Occupational Exposure during the Production and the Spray Deposition of Graphene Nanoplatelets-Based Polymeric Coatings

Graphene-based polymer composites are innovative materials which have recently found wide application in many industrial sectors thanks to the combination of their enhanced properties. The production of such materials at the nanoscale and their handling in combination with other materials introduce growing concerns regarding workers’ exposure to nano-sized materials. The present study aims to evaluate the nanomaterials emissions during the work phases required to produce an innovative graphene-based polymer coating made of a water-based polyurethane paint filled with graphene nanoplatelets (GNPs) and deposited via the spray casting technique. For this purpose, a multi-metric exposure measurement strategy was adopted in accordance with the harmonized tiered approach published by the Organization for Economic Co-operation and Development (OECD). As a result, potential GNPs release has been indicated near the operator in a restricted area not involving other workers. The ventilated hood inside the production laboratory guarantees a rapid reduction of particle number concentration levels, limiting the exposure time. Such findings allowed us to identify the work phases of the production process with a high risk of exposure by inhalation to GNPs and to define proper risk mitigation strategies.

[1]  Pinghui Wu,et al.  Design of Ultra-Narrow Band Graphene Refractive Index Sensor , 2022, Sensors.

[2]  Jing Chen,et al.  High sensitivity active adjustable graphene absorber for refractive index sensing applications , 2022, Diamond and related materials.

[3]  U. Vogel,et al.  Towards health-based nano reference values (HNRVs) for occupational exposure: Recommendations from an expert panel , 2022, NanoImpact.

[4]  M. Niang,et al.  Occupational Exposures to Engineered Nanomaterials: a Review of Workplace Exposure Assessment Methods , 2021, Current Environmental Health Reports.

[5]  A. Pelliccioni,et al.  Relationship between Indoor High Frequency Size Distribution of Ultrafine Particles and Their Metrics in a University Site , 2021, Sustainability.

[6]  A. E. Del Río Castillo,et al.  An integrated and multi-technique approach to characterize airborne graphene flakes in the workplace during production phases. , 2021, Nanoscale.

[7]  S. Sabella,et al.  Occupational exposure to graphene and silica nanoparticles. Part II: pilot study to identify a panel of sensitive biomarkers of genotoxic, oxidative and inflammatory effects on suitable biological matrices , 2020, Nanotoxicology.

[8]  A. Pelliccioni,et al.  Development and validation of an intra-calibration procedure for MiniDISCs measuring ultrafine particles in multi-spatial indoor environments , 2020 .

[9]  S. Russo,et al.  Graphene coated fabrics by ultrasonic spray coating for wearable electronics and smart textiles , 2020, Journal of Physics: Materials.

[10]  Weidong He,et al.  Aerodynamic property and filtration evaluation of airborne graphene nanoplatelets with plate-like shape and folded structure , 2020, Separation and Purification Technology.

[11]  S. Sabella,et al.  Occupational exposure to graphene and silica nanoparticles. Part I: workplace measurements and samplings , 2020, Nanotoxicology.

[12]  M. S. Sarto,et al.  Workers’ Exposure Assessment during the Production of Graphene Nanoplatelets in R&D Laboratory , 2020, Nanomaterials.

[13]  Maria Sabrina Sarto,et al.  Flexible Ecoflex®/Graphene Nanoplatelet Foams for Highly Sensitive Low-Pressure Sensors , 2020, Sensors.

[14]  M. S. Sarto,et al.  Development and Characterization of a Piezoresistive Polyurethane/GNP Coating for Strain Sensing Applications , 2020, 2020 IEEE 20th International Conference on Nanotechnology (IEEE-NANO).

[15]  J. Pagels,et al.  Emissions and exposures of graphene nanomaterials, titanium dioxide nanofibers, and nanoparticles during down-stream industrial handling , 2020, Journal of Exposure Science & Environmental Epidemiology.

[16]  Heon-Jin Choi,et al.  Highly flexible graphene nanoplatelet-polydimethylsiloxane strain sensors with proximity-sensing capability , 2020, Materials Research Express.

[17]  T. Jankowski,et al.  Inhalation exposure to various nanoparticles in work environment—contextual information and results of measurements , 2019, Journal of Nanoparticle Research.

[18]  I. Yu,et al.  Derivation of occupational exposure limits for multi-walled carbon nanotubes and graphene using subchronic inhalation toxicity data and a multi-path particle dosimetry model. , 2019, Toxicology research.

[19]  Bengt Fadeel,et al.  Safety Assessment of Graphene-Based Materials: Focus on Human Health and the Environment. , 2018, ACS nano.

[20]  M. Prato,et al.  Occupational exposure to graphene based nanomaterials: risk assessment. , 2018, Nanoscale.

[21]  Athanassia Athanassiou,et al.  Graphene Nanoplatelets-Based Advanced Materials and Recent Progress in Sustainable Applications , 2018, Applied Sciences.

