BIOSENSOR FOR THIAMINE DETECTION USING YEAST SACCHAROMYCES CEREVISIAE

JOURNAL ONLINE OF PHYSICS Pub Date : 2022-11-22 DOI:10.22437/jop.v8i1.21411

Leonardus Riski Nainggolan, S. R. Ibmar, Sumi Komala, V. A. Rosandi, L. Umar

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Abstract

Nowadays, people's lifestyles have undergone significant changes, such as decreased physical activity and increased sedentary behavior, as well as an increase in nutritionally unbalanced diets, especially in vitamin B1 (thiamine) intake. Deficiency and excess of thiamine can cause various diseases. Based on this, it is important to know the level of thiamine intake in dietary supplements and medicines. This study used a biosensor with amperometric principles to determine the effect of thiamine on the yeast Saccharomyces cerevisiae as a cell model. Measurements were made by adding controlled vitamins to cell metabolic activity using an amperometric biosensor based on Pt/Ag electrodes. An amperometric biosensor will measure the current from a reduction and oxidation reaction with a constant potential. The effect of adding vitamins to yeast cells was observed in the form of cellular respiration, which was expressed as a parameter of dissolved oxygen level (DO). Vitamins used as samples were given various concentrations of 30 mM, 45 mM, and 60 mM. The addition of thiamine causes an increase in the potential value for each increase in concentration, indicating that DO levels in the cell environment have decreased due to yeast cells consuming O2 during the respiration process. The results of this study indicate that yeast cell-based biosensors can detect variations in the concentration of thiamine for further health applications.

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利用酵母、酿酒酵母检测硫胺素的生物传感器

如今，人们的生活方式发生了重大变化，如体力活动减少，久坐行为增加，以及营养不平衡的饮食增加，特别是维生素B1(硫胺素)的摄入量增加。缺乏和过量的硫胺素可引起各种疾病。基于此，了解膳食补充剂和药物中硫胺素的摄入量是很重要的。本研究采用安培原理的生物传感器测定硫胺素对酵母(Saccharomyces cerevisiae)细胞模型的影响。通过使用基于Pt/Ag电极的安培生物传感器将受控维生素添加到细胞代谢活性中进行测量。安培式生物传感器将以恒定电位测量还原和氧化反应产生的电流。添加维生素对酵母细胞的影响以细胞呼吸的形式进行观察，以溶解氧水平(DO)为参数表示。作为样品的维生素被给予30mm、45mm和60mm的不同浓度。硫胺素的添加导致浓度每增加一次，潜在值就会增加，这表明细胞环境中的DO水平由于酵母细胞在呼吸过程中消耗氧气而降低。本研究结果表明，基于酵母细胞的生物传感器可以检测硫胺素浓度的变化，用于进一步的健康应用。

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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JOURNAL ONLINE OF PHYSICS

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