DIRECT-READING METHODS DALAM ANALISIS PAJANAN NANOPARTIKEL PADA PERSONAL BREATHING ZONE (PBZ) DI INDONESIA : SYSTEMATIC LITERATURE REVIEW

Authors

  • Anita Maria Magdalena Silaban Departemen Keselamatan dan Kesehatan Kerja, Fakultas Kesehatan Masyarakat, Universitas Indonesia
  • Mila Tejamaya Departemen Keselamatan dan Kesehatan Kerja, Fakultas Kesehatan Masyarakat, Universitas Indonesia

DOI:

https://doi.org/10.31004/prepotif.v5i2.2001

Keywords:

Measurement of nanoparticles, personal breathong zone (PBZ), direct reading

Abstract

Measurement of nanoparticles in the personal breathing zone (PBZ) is an effort to assess the risk of nanoparticle exposure in the workplace. Can be done with Direct-Reading as a monitor effort. Indonesia, as one of the countries that also participates in the use of nanotechnology, requires a measurement method that is appropriate to its conditions. Methods: this systematic literature review examines direct-reading methods. Result: two types of instruments were found for direct reading. Results: by conducting an assessment in accordance with the conditions of the Indonesian state, this study recommends Condensation particle counter (CPC) as an instrument that can be used

References

Albanese, A., Tang, P.S., & Chan, W. C.W. The effect of nanoparticle size, shape, and surface chemistry on biological systems. Annual Review of Biomedical Engineering. 2012; 14: 1-16.

Asbach, C. et al. Intercomparison of a Personal CPC and Different Conventional CPCs. Aerosol and Air Quality Research. 2017; 17: 1132–1141.

______________. Review of measurement techniques and methods for assessing personal exposure to airborne nanomaterials in workplaces. Science of the Total Environment. 2017; 603-604, 793-806.

Azong-Wara, N. et al. Design and experimental evaluation of a new nanoparticle thermophoretic personal sampler. Journal of Nanoparticle Research. 2013: 15(4).

Bacca, J., Baldiris, S., Fabregat, R., Graf, S., & Kinshuk. Augmented Reality Trends in Education: A Systematic Review of Research and Applications. Educational Technology & Society. 2014; 17 (4): 133–149.

Bakshi, S., He, Z.L., & Harris, W.G. Natural nanoparticles: implication for environment and human health. Environmental Science amd Technology. 2014; 10.1080/10643389.2014.921975.

Bau, S. et al. A laboratory study of the performance of the handheld diffusion size classifier (DiSCmini) for various aerosols in the 15–400 nm range. Environmental Science Processes & Impacts. 2015.

Brouwer, D. et al. From workplace air measurement results toward estimates of exposure? Development of a strategy to assess exposure to manufactured nano-objects. Journal of Nanoparticle Research. 2009;11(8): 1867-1881.

Brouwer, D.H. et al. Workplace air measurements and likelihood of exposure to manufactured nano-objects, agglomerates, and aggregates. Journal of Nanoparticle Research. 2013; 15(11).

Buonanno, G., Stabile, L., & Morawska, L. Personal exposure to ultrafine particles: The influence of time-activity patterns. Science of the Total Environment. 2014; 468-469: 903-907.

Cena, L.G., Anthony, R.T., & Peters, T.M. A personal nanoparticle respiratory deposition (NRD) sampler. Environmental Science & Technology. 2011; 45: 6483-6490.

Chiu, Y., Leong, K., & Chang, L. CPC and SMPS Systems of Monitoring Airborne Nanoparticles-Theory and Experiment. Applied Mechanics and Materials. 2012; 101-102: 60-66.

Duarte, K. et al. Direct-reading methods for analysis of volatile organic compounds and nanoparticles in workplace air. TrAC - Trends in Analytical Chemistry. 2014; 53: 21-32.

