Plant starch extraction, modification, and green applications: a review

Fossil fuel-based products should be replaced by products derived from modern biomass such as plant starch, in the context of the future circular economy. Starch production globally surpasses 50 million tons annually, predominantly sourced from maize, rice, and potatoes. Here, we review plant starch...

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Veröffentlicht in:	Environmental chemistry letters 2024-10, Vol.22 (5), p.2483-2530
Hauptverfasser:	Rashwan, Ahmed K., Younis, Hala A., Abdelshafy, Asem M., Osman, Ahmed I., Eletmany, Mohamed R., Hafouda, Mahmoud A., Chen, Wei
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Sprache:	eng
Schlagworte:	Alternative energy sources Amylose Analytical Chemistry biodegradability Biodegradation biomass Bioplastics Carbon footprint Cassava Circular economy Corn Earth and Environmental Science Ecotoxicology encapsulation energy Energy consumption Environment Environmental Chemistry Food Food plants Foods Fossil fuels Geochemistry industry Layouts markets Meat Plant extracts Plant-based foods Plants Pollution Potatoes Prebiotics Review Article rice Starch Starches Structural integrity Sustainability Sustainable packaging Texturizers Wastewater Wet milling wood
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creator	Rashwan, Ahmed K. Younis, Hala A. Abdelshafy, Asem M. Osman, Ahmed I. Eletmany, Mohamed R. Hafouda, Mahmoud A. Chen, Wei
description	Fossil fuel-based products should be replaced by products derived from modern biomass such as plant starch, in the context of the future circular economy. Starch production globally surpasses 50 million tons annually, predominantly sourced from maize, rice, and potatoes. Here, we review plant starch with an emphasis on structure and properties, extraction, modification, and green applications. Modification techniques comprise physical, enzymatic, and genetic methods. Applications include stabilization of food, replacement of meat, three-dimensional food printing, prebiotics, encapsulation, bioplastics, edible films, textiles, and wood adhesives. Starch from maize, potatoes, and cassava shows amylose content ranging from 20 to 30% in regular varieties to 70% in high-amylose varieties. Extraction by traditional wet milling achieves starch purity up to 99.5%, while enzymatic methods maintain higher structural integrity, which is crucial for pharmaceutical applications. Enzymatic extraction improves starch yield by of up to 20%, reduces energy consumption by about 30%, and lowers wastewater production by up to 50%, compared to conventional methods. Sustainable starch modification can reduce the carbon footprint of starch production by up to 40%. Modified starches contribute to approximately 70% of the food texturizers market. The market of starch in plant-based meat alternatives has grown by over 30% in the past five years. Similarly, the use of biodegradable starch-based plastics by the bioplastic industry is growing over 20% annually, driven by the demand for sustainable packaging.Kindly check and confirm the layout of Table 1.Layout is right
doi_str_mv	10.1007/s10311-024-01753-z
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Enzymatic extraction improves starch yield by of up to 20%, reduces energy consumption by about 30%, and lowers wastewater production by up to 50%, compared to conventional methods. Sustainable starch modification can reduce the carbon footprint of starch production by up to 40%. Modified starches contribute to approximately 70% of the food texturizers market. The market of starch in plant-based meat alternatives has grown by over 30% in the past five years. 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Starch production globally surpasses 50 million tons annually, predominantly sourced from maize, rice, and potatoes. Here, we review plant starch with an emphasis on structure and properties, extraction, modification, and green applications. Modification techniques comprise physical, enzymatic, and genetic methods. Applications include stabilization of food, replacement of meat, three-dimensional food printing, prebiotics, encapsulation, bioplastics, edible films, textiles, and wood adhesives. Starch from maize, potatoes, and cassava shows amylose content ranging from 20 to 30% in regular varieties to 70% in high-amylose varieties. Extraction by traditional wet milling achieves starch purity up to 99.5%, while enzymatic methods maintain higher structural integrity, which is crucial for pharmaceutical applications. 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subjects	Alternative energy sources Amylose Analytical Chemistry biodegradability Biodegradation biomass Bioplastics Carbon footprint Cassava Circular economy Corn Earth and Environmental Science Ecotoxicology encapsulation energy Energy consumption Environment Environmental Chemistry Food Food plants Foods Fossil fuels Geochemistry industry Layouts markets Meat Plant extracts Plant-based foods Plants Pollution Potatoes Prebiotics Review Article rice Starch Starches Structural integrity Sustainability Sustainable packaging Texturizers Wastewater Wet milling wood
title	Plant starch extraction, modification, and green applications: a review
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