基于智能手机图像的移动反应界面电泳距离检测和分析

doi:10.3724/SP.J.1123.2023.06001

摘要/Abstract

摘要：

现有的电泳滴定(electrophoresis titration, ET)技术仍采用计算机进行数据处理和分析,其定量检测的即时性和便携性仍存在明显不足。针对这一问题,本文发展了一种基于智能手机的ET系统,实现了ET的即时性定量分析。该系统集成了三通道电泳滴定芯片与蓝牙通信功能,并设计了手机软件。通过该软件,不仅可以控制ET装置的电泳运行,还可以调用手机摄像头获取有色电泳界面,即时识别反应界面并显示定量检测结果。ET装置尺寸为10 cm×15 cm×2.5 cm,重300 g,可轻松手持,适用于现场检测。本文以人源血清总蛋白和尿酸(UA)为研究目标,分别使用基于聚丙烯酰胺凝胶的蛋白电泳酸碱滴定与基于琼脂糖凝胶的尿酸酶催化电泳滴定进行检测分析。用人血清白蛋白(HSA)标准品与尿酸标准品验证装置的性能,结果表明:HSA和UA的拟合优度(决定系数)分别为0.9959和0.9935,线性(或对数线性)范围分别为0.5~35.0 g/L和100~4000 μmol/L,检出限分别为0.05 g/L和50 μmol/L,相对标准偏差最大值分别为2.87%和3.21%,表明该系统具有较好的检测准确性和稳定性。选取了5位志愿者的血清样本,针对人源实际血样中的血清总蛋白含量和尿酸含量进行检测,并与医院临床检测所使用方法的检测结果进行对比,检测相对误差分别≤6.03%和6.21%,证明本文提出的检测系统是一种具有综合性检测潜力的通用平台,具有临床应用价值与现场检测潜力。

关键词: 电泳滴定, 血清标志物, 手机检测, 即时检测

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.

Key words: electrophoretic titration, serum markers, smartphone detection, real-time detection

中图分类号:

O658

宋欣樵, 郭泽华, 刘伟文, 查根晗, 樊柳荫, 曹成喜, 张强. 基于智能手机图像的移动反应界面电泳距离检测和分析[J]. 色谱, 2023, 41(9): 752-759.

SONG Xinqiao, GUO Zehua, LIU Weiwen, ZHA Genhan, FAN Liuyin, CAO Chengxi, ZHANG Qiang. Detection and analysis of moving reaction boundary-based electrophoresis distance using smartphone images[J]. Chinese Journal of Chromatography, 2023, 41(9): 752-759.

图/表 8

图 1 ET检测系统示意图

Fig. 1 Schematic diagram of electrophoresis titration (ET) detection system a. model diagram of portable ET device with three channels. 1. three-channel ET chip; 2. touch screen; 3. charging interface; 4. device switch. b. smartphone and software interface. The user uses software to control the electrophoresis process through Bluetooth. Call the smartphone camera through the software, take the electrophoresis results, and show the quantitative results after program analysis and calculation. c. structure diagram of portable ET device. The device consists of power supply (rechargeable lithium battery), microcontroller (stm32), touch screen (liquid crystal display, LCD), Bluetooth (B-0004 wireless transmission), and three-channel ET chip (independently developed in the laboratory).

图 2 ET结果识别和定量方法流程图

Fig. 2 Flow chart of ET result recognition and quantification method

图 3 采用HSA和UA对于检测系统进行性能测试的结果图(n=3)

Fig. 3 Results of performance testing of the detection system using HSA and UA (n=3) a. relationship between moving reaction boundary (MRB) motion distance and running time for HSA under five content levels (10-30 g/L); b. calibration curves of MRB motion distance and protein content for HSA; c. relationship between MRB motion distance and running time for UA under five content levels (100-1000 μmol/L); d. calibration curves of MRB motion distance and UA content.

表 1 HSA与UA的线性范围、LOD及RSD

Table 1 Linear ranges, LODs and RSDs of HSA and UA

Analyte	Linear range	LOD	RSD/%(n=3)
HSA	0.5-35.0 g/L	0.05 g/L	2.87
UA	100-4000 μmol/L	50 μmol/L	3.21

图 4 采用实际血样中总蛋白和尿酸对于检测系统进行性能测试的结果图(n=3)

Fig. 4 Results of performance testing of the detection system using TP and uric acid in a real serum sample (n=3) a. relationship between MRB motion distance and running time for serum TP under five content levels (9.77-34.2 g/L); b. calibration curve of MRB motion distance and TP content in serum; c. relationship between MRB motion distance and running time for UA under five content levels (97.75-991 μmol/L); d. calibration curve of MRB motion distance and UA content in serum.

图 5 (a)血清总蛋白和(b)尿酸实际检测结果图

Fig. 5 Actual detection results of (a) serum total protein and (b) uric acid U: upper standard; L: lower standard; S: sample.

表 2 临床血清样本总蛋白检测结果

Table 2 Detection results of total protein (TP) in clinical serum samples

Serum sample	Hospital detection result/(g/L)	ET method/ (g/L)	Relative error/%	RSD of ET method/ %(n=3)
1	68.4	71.39	4.37	1.55
2	73.7	78.14	6.03	1.48
3	61.8	64.96	5.12	2.80
4	48.5	49.88	2.85	3.72
5	51.8	54.22	4.68	3.49

表 3 临床血清样本尿酸检测结果

Table 3 Detection results of UA in clinical serum samples

Serum sample	Hospital detection results/(μmol/L)	ET method/ (μmol/L)	Relative error/%	RSD of ET method/ %(n=3)
1	391	401.1	2.58	3.18
2	327	337.2	3.12	2.96
3	380	403.6	6.21	4.25
4	156	156.7	0.45	5.84
5	163	172.5	5.83	2.63

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