nanotecnologia e ambiente a.a. 2011-2012. the impact of new nanotechnology products with the...
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Nanotecnologia e Nanotecnologia e ambienteambiente
A.A. 2011-2012A.A. 2011-2012
The impact of new nanotechnology products with the environment are two-faced matter.
Several nanotech are environmentally friend and provide good means for soil remediation, water purification and energy storage.
On the other side, nanotechnology products can be considered a chemical hazard with unknown potential, poorly predictable from the knowledge about the corresponding bulk material.
The Janus-faced nanotechThe Janus-faced nanotech
Chemical hazard.Chemical hazard.
Nanomaterials represent a chemical hazard Nanomaterials represent a chemical hazard unpredictable from known properties of unpredictable from known properties of corresponding bulk materialcorresponding bulk materialOther variable tio be considered are:Other variable tio be considered are:1.1. Poorly controlled increment of productionPoorly controlled increment of production2.2. Poorly known dynamics in the environmental Poorly known dynamics in the environmental
matricesmatrices3.3. Poorly known environmental toxicityPoorly known environmental toxicity
Need for standardizationNeed for standardization
Standardization is recommended for:Standardization is recommended for:
• ProductionProduction• ManipulationManipulation• TransportTransport• Waste dispersionWaste dispersion• NanometrologyNanometrology• Toxicology studies in environmental matricesToxicology studies in environmental matrices
Agencies for nanotech monitoring: Agencies for nanotech monitoring: supernational.supernational.
Organization for Economic Co-operation Organization for Economic Co-operation and Development (OECD: WPN): and Development (OECD: WPN): http://www.oecd.org/http://www.oecd.org/
International Organization for International Organization for Standardization (ISO):Standardization (ISO):
http://www.iso.org/http://www.iso.org/
International Electrotechnical Commission International Electrotechnical Commission (IEC):(IEC):
http://www.iec.ch/http://www.iec.ch/
Environmental Protection Agency (EPA):Environmental Protection Agency (EPA):
http://www.epa.gov/http://www.epa.gov/
National Nanotechnology Initiative (NNI): National Nanotechnology Initiative (NNI): http://www.nano.gov/http://www.nano.gov/
Food and Drug Administration (FDA): Food and Drug Administration (FDA): http://www.fda.gov/http://www.fda.gov/
Agencies for nanotech monitoring: Agencies for nanotech monitoring: USAUSA
Community Research and Development Community Research and Development Information Service (CORDIS)Information Service (CORDIS): :
http://cordis.europa.eu/home_it.htmlhttp://cordis.europa.eu/home_it.html
Scientific Committee on Emerging and Scientific Committee on Emerging and Newly Identified Health Risks (Newly Identified Health Risks (SCENIHR): SCENIHR):
http://http://ec.europa.euec.europa.eu//healthhealth//scientific_committeesscientific_committees//emergingemerging/index_en.htm/index_en.htm
Agencies for nanotech monitoring: Agencies for nanotech monitoring: EUEU
The following list of needed methods for the
International Standardization for Nanotechnologies
Have been discussed by Dr Peter Hatto (Director of Research, IonBond Ltd, Chairman ISO TC 229 and UK NTI/1 Nanotechnologies Standardization committees) at the meeting organized at the Michigan State University (East Lansing, Michigan, USA, 7th February 2007).
Needs of standard methods for Needs of standard methods for NanoparticlesNanoparticles
1. Concentrations in air and water2. Stability, dissolution, aggregation and diffusion rates in the
environment3. Toxicological screening, physical and chemical hazard 4. Risk Assessments on exposure and use5. Environmental Toxicity Assessment for Nanomaterials6. Assessment of Product Degradation and Release of
Nanomaterials from Consumer Products7. Nanomaterial Product Labelling
Needs of standard methods for Needs of standard methods for NanotubesNanotubes
1.Eco-toxicology testing2.Exposure determination (environment and
food contamination)3. Inhalation testing4.Toxicology testing
An algorythm for NPs An algorythm for NPs environmental toxicity environmental toxicity
1.NPs characterization,
experimental plan
2.NPs interaction with
complex environments
3.Dissolution rate, end products
4.Solubility, diffusion
5.Evaluation of toxicity
If yes
Airborne NPs: models for Airborne NPs: models for toxicitytoxicity
SYSTEMSYSTEM TYPETYPE NPs studied NPs studied (exemples)(exemples)
Respiratory cellsRespiratory cells ““in vitro”in vitro” Metals, Metals, fullerenesfullerenes
Lung, rodentsLung, rodents ““in vivo”, experimentalin vivo”, experimental Fullerenes, Fullerenes, particulate particulate
matter (PM)matter (PM)
Brain, blood, Brain, blood, animalsanimals
““in vivo”, experimental in vivo”, experimental (diffusion from lung)(diffusion from lung)
fullerenesfullerenes
Human lungHuman lung ““in vivo”, professional or in vivo”, professional or accidentalaccidental
SWCNTsSWCNTs
Environmental pollution: airborneEnvironmental pollution: airborne
Nanometals permanently aggregate in air (right)….and enter the cells (left)
Nanoparticles in the lungNanoparticles in the lung
Carbon nanoparticles in the macrophages of the lung (mouse)
.
