Kinetic Evidence of the Maillard Reaction in Hydrothermal Biomass Processing: Glucose−Glycine Interactions in High-Temperature, High-Pressure Water

Kinetic Evidence of the Maillard Reaction in Hydrothermal Biomass Processing: Glucose−Glycine Interactions in High-Temperature, High-Pressure Water

Kinetic and mechanistic evidence is presented of the occurrence of a Maillard-type reaction under conditions of interest to hydrothermal biomass processing. Glucose−glycine mixtures were reacted at 250 °C and 10 MPa in an excess of water; both glucose and glycine were found to strongly influence the...

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Bibliographic Details
Published in:Industrial & engineering chemistry research Vol. 49; no. 5; pp. 2107 - 2117
Main Authors: Peterson, Andrew A, Lachance, Russell P, Tester, Jefferson W
Format: Journal Article
Language:English
Published: Washington, DC American Chemical Society 03-03-2010
Subjects:
Applied sciences
Chemical engineering
Exact sciences and technology
Kinetics, Catalysis, and Reaction Engineering
Biomass
Kinetics
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Summary:Kinetic and mechanistic evidence is presented of the occurrence of a Maillard-type reaction under conditions of interest to hydrothermal biomass processing. Glucose−glycine mixtures were reacted at 250 °C and 10 MPa in an excess of water; both glucose and glycine were found to strongly influence the destruction kinetics of the other species and to result in quantitative and qualitative changes, such as strong absorbance at 420 nm and the production of a dark brown appearance and nutty odor, which are characteristic of the Maillard reaction. The presence of glucose always resulted in higher glycine destruction; the presence of glycine resulted in increased or decreased glucose destruction, depending on initial concentrations, which is consistent with results reported in the literature for lower temperature Maillard reactions. Surrogate compounds that contain the same chemical functional groups also resulted in similar trends. As a result of this reaction, the presence of proteins and amino acids in biomass feedstocks can be expected to result in processing difficulties at hydrothermal conditions: these difficulties will include fouling of process equipment, the quenching of desired reaction pathways, and difficulty in achieving separations between aqueous and oil phases produced.
ISSN:0888-5885
1520-5045
DOI:10.1021/ie9014809