Hypoglycemia, Hyperglycemia and Astaxanthin: An in Vitro Alzheimer’s Disease Model

J. A. Griffith, S. Northrup, Emma Cieslik, Marie Kelly-Worden
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引用次数: 1

Abstract

Alzheimer’s Disease is projected to increase to 30 million people in the next 30 years and the rate of diabetes mellitus is projected to rise also. Hyperglycemia is commonly observed in patients with diabetes mellitus, and hypoglycemia is a common consequence due to insulin therapy. Previous research has shown a potential link between Alzheimer’s disease and diabetes. This study sought to determine if Astaxanthin (ATX) could prevent mitochondrial dysfunction from the compounded effects of amyloid β (Aβ) plaque and hypoglycemia or hyperglycemia. Growth patterns, ATP production, and ROS generation were examined in 2 μM, 5 μM, 25 μM (hypoglycemic groups), 2 mM, 5 mM (normal groups), and 25 mM glucose (hyperglycemic group), and then treated with or without ATX or Aβ. When hypoglycemia groups and the hyperglycemia group were treated with ATX, their growth patterns were either comparable to control or increased. ATX and Aβ treated cells demonstrated increased growth patterns over cells treated with Aβ alone. Aβ alone treated groups overall had significantly less growth than controls (p β demonstrated low levels of average fluorescence generated by ROS production as determined by MitoSox assay while ATX groups actually produced higher to normal levels of ROS. Cells grown in the presence of Aβ and ATX generally produced more ROS than just Aβ groups. Thus, hypoglycemia and hyperglycemia do appear to compound the effects of Aβ on hippocampal cells. ATX treatment demonstrated promise with increased cellular growth, which promoted usage of ATP by the cell and ROS production. This growth was present even in the presence of Aβ, suggesting that ATX is able to overcome the negative effects of Aβ.
低血糖、高血糖和虾青素:阿尔茨海默病体外模型
阿尔茨海默病预计在未来30年将增加到3000万人,糖尿病的发病率预计也将上升。高血糖常见于糖尿病患者,而低血糖是胰岛素治疗的常见后果。此前的研究表明,阿尔茨海默病和糖尿病之间存在潜在联系。本研究旨在确定虾青素(ATX)是否可以预防β淀粉样蛋白(Aβ)斑块和低血糖或高血糖的复合作用导致的线粒体功能障碍。在2 μM、5 μM、25 μM(低血糖组)、2 mM、5 mM(正常组)和25 mM葡萄糖(高血糖组)中检测生长模式、ATP生成和ROS生成,然后分别用或不加ATX或Aβ处理。当低血糖组和高血糖组接受ATX治疗时,它们的生长模式与对照组相当或增加。ATX和Aβ处理的细胞比单独用Aβ处理的细胞表现出更高的生长模式。Aβ单独处理组的总体生长明显低于对照组(通过MitoSox测定,p β显示ROS产生的平均荧光水平较低,而ATX组实际上产生高于正常水平的ROS。在存在Aβ和ATX的情况下生长的细胞通常比只有Aβ组产生更多的ROS。因此,低血糖和高血糖似乎确实复合了Aβ对海马细胞的影响。ATX处理显示出增加细胞生长的希望,这促进了细胞对ATP的使用和ROS的产生。即使在Aβ存在的情况下,这种生长也存在,这表明ATX能够克服Aβ的负面影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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