Elmes, M & Gasparon, M. Sampling and single particle analysis for the chemical characterization of fine atmospheric particulates: A review. Journal of Environmental Management. 2017; 202: 137-150.

European Agency for Safety and Health at Work. Literture Review: workplace exposure to nanoparticles. 2009.

Faure, B. et al. Assessment of personal exposure to airborne nanomaterials: Evaluation of a novel sampler. Journal of Physics: Conference Series. 2017; 838.

Fierro, M. Particulate matter; 2000. Tersedia dari: file:///L|/Air_updates/particulate matter-singspace.htm.

Fierz, M. et al. Design, Calibration, and Field Performance of a Miniature Diffusion Size Classifier. Aerosol Science and Technology. 2011; 45(1): 1-10.

Furuuchi, M. et al. Development of a personal sampler for evaluating exposure to ultrafine particles. Aerosol and Air Quality Research. 2010; 10(1): 30-37.

Haryanto, A. et al. Kondisi terkini penerapan nanoteknologi pada industri di Indonesia. Prosiding Pertemuan Ilmiah Ilmu Pengetahuan dan Teknologi Bahan 2008; 2008.

Hernández, R., Fernández, F., & Baptista, P. Metodologia de la investigacion, 6th Editio. Mexico: MacGraw-Hill/Interamericana; 2014.

Hubbs, A.F. et al. Nanotechnology: toxicologic pathology, toxicol. Forest Pathology. 2013; 41 (2): 395-409.

Kementerian Perindustrian Republik Indonesia. Rencana strategis kementerian perindustrian tahun 2020-2024; 2020.

Kitchenham, B. Procedure for performing systematic review. Australia: NICTA Technical Report; 2006.

Kuhlbusch, T.A.J. et al. Nanoparticle exposure at nanotechnology workplaces: A review. Particle and Fibre Toxicology. 2011; 8: 1-18.

Lee, J.H. et al. Exposure monitoring of graphene nanoplatelets manufacturing workplaces. Inhalation Toxicology. 2016; 28(6): 281-291.

Leith, D. et al. Development of a transfer function for a personal, thermophoretic nanoparticle sampler. Aerosol Science and Technology, 48(1), 81-89.

Lembaga Ilmu Pengetahuan Indonesia. (2014). Peneliti LIPI Kembangkan Alat Penghasil Nanopartikel. Tersedia dari: http://lipi.go.id/berita/single/Peneliti-LIPI-Kembangkan-Alat-Penghasil-Nanopartikel/9497.

Lespes, G., Faucher, S., & Slaveykova, V. Natural nanoparticles, anthropogenic nanoparticles, where is the frontier? Frontier in Environmental Science. 2020; 8(71): 1-5.

Li, L. et al. A miniature disk electrostatic aerosol classifier (mini-disk EAC) for personal nanoparticle sizers. Journal of Aerosol Science. 2009; 40(11): 982-992.

Majestic, B.J. et al. A review of selected engineered nanoparticles in the atmosphere: Sources, transformations, and techniques for sampling and analysis. International Journal of Occupational and Environmental Health. 2010; 16(4): 488-507.

Modena, M. et al. Nanoparticles characterization: what to measure? Advanced Materials. 2019; 1901556: 1-26. DOI: 10.1002/adma.201901556.

MSP Corporation. Models 100 and 110—MOUDI™ Impactors. MSP Corporation; 2017.

MSP Corporation. Models 100, 110, 115 and 116—MOUDI™ Impactors. MSP Corporation; 2017.

Nanoindex. Assessment of personal exposure to airborne nanomaterials a guidance document. 2016. Tersedia dari: https://nanopartikel.info/wp-content/upload-s/2020/10/NanoIndEx-GuidanceDocument-2016.pdf.

NIOSH. Health effect of occupational exposure to silver nanomaterails. 2021; https://doi.org/10.26616/NIOSHPUB2021112.

