The monitoring of biopharmaceutical products using Fourier transform infrared (FT-IR) spectroscopy relies on calibration techniques involving the acquisition of spectra of bioprocess samples along the process. The most commonly used method for that purpose is partial least squares (PLS) regression, under the assumption that a linear model is valid. Despite being successful in the presence of small nonlinearities, linear methods may fail in the presence of strong nonlinearities. This paper studies the potential usefulness of nonlinear regression methods for predicting, from in situ near-infrared (NIR) and mid-infrared (MIR) spectra acquired in high-throughput mode, biomass and plasmid concentrations in Escherichia coli DH5-α cultures producing the plasmid model pVAX-LacZ. The linear methods PLS and ridge regression (RR) are compared with their kernel (nonlinear) versions, kPLS and kRR, as well as with the (also nonlinear) relevance vector machine (RVM) and Gaussian process regression (GPR). For the systems studied, RR provided better predictive performances compared to the remaining methods. Moreover, the results point to further investigation based on larger data sets whenever differences in predictive accuracy between a linear method and its kernelized version could not be found. The use of nonlinear methods, however, shall be judged regarding the additional computational cost required to tune their additional parameters, especially when the less computationally demanding linear methods herein studied are able to successfully monitor the variables under study.
MercierS.M.DierpenbroekB.WijffelsR.H.StreeflendM.“Multivariate PAT Solutions for Biopharmaceutical Cultivation: Current Progress and Limitations”. Trends Biotechnol2014; 32(6): 329–336.
2.
WhelanJ.CravenS.GlennonB.“In Situ Raman Spectroscopy for Simultaneous Monitoring of Multiple Process Parameters in Mammalian Cell Culture Bioreactors”. Biotechnol. Prog2012; 28(5): 1355–1362.
3.
GlasseyJ.GernaeyK.V.ClemensC.SchulzT.W.OliveiraR.StriednerG.MandeniusC.-F.“Process Analytical Technology (PAT) for Biopharmaceuticals”. Biotechnol. J2011; 6: 369–377.
4.
BhambureR.KumarK.RathoreA.S.“High-Throughput Process Development for Biopharmaceutical Drug Substances”. Trends Biotechnol2011; 29(3): 127–135.
5.
ÜndeyC.ErtuncS.MistrettaT.LoozeB.“Applied Advanced Process Analytics in Biopharmaceutical Manufacturing: Challenges and Prospects in Real-Time Monitoring and Control”. J. Process Contr2010; 20: 1009–1018.
6.
LopesM.B.GonçalvesG.A.L.Felício-SilvaD.PratherK.L.J.MonteiroG.A.PrazeresD.M.F.CaladoC.R.C.“In Situ NIR Spectroscopy Monitoring of Plasmid Production Processes: Effect of Producing Strain, Medium Composition and the Cultivation Strategy”. Chem. Technol. Biotechnol2015; 90: 255–261.
7.
SalesK.C.RosaF.SampaioP.N.FonsecaL.P.LopesM.B.CaladoC.R.C.“In Situ Near-Infrared (NIR) Versus High-Throughput Mid-Infrared (MIR) Spectroscopy to Monitor Biopharmaceutical Production”. Appl. Spectrosc2015; 69: 760–772.
8.
SampaioP.N.SalesK.C.RosaF.O.LopesM.B.CaladoC.R.C.“In Situ Near Infrared Spectroscopy Monitoring of Cyprosin Production by Recombinant Saccharomyces cerevisiae Strains”. J. Biotechnol2014; 188C: 148–157.
9.
ScholzT.LopesV.V.CaladoC.R.C.“High-Throughput Analysis of the Plasmid Bioproduction Process in Escherichia coli by FTIR Spectroscopy”. Biotechnol. Bioeng2012; 109: 2279–2285.
10.
NavrátilM.NorbergA.LembrénL.MandeniusC.F.“On-Line Multi-Analyzer Monitoring of Biomass, Glucose and Acetate for Growth Rate Control of a Vibrio cholerae, Fed-Batch Cultivation”. J. Biotechnol2005; 115: 67–79.
11.
