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用于阐明植物提取物(来自根部)及其生物活性成分对葡萄糖稳态调节特性的综合/筛选工具箱。

A comprehensive / screening toolbox for the elucidation of glucose homeostasis modulating properties of plant extracts (from roots) and its bioactives.

作者信息

Bauer Ilka, Rimbach Gerald, Cordeiro Sönke, Bosy-Westphal Anja, Weghuber Julian, Ipharraguerre Ignacio R, Lüersen Kai

机构信息

Division of Food Sciences, Institute of Human Nutrition and Food Science, University of Kiel, Kiel, Germany.

Institute of Physiology, University of Kiel, Kiel, Germany.

出版信息

Front Pharmacol. 2024 Jun 26;15:1396292. doi: 10.3389/fphar.2024.1396292. eCollection 2024.

DOI:10.3389/fphar.2024.1396292
PMID:38989154
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11233739/
Abstract

Plant extracts are increasingly recognized for their potential in modulating (postprandial) blood glucose levels. In this context, root extracts are of particular interest due to their high concentrations and often unique spectrum of plant bioactives. To identify new plant species with potential glucose-lowering activity, simple and robust methodologies are often required. For this narrative review, literature was sourced from scientific databases (primarily PubMed) in the period from June 2022 to January 2024. The regulatory targets of glucose homeostasis that could be modulated by bioactive plant compounds were used as search terms, either alone or in combination with the keyword "root extract". As a result, we present a comprehensive methodological toolbox for studying the glucose homeostasis modulating properties of plant extracts and its constituents. The described assays encompass investigations involving enzyme inhibition (α-amylase, α-glucosidase, dipeptidyl peptidase 4), assessment of sodium-dependent glucose transporter 1 activity, and evaluation of glucose transporter 4 translocation. Furthermore, we describe a patch-clamp technique to assess the impact of extracts on K channels. While validating findings in living organisms is imperative, we introduce two screenable models (the hen's egg test and ). Given that evaluation of the bioactivity of plant extracts in rodents and humans represents the current gold standard, we include approaches addressing this aspect. In summary, this review offers a systematic guide for screening plant extracts regarding their influence on key regulatory elements of glucose homeostasis, culminating in the assessment of their potential efficacy . Moreover, application of the presented toolbox might contribute to further close the knowledge gap on the precise mechanisms of action of plant-derived compounds.

摘要

植物提取物在调节(餐后)血糖水平方面的潜力日益受到认可。在此背景下,根提取物因其高浓度以及通常独特的植物生物活性成分谱而备受关注。为了鉴定具有潜在降血糖活性的新植物物种,通常需要简单且可靠的方法。在本叙述性综述中,文献来源于2022年6月至2024年1月期间的科学数据库(主要是PubMed)。将可被生物活性植物化合物调节的葡萄糖稳态调节靶点用作检索词,单独使用或与关键词“根提取物”组合使用。结果,我们展示了一个全面的方法工具箱,用于研究植物提取物及其成分调节葡萄糖稳态的特性。所描述的测定包括涉及酶抑制(α -淀粉酶、α -葡萄糖苷酶、二肽基肽酶4)的研究、钠依赖性葡萄糖转运蛋白1活性的评估以及葡萄糖转运蛋白4易位的评估。此外,我们描述了一种膜片钳技术来评估提取物对钾通道的影响。虽然在活生物体中验证研究结果至关重要,但我们引入了两种可筛选模型(鸡蛋试验和……)。鉴于在啮齿动物和人类中评估植物提取物的生物活性是当前的金标准,我们纳入了涉及这方面的方法。总之,本综述为筛选植物提取物对葡萄糖稳态关键调节元件的影响提供了系统指南,最终评估其潜在功效。此外,所展示的工具箱的应用可能有助于进一步缩小关于植物源化合物精确作用机制的知识差距。

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2
and studies reveal antidiabetic properties of arylbenzofurans from the root bark of Stapf.并且研究揭示了来自施塔普夫(Stapf)根皮的芳基苯并呋喃的抗糖尿病特性。
Front Pharmacol. 2024 Feb 23;15:1338333. doi: 10.3389/fphar.2024.1338333. eCollection 2024.
3
Bioassay-guided discovery and identification of new potent α-glucosidase inhibitors from Morus alba L. and the interaction mechanism.
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J Ethnopharmacol. 2024 Mar 25;322:117645. doi: 10.1016/j.jep.2023.117645. Epub 2023 Dec 24.
4
Chemical profile and quantitative comparison of constituents in different medicinal parts of during varied harvest periods using UPLC-MS/MS method.采用超高效液相色谱-串联质谱法对不同采收期的不同药用部位的成分进行化学特征分析和定量比较。
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