[22]  Delphine Bard,et al.  Inter-comparison of personal monitors for nanoparticles exposure at workplaces and in the environment. , 2017, The Science of the total environment.

[23]  Tuah Mohammad Haffiz,et al.  Towards wearable pressure sensors using multiwall carbon nanotube/polydimethylsiloxane nanocomposite foams , 2017 .

[24]  Raluca Mihalache,et al.  Occupational exposure limits for manufactured nanomaterials, a systematic review , 2017, Nanotoxicology.

[25]  Maria Sabrina Sarto,et al.  A Flexible and Highly Sensitive Pressure Sensor Based on a PDMS Foam Coated with Graphene Nanoplatelets , 2016, Sensors.

[26]  Christof Asbach,et al.  Silicone sampling tubes can cause drastic artifacts in measurements with aerosol instrumentation based on unipolar diffusion charging , 2016 .

[27]  玛丽亚·塞布丽娜·萨尔托,et al.  Water-based piezoresistive conductive polymeric paint containing graphene for electromagnetic and sensor applications , 2016 .

[28]  Andrea Cattaneo,et al.  Engineered nanomaterials exposure in the production of graphene , 2016 .

[29]  Dhimiter Bello,et al.  Exposure monitoring of graphene nanoplatelets manufacturing workplaces , 2016, Inhalation toxicology.

[30]  Yung-sung Cheng,et al.  Deposition of graphene nanomaterial aerosols in human upper airways , 2016, Journal of occupational and environmental hygiene.

[31]  J. Sunyer,et al.  Field comparison of portable and stationary instruments for outdoor urban air exposure assessments , 2015 .

[32]  P. Schulte,et al.  Perspectives on the design of safer nanomaterials and manufacturing processes , 2015, Journal of Nanoparticle Research.

[33]  M. S. Sarto,et al.  Highly conductive multilayer-graphene paper as a flexible lightweight electromagnetic shield , 2015 .

[34]  M. S. Sarto,et al.  Antimicrobial activity of graphene nanoplatelets against Streptococcus mutans , 2015, 2015 IEEE 15th International Conference on Nanotechnology (IEEE-NANO).

[35]  Wouter Fransman,et al.  Occupational Exposure to Nano-Objects and Their Agglomerates and Aggregates Across Various Life Cycle Stages; A Broad-Scale Exposure Study. , 2015, The Annals of occupational hygiene.

[36]  Zhaohui Zhang,et al.  Development and application of tetrabromobisphenol A imprinted electrochemical sensor based on graphene/carbon nanotubes three-dimensional nanocomposites modified carbon electrode. , 2015, Talanta.

[37]  M. S. Sarto,et al.  Electromagnetic absorbing properties of graphene–polymer composite shields , 2014 .

[38]  Norman Schehl,et al.  Health monitoring of structural composites with embedded carbon nanotube coated glass fiber sensors , 2014 .

[39]  Nemkumar Banthia,et al.  Cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing , 2012 .

[40]  Pieter van Broekhuizen,et al.  Exposure limits for nanoparticles: report of an international workshop on nano reference values. , 2012, The Annals of occupational hygiene.

[41]  Dirk Dahmann,et al.  Comparability of portable nanoparticle exposure monitors. , 2012, The Annals of occupational hygiene.

[42]  M. S. Sarto,et al.  Synthesis, Modeling, and Experimental Characterization of Graphite Nanoplatelet-Based Composites for EMC Applications , 2012, IEEE Transactions on Electromagnetic Compatibility.

[43]  Ken Donaldson,et al.  Graphene-based nanoplatelets: a new risk to the respiratory system as a consequence of their unusual aerodynamic properties. , 2012, ACS nano.

[44]  Laura Hodson,et al.  Harmonization of measurement strategies for exposure to manufactured nano-objects; report of a workshop. , 2012, The Annals of occupational hygiene.

[45]  E. Kuempel,et al.  Occupational exposure to titanium dioxide , 2011 .

[46]  Heinz Burtscher,et al.  Design, Calibration, and Field Performance of a Miniature Diffusion Size Classifier , 2011 .

[47]  Delphine Bard,et al.  From workplace air measurement results toward estimates of exposure? Development of a strategy to assess exposure to manufactured nano-objects , 2009 .

[48]  Charles L Geraci,et al.  National Prevention through Design (PtD) Initiative. , 2008, Journal of safety research.

[49]  D. Taylor,et al.  Human Respiratory Tract Model for Radiological Protection , 1996 .

[50]  Japan ChemSHERPA Titanium dioxide. , 1989, IARC monographs on the evaluation of carcinogenic risks to humans.

[51]  A. Moiseev Conference of the Fourth Committee of the International Commission on Radiological Protection (ICRP) , 1976 .