Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process

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Standard

Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process. / Tonolini, Margherita; van den Berg, Frans W.J.; Skou, Peter Bæk; Sørensen, Klavs Martin; Engelsen, Søren Balling.

I: Journal of Food Engineering, Bind 350, 111487, 2023.

Publikation: Bidrag til tidsskriftTidsskriftartikelForskningfagfællebedømt

Harvard

Tonolini, M, van den Berg, FWJ, Skou, PB, Sørensen, KM & Engelsen, SB 2023, 'Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process', Journal of Food Engineering, bind 350, 111487. https://doi.org/10.1016/j.jfoodeng.2023.111487

APA

Tonolini, M., van den Berg, F. W. J., Skou, P. B., Sørensen, K. M., & Engelsen, S. B. (2023). Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process. Journal of Food Engineering, 350, [111487]. https://doi.org/10.1016/j.jfoodeng.2023.111487

Vancouver

Tonolini M, van den Berg FWJ, Skou PB, Sørensen KM, Engelsen SB. Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process. Journal of Food Engineering. 2023;350. 111487. https://doi.org/10.1016/j.jfoodeng.2023.111487

Author

Tonolini, Margherita ; van den Berg, Frans W.J. ; Skou, Peter Bæk ; Sørensen, Klavs Martin ; Engelsen, Søren Balling. / Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process. I: Journal of Food Engineering. 2023 ; Bind 350.

Bibtex

@article{5f1be9db532d4aa4b9f9c234404c0979,
title = "Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process",
abstract = "A successful transition from a laboratory proof-of-principle to a functioning industrial Process Analytical Technology (PAT) application of spectroscopy and chemometrics is still an active area of research and development. A comprehensive understanding on how the design and implementation of the optical instrumentation affect the data quality, and how this will affect the performance of the prediction models is vital for the successful implementation of in-line monitoring. In a previous study, we have demonstrated that near-infrared spectroscopy (NIRS), combined with chemometric techniques, can be used to quantify α-lactalbumin and β-lactoglobulin in aqueous whey solutions. This work demonstrates the potential, both at-line and in-line, of monitoring a protein fractionation process in a full-scale production. An in-line near infrared spectrometer (NIRS) was used to monitor the individual protein concentrations in a protein fractionation process over 20 days. In addition, samples were extracted from the process and analysed with at-line NIRS and an in-house HPLC reference method. The developed models could predict β-lactoglobulin and α-lactalbumin concentrations with satisfactory precision and accuracy, yielding a root mean square error of cross-validation of 0.08 and 0.18 w/w% proteins, respectively. For the first time, the whey proteins concentrations were measured continuously in a production facility to demonstrate the potential of NIRS for at-line and in-line rapid monitoring of protein composition in industrial whey streams. A PAT tool was developed from NIRS data where Partial Least Squares regression modelling and an Exponentially Weighted Moving Average filtering were used to extract and visualize valuable information on the process dynamics and performance. The study demonstrates that continuous monitoring by in-line NIRS allowed elucidation of some process behaviours not readily detectable with the current sampling frequency and that it offers novel process optimisation opportunities by providing increased process understanding and decision support information concerning preventive maintenance and real-time process validation.",
keywords = "Membrane filtration, Near-infrared spectroscopy, Process analytical technology, Process monitoring, Separation, Whey proteins",
author = "Margherita Tonolini and {van den Berg}, {Frans W.J.} and Skou, {Peter B{\ae}k} and S{\o}rensen, {Klavs Martin} and Engelsen, {S{\o}ren Balling}",
note = "Publisher Copyright: {\textcopyright} 2023 The Authors",
year = "2023",
doi = "10.1016/j.jfoodeng.2023.111487",
language = "English",
volume = "350",
journal = "Journal of Food Engineering",
issn = "0260-8774",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Near-infrared spectroscopy as a process analytical technology tool for monitoring performance of membrane filtration in a whey protein fractionation process

AU - Tonolini, Margherita

AU - van den Berg, Frans W.J.

