Environmental release of engineered nanomaterials from commercial tiles under standardized abrasion conditions

Journal of Hazardous Materials

Volumn 322, Issue , 2017, Pages 276-283

  Bressot, Christophe ^a   Manier, Nicolas ^a   Pagnoux, Cécile ^b   Aguerre Chariol, Olivier ^a   Morgeneyer, Martin ^c  

^a INSTITUT NATIONAL DE L ENVIRONNEMENT INDUSTRIEL ET DES RISQUES INERIS   (France)

^b CEC   (France)

^c SORBONNE UNIVERSITÉ   (France)

Author keywords

Abrasion; Aerosol emission; Antibacterial; Nanomaterial; Tiles; TiO2

Indexed keywords

ABRASION; NANOSTRUCTURED MATERIALS; OXIDES; TILE; TITANIUM DIOXIDE;

AEROSOL EMISSIONS; ANTIBACTERIAL; DEPOSITION TECHNIQUE; ENGINEERED NANOMATERIALS; ENVIRONMENTAL RELEASE; PRODUCT FORMULATION; SUBMICRONIC PARTICLES; TIO2;

TRIBOLOGY;

NANOCOATING; TITANIUM DIOXIDE NANOPARTICLE; NANOMATERIAL; TITANIUM; TITANIUM DIOXIDE;

AEROSOL; ANTIMICROBIAL ACTIVITY; CERAMICS; COMMERCIALIZATION; EMISSION; EMISSIVITY; INORGANIC COMPOUND; NANOPARTICLE; PARTICLE SIZE;

AEROSOL; ANTIBACTERIAL ACTIVITY; ARTICLE; COMMERCIAL PHENOMENA; CONTROLLED STUDY; ENVIRONMENTAL RELEASE; NANOENGINEERING; PARTICLE SIZE; STANDARD; SURFACE PROPERTY; TEXTILE; VELOCITY; CERAMICS; CHEMISTRY;

CERAMICS; NANOSTRUCTURES; SURFACE PROPERTIES; TITANIUM;

EID: 84994235640     PISSN: 03043894     EISSN: 18733336     Source Type: Journal    
DOI: 10.1016/j.jhazmat.2016.05.039     Document Type: Article

References (62)

