Curve fitting in Fourier transform near infrared spectroscopy used for the analysis of bacterial cells
Infrared spectroscopy is a prominent molecular technique for bacterial analysis. Within its context, near infrared spectroscopy in particular brings benefits over other vibrational approaches; these advantages include, for example, lower sensitivity to water, high penetration depth and low cost. How...
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| Published in: | Journal of near infrared spectroscopy (United Kingdom) Vol. 25; no. 3; pp. 151 - 164 |
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SAGE Publications
01-06-2017
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| Abstract | Infrared spectroscopy is a prominent molecular technique for bacterial analysis. Within its context, near infrared spectroscopy in particular brings benefits over other vibrational approaches; these advantages include, for example, lower sensitivity to water, high penetration depth and low cost. However, near infrared spectroscopy is not popular within microbiology, because the spectra of organic samples are difficult to interpret. We propose a comparison of spectral curve-fitting methods, namely, techniques that facilitate the interpretation of most peaks, simplify the spectra and improve the prediction of bacterial species from the relevant near infrared spectra. The performances of three common curve-fitting algorithms and the technique based on the differential evolution were compared via a synthesized experimental spectrum. Utilizing the obtained results, the spectra of three different bacterial species were curve fit by optimized algorithm. The proposed algorithm decomposed the spectra to specific absorption peaks, whose parameters were estimated via the differential evolution approach initialized through Levenberg-Marquardt optimization; subsequently, the spectra were classified with conventional procedures and using the parameters of the revealed peaks. On a limited data set, the correct classification rate computed by partial least squares discriminant analysis was 95%. When we employed the peak parameters for the classification, the rate corresponded to 91.7%. According to the Gaussian formula, the parameters comprise the spectral peak position, amplitude and width. The most important peaks for bacterial discrimination were identified by analysis of variance and interpreted as N–H stretching bonds in proteins, cis bonds and CH2 absorption in fatty acids. We examined some aspects of the behaviour of standard curve-fitting algorithms and proposed differential evolution to optimize the fitting process. Based on the correct use of these algorithms, the near infrared spectra of bacteria can be interpreted and the full potential of near infrared spectroscopy in microbiology exploited. |
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| AbstractList | Infrared spectroscopy is a prominent molecular technique for bacterial analysis. Within its context, near infrared spectroscopy in particular brings benefits over other vibrational approaches; these advantages include, for example, lower sensitivity to water, high penetration depth and low cost. However, near infrared spectroscopy is not popular within microbiology, because the spectra of organic samples are difficult to interpret. We propose a comparison of spectral curve-fitting methods, namely, techniques that facilitate the interpretation of most peaks, simplify the spectra and improve the prediction of bacterial species from the relevant near infrared spectra. The performances of three common curve-fitting algorithms and the technique based on the differential evolution were compared via a synthesized experimental spectrum. Utilizing the obtained results, the spectra of three different bacterial species were curve fit by optimized algorithm. The proposed algorithm decomposed the spectra to specific absorption peaks, whose parameters were estimated via the differential evolution approach initialized through Levenberg-Marquardt optimization; subsequently, the spectra were classified with conventional procedures and using the parameters of the revealed peaks. On a limited data set, the correct classification rate computed by partial least squares discriminant analysis was 95%. When we employed the peak parameters for the classification, the rate corresponded to 91.7%. According to the Gaussian formula, the parameters comprise the spectral peak position, amplitude and width. The most important peaks for bacterial discrimination were identified by analysis of variance and interpreted as N-H stretching bonds in proteins, cis bonds and CH2 absorption in fatty acids. We examined some aspects of the behaviour of standard curve-fitting algorithms and proposed differential evolution to optimize the fitting process. Based on the correct use of these algorithms, the near infrared spectra of bacteria can be interpreted and the full potential of near infrared spectroscopy in microbiology exploited. Infrared spectroscopy is a prominent molecular technique for bacterial analysis. Within its context, near infrared spectroscopy in particular brings benefits over other vibrational