Brewer's spent grain (BSG) is the most abundant by-product of the brewing industry and its main application is limited to low-value cattle feed. Since BSG contains 20 to 25% of proteins, it has the potential to provide a new protein source to the food industry. In this research, an ultrasound-assisted enzymatic extraction was designed to extract protein hydrolysates from BSG. Original BSG and ultrasound pretreated BSG were hydrolyzed under different enzyme (Alcalase) loadings and incubation times. Centrifugation was applied to separate solubilized proteins from insoluble BSG residue. When the enzyme loading increased from 1 to 40 uL /g BSG, the solubilized proteins increased from 34% to 64.8%. The application of ultrasound further increased the solubilized proteins from 64.8% to 69.8%. Solubilized proteins from ultrasound pretreated BSG was significantly higher (p < 0.05) than that from the original BSG. Particle size distribution analysis showed that the application of ultrasound pretreatment reduced the BSG particle size from 331.2 to 215.7 um. Scanning electron microscopy images revealed that the BSG particle surface was partially ruptured by the ultrasound pretreatment. These two phenomena might have contributed to the increased protein separation efficiency with ultrasound pretreatment. The solubility (pH 1.0 to 11.0) of protein hydrolysate increased by the application of ultrasound and the ultrasound did not lead to the change of the amino acid composition of the separated protein hydrolysates. Based on sodium dodecyl sulfate-polyacrylamide gel electrophoresis profile, the protein was degraded to peptides which had molecular weights lower than 15 kDa. The color of the separated protein hydrolysates by enzymatic hydrolysis was brighter and lighter than the original BSG. The application of ultrasound did not affect the color of the separated protein hydrolysates. Overall, the ultrasound pretreatment prior to enzymatic hydrolysis enhanced the extraction of proteins from BSG in terms of higher protein separation efficiency, lower enzyme loadings, and reduced incubation time. This study developed a novel and green method to effectively extract value-added protein hydrolysates from the low-value food processing byproducts. / MSLFS / Brewer’s spent grain (BSG) is the most abundant waste generated by beer industries after beer production and it is mainly used to feed cattle. Since BSG contains 20 to 25% proteins, it has the potential to provide a new protein source to food industries. The aim of this research is to study if the ultrasound technology can assist the enzymatic extraction of proteins from BSG. If it can, the cost of the protein extraction from BSG can be reduced. In this research, the original BSG and the BSG pretreated with ultrasound were incubated under different enzyme loadings and incubation times. The protein-rich liquid was separated from fiber-rich solids using a centrifuge. When the enzyme loading increased from 1 to 40 L /g BSG, 34% to 64.8% of proteins were separated from the original BSG. The application of ultrasound further increased the solubilized proteins from 64.8% to 69.8%. For the BSG pretreated with ultrasound, there were significantly more proteins separated from BSG compared to the original BSG. Particle size of the original BSG and the ultrasound pretreated BSG was measured, and the results showed that the application of ultrasound pretreatment decreased the BSG particle size from 331.2 to 215.7 µm. Scanning electron microscopy images were taken to investigate the effect of ultrasound on the surface of BSG particles. Based on the photos, we found that the BSG particle surface was partially broken by the ultrasound pretreatment. The surface was rough and contained large amounts of holes instead of being flat and smooth observed without ultrasound. Therefore, there were more locations for the enzyme to attack. These two phenomena might have contributed to extracting more proteins from BSG. Protein solubility (pH 1.0 to 11.0) increased by the application of ultrasound. The nutritional value of the protein extracted was not altered by the ultrasound. The extracted protein hydrolysates had a small molecular weight and the application of ultrasound did not affect the color of the extracted protein hydrolysates. The ultrasound pretreatment prior to enzymatic hydrolysis increased the extraction of proteins from BSG, decreased the enzyme consumption and incubation time. This study developed a novel and green method to effectively extract value-added protein hydrolysates from the low-value food processing byproducts.
Identifer | oai:union.ndltd.org:VTETD/oai:vtechworks.lib.vt.edu:10919/97875 |
Date | 29 October 2018 |
Creators | Yu, Dajun |
Contributors | Food Science and Technology, Huang, Haibo, O'Keefe, Sean F., Neilson, Andrew P. |
Publisher | Virginia Tech |
Source Sets | Virginia Tech Theses and Dissertation |
Language | English |
Detected Language | English |
Type | Thesis |
Format | ETD, application/pdf |
Rights | In Copyright, http://rightsstatements.org/vocab/InC/1.0/ |
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