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自参考离子选择性电极技术应用中的微电极制备及测试  ( EI收录)  

Test and preparation of microelectrode in applications of self-referencing ion electrode technique

文献类型:期刊文献

中文题名:自参考离子选择性电极技术应用中的微电极制备及测试

英文题名:Test and preparation of microelectrode in applications of self-referencing ion electrode technique

作者:薛琳[1,2];赵东杰[1];侯佩臣[3];王晓冬[3];王媛[1];王成[3];王忠义[1];黄岚[1]

第一作者:薛琳

通讯作者:Huang, L.

机构:[1]中国农业大学信息与电气工程学院;[2]北京联合大学信息学院;[3]国家农业信息化工程技术研究中心

第一机构:中国农业大学信息与电气工程学院,北京100083

年份:2013

卷号:29

期号:16

起止页码:182-189

中文期刊名:农业工程学报

外文期刊名:Transactions of the Chinese Society of Agricultural Engineering

收录:CSTPCD;;EI(收录号:20133516679269);Scopus(收录号:2-s2.0-84882957214);北大核心:【北大核心2011】;CSCD:【CSCD2013_2014】;

基金:国家重大科学仪器设备开发专项(2011YQ080052);中央高校基本科研业务费专项资金(2013YJ008)

语种:中文

中文关键词:无损检测;微电极;测试;硅烷化;能斯特斜率

外文关键词:non-distructive examination; microelectrodes; test; silanization; Nernstian slope

摘要:SIET(self-referencing ion electrode technique,自参考离子选择性电极技术)是电生理学研究的新手段,可以在植物抗逆研究中无损地获得植物细胞、组织、器官微区内离子流动态变化信息,而离子选择性微电极的制备及性能测试的标准化是SIET系统对植物活细胞、活体组织原位离子流测试的前提。该文以钾离子选择性微电极为例,详细讨论了离子选择性微电极的拉制、硅烷化、灌充等制备过程,研究了微电极内阻等电极参数的测量方法,测试了微电极的能斯特响应斜率、检测范围、响应时间等参数,讨论了制备过程中微电极性能的影响因素。离子选择性微电极使用WD-2型微电极拉制仪由无导液丝的TW150-3型硼硅酸盐玻璃毛细管拉制成形,其尖端直径为1~9μm,干燥后用5%硅烷试剂在150℃温度下做硅烷化处理,再灌充入内充液与LIX(liquid ion exchanger,液态离子交换剂)而制成。研究表明:LIX成分是影响微电极内阻的重要因素,灌充LIX后的钾离子选择微电极(LIX长度为150~210μm)内阻达到108~109Ω,明显高于灌充LIX前;微电极在0.01~500mmol/L K+浓度范围内具有很好的线性关系,R2=0.9998,能斯特斜率为53.095mV/dec;微电极对1和100mmol/L KCl溶液的平均响应时间t95%小于1s。研究结果表明,离子选择性玻璃微电极的制备过程是影响微电极性能的关键,微电极尖端尺寸、内阻、响应时间等参数对微电极的应用影响显著。该研究可为离子选择性微电极的制备及其在SIET系统中的应用提供参考。
An self-referencing ion electrode technique provides a novel electrophysiological tool which can non-invasively measure the dynamic influxes and effluxes of ions from cells and organs in vivo. In fact, the foundation of this technique is the fabrication and performance test of an ion selective microelectrode (ISME). In this paper, the K + ISMEs with good performances were obtained. We elaborated the procedure to prepare the glass micropipettes and to fill the pipettes with internal filling solution and liquid ion exchangers (LIX) of potassium, and then estimated the performance of these ion selective microelectrodes. Measurement of tip size, measuring method of resistance, testing of detection range, Nernstian slope, and response time, were described in detail. Ion selective microelectrodes were calibrated before and after experiments using two or more different kinds of concentrations of K + within its operating range based directly on the potentiometric analysis. The procedure for ion selective microelectrodes fabrication is strict. The electrodes (the diameter of the apex of the tip was 1~9 μm) were pulled from non-filamented borosilicate glass capillaries (TW150-3, World Precision Instruments, USA) on a vertical micropipette puller (WD-2, Chengdu Instrument Factory, Chengdu), oven dried, and then silanized by injecting 2 mL of 5% dimethyldichlorosilane (Sinopharm Chemcial Reagent Co. Ltd, Beijing) with n-hexane as the solvent in a glass preparation chamber at 150℃. Afterwards, dried and cooled electrode blanks were back-filled with a 100 mmol/L KCl solution. Immediately after back-filling, the microelectrode tips were front-filled with liquid ion exchangers of potassium (60031, Sigma, USA). Furthermore, some of the factors that affect the performance of the microelectrode in the preparation were discussed in detail. The ISME’s resistance reaches to 10 8 ~10 9 filling with LIX (length is 150~210 μm), much higher than that which occurs without LIX. The detection range obtained by the K + ISME is linear within a wide range of 0.01~500 mM KCl solutions with the slope of 53.095 mV per decade, and R 2 of 0.9998, which means the K + ISME response is in accordance with the Nernst equation. Besides the attainable Nernstian response range, the response time t 95% , from the beginning of that ISE immersed into the K + ion standard solutions with two concentrations, 1 and 100 mmol/L KCl, with 8 assays each concentration, to the 95% of stable potentials, is less than 1s. These measurements were made at room temperature (20~25℃). The results show that the fabrication of the ion selective glass microelectrodes is the key to obtaining the high performance of the microelectrode. The parameters of microelectrodes, i.e. tip size, resistance and response time, etc. are very important in practical application. This work can provide a reference basis for the fabrication and application in SIET of ion selective microelectrodes. Moreover, the standardized fabrication is the precondition to measure the dynamic influxes and effluxes of ions from cells and organs in vivo using the SIET.

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