[Determination of human serum total protein via electrophoresis titration and capacitively coupled contactless conductivity detection].

IF 1.2 4区 化学 Q4 CHEMISTRY, ANALYTICAL
Rui-Hua Zhang, Ze-Hua Guo, Qiang Zhang, Gen-Han Zha, Cheng-Xi Cao, Liu-Yin Fan, Wei-Wen Liu
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Under an electric field, ion migration results in different pH levels before and after the boundary, leading to a protein surface charge difference. The maintenance of the electrical neutrality of the substances in the detection channel is related to the protein surface charge; therefore, the ion concentration distribution of the substances in the detection channel changes as the protein surface charge varies. A plot of conductivity as a function of running time showed an \"inverted clock shape\", first falling and then rising. Owing to the addition of different types and concentrations of proteins, the microenvironment of the entire system changes, resulting in different changes in conductivity. Third, the performance of the detection system was tested using human serum albumin (HSA) standard protein, which was mixed with polyacrylamide gel (PAG) mother liquor, riboflavin, etc., and irradiated under ultraviolet light for 10 min to form a gel. The ET experiments were then carried out. The shape of the conductivity curve was consistent with the proposed principle, and the higher the HSA concentration, the lower the conductivity curve trough, followed by a lagged time of the trough. Quantitative analysis of the conductivity signals showed that the linear range was 0.25-3.00 g/L, with a linearity of up to 0.98. The limit of detection (LOD) was 0.01 g/L, the relative standard deviation (RSD) was 1.90%, and the relative error of the test values was <7.20%, indicating the good detection stability and sensitivity of the system. Clinical samples collected from healthy volunteers were used as target blood samples for serum total protein content measurement using our detection system. Blood samples from a volunteer were used to obtain a standard curve, and the serum samples of other four volunteers were selected for ET-C<sup>4</sup>D and biuret detection. 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引用次数: 0

Abstract

Serum total protein refers to the sum of all proteins in the serum, and its content determination is relevant to human health monitoring and disease diagnosis. However, existing detection techniques present a number of limitations; for example, the Kjeldahl method suffers from the negative effects of interfering substances such as non-protein nitrogen (NPN). Although the electrophoresis titration (ET) method has solved interference problems to some extent, the current ET technique relies on optical detection methods, which increases the tediousness of the operation. This study addresses the challenge of accurate serum total protein detection by combining the traditional ET technique with capacitively coupled contactless conductivity detection (C4D). The research contributions of this work are multifold. First, it presents the first development of an ET-C4D detection system, which consists of six components: an ET power module, an ET chip, a C4D sensing module, a detection module, a data acquisition card, and software. The developed system can capture the conductivity of substances in the channel using the software developed by our laboratory during ET. The detection system can be used to quantify the total protein content in human serum without the addition of specific labeling reagents or using optical detection equipment, and its running time is approximately 300 s. Second, this research proposes the corresponding principle of the system. Under an electric field, ion migration results in different pH levels before and after the boundary, leading to a protein surface charge difference. The maintenance of the electrical neutrality of the substances in the detection channel is related to the protein surface charge; therefore, the ion concentration distribution of the substances in the detection channel changes as the protein surface charge varies. A plot of conductivity as a function of running time showed an "inverted clock shape", first falling and then rising. Owing to the addition of different types and concentrations of proteins, the microenvironment of the entire system changes, resulting in different changes in conductivity. Third, the performance of the detection system was tested using human serum albumin (HSA) standard protein, which was mixed with polyacrylamide gel (PAG) mother liquor, riboflavin, etc., and irradiated under ultraviolet light for 10 min to form a gel. The ET experiments were then carried out. The shape of the conductivity curve was consistent with the proposed principle, and the higher the HSA concentration, the lower the conductivity curve trough, followed by a lagged time of the trough. Quantitative analysis of the conductivity signals showed that the linear range was 0.25-3.00 g/L, with a linearity of up to 0.98. The limit of detection (LOD) was 0.01 g/L, the relative standard deviation (RSD) was 1.90%, and the relative error of the test values was <7.20%, indicating the good detection stability and sensitivity of the system. Clinical samples collected from healthy volunteers were used as target blood samples for serum total protein content measurement using our detection system. Blood samples from a volunteer were used to obtain a standard curve, and the serum samples of other four volunteers were selected for ET-C4D and biuret detection. The results showed that the relative errors between the two methods were within 4.43%, indicating the accuracy and reliability of the detection system. The advantages of the ET-C4D detection system proposed in this paper are as follows: (i) ET-C4D realizes the rapid detection of total serum protein content based on the ET technique; (ii) compared with the traditional protein ET technique, the ET-C4D method does not rely on specific labeling components or optical detection equipment, thereby reducing the complexity of the operation; and (iii) the output signal of ET-C4D can be used for quantitative analysis with excellent analytical performance and high accuracy. These merits highlight the potential of the developed system for clinical application and biochemical analysis.

