绿色技术对蜂花粉复杂细胞壁结构的影响,以增强其功能特性并提高其体外消化率。

IF 3.2 2区 农林科学 Q2 FOOD SCIENCE & TECHNOLOGY Journal of Food Science Pub Date : 2024-11-04 DOI:10.1111/1750-3841.17472
Anamika Sharma, Avinash Thakur, Vikas Nanda
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引用次数: 0

摘要

蜂花粉是一种营养丰富的超级食物,但其僵硬的双层结构限制了营养的释放和吸收。由抗压孢粉蛋白组成的外层外膜和由纤维素和果胶组成的内层内膜形成了消化分解的屏障。本研究探讨了绿色技术(特别是超临界流体萃取和超声波处理)分解花粉细胞壁的潜力,从而提高花粉的生物利用率,最大限度地提高营养物质的利用率。扫描电子显微镜成像显示,经超声波处理的花粉(USTP)和经超临界流体萃取处理的花粉(STP)显示出了破坏性。与扫描电子显微镜有关的技术功能、抗氧化和成分分析显示了积极的结果,粗脂肪、蛋白质、抗氧化活性(2,2-二苯基-1-苦基肼活性和 2,2'-Azino-bis-3-ethylbenzthiazoline-6-sulphonic acid assay)和总酚含量分别增加了 34.80%、32.58%、10.80%、11.37% 和 83.94%。根据上述特性,确定 USTP 4 小时和 STP 400 巴 40 分钟为最佳崩解条件。此外,对优化后的样品进行氨基酸和矿物质释放分析后发现,必需氨基酸和矿物质(钙、铜、铁等)的含量分别显著增加了 1.5 倍和 1.2 倍。在成分发生重大变化的同时,通过差示扫描量热仪和 X 射线衍射分析,断裂花粉的蛋白质消化率提高了 1.4 倍,但热稳定性和结晶度略有不同。研究证实,如果不进行预处理,营养物质的释放和吸收仍然会受到限制,这突出表明,在将蜂花粉用作功能性食品配料之前,有必要对其进行特殊处理,使其分解。实际应用:蜂花粉富含人体所需的各种营养物质,是公认的全营养食品。然而,蜂花粉坚硬的细胞结构限制了它在众多食品应用中的使用。因此,为了分解蜂花粉并释放其营养成分,我们采用了超声波和超临界流体萃取工艺来提高蜂花粉的利用率。事实证明,这两种处理技术提高了蜂花粉的生物利用率和功能特性,使其更适合用于营养保健品和功能食品。
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Impact of green techniques on intricate cell wall structure of bee pollen to enhance functional characteristics and improve its in vitro digestibility.

Bee pollen is a nutrient-rich super food, but its rigid dual-layered structure limits nutrient release and absorption. The outer exine, composed of stress-resistant sporopollenin, and the inner intine, consisting of cellulose and pectin, form a barrier to digestive breakdown. This study investigates the potential of green techniques, specifically supercritical fluid extraction and ultrasonication, to disaggregate pollen cell walls, enhancing its bioavailability and maximizing nutrient utilization. Ultrasonication treated pollen (USTP) and supercritical fluid extraction-treated pollen (STP) demonstrated disruption, as evidenced by scanning electron microscopy imaging. In relation to scanning electron microscopy, techno-functional, antioxidant, and compositional analysis displayed a positive outcome, with crude lipid, protein, antioxidant activity (2,2-diphenyl-1-picrylhydrazyl activity and 2,2'-azino-bis-3-ethylbenzthiazoline-6-sulphonic acid assay) and total phenolic content increased by 34.80%, 32.58%, 10.80%, 11.37%, and 83.94%, respectively. Based on the above properties, USTP for 4 h and STP at 400 bar for 40 min were identified as the optimal conditions for disintegration. Furthermore, optimized samples analyzed for amino acid and mineral release revealed a notable increase in composition of essential amino acid and minerals (Ca, Cu, Fe, etc.) by ∼1.5 and 1.2 times, respectively. Along with significant changes in composition, fractured pollen exhibited 1.4 folds increase in protein digestibility with minor differences in thermal stability, and crystallinity as established by differential scanning calorimetry, and X-ray diffraction analysis. The study confirms that nutrient release and absorption remain restricted without pre-treatment, highlighting the necessity of specific treatment to disintegrate bee pollen before its use as a functional food ingredient. PRACTICAL APPLICATION: Bee pollen is a rich source of all the essential nutrients required by the humans and recognised as a complete food. However, its tough cellular structure restricts its utilisation in numerous food applications. Therefore, to disintegrate bee pollen and release its nutrients, ultrasonication and super critical fluid extraction processes were employed to improve its utilization for human purposes. Both the treatment techniques, enhanced bee pollen's bioavailability and functional properties, making it more suitable for use in nutraceuticals and functional foods.These treatments proved to increase the antioxidant capacity, digestibility, and create high-value ingredient for supplements, beverages, and fortified foods.

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来源期刊
Journal of Food Science
Journal of Food Science 工程技术-食品科技
CiteScore
7.10
自引率
2.60%
发文量
412
审稿时长
3.1 months
期刊介绍: The goal of the Journal of Food Science is to offer scientists, researchers, and other food professionals the opportunity to share knowledge of scientific advancements in the myriad disciplines affecting their work, through a respected peer-reviewed publication. The Journal of Food Science serves as an international forum for vital research and developments in food science. The range of topics covered in the journal include: -Concise Reviews and Hypotheses in Food Science -New Horizons in Food Research -Integrated Food Science -Food Chemistry -Food Engineering, Materials Science, and Nanotechnology -Food Microbiology and Safety -Sensory and Consumer Sciences -Health, Nutrition, and Food -Toxicology and Chemical Food Safety The Journal of Food Science publishes peer-reviewed articles that cover all aspects of food science, including safety and nutrition. Reviews should be 15 to 50 typewritten pages (including tables, figures, and references), should provide in-depth coverage of a narrowly defined topic, and should embody careful evaluation (weaknesses, strengths, explanation of discrepancies in results among similar studies) of all pertinent studies, so that insightful interpretations and conclusions can be presented. Hypothesis papers are especially appropriate in pioneering areas of research or important areas that are afflicted by scientific controversy.
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