1. [1] Mitrano, D.M., Motellier, S., Clavaguera, S., Nowack, B., Review of nanomaterial aging and transformations through the life cycle of nano-enhanced products. Environ. Int. 77 (2015), 132–147.
2. [2] Piccinno, F., Gottschalk, F., Seeger, S., Nowack, B., Industrial production quantities and uses of ten engineered nanomaterials in Europe and the world. J. Nanopart. Res. 14 (2012), 1–11.
3. [3] Chapman, T., Nanoparticles in Anti-microbial Materials: Use and Characterisation. 2012, Royal Society of Chemistry Cambridge, U.K.
4. [4] Nowack, B., Ranville, J.F., Diamond, S., Gallego-Urrea, J.A., Metcalfe, C., Rose, J., Horne, N., Koelmans, A.A., Klaine, S.J., Potential scenarios for nanomaterial release and subsequent alteration in the environment. Environ. Toxicol. Chem./SETAC 31 (2012), 50–59.
5. [5] Kaegi, R., Sinnet, B., Zuleeg, S., Hagendorfer, H., Mueller, E., Vonbank, R., Boller, M., Burkhardt, M., Release of silver nanoparticles from outdoor facades. Environ. Pollut. 158 (2010), 2900–2905.
6. [6] Schlich, K., Klawonn, T., Terytze, K., Hund-Rinke, K., Hazard assessment of a silver nanoparticle in soil applied via sewage sludge. Environ. Sci. Eur., 2013, 1.
7. [7] C.C. Daigle, D.C., Chalupa, F.R., Gibb, P.E., Morrow, G., Oberdorster, M.J., Utell, M.W. Frampton, Ultrafine particle deposition in humans during rest and exercise, 2003.
8. [8] Handy, R.D., Shaw, B.J., Toxic effects of nanoparticles and nanomaterials: implications for public health, risk assessment and the public perception of nanotechnology Health. Risk Soc., 9, 2007, 125.
9. [9] Lapresta-Fernandez, A., Fernandez, A., Blasco, J., Nanoecotoxicity effects of engineered silver and gold nanoparticles in aquatic organisms. Trac-Trend Anal. Chem. 32 (2012), 40–59.
10. [10] Menard, A., Drobne, D., Jemec, A., Ecotoxicity of nanosized TiO2. Review of in vivo data. Environ. Pollut. 159 (2011), 677–684.
11. [11] Kahru, A., Dubourguier, H.C., From ecotoxicology to nanoecotoxicology. Toxicology 269 (2010), 105–119.
12. [12] Maynard, A.D., Aitken, R.J., Butz, T., Colvin, V., Donaldson, K., Oberdorster, G., Philbert, M.A., Ryan, J., Seaton, A., Stone, V., Tinkle, S.S., Tran, L., Walker, N.J., Warheit, D.B., Safe handling of nanotechnology. Nature 444 (2006), 267–269.
13. [13] Clemente, Z., Castro, V.L., Moura, M.A., Jonsson, C.M., Fraceto, L.F., Toxicity assessment of TiO(2) nanoparticles in zebrafish embryos under different exposure conditions. Aquat. Toxicol. 147 (2014), 129–139.
14. [14] Clemente, Z., Castro, V.L., Feitosa, L.O., Lima, R., Jonsson, C.M., Maia, A.H.N., Fraceto, L.F., Fish exposure to nano-TiO2 under different experimental conditions: methodological aspects for nanoecotoxicology investigations. Sci. Total Environ. 463–464 (2013), 647–656.
15. [15] Gunawan, C., Sirimanoonphan, A., Teoh, W.Y., Marquis, C.P., Amal, R., Submicron and nano formulations of titanium dioxide and zinc oxide stimulate unique cellular toxicological responses in the green microalga Chlamydomonas reinhardtii. J. Hazard. Mater. 260 (2013), 984–992.
16. [16] Hong, F., Zhao, X., Si, W., Ze, Y., Wang, L., Zhou, Y., Hong, J., Yu, X., Sheng, L., Liu, D., Xu, B., Zhang, J., Decreased spermatogenesis led to alterations of testis-specific gene expression in male mice following nano-TiO exposure. J. Hazard. Mater. 300 (2015), 718–728.
17. [17] Gao, G., Ze, Y., Zhao, X., Sang, X., Zheng, L., Ze, X., Gui, S., Sheng, L., Sun, Q., Hong, J., Yu, X., Wang, L., Hong, F., Zhang, X., Titanium dioxide nanoparticle-induced testicular damage, spermatogenesis suppression, and gene expression alterations in male mice. J. Hazard. Mater. 258–259 (2013), 133–143.
18. [18] Sheng, L., Wang, L., Sang, X., Zhao, X., Hong, J., Cheng, S., Yu, X., Liu, D., Xu, B., Hu, R., Sun, Q., Cheng, J., Cheng, Z., Gui, S., Hong, F., Nano-sized titanium dioxide-induced splenic toxicity: a biological pathway explored using microarray technology. J. Hazard. Mater. 278 (2014), 180–188.
19. [19] Gui, S., Zhang, Z., Zheng, L., Cui, Y., Liu, X., Li, N., Sang, X., Sun, Q., Gao, G., Cheng, Z., Cheng, J., Wang, L., Tang, M., Hong, F., Molecular mechanism of kidney injury of mice caused by exposure to titanium dioxide nanoparticles. J. Hazard. Mater. 195 (2011), 365–370.
20. [20] Hu, R., Zheng, L., Zhang, T., Gao, G., Cui, Y., Cheng, Z., Cheng, J., Hong, M., Tang, M., Hong, F., Molecular mechanism of hippocampal apoptosis of mice following exposure to titanium dioxide nanoparticles. J. Hazard. Mater. 191 (2011), 32–40.
