Metabolic Signatures of Oxidative Stress and Their Relationship with Erythrocyte Membrane Surface Roughness Among Workers of Manual Materials Handling (MMH)

North American Journal of Medical Sciences Pub Date : 2015-12-01 DOI:10.4103/1947-2714.172846

Subrata Ghosh, M. Acharyya, Titlee Majumder, Anandi Bagchi

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引用次数: 4

Abstract

Background: Brickfield workers in India perform manual materials handling (MMH) and as a result, are at a high risk of developing oxidative stress. This results in an alteration of the various markers of metabolic oxidative stress at the cellular level. Since red blood cell (RBC) is the central point where oxygen, glucose-6-phosphate dehydrogenase (G-6-PD), and glutathione (GSH) are involved, the surface roughness and its alteration and modeling with respect to workers exposed to MMH may be considered as helpful determinants in predicting early damage to the cell and restoring better health to the exposed population, that is, the worker exposed to stress. Hence, nanometric analysis of the surface roughness of the RBC may serve as an early indicator of the stress-related damage in these individuals. Aims: The purpose of the study was to identify early red blood corpuscular surface damage profile in terms of linear modeling correlating various biochemical parameters. Linear modeling has been aimed to be developed in order to demonstrate how individual oxidative stress markers such as malondialdehyde (MDA), G-6-PD, and reduced GSH are related to the RBC surface roughness [root mean square (RMS)]. Materials and Methods: Conventional analysis of these biochemical responses were evaluated in MMH laborers (age varying between 18 years and 21 years) and a comparable control group of the same age group (with sedentary lifestyles). Peak expiratory flow rate (PEFR) and RBC surface analysis by atomic-force microscopy (AFM) and correlated scanning probe microscopy (SPM-analytical software) with corresponding image analysis were performed immediately after completion of standardized exercise (MMH) at the brickfield. Results: A number of correlated significances and regressive linear models were developed among MDA, G-6-PD, GSH, and RBC surface roughness. Conclusion: It appears that these linear models might be instrumental in predicting early oxidative damages related to specific occupational hazards.

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手工搬运工人氧化应激代谢特征及其与红细胞膜表面粗糙度的关系

背景:印度的砖瓦工人从事手工材料处理(MMH)，因此，他们患氧化应激的风险很高。这导致在细胞水平上代谢氧化应激的各种标记物的改变。由于红细胞(RBC)是氧气、葡萄糖-6-磷酸脱氢酶(G-6-PD)和谷胱甘肽(GSH)参与的中心点，因此暴露于MMH的工人的表面粗糙度及其变化和建模可能被认为是预测细胞早期损伤和恢复暴露人群(即暴露于压力的工人)更好健康的有用决定因素。因此，红细胞表面粗糙度的纳米分析可以作为这些个体应力相关损伤的早期指标。目的:本研究的目的是通过建立各种生化参数相关的线性模型来确定早期红细胞表面损伤特征。线性模型的目的是为了证明个体氧化应激标志物，如丙二醛(MDA)、G-6-PD和减少的GSH是如何与RBC表面粗糙度相关的[均方根(RMS)]。材料和方法:对MMH工人(年龄在18岁到21岁之间)和同一年龄组(久坐不动的生活方式)的对照组进行常规生化反应分析。在砖场完成标准化运动(MMH)后立即用原子力显微镜(AFM)和相关扫描探针显微镜(spm -分析软件)进行呼气峰流速(PEFR)和红细胞表面分析，并进行相应的图像分析。结果:MDA、G-6-PD、GSH和RBC表面粗糙度之间建立了许多相关的显著性和回归的线性模型。结论:这些线性模型可能有助于预测与特定职业危害相关的早期氧化损伤。

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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North American Journal of Medical Sciences

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