Mechanochemical extraction of edible proteins from moor grass†

Olusegun Abayomi Olalere, Fatma Guler, Christopher J. Chuck, Hannah S. Leese and Bernardo Castro-Dominguez
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Abstract

Extracting edible nutrient-rich food fractions from unconventional sources, such as grass, could play a pivotal role in ensuring food security, bolstering economic prosperity, combating climate change, and enhancing overall quality of life. Current extraction techniques rely heavily on harsh chemicals, which not only degrade nutrients but can also substantially add to the cost of the process and make downstream separation challenging. In this study, we harnessed a mechanochemical process, liquid-assisted grinding (LAG) with and without Na2CO3, termed sodium carbonate assisted grinding (SAG), to extract the protein fraction from moor grass. These techniques were compared to the conventional alkaline extraction (AE) method. Unlike alkaline extraction, which solubilized over 70% of the material, the mechanochemical approach using Na2CO3 solubilized only 55% of the grass while still extracting the vast majority of the protein in the original grass feedstock. The protein fractions obtained from the SAG process had a similar amino acid profile to the core feedstock but also contained distinct characteristics over the other methods of extraction. FT-IR analysis, for example, identified the presence of an amide III band in the protein fractions obtained from the SAG process, indicating unique structural features that contribute to improved dispersibility, gelation properties, and water-in-water stability. Furthermore, the extracted moor grass protein contained a higher proportion of glutamic acid in comparison to other amino acids in the protein, which indicates a savoury umami (meaty) characteristic to the protein fraction. The protein extracted via SAG also exhibited good heat stability (139–214 °C), rendering them potentially suitable for baking applications. Additionally, coupling Na2CO3 with liquid assisted grinding not only removed the need for organic solvents and conventional heating but also reduced solvent consumption by 83%, compared with the typical alkaline extraction, thus simplifying the downstream processes necessary to produce food fractions. This study demonstrates the potential significance of mechanochemical extraction processes in unlocking nutrients from unconventional resources like grass, to produce the next generation of sustainable food ingredients.

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从荒草中机械化提取可食用蛋白质†。
从草等非常规资源中提取可食用的营养丰富的食物成分,可在确保粮食安全、促进经济繁荣、应对气候变化和提高整体生活质量方面发挥关键作用。目前的萃取技术严重依赖于刺激性化学物质,这不仅会降低营养成分,还会大大增加工艺成本,并使下游分离工作面临挑战。在本研究中,我们利用一种机械化学工艺,即添加或不添加 Na2CO3 的液体辅助研磨(LAG),称为碳酸钠辅助研磨(SAG),来提取荒草中的蛋白质部分。这些技术与传统的碱性提取(AE)方法进行了比较。碱性萃取法溶解了 70% 以上的原料,而使用 Na2CO3 的机械化学法仅溶解了 55% 的牧草,但仍提取了原始牧草原料中的绝大部分蛋白质。从 SAG 工艺中获得的蛋白质馏分具有与核心原料相似的氨基酸谱,但与其他提取方法相比,也具有明显的特征。例如,傅立叶变换红外光谱分析发现,从 SAG 工艺中提取的蛋白质馏分中存在酰胺 III 带,这表明其独特的结构特征有助于改善分散性、凝胶特性和水包水稳定性。此外,与蛋白质中的其他氨基酸相比,提取的沼泽草蛋白质含有较高比例的谷氨酸,这表明蛋白质部分具有咸味(肉味)特征。通过 SAG 提取的蛋白质还具有良好的热稳定性(139-214 °C),因此可能适合烘焙应用。此外,将 Na2CO3 与液体辅助研磨相结合,不仅不再需要有机溶剂和传统加热,而且与典型的碱性提取相比,溶剂消耗量减少了 83%,从而简化了生产食品馏分所需的下游工艺。这项研究表明,机械化学萃取工艺对于从草类等非常规资源中提取营养物质,生产下一代可持续食品配料具有潜在的重要意义。
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