21. [21] Luo, Z., Wang, Z., Wei, Q., Yan, C., Liu, F., Effects of engineered nano-titanium dioxide on pore surface properties and phosphorus adsorption of sediment: its environmental implications. J. Hazard. Mater. 192 (2011), 1364–1369.
22. [22] Liu, H., Yang, D., Yang, H., Zhang, H., Zhang, W., Fang, Y., Lin, Z., Tian, L., Lin, B., Yan, J., Xi, Z., Comparative study of respiratory tract immune toxicity induced by three sterilisation nanoparticles: silver zinc oxide and titanium dioxide. J. Hazard. Mater. 248-249 (2013), 478–486.
23. [23] Al-Kattan, A., Wichser, A., Vonbank, R., Brunner, S., Ulrich, A., Zuin, S., Arroyo, Y., Golanski, L., Nowack, B., Characterization of materials released into water from paint containing nano-SiO2. Chemosphere 119 (2015), 1314–1321.
24. [24] Labille, J., Feng, J., Botta, C., Borschneck, D., Sammut, M., Cabie, M., Auffan, M., Rose, J., Bottero, J.Y., Aging of TiO(2) nanocomposites used in sunscreen. Dispersion and fate of the degradation products in aqueous environment. Environ. Pollut. 158 (2010), 3482–3489.
25. [25] Shandilya, N., Le Bihan, O., Bressot, C., Morgeneyer, M., Emission of titanium dioxide nanoparticles from building materials to the environment by wear and weather. Environ. Sci. Technol. 49 (2015), 2163–2170.
26. [26] Olofsson, U., Olander, L., Jansson, A., Towards a model for the number of airborne particles generated from a sliding contact. Wear 267 (2009), 2252–2256.
27. [27] Vorbau, M., Hillemann, L., Stintz, M., Method for the characterization of the abrasion induced nanoparticle release into air from surface coatings. J. Aerosol Sci. 40 (2009), 209–217.
28. [28] Stewart, S., Ahmed, R., Rolling contact fatigue of surface coatings—a review. Wear 253 (2002), 1132–1144.
29. [29] Govindarajan, N., Gnanamoorthy, R., Study of damage mechanisms and failure analysis of sintered and hardened steels under rolling-sliding contact conditions. Mater. Sci. Eng. A Struct. 445 (2007), 259–268.
30. [30] Ding, Y., Rieger, N.F., Spalling formation mechanism for gears. Wear 254 (2003), 1307–1317.
31. [31] Wohlleben, W., Brill, S., Meier, M.W., Mertler, M., Cox, G., Hirth, S., von Vacano, B., Strauss, V., Treumann, S., Wiench, K., Ma-Hock, L., Landsiedel, R., On the lifecycle of nanocomposites: comparing released fragments and their In-Vivo hazards from three release mechanisms and four nanocomposites. Small 7 (2011), 2384–2395.
32. [32] Gohler, D., Stintz, M., Hillemann, L., Vorbau, M., Characterization of nanoparticle release from surface coatings by the simulation of a sanding process. Ann. Occup. Hyg. 54 (2010), 615–624.
33. [33] Thio, B.J., Zhou, D., Keller, A.A., Influence of natural organic matter on the aggregation and deposition of titanium dioxide nanoparticles. J. Hazard. Mater. 189 (2011), 556–563.
34. [34] Godwin, H., Nameth, C., Avery, D., Bergeson, L.L., Bernard, D., Beryt, E., Boyes, W., Brown, S., Clippinger, A.J., Cohen, Y., Doa, M., Hendren, C.O., Holden, P., Houck, K., Kane, A.B., Klaessig, F., Kodas, T., Landsiedel, R., Lynch, I., Malloy, T., Miller, M.B., Muller, J., Oberdorster, G., Petersen, E.J., Pleus, R.C., Sayre, P., Stone, V., Sullivan, K.M., Tentschert, J., Wallis, P., Nel, A.E., Nanomaterial categorization for assessing risk potential to facilitate regulatory decision-making. ACS Nano, 2015, 3409–3417.
35. [35] Brouwer, D.H., Lidén, C., Asbach, M.G.M., van Tongeren, M., Chapter 5 ? monitoring and sampling strategy for (Manufactured) nano objects, agglomerates and aggregates (NOAA): potential added value of the NANODEVICE project. Berges, U.V.S.W.v.T.B., (eds.) Handbook of Nanosafety, 2014, Academic Press, San Diego, 173–206.
36. [36] ISO, XP ISO/TS 12901-1 Nanotechnologies—Occupational risk management applied to engineered nanomaterials—Part 1: Principles and approaches, in 2012, pp. 37.
37. [37] Bianchi, C.L., Gatto, S., Pirola, C., Scavini, M., Vitali, S., Capucci, V., Micro-TiO2 as a starting material for new photocatalytic tiles. Cem. Concr. Compos. 36 (2013), 116–120.
38. [38] Kaegi, R., Ulrich, A., Sinnet, B., Vonbank, R., Wichser, A., Zuleeg, S., Simmler, H., Brunner, S., Vonmont, H., Burkhardt, M., Boller, M., Synthetic TiO2 nanoparticle emission from exterior facades into the aquatic environment. Environ. Pollut. 156 (2008), 233–239.
