[59] Ultra-sensitive cholesterol biosensor based on low
Transcription
[59] Ultra-sensitive cholesterol biosensor based on low
Electrochemistry Communications 11 (2009) 118–121 Contents lists available at ScienceDirect Electrochemistry Communications journal homepage: www.elsevier.com/locate/elecom Ultra-sensitive cholesterol biosensor based on low-temperature grown ZnO nanoparticles Ahmad Umar, M.M. Rahman, Mohammad Vaseem, Yoon-Bong Hahn * School of Semiconductor and Chemical Engineering, BK21 Centre for Future Energy Materials and Devices and Nanomaterials Research Processing Centre, Chonbuk National University, 664-14, Duckjin Dong, 1 Ga Jeonju, Jeonju, Cholla Bukto 561-756, South Korea a r t i c l e i n f o Article history: Received 2 October 2008 Received in revised form 11 October 2008 Accepted 15 October 2008 Available online 30 October 2008 Keywords: ZnO nanoparticles Cholesterol oxidase Cholesterol biosensor a b s t r a c t A high-sensitive cholesterol amperometric biosensor based on the immobilization of cholesterol oxidase (ChOx) onto the ZnO nanoparticles has been fabricated which shows a very high and reproducible sensitivity of 23.7 lA mM1 cm2, detection limit (based on S/N ratio) 0.37 ± 0.02 nM, response time less than 5 s, linear range from 1.0 to 500.0 nM and correlation coefficient of R = 0.9975. A relatively low value of enzyme’s kinetic parameter (Michaelis–Menten constant) 4.7 mM has been obtained which indicates the enhanced enzymatic affinity of ChOx to Cholesterol. To the best of our knowledge, this is the first report in which such a very high-sensitivity and low detection limit has been achieved for the cholesterol biosensor by using ZnO nanostructures modified electrodes. Ó 2008 Elsevier B.V. All rights reserved. 1. Introduction Cholesterol and its fatty acid esters are one of the main constituents for the human beings as they are the components of nerve and brain cells [1] and are the precursors for other biological materials, such as bile acid and steroid hormones [2]. Due to high-rate of clinical disorders, such as heart disease, coronary artery disease, cerebral thrombosis, etc. (caused by the anomalous levels of cholesterol in blood), it is desirable to develop a reliable and sensitive biosensor which can allow a convenient and rapid determination of cholesterol [3,4]. The amperometric biosensor (which is based on the proper immobilization of enzyme on suitable matrixes) offers a portable, cheap, and rapid method for the determination of cholesterol [5–17]. Due to exotic properties, it is expected that biocompatible nanomaterials could be the promising matrixes for enzyme immobilization which can enhance the sensitivity and selectivity of biosensors [5–10]. Among different nanomaterials, the ZnO nanostructures possess a special place due to their own merits such as high specific surface area, optical transparency, bio-compatibility, non-toxicity, chemical and photochemical stability, ease of fabrication, high-electron communication features, electrochemical activities, and so on. Even having versatile properties, the biosensor applications of ZnO nanostructures are very rare. There are only two reports on ZnO nanostructures based cholesterol biosensor [11,12]. Cholesterol biosensor based on rf-sputtered ZnO nanoporous thin films exhibited a linear range of * Corresponding author. Tel.: +82 63 270 2439; fax: +82 63 270 2306. E-mail addresses: [email protected] (A. Umar), [email protected] (Y.-B. Hahn). 1388-2481/$ - see front matter Ó 2008 Elsevier B.V. All rights reserved. doi:10.1016/j.elecom.2008.10.046 25–400 mg dl1 and response time 15 s [11]. A cholesterol biosensor based on ZnO nanoparticles–chitosan composite films shows the linear range of 5–300 mg dl1, detection limit of 5 mg dl1, and sensitivity of 1.41 104 Amg dl1 [12]. In this paper, ultrasensitive cholesterol biosensors based on the immobilization of ChOx onto the ZnO nanoparticles is presented showed a very high and reproducible sensitivity of 23.7 lA mM1 cm2, detection limit of 0.37 ± 0.02 nM and linear dynamic range from 1 to 500 nM. To the best of our knowledge, this is the first report in which such a very high-sensitivity and low detection limit has been achieved for the cholesterol biosensor by using ZnO nanostructures modified electrodes. 