KornmannH.ValentinottiS.DubocP.MarisonI.von StockarU.“Monitoring and Control of Gluconacetobacter xylinus Fed-Batch Cultures Using In Situ Mid-IR Spectroscopy”. J. Biotechnol2004; 113: 231–245.
12.
TosiS.RossiM.TamburiniE.VaccariG.AmarettiA.MatteuzziD.“Assessment of In-Line Near-Infrared Spectroscopy for Continuous Monitoring of Fermentation Processes”. Biotechnol. Prog2003; 19: 1816–1821.
13.
TamburiniE.VaccariG.TosiS.TrilliA.“Near-Infrared Spectroscopy: A Tool for Monitoring Submerged Fermentation Processes Using an Immersion Optical-Fiber Probe”. Appl. Spectrosc2003; 57: 132–138.
14.
ArnoldS.A.CrowleyJ.WoodsN.HarveyL.M.McNeillB.“In-Situ Near Infrared Spectroscopy to Monitor Key Analytes in Mammalian Cell Cultivation”. Biotechnol. Bioeng2003; 84: 13–19.
15.
ArnoldS.A.GaensakooR.HarveyL.M.McNeilB.“Use of At-Line and In-Situ Near-Infrared Spectroscopy to Monitor Biomass in an Industrial Fed-Batch Escherichia coli Process”. Biotechnol. Bioeng2002; 80: 405–413.
16.
CimanderC.MandeniusC.-F.“Online Monitoring of a Bioprocess Based on a Multi-Analyser System and Multivariate Statistical Process Modeling”. J. Chem. Technol. Biotechnol2002; 77: 1157–1168.
17.
Arenas-GarcíaJ.PetersenK.B.Camps-VallsG.HansenL.K.“Kernel Multivariate Analysis Framework for Supervised Subspace Learning”. IEEE Signal. Proc. Mag2013; 30: 16–29.
18.
H. Wold. “Path Models with Latent Variables: The NIPALS Approach”. In: H.M. Blalock, editor. Quantitative Sociology: International Perspectives on Mathematical and Statistical Model Building. New York: Academic Press, 1975. Pp 307–357.
19.
WoldS.RuheA.WoldH.DunnW.J.III. “The Collinearity Problem in Linear Regression. The Partial Least Squares (PLS) Approach to Generalized Inverses”. SIAM J. Sci. Stat. Comput1984; 5: 735–743.
20.
WoldS.SjöströmL.ErikssonL.“PLS-Regression: A Basic Tool of Chemometrics”. Chemom. Intell. Lab. Syst2001; 58: 109–130.
21.
LourençoN.D.LopesJ.A.AlmeidaC.F.SarraguçaM.C.PinheiroH.M.“Bioreactor Monitoring with Spectroscopy and Chemometrics: A Review”. Anal. Bioanal. Chem2012; 404(4): 1211–1237.
22.
RoggoY.ChalusP.MaurerL.Lema-MartinezC.EdmondA.JentN.“A Review of Near Infrared Spectroscopy and Chemometrics in Pharmaceutical Technologies”. J. Pharm. Biomed. Anal2007; 44: 683–700.
23.
PrietoN.RoeheR.LavínP.BattenG.AndrésS.“Application of Near Infrared Reflectance Spectroscopy to Predict Meat and Meat Products Quality: A Review”. Meat Sci2009; 83: 175–186.
24.
TibshiraniR.“Regression Shrinkage and Selection Via the Lasso”. J. Roy. Stat. Soc. B Stat. Meth1996; 58: 267–288.
25.
ZouH.HastieT.“Regularization and Variable Selection Via the Elastic Net”. J. Roy. Stat. Soc. B. Stat. Meth2005; 67: 301–320.
26.
ChenZ.MorrisJ.“Process Analytical Technology and Compensating for Nonlinear Effects in Process Spectroscopic Data for Improved Process Monitoring and Control”. Biotechnol. J2009; 4: 610–619.
27.
HellandI.S.NaesT.IsakssonT.“Related Versions of the Multiplicative Scatter Correction Method for Preprocessing Spectroscopic Data”. Chemom. Intell. Lab. Syst2001; 29: 233–241.