Cozzi E et al. Am J Physiol Heart Circ Physiol 2006;291:H894-H903
Mice lung (©2006 by American Physiological Society): A)normal aspectB) 24 h after exposure to ultrafine particulate matter (PM). Moderate neutrophil infiltration (arrows) and minimal edema, without increased alveolar macrophage and subpleural lymphocyte aggregates.
10 m 10 m
SWCNTs and the human lungSWCNTs and the human lung
Professional exposure to SWCNTs (Single Walled Carbon NanoTubes), Green regions inside the lung tissue show the production of reactive oxygen species.
Source: http://nanotech.dit.ie/nanotoxicology.html
Carbon nanospheres and cytotoxicityCarbon nanospheres and cytotoxicity
Carbon nanospheres CNs, functionalized with fluorescent dye at the surface. Vital staining, fluorescent dye.
Carbon nanospheres in the cells (B) and in the nucleus (C; time- dependent migration). Dissolution occurs, with delivery of the toxic functionalizing dye (a semiconductor or a QD). Dissolution is time-dependent and happens in the nucleus.
Selvi et al. Nano Letters 2008, 8(10): 3182–3188 DOI: 10.1021/nl801503m
““in vitro” models.in vitro” models.ORGANISMORGANISM EFFECTEFFECT TEST NAMETEST NAME
S. typhimurium, Escherichia coli
Genotoxicity, DNA oxidative damage
Ames Assay
Eukaryote, cellEukaryote, cell Genotoxicity, DNA oxidative damage
COMET assayCOMET assay
Eukaryote, cellEukaryote, cell Viability, apoptosisViability, apoptosis Trypan blue dye exclusion,Trypan blue dye exclusion,
MTT uptake test,MTT uptake test,
Apotosis genesApotosis genes
Eukaryote, cellEukaryote, cell Lipid peroxidationLipid peroxidation MDA determination assayMDA determination assay
Eukaryote, cellEukaryote, cell Substrate adhesionSubstrate adhesion Viability, light microscopyViability, light microscopy
Eukaryote, Eukaryote,
““in vitro” in vitro” developing developing
organsorgans
Gene expression, altered Gene expression, altered developmentdevelopment
Ex.: micro organ from Ex.: micro organ from cultured nasal epithelium, cultured nasal epithelium,
embryonic heartembryonic heart
Genotoxicity: Ames Assay in Salmonella typhimurium and Escherichia coli
Kumar et al., 2011. Chemosphere 83: 1124–1132
Toxicity in prokaryotes: eubacteria.Toxicity in prokaryotes: eubacteria.
Toxicity in prokaryotes: eubacteria.Toxicity in prokaryotes: eubacteria.
Damage to the membrane of E.coli exposed to TiO2 nanoparticles (10 mg/l). Cells stained red are damaged.
Toxicity in prokaryotes: cyanobacteriaToxicity in prokaryotes: cyanobacteria
Wang et al. 2011. Environ. Sci. Technol. 45: 6032–6040
““in vitro” cytotoxicity: nanometals. in vitro” cytotoxicity: nanometals.
Comparison of cytotoxic effects of CuO, micro (black) and nano-sized (gray) on A549 cells after 18 h exposure (40 μg/cm2)The percent of non-viable cells was evaluated by trypan blue staining. Means ± SD. ** < 0.05*** <0.01
The COMET assayThe COMET assay
Seriously (H2O2, 300 M) and moderately (nCo, 1 M) damagedDNA.
H2O2Co NPs
Hartung & Sabbioni. 2011. Nanomedicine and Nanobiotechnology, DOI: 10.1002/wnan.153
““in vitro” cell adhesion (Eukaryote)in vitro” cell adhesion (Eukaryote)
Quantification of human dermal fibroblast adhesion and viability on two different polymeric scaffolds (fibers diameter: 800 nm ca). Green: Viable cells Red: dead cells.