2. Experimental details In a typical synthesis process, aqueous solutions of 0.1 M zinc acetate dihydrate (ZnAc) and 0.05 M HMTA (each 50.0 ml) were mixed under continuous stirring and subsequently, stock aqueous solution of 1.0 M LiOH was slowly added in this solution until the solution pH became 10. The obtained solution was then refluxed at 90.0 °C for 3 h. White precipitates were obtained which were filtered off, washed thoroughly with deionized water and ethanol, and dried at room temperature. For the fabrication of cholesterol biosensors, ChOx was immobilized onto the ZnO nanoparticles, coated onto gold (Au) electrode surface (3.0 mm2), by physical adsorption technique. The ZnO nanoparticles surface was immobilized in a solution of ChOx (1.0 mg/ml), prepared in phosphate buffer (PBS, pH 7.4) 150.0 mM (0.9% NaCl) for 24 h. The electrode is kept overnight for ChOx immobilization and subsequently washed with buffer solution, A. Umar et al. / Electrochemistry Communications 11 (2009) 118–121 and dried in nitrogen environment. After drying the modified ChOx/ ZnO/Au electrode, a 10.0 ll Nafion solution was dropped onto the electrode and dried for 24 h at 4.0 °C to form a film on the modified electrode. When, not in use, the ZnO modified gold electrodes (i.e., Nafion/ChOx/ZnO/Au electrodes) were stored in PBS at 4.0 °C. The electrochemical experiments were carried with a conventional three-electrode configuration. 3. Results and discussion Fig. 1a exhibits the typical FESEM image of the as-grown nanoparticles which shows that the grown products are synthesized in a large-quantity with almost uniform sizes and shapes. The nanoparticles are almost spherical and triangular shaped while some of them also possess hexagonal structures. The typical sizes of the grown nanoparticles were 80 ± 20 nm. All the obtained peaks in the X-ray diffraction pattern of as-grown nanoparticles are similar to known wurtzite-structured hexagonal phase single crystalline bulk ZnO (JCPDS Card No. 36–1451) confirming the synthesis of 119 pure ZnO nanoparticles (Fig. 1b). Even not shown here, the EDS also confirmed that the grown nanoparticles are made with almost 1:1 stoichiometry of zinc and oxygen, respectively. The low-magnification TEM image (Fig. 1c) of as-grown ZnO nanoparticles revealed the full consistency with the FESEM observation (Fig. 1a) in terms of density and dimensionality. The high-resolution TEM (HRTEM) image shown in Fig. 1d gives the lattice fringe of about 0.26 nm, corresponding to the (0 0 0 2) fringes, clearly confirms the single crystallinity and wurtzite hexagonal phase of the as-synthesized nanoparticles. The composition and quality of the product was analyzed by the FTIR, in the range of 400–4000 cm1 (Fig. 1e). The band at 434 cm1 is correlated to zinc oxide [13]. A broad band in the range of 3350–3500 cm1 and at 1632 cm1 corresponds to OAH stretching and bending modes of vibrations, respectively [14]. The presence of other bands at 878, 1380, and 2359 cm1 are probably due to the carbonate moieties which generally observed when FTIR samples are measured in air [13]. A sharp band at 375 nm, from the room temperature UV–vis absorption spectrum, was observed from the synthesized ZnO nanoparticles, Fig. 1. Typical (a) FESEM image; (b) X-ray diffraction pattern; (c) low-magnification and (d) high-resolution TEM images; (e) FTIR spectrum and (f) UV–vis spectrum of the assynthesized ZnO nanoparticles grown at low temperature by aqueous solution process. 