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http://dx.doi.org/10.5050/KSNVE.2014.24.12.977

Trend of Toxic Nanomaterial Detecting Sensors  

Jang, Kuewhan (Department of Mechanical Engineering, Korea University)
Na, Sungsoo (Department of Mechanical Engineering, Korea University)
Publication Information
Transactions of the Korean Society for Noise and Vibration Engineering / v.24, no.12, 2014 , pp. 977-984 More about this Journal
Abstract
Nanomaterial have grown from scientific interest to commercial products and the nanomaterial market has grown 19.1 % each year. As the nanomaterial market size increases, it is expected that nanomaterial production will increase and its contamination of outdoor environmental system will also increase in the form of industrial waste. Since most of nanomaterials are known as biologically non-degradable materials, nanomaterials will accumulate in the environment, and this will increase the potential threats to human health along the food chain. Recent studies have investigated the toxicity effect of nanomaterials due to their size, chemical composition and shape. For the development of nanomaterial while taking human health into consideration, a nanomaterial detecting sensor is required. In this paper, we have observed the trend of nanomaterial detecting sensor of mechanical, electrochemical, optical and kelvin probe force microscopy sensors and we believe that this trend will shed the light on the development of real-life nanomaterial detecting sensors.
Keywords
Nanomaterial; Toxic; Detection; Mechanical Sensor; Electrochemical Sensor; Optical Sensor; Kelvin Prove Force Microscopy Sensor;
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1 Kim, I. K. and Lee, S., 2011, Nonlinear Dynamic Response of Cantilevered Carbon Nanotube Resonator by Electrostatic Excitation, Transactions of the Korean Society for Noise and Vibration Engineering, Vol. 21, pp. 813-819.   과학기술학회마을   DOI
2 De Volder, M. F. L., Tawfick, S. H., Baughman, R. H. and Hart, A. J., 2013, Carbon Nanotubes: Present and Future Commercial Applications, Science, Vol. 339, pp. 535-539.   DOI   ScienceOn
3 BBC Research, 2013, Nanomaterials in Personalized Medicine: Global Markets, HLC144A.
4 Salamon, A. W., 2013, The Current World of Nanomaterial Characterization: Discussion of Analytical Instruments for Nanomaterial Characterization, Environmental Engineering Science, Vol. 30, pp. 101-108.   DOI
5 Wiesner, M. R., Lowry, G. V., Alvarez, P., Dionysiou, D. and Biswas, P., 2006, Assessing the Risks of Manufactured Nanomaterials, Environmental Science & Technology, Vol. 40, pp. 4336-4345.   DOI   ScienceOn
6 Lam, C.-W., James, J. T., McCluskey, R., Arepalli, S. and Hunter, R. L., 2006, A Review of Carbon Nanotube Toxicity and Assessment of Potential Occupational and Environmental Health Risks, Critical Reviews in Toxicology, Vol. 36, pp. 189-217.   DOI   ScienceOn
7 Ge, C., Li, Y., Yin, J.-J., Liu, Y., Wang, L., Zhao, Y. and Chen, C., 2012, The Contributions of Metal Impurities and Tube Structure to the Toxicity of Carbon Nanotube Materials, NPG Asia Mater, Vol. 4, p. e32.   DOI
8 Donaldson, K. and Poland, C. A., 2009, Nanotoxicology: New Insights Into Nanotubes, Nat Nano, Vol. 4, pp. 708-710.   DOI
9 Aragay, G., Pons, J. and Merkoci, A., 2011, Recent Trends in Macro-, Micro-, and Nanomaterial-Based Tools and Strategies for Heavy-Metal Detection, Chemical Reviews, Vol. 111, pp. 3433-3458.   DOI
10 Maynard, A. D. et al., 2006, Safe Handling of Nanotechnology, Nature, Vol. 444, pp. 267-269.   DOI   ScienceOn
11 Arlett, J. L., Myers, E. B. and Roukes, M. L., 2011, Comparative Aadvantages of Mechanical Biosensors, Nat Nano, Vol. 6, pp. 203-215.   DOI
12 Yang, Y. T., Callegari, C., Feng, X. L., Ekinci, K. L. and Roukes, M. L., 2006, Zeptogram-scale Nanomechanical Mass Sensing, Nano Letters, Vol. 6, pp. 583-586.   DOI   ScienceOn
13 Jang, K., Park, J., Bang, D., Lee, S., You, J., Haam, S. and Na, S., 2013, Highly Sensitive Detection of Self-aggregated Single-walled Carbon Nanotubes Using a DNA-immobilized Resonator, Chemical Communications, Vol. 49, pp. 8635-8637.   DOI
14 Stoney, G. G., 1909, The Tension of Metallic Films Deposited by Electrolysis, Proceedings of the Royal Society of London. Series A, Containing Papers of a Mathematical and Physical Character, Vol. 82, pp. 172-175.