[通过电泳滴定和电容耦合非接触电导检测法测定人血清总蛋白]。
血清总蛋白是指血清中所有蛋白质的总和,其含量测定与人体健康监测和疾病诊断息息相关。然而,现有的检测技术存在许多局限性,例如凯氏定氮法受到非蛋白氮(NPN)等干扰物质的负面影响。虽然电泳滴定法(ET)在一定程度上解决了干扰问题,但目前的 ET 技术依赖于光学检测方法,增加了操作的繁琐性。本研究将传统的 ET 技术与电容耦合非接触电导检测(C4D)相结合,解决了血清总蛋白精确检测的难题。这项研究的贡献是多方面的。首先,它首次开发了 ET-C4D 检测系统,该系统由六个部分组成:ET 电源模块、ET 芯片、C4D 传感模块、检测模块、数据采集卡和软件。所开发的系统可利用本实验室在 ET 过程中开发的软件捕捉通道中物质的电导率。该检测系统无需添加特定的标记试剂,也无需使用光学检测设备,即可用于定量检测人体血清中的总蛋白质含量,其运行时间约为 300 秒。在电场作用下,离子迁移导致边界前后的 pH 值不同,从而产生蛋白质表面电荷差。检测通道中物质电中性的维持与蛋白质表面电荷有关,因此检测通道中物质的离子浓度分布会随着蛋白质表面电荷的变化而变化。电导率与运行时间的函数关系图显示出 "倒时钟形状",先下降后上升。由于加入了不同种类和浓度的蛋白质,整个系统的微环境发生了变化,从而导致电导率的不同变化。第三,使用人血清白蛋白(HSA)标准蛋白,将其与聚丙烯酰胺凝胶(PAG)母液、核黄素等混合,在紫外线下照射 10 分钟形成凝胶,测试检测系统的性能。然后进行 ET 实验。电导率曲线的形状与提出的原理一致,HSA 浓度越高,电导率曲线谷底越低,谷底时间滞后。对电导率信号的定量分析表明,其线性范围为 0.25-3.00 g/L,线性关系高达 0.98。检测限(LOD)为 0.01 g/L,相对标准偏差(RSD)为 1.90%,检测值的相对误差为 4D 和生物脲检测。结果表明,两种方法的相对误差在 4.43% 以内,表明检测系统准确可靠。本文提出的 ET-C4D 检测系统具有以下优点:(i)ET-C4D在ET技术的基础上实现了对血清总蛋白含量的快速检测;(ii)与传统的蛋白质ET技术相比,ET-C4D方法不依赖于特定的标记元件或光学检测设备,从而降低了操作的复杂性;(iii)ET-C4D的输出信号可用于定量分析,分析性能优异,准确度高。这些优点凸显了所开发系统在临床应用和生化分析方面的潜力。
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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来源期刊
色谱
色谱 CHEMISTRY, ANALYTICAL-
CiteScore
1.30
自引率
42.90%
发文量
7198
期刊介绍: "Chinese Journal of Chromatography" mainly reports the basic research results of chromatography, important application results of chromatography and its interdisciplinary subjects and their progress, including the application of new methods, new technologies, and new instruments in various fields, the research and development of chromatography instruments and components, instrument analysis teaching research, etc. It is suitable for researchers engaged in chromatography basic and application technology research in scientific research institutes, master and doctoral students in chromatography and related disciplines, grassroots researchers in the field of analysis and testing, and relevant personnel in chromatography instrument development and operation units. The journal has columns such as special planning, focus, perspective, research express, research paper, monograph and review, micro review, technology and application, and teaching research.
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