approaches; these advantages include, for example, lower sensitivity to water, high penetration depth and low cost. However, near infrared spectroscopy is not popular within microbiology, because the spectra of organic samples are difficult to interpret. We propose a comparison of spectral curve-fitting methods, namely, techniques that facilitate the interpretation of most peaks, simplify the spectra and improve the prediction of bacterial species from the relevant near infrared spectra. The performances of three common curve-fitting algorithms and the technique based on the differential evolution were compared via a synthesized experimental spectrum. Utilizing the obtained results, the spectra of three different bacterial species were curve fit by optimized algorithm. The proposed algorithm decomposed the spectra to specific absorption peaks, whose parameters were estimated via the differential evolution approach initialized through Levenberg-Marquardt optimization; subsequently, the spectra were classified with conventional procedures and using the parameters of the revealed peaks. On a limited data set, the correct classification rate computed by partial least squares discriminant analysis was 95%. When we employed the peak parameters for the classification, the rate corresponded to 91.7%. According to the Gaussian formula, the parameters comprise the spectral peak position, amplitude and width. The most important peaks for bacterial discrimination were identified by analysis of variance and interpreted as N–H stretching bonds in proteins, cis bonds and CH 2 absorption in fatty acids. We examined some aspects of the behaviour of standard curve-fitting algorithms and proposed differential evolution to optimize the fitting process. Based on the correct use of these algorithms, the near infrared spectra of bacteria can be interpreted and the full potential of near infrared spectroscopy in microbiology exploited. |
| Author | Pytel, Roman Roger, Jean-Michel Krepelka, Pavel Drexler, Petr Hynstova, Iveta Pérez-Rodríguez, Fernando |
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| Cites_doi | 10.4315/0362-028X-67.11.2555 10.1128/JCM.01881-09 10.1109/CGIV.2010.18 10.1093/oso/9780195099713.001.0001 10.1366/0003702884429869 10.1021/ac60214a047 10.1021/ed039p333 10.1111/j.1574-6968.1995.tb07393.x 10.1080/00401706.1975.10489269 10.1007/s12161-011-9221-5 10.1016/j.bbamem.2008.08.025 10.1007/BFb0008734 10.1007/978-3-642-28738-1 10.1007/s00269-010-0388-x 10.1255/jnirs.778 10.1145/2463372.2463392 10.1080/05704929608000571 10.1002/cem.785 10.1255/jnirs.253 10.1099/00221287-137-1-69 10.1021/jf000776j 10.1016/j.fm.2005.01.001 10.1137/1.9780898719857 10.1016/j.bbamem.2007.06.007 10.1255/jnirs.325 10.1002/0470047704 10.1007/978-3-540-28645-5_41 10.1111/j.1574-6976.2007.00094.x 10.1021/ac00289a029 10.1201/9781420018318 10.1111/j.1745-4581.2008.00117.x |
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| Keywords | spectral decomposition near infrared spectroscopy microbiology curve fitting classification Bacterial identification SPECTRAL DECOMPOSITION MATRIX PEPTIDOGLYCAN STRUCTURE CURVE FITTING ARCHITECTURE CHEMISTRY MULTIVARIATE-ANALYSIS IDENTIFICATION BACTERIAL IDENTIFICATION LEAST-SQUARES |
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| References | Wesley 1999; 7 Barker, Rayens 2003; 17 Naumann 2000 AL-Qadiri 2008; 16 Honigs, Hieftje, Mark 1985; 57 Helm, Naumann 1995; 126 Cámara-Martos, Zurera-Cosano, Moreno-Rojas 2012; 5 Isaksson, Naes 1988; 42 Katsumoto, Adachi, Sato 2002; 10 Workman 1996; 31 Helm, Labischinski, Schallehn 1991; 137 Swinehart 1962; 39 Rodriguez-Saona, Khambaty, Fry 2001; 49 Vollmer, Bertsche 2008; 1778 Disalvo 2008; 1778 Olsson, Nelson 1975; 17 Rodriguez-Saona, Khambaty, Fry 2004; 67 Savitzky, Golay 1964; 36 Vienvilay Phandanouvong, Liliana Betancourt, Fernando Rodriguez 2010; 15 Koljonen, Nordling, Alander 2008; 16 Vollmer, Blanot, De Pedro 2008; 32 bibr17-0967033517705032 bibr21-0967033517705032 Osborne BG (bibr39-0967033517705032) 1993 bibr34-0967033517705032 Vienvilay Phandanouvong L (bibr1-0967033517705032) 2010; 15 Naumann D (bibr6-0967033517705032) 2000 Baron S (bibr19-0967033517705032) 1996 bibr8-0967033517705032 bibr20-0967033517705032 bibr4-0967033517705032 bibr26-0967033517705032 bibr5-0967033517705032 bibr35-0967033517705032 bibr22-0967033517705032 bibr18-0967033517705032 bibr9-0967033517705032 bibr14-0967033517705032 bibr27-0967033517705032 bibr10-0967033517705032 bibr28-0967033517705032 bibr15-0967033517705032 bibr23-0967033517705032 bibr36-0967033517705032 bibr31-0967033517705032 bibr2-0967033517705032 bibr32-0967033517705032 bibr37-0967033517705032 bibr24-0967033517705032 bibr11-0967033517705032 bibr30-0967033517705032 bibr16-0967033517705032 bibr33-0967033517705032 bibr38-0967033517705032 Jeremy IP (bibr25-0967033517705032) 2012 bibr3-0967033517705032 bibr29-0967033517705032 bibr7-0967033517705032 Naes T (bibr13-0967033517705032) 2002 bibr12-0967033517705032 |
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| Title | Curve fitting in Fourier transform near infrared spectroscopy used for the analysis of bacterial cells |
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