28.
RannarS.LindgrenF.GeladiP.WoldS.“A PLS Kernel Algorithm for Data Sets with Many Variables and Fewer Objects. J. Chemom1994; 8: 111–125.
29.
LindgrenF.GeladiP.WoldS.“The Kernel Algorithm for PLS”. J. Chemom1993; 7: 45–59.
30.
NicolaïB.M.TheronK.I.LammertynJ.“Kernel PLS Regression on Wavelet Transformed NIR Spectra for Prediction of Sugar Content of Apple”. Chemom. Intell. Lab. Syst2007; 85: 243–252.
31.
WalczakB.MassardD.L.“The Radial Basis Functions - Partial Least Squares Approach as a Flexible Non-Linear Regression Technique”. Anal. Chim. Acta1996; 331(3): 177–185.
32.
WalczakB.MassardD.L.“Application of Radial Basis Functions - Partial Least Squares to Non-Linear Pattern Recognition Problems: Diagnosis of Process Faults”. Anal. Chim. Acta1996; 331: 187–193.
33.
RosipalR.TrejoL.“Kernel Partial Least Squares Regression in Reproducing Kernel Hilbert Space”. J. Mach. Learn. Res2001; 2: 97–123.
34.
M. Momma, K. Bennett. “Sparse Kernel Partial Least Squares Regression”. In: Proceedings of the Conference on Learning Theory (COLT 2003), Washington, DC, USA, August, 2003. Lecture Notes in Computer Science. 2003. Berlin: Springer. Pp. 216–230.
35.
J. Arenas-García, K.B. Petersen, L.K. Hansen. “Sparse Kernel Orthonormalized PLS for Feature Extraction in Large Data Sets”. In: B. Schölkopf, J.C. Platt, T. Hofmann, editors. Advances in Neural Information Processing Systems. Cambridge, MA: MIT Press. 2007. Pp. 33–40.
36.
J. Arenas-García, G. Camps-Valls. “Feature Extraction from Remote Sensing Data using Kernel Orthonormalized PLS”. In: Proceedings of IEEE IGARSS. 2007. Barcelona: IEEE. Pp. 258–261.
M. Tipping. “The Relevance Vector Machine”. In: S.A. Solla, T.K. Leen, K.-R. Müller, editors. Advances in Neural Information Processing Systems. Cambridge, MA: MIT Press, 2000. Pp. 652–658.
39.
TippingM.E.“Sparse Bayesian Learning and the Relevance Vector Machine”. J. Mach. Learning Res2001; 1: 211–244.
40.
C.E. Rasmussen, C.K.I. Williams. Gaussian Processes for Machine Learning. New York: MIT Press, 2006.
41.
Camps-VallsG.Gómez-ChovaL.Munõz-MaríJ.Vila-FrancésJ.Amorós-LópezJ.Calpe-MaravillaJ.“Retrieval of Oceanic Chlorophyll Concentration with Relevance Vector Machines”. Remote Sens. Environ2006; 105: 23–33.
42.
VerrelstJ.AlonsoL.Camps-VallsG.DelegidoJ.MorenoJ.“Retrieval of Vegetation Biophysical Parameters using Gaussian Process Techniques”. IEEE Trans. Geosci. Remote Sens2012; 50: 1832–1843.
43.
PasolliL.MelganiF.BlanzieriE.“Gaussian Process Regression for Estimating Chlorophyll Concentration in Subsurface”. IEEE Geosci. Remote Sens. Lett2010; 7: 464–468.
44.
Lázaro-GredillaM.TitsiasM.K.VerrelstJ.Camps-VallsG.“Retrieval of Biophysical Parameters with Heteroscedastic Gaussian Processes”. IEEE Geosci. Remote Sens. Lett2014; 11: 838–842.
45.
NiW.NørgaardL.MørupM.“Non-Linear Calibration Models for Near Infrared Spectroscopy”. Anal. Chim. Acta2014; 813: 1–14.
46.
Matlab, 7.9.0 R2009a. Natick, MA: The MathWorks, 2009.