120 A. Umar et al. / Electrochemistry Communications 11 (2009) 118–121 exhibiting a characteristic band for the wurtzite hexagonal pure ZnO [14] (Fig. 1f). Fig. 2a exhibits the schematic of the modification of gold electrode with ZnO nanoparticles, ChOx and Nafion for efficient detection of cholesterol. Fig. 2b shows a cyclic voltammetric (CV) sweep curve for the ZnO-modified gold electrode (Nafion/ChOx/ZnO/Au) without (dotted line) and with (solid line) 0.1 mM cholesterol in 0.1 M PBS buffer at pH 7.4 in the range of 0.3 to 0.7 V at scan rate of 100 mV/s. The CV curve of Nafion/ChOx/ZnO/Au electrode with cholesterol in PBS shows an increase in current from 0.01 to 0.68 V compared to PBS without cholesterol, confirming the electrochemical response of the Nafion/ChOx/ZnO/Au electrode in cholesterol. A peak at approximately +0.355 V has been observed from the CV curve of Nafion/ChOx/ZnO/Au electrode in PBS with 0.1 mM cholesterol which is because of the generation of H2O2 during the oxidation of cholesterol by ChOx. Due to high surface area of ZnO nanoparticles, the ChOx attached to the surfaces of nanoparticles facilitates the faster direct electron transfer between the active sites of immobilized ChOx and electrode surface which leads to a sharper and well-defined peak. Therefore, cholesterol is efficiently detected with the Nafion/ChOx/ZnO/Au electrodes. According to the previous report, the electrochemical reaction for the detection of cholesterol in presence of ChOx is proposed and the enzymatic reaction is written as ChOx Cholesterol þ O2 ! Cholestenone þ H2 O2 The amperometry under stirred conditions has a much higher current sensitivity than the cyclic voltammetry, hence the amperometric experiments have been performed under continuous stirring. A typical amperometric response of the Nafion/ChOx/ZnO/ Au electrode on a successive addition of cholesterol (from 1.0 to 700.0 nM) into continuously stirred 0.01 M PBS solution (pH 7.4) at an applied potential of +0.355 V is shown in Fig. 2c. With successively increasing the concentration of cholesterol, the sensing current increases and 95% steady state response was achieved in less than 5 s which confirms a good electro-catalytic and fast electron exchange behavior of modified electrode. Fig. 2d exhibits the relation between the response current and cholesterol concentration for the fabricated amperometric sensor which clearly shows that the response current increases as the concentration of cholesterol increases and saturated at high concentration of cholesterol which suggests the saturation of active sites of the enzymes at those cholesterol levels. Under optimized conditions, the steady-state current showed a linear dynamic range of 1.0 to 500.0 nM (Fig. 2d). The correlation coefficient (R) was estimated to be R = 0.9975 and the sensitivity was found to be 23.7 lA mM1 cm2 from the fabricated biosensor. The detection limit, estimated based on signal to noise ratio (S/N = 3), was found to be 0.37 ± 0.02 nM. To the best of our knowledge, this is the first time such a very high-sensitivity and low detection limit has been achieved for cholesterol biosensors by using ZnO nanostructures modified electrodes. The apparent Michaelis–Menten constant (Kmapp) which gives an indication of the enzyme substrate kinetics can be calculated from the Lineweaver–Burk equation 1/i = (Kmapp/imax) (1/C) + (1/imax), where i is the current, imax is the maximum current measured under saturated substrate conditions, and C is the cholesterol concentration. The Kmapp value was determined by the analysis of the slope and intercept for the plot of the reciprocals of steady-state current vs. cholesterol concentrations, i.e., the Lineweaver–Burk plot of 1/i vs. 1/C (Fig. 2e). According to the Lineweaver–Burk plot, the Kmapp is calculated to be 4. 7 mM. The lower Kmapp value can be attributed to the favorable confirmation of the enzyme and an efficient ChOx loading provided by the microenvironment of ZnO nanoparticles surfaces. For comparison, the performances of the fabricated biosensor is compared with the previously reported cholesterol biosensors based on the utilization of different materials as the working electrode (Table 1) and it was confirmed that the presented ZnO nanoparticles based cholesterol biosensor exhibited an excellent and reproducible sensitivity [11–16]. It was examined that the fabricated sensors did not show any significant decrease in Fig. 2. (a) Schematic of the modification of gold electrode with ZnO nanoparticles, ChOx and Nafion for efficient detection of cholesterol; (b) cyclic voltammetric sweep curve for the Nafion/ChOx/ZnO/Au electrode without cholesterol (dotted line) and with 0.1 mM cholesterol (solid line) in 0. 