Rapid Simulation of Electrode Surface Treatment Based on Monte-Carlo Model_Journal of Biomedical Engineering

Authors：

HUZhengtian ¹ ,  XUYing ¹ , GUOMiao ¹ , SUNZhitong ¹ , LIYan ²

1. Biomedical Engineering Institute, Hangzhou Dianzi University, Hangzhou 310018, China;
2. Department of Comprehensive Review, National Patent Office, Beijing 100088, China;

Corresponding author：

XUYing, Email: xuyingxy@hdu.edu.cn

Keywords：

surface treatment of electrode; nanoparticle; Monte-Carlo model; grid search

DOI：

10.7507/1001-5515.20140258

Video：

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Micro- and integrated biosensor provides a powerful means for cell electrophysiology research. The technology of electroplating platinum black on the electrode can uprate signal-to-noise ratio and sensitivity of the sensor. For quantifying analysis of the processing method of electroplating process, this paper proposes a grid search algorithm based on the Monte-Carlo model. The paper also puts forward the operational optimization strategy, which can rapidly implement the process of large-scale nanoparticles with different particle size of dispersion (20-200 nm) attaching to the electrode and shortening a simulation time from average 20 hours to 0.5 hour when the test number is 10 and electrode radius is 100 μm. When the nanoparticle was in a single layer or multiple layers, the treatment uniformity and attachment rate was analyzed by using the grid search algorithm with different sizes and shapes of electrode. Simulation results showed that under ideal conditions, when the electrode radius is less than 100 μm, with the electrode size increasing, it has an obvious effect for the effective attachment and the homogeneity of nanoparticle, which is advantageous to the quantitative evaluation of electrode array's repeatability. Under the condition of the same electrode area, the best attachment is on the circular electrode compared to the attachments on the square and rectangular ones.

Citation： HUZhengtian, XUYing, GUOMiao, SUNZhitong, LIYan. Rapid Simulation of Electrode Surface Treatment Based on Monte-Carlo Model. Journal of Biomedical Engineering, 2014, 31(6): 1361-1367. doi: 10.7507/1001-5515.20140258 Copy

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1. PRICE D T, RAHMAN A R, BHANSALI S. Design rule for optimization of microelectrodes used in electric cell-substrate impedance sensing (ECIS)[J]. Biosens Bioelectron, 2009, 24(7):2071-2076.
2. FERGUSON J E, BOLDT C, REDISH A D. Creating low-impedance coatings for neural recording electrodes using electroplating inhibitors[J]. J Med Devices, 2009, 3(2):27523-27523.
3. 张英.化学修饰电极电催化过氧化氢、有机及生物小分子的研究[D].重庆:西南大学,2006:1-49.
4. PORNPRASERTSUK R, CHENG J, HUANG H, et al. Electrochemical impedance analysis of solid oxide fuel cell electrolyte using kinetic Monte Carlo technique[J]. Solid State Ionics, 2007, 178(3):195-206.
5. MATHERS A, MOON K S, YI J. A vibration-based PMN-PT energy harvester[J]. IEEE Sens J, 2009, 9(7):731-739.
6. BIOPHYSICS A, Inc. ECIS cultureware[EB/OL] [2013-08-29]. http://www.biophysics.com/PDFS.php.
7. NEHER E. Molecular biology meets microelectronics[J]. Nat Biotechnol, 2001, 19(2):114.
8. 徐莹,韩斌,徐铭恩,等.基于MONTE-CARLO模型的细胞传感器纳米颗粒表面处理分析[J].传感技术学报,2011,24(4):480-486.
9. QIN M, HOU S, WANG L, et al. Two methods for glass surface modification and their application in protein immobilization[J]. Colloids Surf B Biointerfaces, 2007, 60(2):243-249.
10. MA Z, MAO Z, GAO C. Surface modification and property analysis of biomedical polymers used for tissue engineering[J]. Colloids Surf B Biointerfaces, 2007, 60(2):137-157.
11. MANLY B F J. Randomization, bootstrap and monte carlo methods in biology[M].3rd edn. London:Chapman & Hall, 2006:171-257.
12. 沈良.高分子有机/无机纳米复合材料的制备及其结构性能研究[D].上海:复旦大学,2006.
13. BENILOVA I V, VIDIC J M, PAJOT-AUGY E, et al. Electrochemical study of human olfactory receptor OR 17-40 stimulation by odorants in solution[J].Mater Sci Eng, 2008, 28(5-6):633-639.
14. 郑环宇.(Zn-Ni)-Al₂O₃纳米复合镀层的制备及耐蚀性能研究[D].哈尔滨:哈尔滨工业大学,2007.
15. 宋超群,井西利,段玉华.非均匀基底薄膜生长的Monte Carlo模拟研究[J].高师理科学刊,2009,29(1):58-61.
16. YANG Y G, JOHNSON R A, WADLEY H G. A Monte Carlo simulation of physical vapor deposition of nickel[J]. Acta Mater, 1997, 45(3):1445-1468.

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