AU - Skou, Peter Bæk

AU - Sørensen, Klavs Martin

AU - Engelsen, Søren Balling

N1 - Publisher Copyright: © 2023 The Authors

PY - 2023

Y1 - 2023

N2 - A successful transition from a laboratory proof-of-principle to a functioning industrial Process Analytical Technology (PAT) application of spectroscopy and chemometrics is still an active area of research and development. A comprehensive understanding on how the design and implementation of the optical instrumentation affect the data quality, and how this will affect the performance of the prediction models is vital for the successful implementation of in-line monitoring. In a previous study, we have demonstrated that near-infrared spectroscopy (NIRS), combined with chemometric techniques, can be used to quantify α-lactalbumin and β-lactoglobulin in aqueous whey solutions. This work demonstrates the potential, both at-line and in-line, of monitoring a protein fractionation process in a full-scale production. An in-line near infrared spectrometer (NIRS) was used to monitor the individual protein concentrations in a protein fractionation process over 20 days. In addition, samples were extracted from the process and analysed with at-line NIRS and an in-house HPLC reference method. The developed models could predict β-lactoglobulin and α-lactalbumin concentrations with satisfactory precision and accuracy, yielding a root mean square error of cross-validation of 0.08 and 0.18 w/w% proteins, respectively. For the first time, the whey proteins concentrations were measured continuously in a production facility to demonstrate the potential of NIRS for at-line and in-line rapid monitoring of protein composition in industrial whey streams. A PAT tool was developed from NIRS data where Partial Least Squares regression modelling and an Exponentially Weighted Moving Average filtering were used to extract and visualize valuable information on the process dynamics and performance. The study demonstrates that continuous monitoring by in-line NIRS allowed elucidation of some process behaviours not readily detectable with the current sampling frequency and that it offers novel process optimisation opportunities by providing increased process understanding and decision support information concerning preventive maintenance and real-time process validation.

AB - A successful transition from a laboratory proof-of-principle to a functioning industrial Process Analytical Technology (PAT) application of spectroscopy and chemometrics is still an active area of research and development. A comprehensive understanding on how the design and implementation of the optical instrumentation affect the data quality, and how this will affect the performance of the prediction models is vital for the successful implementation of in-line monitoring. In a previous study, we have demonstrated that near-infrared spectroscopy (NIRS), combined with chemometric techniques, can be used to quantify α-lactalbumin and β-lactoglobulin in aqueous whey solutions. This work demonstrates the potential, both at-line and in-line, of monitoring a protein fractionation process in a full-scale production. An in-line near infrared spectrometer (NIRS) was used to monitor the individual protein concentrations in a protein fractionation process over 20 days. In addition, samples were extracted from the process and analysed with at-line NIRS and an in-house HPLC reference method. The developed models could predict β-lactoglobulin and α-lactalbumin concentrations with satisfactory precision and accuracy, yielding a root mean square error of cross-validation of 0.08 and 0.18 w/w% proteins, respectively. For the first time, the whey proteins concentrations were measured continuously in a production facility to demonstrate the potential of NIRS for at-line and in-line rapid monitoring of protein composition in industrial whey streams. A PAT tool was developed from NIRS data where Partial Least Squares regression modelling and an Exponentially Weighted Moving Average filtering were used to extract and visualize valuable information on the process dynamics and performance. The study demonstrates that continuous monitoring by in-line NIRS allowed elucidation of some process behaviours not readily detectable with the current sampling frequency and that it offers novel process optimisation opportunities by providing increased process understanding and decision support information concerning preventive maintenance and real-time process validation.

KW - Membrane filtration

KW - Near-infrared spectroscopy

KW - Process analytical technology

KW - Process monitoring

KW - Separation

KW - Whey proteins

U2 - 10.1016/j.jfoodeng.2023.111487

DO - 10.1016/j.jfoodeng.2023.111487

M3 - Journal article

AN - SCOPUS:85150338446

VL - 350

JO - Journal of Food Engineering

JF - Journal of Food Engineering

SN - 0260-8774

M1 - 111487

ER -

ID: 344368704