Van Wuijckhuijse, A.L., Stowers, M.A., Kleefsman, W.A., Van Baar, B.L.M., Kientz, C.E., and Marijnissen, J.C.M. (2005). Matrix-assisted laser desorption/ionisation aerosol time-offlight mass spectrometry for the analysis of bioaerosols: development of a fast detector for airborne biological pathogens. J. Aerosol Sci. 36, 677.
46. Varma, J.K., Greene, K.D., Reller, M.E., DeLong, S.M., Trottier, J., Nowicki, S.F., DiOrio, M., Koch, E.M., Bannerman, T.L., and York, S.T. (2003). An outbreak of Escherichia coli O157 infection following exposure to a contaminated building. JAMA 290, 2709.
47. Yao, M., and Mainelis, G. (2006). Effect of physical and biological parameters on enumeration of bioaerosols by portable microbial impactors. J. Aerosol Sci. 37, 1467.