Electrochemical quantification of D-glucose during the production of bioethanol from thermo-mechanically pre-treated wheat straw

Rhys A. Ward; Adam Charlton; Kevin J. Welham; Paul Baker; Sharif H. Zein; Jeremy Tomkinson; David I. Richards; Stephen M. Kelly; Nathan S. Lawrence; Jay D. Wadhawan

doi:10.1016/j.elecom.2021.106942

Electrochemical quantification of D-glucose during the production of bioethanol from thermo-mechanically pre-treated wheat straw

Rhys A. Ward, Adam Charlton, Kevin J. Welham, Paul Baker, Sharif H. Zein, Jeremy Tomkinson, David I. Richards, Stephen M. Kelly, Nathan S. Lawrence, Jay D. Wadhawan

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7 Citas (Scopus)

Resumen

Mechanical pre-treatment (disc refining) of wheat straw, at both atmospheric and elevated pressure, is shown to be an efficient process to access fermentable monosaccharides, with the potential to integrate within the infrastructure of existing first-generation bioethanol plants. The mild, enzymatic degradation of this sustainable lignocellulosic biomass affords ca. 0.10–0.13 g/g (dry weight) of D-glucose quantifiable voltammetrically in real time, over a two hundred-fold range in experimental laboratory scales (25 mL to 5.0 L), with pressure disc refining of the wheat straw enabling almost twice the amount of D-glucose to be generated during the hydrolysis stage than experiments using atmospheric refining (0.06–0.09 g/g dry weight). Fermentation of the resulting hydrolysate affords 0.08–0.10 g/g (dry weight) of ethanol over similar scales, with ethanol productivity at ca. 37 mg/(L h). These results demonstrate that minimal cellulose decomposition occurs during pressure refining of wheat straw, in contrast to hemicellulose, and suggest that the development of green, mechanochemical processes for the scalable and cost-effective manufacture of second-generation bioethanol requires improved cellulose decomposition.

Idioma original	English
Número de artículo	106942
Publicación	Electrochemistry Communications
Volumen	124
DOI	https://doi.org/10.1016/j.elecom.2021.106942
Estado	Published - mar. 2021
Publicado de forma externa	Sí

Nota bibliográfica

Funding Information:
This work was funded by the Biotechnology and Biological Sciences Research Council's Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to Dávid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund.

Funding Information:
This work was funded by the Biotechnology and Biological Sciences Research Council’s Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to Dávid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund.

Publisher Copyright:
© 2021 The Author(s)

ASJC Scopus Subject Areas

Electrochemistry

PubMed: MeSH publication types

Journal Article

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Ward, R. A., Charlton, A., Welham, K. J., Baker, P., Zein, S. H., Tomkinson, J., Richards, D. I., Kelly, S. M., Lawrence, N. S., & Wadhawan, J. D. (2021). Electrochemical quantification of D-glucose during the production of bioethanol from thermo-mechanically pre-treated wheat straw. Electrochemistry Communications, 124, Artículo 106942. https://doi.org/10.1016/j.elecom.2021.106942

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title = "Electrochemical quantification of D-glucose during the production of bioethanol from thermo-mechanically pre-treated wheat straw",

abstract = "Mechanical pre-treatment (disc refining) of wheat straw, at both atmospheric and elevated pressure, is shown to be an efficient process to access fermentable monosaccharides, with the potential to integrate within the infrastructure of existing first-generation bioethanol plants. The mild, enzymatic degradation of this sustainable lignocellulosic biomass affords ca. 0.10–0.13 g/g (dry weight) of D-glucose quantifiable voltammetrically in real time, over a two hundred-fold range in experimental laboratory scales (25 mL to 5.0 L), with pressure disc refining of the wheat straw enabling almost twice the amount of D-glucose to be generated during the hydrolysis stage than experiments using atmospheric refining (0.06–0.09 g/g dry weight). Fermentation of the resulting hydrolysate affords 0.08–0.10 g/g (dry weight) of ethanol over similar scales, with ethanol productivity at ca. 37 mg/(L h). These results demonstrate that minimal cellulose decomposition occurs during pressure refining of wheat straw, in contrast to hemicellulose, and suggest that the development of green, mechanochemical processes for the scalable and cost-effective manufacture of second-generation bioethanol requires improved cellulose decomposition.",

author = "Ward, {Rhys A.} and Adam Charlton and Welham, {Kevin J.} and Paul Baker and Zein, {Sharif H.} and Jeremy Tomkinson and Richards, {David I.} and Kelly, {Stephen M.} and Lawrence, {Nathan S.} and Wadhawan, {Jay D.}",

note = "Funding Information: This work was funded by the Biotechnology and Biological Sciences Research Council's Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to D{\'a}vid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund. Funding Information: This work was funded by the Biotechnology and Biological Sciences Research Council{\textquoteright}s Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to D{\'a}vid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund. Publisher Copyright: {\textcopyright} 2021 The Author(s)",

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AU - Ward, Rhys A.

AU - Charlton, Adam

AU - Welham, Kevin J.

AU - Baker, Paul

AU - Zein, Sharif H.

AU - Tomkinson, Jeremy

AU - Richards, David I.

AU - Kelly, Stephen M.

AU - Lawrence, Nathan S.

AU - Wadhawan, Jay D.

N1 - Funding Information: This work was funded by the Biotechnology and Biological Sciences Research Council's Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to Dávid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund. Funding Information: This work was funded by the Biotechnology and Biological Sciences Research Council’s Network in Biotechnology and Bioenergy proof-of-concept fund within the Plants-to-Products network (grant reference number HD-RD0300E). RAW, SMK, NSL and JDW express gratitude to Dávid Kocsis and Dr. Christopher Meyer of Singleton Birch, Ltd for their generous donation of slaked lime and thank the University of Hull for additional funding through the Higher Education Innovation Fund. Publisher Copyright: © 2021 The Author(s)

PY - 2021/3

Y1 - 2021/3

N2 - Mechanical pre-treatment (disc refining) of wheat straw, at both atmospheric and elevated pressure, is shown to be an efficient process to access fermentable monosaccharides, with the potential to integrate within the infrastructure of existing first-generation bioethanol plants. The mild, enzymatic degradation of this sustainable lignocellulosic biomass affords ca. 0.10–0.13 g/g (dry weight) of D-glucose quantifiable voltammetrically in real time, over a two hundred-fold range in experimental laboratory scales (25 mL to 5.0 L), with pressure disc refining of the wheat straw enabling almost twice the amount of D-glucose to be generated during the hydrolysis stage than experiments using atmospheric refining (0.06–0.09 g/g dry weight). Fermentation of the resulting hydrolysate affords 0.08–0.10 g/g (dry weight) of ethanol over similar scales, with ethanol productivity at ca. 37 mg/(L h). These results demonstrate that minimal cellulose decomposition occurs during pressure refining of wheat straw, in contrast to hemicellulose, and suggest that the development of green, mechanochemical processes for the scalable and cost-effective manufacture of second-generation bioethanol requires improved cellulose decomposition.

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Electrochemical quantification of D-glucose during the production of bioethanol from thermo-mechanically pre-treated wheat straw

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