[Detection and analysis of moving reaction boundary-based electrophoresis distance using smartphone images].

IF 1.2 4区 化学 Q4 CHEMISTRY, ANALYTICAL 色谱 Pub Date : 2023-09-01 DOI:10.3724/SP.J.1123.2023.06001
Xin-Qiao Song, Ze-Hua Guo, Wei-Wen Liu, Gen-Han Zha, Liu-Yin Fan, Cheng-Xi Cao, Qiang Zhang
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引用次数: 0

Abstract

Electrophoresis titration (ET) based on the moving reaction boundary (MRB) theory can detect the analyte contents in different samples by converting content signals into distance signals. However, this technique is only suitable for on-site qualitative testing, and accurate quantification relies on complex optical equipment and computers. Hence, applying this method to real-time point-of-care testing (POCT) is challenging. In this study, we developed a smartphone-based ET system based on a visual technique to achieve real-time quantitative detection. First, we developed a portable quantitative ET device that can connect to a smartphone; this device consisted of five components, namely, an ET chip, a power module, a microcontroller, a liquid crystal display screen, and a Bluetooth module. The device measured 10 cm×15 cm×2.5 cm, weighed 300 g, and was easy to hold. Thus, it is suitable for on-site testing with a run time of only 2-4 min. An assistant mobile software program was also developed to control the device and perform ET. The colored electrophoresis boundary can be captured using the smartphone camera, and quantitative detection results can be obtained in real time. Second, we proposed a quantitative algorithm based on ET channels. The software was used to recognize the boundary migration distance of three channels, a standard curve based on two given contents of the standards was established using the two-point method, and the content of the test sample was calculated. Human serum albumin (HSA) and uric acid (UA) were used as a model protein and biosample, respectively, to test the performance of the detection system. For HSA detection, different HSA solutions were mixed with a polyacrylamide gel (PAG) stock solution, phenolphthalein was added as an indicator, and sodium persulfate and tetramethyl ethylenediamine (TEMED) were used to promote polymerization to form a gel. For UA detection, agarose gel was filled into the ET channel, the UA sample, urate oxidase, and leucomalachite green were added into the anode cell and incubated for 20 min. ET was then performed. The fitting goodness (R2) values of HSA and UA were 0.9959 and 0.9935, respectively, with a linear range of 0.5-35.0 g/L and a log-linear range of 100-4000 μmol/L. The limits of detection for HSA and UA were 0.05 g/L and 50 μmol/L, respectively, and the corresponding relative standard deviations (RSDs) were not greater than 2.87% and 3.21%, respectively. These results demonstrate that the detection system has good accuracy and sensitivity. Clinical samples collected from healthy volunteers were used as target blood samples, and the developed system was used to measure serum total protein and UA levels. Serum samples from five volunteers were selected, standard curves of total serum protein and UA were established, and the test results were compared with hospital standard testing results. The relative errors for serum total protein and UA were less than 6.03% and 6.21%, respectively, and the corresponding RSDs were less than 3.72% and 5.84%, respectively. These findings verify the accuracy and reliability of the proposed detection system. The smartphone-based ET detection system introduced in this paper presents several advantages. First, it enables the portable real-time detection of total serum protein and UA. Second, compared with traditional ET strategies based on colored boundaries, it does not rely on optical detection equipment or computers to obtain quantitative detection results; as such, it can reduce the complexity of the operation and provide portability and real-time metrics. Third, the detection of two biomarkers, serum total protein and UA, is achieved on the same device, thereby improving the multitarget detection potential of the ET method. These advantages render the developed method a promising detection platform for clinical applications and real-time POCT.

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[使用智能手机图像检测和分析基于移动反应边界的电泳距离]。
基于移动反应边界(MRB)理论的电泳滴定(ET)可以通过将含量信号转换为距离信号来检测不同样品中的分析物含量。然而,这项技术仅适用于现场定性测试,准确的定量依赖于复杂的光学设备和计算机。因此,将这种方法应用于实时护理点测试(POCT)具有挑战性。在本研究中,我们开发了一种基于视觉技术的智能手机ET系统,以实现实时定量检测。首先,我们开发了一种便携式定量ET设备,可以连接到智能手机;该装置由ET芯片、电源模块、微控制器、液晶显示屏和蓝牙模块五部分组成。该装置尺寸为10厘米×15厘米×2.5厘米,重量为300克,易于握持。因此,它适用于现场测试,运行时间仅为2-4分钟。还开发了一个辅助移动软件程序来控制设备并执行ET。使用智能手机摄像头可以捕捉彩色电泳边界,并实时获得定量检测结果。其次,我们提出了一种基于ET通道的定量算法。该软件用于识别三个通道的边界偏移距离,使用两点法建立了基于两个给定标准内容的标准曲线,并计算了试样的含量。使用人血清白蛋白(HSA)和尿酸(UA)分别作为模型蛋白和生物样品来测试检测系统的性能。对于HSA检测,将不同的HSA溶液与聚丙烯酰胺凝胶(PAG)储备溶液混合,加入酚酞作为指示剂,并使用过硫酸钠和四甲基乙二胺(TEMED)促进聚合以形成凝胶。对于UA检测,将琼脂糖凝胶填充到ET通道中,将UA样品、尿酸盐氧化酶和无色孔雀绿加入阳极细胞中并孵育20分钟。然后进行ET。HSA和UA的拟合优度(R2)分别为0.9959和0.9935,线性范围为0.5-35.0g/L,对数线性范围为100-4000μmol/L。HSA和UA的检测限分别为0.05 g/L和50μmol/L,相应的相对标准偏差(RSD)分别不大于2.87%和3.21%。这些结果表明,该检测系统具有良好的精度和灵敏度。从健康志愿者身上采集的临床样本被用作目标血液样本,所开发的系统被用于测量血清总蛋白和UA水平。选择5名志愿者的血清样本,建立血清总蛋白和UA的标准曲线,并将检测结果与医院标准检测结果进行比较。血清总蛋白和UA的相对误差分别小于6.03%和6.21%,相应的RSD分别小于3.72%和5.84%。这些发现验证了所提出的检测系统的准确性和可靠性。本文介绍的基于智能手机的ET检测系统具有几个优点。首先,它实现了血清总蛋白和UA的便携式实时检测。其次,与传统的基于彩色边界的ET策略相比,它不依赖光学检测设备或计算机来获得定量检测结果;因此,它可以降低操作的复杂性,并提供可移植性和实时度量。第三,在同一设备上实现了血清总蛋白和UA两种生物标志物的检测,从而提高了ET方法的多靶点检测潜力。这些优点使所开发的方法成为临床应用和实时POCT的一个有前途的检测平台。
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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.
期刊最新文献
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