Organisation for Economic Co-Operation and Development (OECD). Strategies, techniques and sampling protocols for determining the concentrations of manufactured nanomaterials in air at the workplace. Series on the safety of manufactured nanomaterials. 2017; 82.

Peters, T.M. et al. Assessing and managing exposures to nanomaterials in the workplace. Assessing Nanoparticle Risks to Human Health. 2016; 21-44. http://dx.doi.org/10.1016/B978-0-323-35323-6.00002-5.

Prasetiowati, A.L., Prasetya, A.T., & Wardani, S. Sintesis nanopartikel perak dengan bioreduktor ekstrak daun belimbing wuluh (averrhoa bilimbi l.) Sebagai antibakteri. Indonesian Journal of Chemical Science. 2018; 7(2).

Ramachandran, G. et al. A strategy for assessing workplace exposures to nanomaterials. Journal of Occupational and Environmental Hygiene.2011; 8(11): 673-685.

Sahu, M. & Biswas, P. Size distributions of aerosols in an indoor environment with engineered nanoparticle synthesis reactors operating under different scenarios. Journal of Nanoparticle Research. 2010; 12(3): 1055-1064.

Schulte, P. A. et al. Issues in the development of epidemiologic studies of workers exposed to engineered nanoparticles. Journal of Occupational and Environmental Medicine, 2009; 15(3).

Scientific Committee on Emerging and Newly Identifed Health Risk (SCENIHR). The appropriateness of existing methodologies to assess the potential risks associated with engineered and adventitious products of nanotechnologies. 2006.

Stebounova, L. et al. Particle concentration in occupational settings measured with a nanoparticle respiratory deposition (NRD) sampler. Annals of Work Exposure and Health. 2018; 10: 1-12.

Todea, A.M. et al. Inter-comparison of personal monitors for nanoparticles exposure at workplaces and in the environment. Science of the Total Environment.2017; 605-606: 929-945.

Torres-Carrion, P.V., Rodriguez, G.R., & González, C.S.G. Metodology for systematic liteature review applied to engineering and education. 2018. Tersedia dari: https://www.researchg-ate.net/publication/323277902.

Tritscher, T. et al. NanoScan SMPS-A novel, portable nanoparticle sizing and counting instrument. Journal of Physics: Conference Series.2013; 429(1).

TSI. Optical particle sizer spectrometer (OPC) model 3330. TSI Incorporated. 2013.

______________. Condensation Particle Counter (CPC) model 3772/3771. TSI Incorporated. 2015.

Vance, M.E. et al. Nanotechnology in the real world: redeveloping the nanomaterial consumer products inventory. Beilstein Journal of Nanotechnology. 2015; 6: 1769-1780.

Viitanen, A.K. et al. Workplace Measurements of Ultrafine Particles—A Literature Review. Annals of Work Exposures and Health. 2017; 61(7): 749–758.

Wang, J. et al. Emission measurement and safety assessment for the production process of silicon nanoparticles in a pilot-scale facility. Journal of Nanoparticle Research. 2012; 14(4).

Wardoyo, A.Y.P. Emisi partikulat kendaraan bermotor dan dampak keseahatan. Malang: UB Press. 2016.

Wiesner, M. R. et al. Assessing the Risks of Manufactured Nanomaterials. Environmental Science & Technology. 2006; 40(14): 4336–4345.

Yu, I.J., Ichihara, G., & Ahn, K. Nanoparticle exposure assessment: methods, sampling techniques, and data analysis. Woodhead Publishing Limited. 2014.

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Published

2023-12-20

How to Cite

Silaban, A. M. M., & Tejamaya, M. (2023). DIRECT-READING METHODS DALAM ANALISIS PAJANAN NANOPARTIKEL PADA PERSONAL BREATHING ZONE (PBZ) DI INDONESIA : SYSTEMATIC LITERATURE REVIEW. PREPOTIF : JURNAL KESEHATAN MASYARAKAT, 5(2), 904–917. https://doi.org/10.31004/prepotif.v5i2.2001