15 Braun, T., Barwich, V., Ghatkesar, M. K., Bredekamp, A. H., Gerber, C., Hegner, M. and Lang, H. P., 2005, Micromechanical Mass Sensors for Biomolecular Detection in a Physiological Environment, Physical Review E, Vol. 72, pp. 031907.   DOI
16 Park, J., Choi, W., Jang, K., and Na, S., 2013, High-sensitivity Detection of Silver Ions Using Oligonucleotide-immobilized Oscillator, Biosensors and Bioelectronics, Vol. 41, pp. 471-476.   DOI
17 Ozel, R. E., Liu, X., Alkasir, R. S. J. and Andreescu, S., 2014, Electrochemical Methods for Nanotoxicity Assessment, TrAC Trends in Analytical Chemistry, Vol. 59, pp. 112-120.   DOI
18 Liu, S.-J., Nie, H.-G., Jiang, J.-H., Shen, G.-L. and Yu, R.-Q., 2009, Electrochemical Sensor for Mercury(II) Based on Conformational Switch Mediated by Interstrand Cooperative Coordination, Analytical Chemistry, Vol. 81, pp. 5724-5730.   DOI
19 Parra, E. J., Blondeau, P., Crespo, G. A. and Rius, F. X., 2011, An Effective Nanostructured Assembly for Ion-selective Electrodes. An Ionophore Covalently Linked to Carbon Nanotubes for Pb2+ determination, Chemical Communications, Vol. 47, pp. 2438-2440.   DOI
20 Wang, L., Li, T., Du, Y., Chen, C., Li, B., Zhou, M. and Dong, S., 2010, Au NPs-enhanced Surface Plasmon Resonance for Sensitive Detection of Mercury(II) Ions, Biosensors and Bioelectronics, Vol. 25, pp. 2622-2626.   DOI
21 Park, J., Lee, S., Jang, K. and Na, S., 2014, Ultra-sensitive Direct Detection of Silver Ions Via Kelvin Probe Force Microscopy, Biosensors and Bioelectronics, Vol. 60, pp. 299-304.   DOI
22 Aragay, G., Pons, J., Ros, J. and Merkoci, A., 2010, Aminopyrazole-based Ligand Induces Gold Nanoparticle Formation and Remains Available for Heavy Metal Ions Sensing, A Simple "Mix and Detect" Approach, Langmuir, Vol. 26, pp. 10165-10170.   DOI
23 Nonnenmacher, M., O'Boyle, M. P. and Wickramasinghe, H. K., 1991, Kelvin Probe Force Microscopy, Applied Physics Letters, Vol. 58, pp. 2921-2923.   DOI
24 Tu, X., Manohar, S., Jagota, A. and Zheng, M., 2009, DNA Sequence Motifs for Structure-specific Recognition and Separation of Carbon Nanotubes, Nature, Vol. 460, pp. 250-253.   DOI   ScienceOn
25 Cui, D., Tian, F., Ozkan, C. S., Wang, M. and Gao, H., 2005, Effect of Single Wall Carbon Nanotubes on Human HEK293 Cells, Toxicology Letters, Vol. 155, pp. 73-85.   DOI   ScienceOn