1 M PBS buffer (pH 7.4) in the range of 0.3 to 0.7 V at scan rate of 100 mV/s; (c) amperometric response of the Nafion/ChOx/ZnO/Au electrode with successive addition of cholesterol into 0. 1 M PBS buffer solution (pH 7.4); (d) calibration curve for cholesterol using Nafion/ChOx/ZnO/Au electrode; and (e) the plot of 1/Current vs. 1/Concentration exhibiting a linear relationship with the steady state current and cholesterol concentration. 121 A. Umar et al. / Electrochemistry Communications 11 (2009) 118–121 Table 1 Summary of the key performance parameters of cholesterol biosensor constructed based on ChOx-modified nanomaterials as working electrodes. Electrode materials Sensitivity (lA lM cm2) Detection limit (lM) KMapp (mM) Linear range (lM) Response time (s) Ref. ZnO nanoparticles ZnO nanoporous thin films ZnO nanoparticles + chitosan composite Nanoporous CeO2 film Polypyrrole films Tertraethylortho-silicate 23.7 – 14.1 5.98 15.0 – 0.00037 – 0.125 103 – – 0.500 4.7 2.1 0.223 2.06 9.8 21.2 0.001–0.5 (0.65–10.35) 106 (0.125–7.76) 106 (1.3–10.35) 106 (1.0–8.0) 103 (2.0–10.0) 103 5 15 15 15 – 50 Current work 11 12 9 15 16 the sensitivity for more than 50 days, while storing in an appropriate form when not in use. The long-term storage stability of the sensor was tested for 50 days. The sensitivity retained 91.8% of initial sensitivity up to 50 days which gradually decreases afterwards might be due to the loss of the catalytic activity. 4. Conclusions In conclusion, an ultra-sensitive cholesterol biosensor has been fabricated by modifying the gold electrode with well-crystallized low-temperature grown ZnO nanoparticles. A high reproducible sensitivity of 23.7 lA mM1 cm2, response time less than 5 s and detection limit of 0.37 ± 0.02 nM was found from the fabricated biosensor. A relatively low value of enzyme’s kinetic parameter (Michaelis– Menten constant) 4.7 mM has been obtained which indicates the enhanced enzymatic affinity to ChOx to Cholesterol. To the best of our knowledge, this is the first time such a very high-sensitivity and low detection limit has been achieved for cholesterol biosensors by using ZnO nanostructures modified electrodes. Hence, one can concluded that due to the simple synthesis and electrode fabrication, ultra-sensitivity, low detection limit, and fast response, the as-grown well-crystallized ZnO nanoparticles opens a way for the fabrication of highly efficient cholesterol biosensors. Acknowledgements This work was supported by the Korea Science and Engineering Foundation grant funded by Korea Government (MEST) (No. R01-2006-000-11306-0). Author wish to thank Mr. T.S. Bae and J.C. Lim, KBSI, Jeonju branch, and Mr. Kang, Centre for University Facility for taking good quality SEM and TEM images, respectively. References [1] N.B. Myant, The Biology of Cholesterol and Related Steroids, Willium Heinemann, London, 1981. [2] D.S. Fredrickson, R.I. Levy, in: J.B. Wyngarden, D.D. Fredrickson (Eds.), The Metabolic Basis of Inherited Disease, McGraw-Hill, New York, 1972, p. 545. [3] M. Nauck, Clin. Chem. 43 (1997) 1622. [4] M. Nauck, W. Marz, H. Wieland, Clin. Chem. 46 (2000) 436. [5] A. Umar, M.M. Rahman, S.H. Kim, Y.B. Hahn, Chem. Commun. (2008) 166. [6] X. Tan, M. Li, P. Cai, L. Luo, X. Zou, Ana. Biochem. 337 (2005) 111. [7] A. Umar, M.M. Rahman, S.H. Kim, Y.B. Hahn, J. Nanosci. Nanotech. 8 (2008) 3216. [8] A. Umar, M.M. Rahman, Y.B. Hahn, Talanta, (2008), doi:10.1016/j.talanta.2008. 09.020. [9] A. Ansari, A. Kaushik, P. Solanki, B. Malhotra, Electrochem. Commun. 10 (2008) 1246. [10] A. Umar, M.M. Rahman, Y.B. Hahn, J. Nanosci. Nanotech, (2009), in press. [11] S. Singh, S. Arya, P. Pandey, B. Malhotra, S. Saha, K. Sreenivas, V. Gupta, App. Phys. Lett. 91 (2007) 63901. [12] R. Khan, A. Kaushik, P. Solanki, A. Ansari, M. Pandey, B. Malhotra, Anal. Chim. Acta 616 (2008) 207. [13] W. Lili, W. Youshi, S. Yuanchang, W. Huiying, Rare Metal. 25 (2006) 68. [14] Y.H. Ni, X.W. Wei, J.M. Hong, Y. Ye, Mater. Sci. Eng. B 121 (2005) 42. [15] S. Singh, A. Chaubey, B.D. Malhotra, Anal. Chim. Acta 502 (2004) 229. [16] A. Kumar, R. Malhotra, B.D. Malhotra, S.K. Grover, Anal. Chim. Acta 414 (2000) 43. [17] S. Carrara, V.V. Shumyantseva, A.I. Archakov, B. Samorı, Biosens. Bioelect. 24 (2008) 148.