一种增强免疫能力和运动表现的新型生物类黄酮和植物营养素富集制剂的设计:产品开发研究

B. Downs, S. Banik, M. Bagchi, Bruce S. Morrison, S. Kushner, Matt Piacentino, D. Bagchi
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引用次数: 0

摘要

厌氧(缺氧)发病机制的增加显著增加活性氧(ROS)的产生,对细胞膜和细胞内成分造成损害。活性氧的产生和伴随的炎症反应是由细胞损伤或病原体入侵引起的细胞损伤的两个标志。与缺氧相反,缺氧是导致氧化应激和损伤、细胞因子产生和炎症的主要原因。当我们的细胞不能有效地利用氧气来促进有氧糖酵解和其他细胞代谢事件时,氧气会氧化细胞膜、脂质、神经元、交联蛋白质、破坏DNA、引发炎症等后果。这些无氧事件是慢性退行性疾病(CDD)的标志。过度要求减少氧化损伤可以超载内源性抗氧化能力。解决炎症不良反应的关键治疗策略包括增强细胞材料的结构完整性和功能能力,减少组织损伤的影响和后果;活性氧的产生;以及随后的病理紊乱。此外,恢复细胞有氧代谢事件,如有氧糖酵解和氧化呼吸,是一个同样重要的附带目标。健康的饮食和补充剂,提供丰富的外源抗氧化剂和大量的植物化学膳食成分,对恢复有氧代谢变得更加重要;增强和帮助改善细胞结构完整性,从而减少氧化应激、损伤和炎症后遗症。VMP35 MNC是一种研究证实的基于Prodosomed营养保健技术的植物营养素配方,富含结构多样的生物类黄酮、多酚和酚类糖等,已被证明可以提高细胞结构完整性和生理功能,并恢复有氧代谢能力,包括运动表现和一般健康。本综述为设计一种新型Prodosomed VMP35多营养素/植物药复合物提供了一种策略方法,并评估其逆转无氧病理(包括炎症)和恢复健康细胞有氧糖酵解的能力。
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Design of a Novel Bioflavonoid and Phytonutrient Enriched Formulation in Boosting Immune Competence and Sports Performance: A product Development Investigation
An increase in anaerobic (oxygen-deprived) pathogenesis significantly increases the generation of reactive oxygen species (ROS) inflicting damage on cell membranes and intracellular constituents. Generation of ROS and concomitant inflammatory response is the two hallmarks of cellular damage caused by cellular injury or invasion by pathogens. Oxygen deprivation, as opposed to oxygen deficiency, is a major contributor to oxidative stress and damage, cytokine production, and inflammation. When our cells are unable to efficiently and effectively utilize the oxygen to facilitate aerobic glycolysis and other cellular metabolic events, the oxygen instead oxidizes cell membranes, lipids, neurons, cross-links proteins, damages DNA, and initiates inflammation among other consequences. These anaerobic events are hallmarks of chronic degenerative diseases (CDD). Excessive demands to curtail oxidative damage can overburden endogenous antioxidative capabilities. A key treatment strategy to tackle the adverse effects of inflammation involves the augmentation of the structural integrity and functional competence of cellular materials, reducing the impact and consequences of tissue insult; the generation of ROS; and the cascade of subsequent pathological disorders. Moreover, restoration of cellular aerobic metabolic events, such as aerobic glycolysis and oxidative respiration, is an equally important collateral goal. A healthy diet and supplementation, providing an abundance of exogenous sources of antioxidants and a host of phytochemical dietary components, becomes even more important to restore aerobic metabolism; augment and assist in improving cellular structural integrity, and thereby reducing oxidative stress, damage, and inflammatory sequela. VMP35 MNC, a research-affirmed Prodosomed nutraceutical technology-based phytonutrient formulation, enriched in structurally diverse bioflavonoids, polyphenols, and phenolic saccharides, etc., have been shown to boost cellular structural integrity and physiological functions, and restore aerobic metabolic competence including for athletic performance as well as for general well-being. This review provides a strategic approach for the design of a novel Prodosomed VMP35 Multinutrient/phytoceutical complex and to evaluate its ability to reverse anaerobic pathologies, including inflammation, and restore healthy cellular aerobic glycolysis.
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