39. [39] Kaiser, J.P., Zuin, S., Wick, P., Is nanotechnology revolutionizing the paint and lacquer industry? A critical opinion. Sci. Total Environ. 442 (2013), 282–289.
40. [40] Hanus, M.J., Harris, A.T., Nanotechnology innovations for the construction industry. Prog. Mater. Sci. 58 (2013), 1056–1102.
41. [41] Synnott, D., Nolan, N., Ryan, D., Colreavy, J., Pillai, S.C., 14—Self-cleaning tiles and glasses for eco-efficient buildings. Diamanti, M.V., Nazari, A., Granqvist, C.G., (eds.) Nanotechnology in Eco-Efficient Construction, 2016, Woodhead Publishing, 2013, 327–342.
42. [42] Fujishima, A., Zhang, X.T., Tryk, D.A., TiO2 photocatalysis and related surface phenomena. Surf. Sci. Rep. 63 (2008), 515–582.
43. [43] Hsu, L.Y., Chein, H.M., Evaluation of nanoparticle emission for TiO2 nanopowder coating materials. J. Nanopart. Res. 9 (2007), 157–163.
44. [44] Froggett, S.J., Clancy, S.F., Boverhof, D.R., Canady, R.A., A review and perspective of existing research on the release of nanomaterials from solid nanocomposites. Part. Fibre Toxicol. 11 (2014), 1–28.
45. [45] Sánchez, E., García-Ten, J., Sanz, V., Moreno, A., Review Porcelain tile: almost 30 years of steady scientific-technological evolution. Ceram. Int. 36 (2010), 831–845.
46. [46] Dondi, M., Ercolani, G., Melandri, C., Mingazzini, C., Marsigli, M., The Chemical Composition of Porcelain Stoneware Tiles and Its Influence on Microstructural and Mechanical Properties, In, Germany. 1999, Verlag Schmid Gmbh, 75–83.
47. [47] Martin-Marquez, J., Rincon, J.M., Romero, M., Effect of firing temperature on sintering of porcelain stoneware tiles. Ceram. Int. 34 (2008), 1867–1873.
48. [48] Warheit, D.B., How to measure hazards/risks following exposures to nanoscale or pigment-grade titanium dioxide particles. Toxicol. Lett. 220 (2013), 193–204.
49. [49] ASTM International, Standard test methods for dry abrasion mar resistance of high gloss coatings ASTM D6037, 1996.
50. [50] ASTM International Standard test method for the abrasion of organic coatings by the Taber abradant ASTM D4060, 2007.
51. [51] ASTM International Standard test method for resistance of transparent plastics to surface abrasion, ASTM D104., 2008.
52. [52] Hassan, M.M., Dylla, H., Mohammad, L.N., Rupnow, T., Evaluation of the durability of titanium dioxide photocatalyst coating for concrete pavement. Constr. Build. Mater. 24:August (8) (2010), 1456–1461.
53. [53] Shandilya, N., Le Bihan, O., Bressot, C., Morgeneyer, M., Evaluation of the particle aerosolization from n-tio2 photocatalytic nanocoatings under abrasion. J. Nanomater., 2014, 185080 (11 pages).
54. [54] Le Bihan, O., Morgeneyer, M., Shandilya, N., Aguerre-Chariol, O., Bressot, C., Handbook on Safe Use of Nanomaterials: Chapter 9.2–Emission Chambers, a Method for Nanosafety. 2014, A.P Elsevier Inc., San Diego, California, USA, 2014.
55. [55] Shandilya, N., Le Bihan, O., Morgeneyer, M., Effect of the normal load on the release of aerosol wear particles during abrasion. Tribol. Lett. 55 (2014), 227–234.
56. [56] R'mili, B., O.L.C. le bihan, C. dutouquet O. aguerre-charriol, E., frejafon, particle sampling by TEM grid filtration. Aerosol Sci. Technol. 47 (2013), 767–775.
57. [57] Schlagenhauf, L., Chu, B.T., Buha, J., Nuesch, F., Wang, J., Release of carbon nanotubes from an epoxy-based nanocomposite during an abrasion process. Environ. Sci. Technol. 46 (2012), 7366–7372.
58. [58] Wohlleben, W., Meier, M.W., Vogel, S., Landsiedel, R., Cox, G., Hirth, S., Tomovic, Z., Elastic CNT-polyurethane nanocomposite: synthesis, performance and assessment of fragments released during use. Nanoscale 5 (2013), 369–380.
59. [59] Shandilya, N., Le Bihan, O., Morgeneyer, M., Effect of the normal load on the release of aerosol wear particles during abrasion. Tribol. Lett. 55 (2014), 227–234.
60. [60] Koponen, I.K., Jensen, K.A., Schneider, T., Sanding dust from nanoparticle-containing paints: physical characterisation. J. Phys. Conf. Ser., 151, 2009, 012048.
61. [61] Gottschalk, F., Nowack, B., The release of engineered nanomaterials to the environment. J. Environ. Monit. 13 (2011), 1145–1155.
62. [62] Manier, N., Bado-Nilles, A., Delalain, P., Aguerre-Chariol, O., Pandard, P., Ecotoxicity of non-aged and aged CeO2 nanomaterials towards freshwater microalgae. Environ. Pollut. 180 (2013), 63–70.