Grafahrend et al. 2011. Nature Materials, 10: 67–73. doi:10.1038/nmat2904
Models for aquatic toxicity (fresh Models for aquatic toxicity (fresh and and saltsalt water), invertebrates water), invertebrates
ORGANISMORGANISM Test approved by Test approved by ASTM/EPA/OECD/EU/ISOASTM/EPA/OECD/EU/ISO
Daphnids: D.magna, D. pulex, C.dubiaDaphnids: D.magna, D. pulex, C.dubia ++
Chydorus sphaericusChydorus sphaericus --
Thamnocephalus platyurusThamnocephalus platyurus --
Brachionus calyciflorusBrachionus calyciflorus ++
Hydra attenuataHydra attenuata ++
Elliptio complanataElliptio complanata --
Crustaceans: harpacticoida copepodsCrustaceans: harpacticoida copepods ++
Mytilus edulisMytilus edulis ++
Fluorescently labelled polymeric nanoparticles in the gut of Daphnia magna following ingestion after aqueous exposure.
(Image taken by Dag Altin, BioTrix)
Nanometals and fullerens intake by D.magna.
(Chen et al., 2008 Progress Report: Methodology Development for Manufactured Nanomaterial Bioaccumulation TestEPA Grant Number: R833327)
Models for toxicity in water: DafniaModels for toxicity in water: Dafnia
Mortality of D.pulex exposed to fullerenes and nTiO2 differs in relation with the chemical nature and concentration of the
chemical compound.Klaper et al., Environ. Poll. 2009. 157(4): 1152-1156
Models for aquatic toxicity Models for aquatic toxicity (sediments: fresh- and (sediments: fresh- and saltsalt water) water)
InvertebrateInvertebrate Test approved by international Test approved by international organismsorganisms
Hyalella atzecaHyalella atzeca ++
Lumbriculus variegatusLumbriculus variegatus ++
Leptocheirus plumulosusLeptocheirus plumulosus ++
Algae/PlantAlgae/Plant
Pseudokirchneriella Pseudokirchneriella subcapitatasubcapitata
ProkaryotesProkaryotes
Microcystis aeruginosaMicrocystis aeruginosa ++
Models for soil toxicity: Models for soil toxicity: invertebrates and plantsinvertebrates and plants
ORGANISMORGANISM Test approved by Test approved by ASTM/EPA/OECD/EU/ISOASTM/EPA/OECD/EU/ISO
Eisenia sp.Eisenia sp. ++
Enchytraeus crypticusEnchytraeus crypticus ++
Lumbricus terrestrisLumbricus terrestris --
Porcellio scaberPorcellio scaber --
PLANTSAllium cepa, Hordeum vulgare, Lolium perenne, Phaseolus radiatus,
Solanum lycopersicum, Spinacia oleracea, Triticum aestivum
Effect of nanoZnO on the primary root tip of L.perenne:
A)ControlB)ZnO NPs, 20 nm,
1000 mg/l
Lin & Xing 2008. Environ. Sci. Technol., 42(15): 5580–5585
Models for terrestrial toxicity: plantsModels for terrestrial toxicity: plantsChromosomal aberrations observed in Allium cepa meristematic cells exposed to ZnO NPs.
Sticky chromosomes (A1, B1); binucleated cells (c1); chromosomal break (a2); nuclei with pronucleus (c2).
Metaphase Anaphase Prophase
Anaphase Multipolar Anaphase Interphase
Kumari et al. 2011. Journal of Hazardous Materials. 190: 613–621
X1000’X1000’
X1000’ X1000’
X1000’ X1000’ X1000’
Light microscopy images from Apostain stained tissues (945× magnification) of Lombriculus terrestris exposed to 0 (plates a and c) or 100 mg l− 1 of TiO2 nanoresidues (plates b and d) in water for 7 days distinguishing cuticule (a and b) and intestinal epithelium (c and d). Arrows indicate negative (N) and positive (P) apoptotic responses in stained cells.
(Lapied et al., 2011, Environ. Int. 37(6): 1105–1110)
Models for aquatic toxicity: Models for aquatic toxicity: vertebratevertebrate
The fishes O. mykiss, O.latipes and D.rerio have been studied during exposure to NPs, in natural or experimental conditions.
The developmental effects on the model organism X.laevis, a clawed frog, have been also studied in laboratory conditions.
Nanometals: toxicity in zebrafishNanometals: toxicity in zebrafish
Fully developed zebrafish embryo with accumulated particles of nAg in different areas of the body:i) Retinaii) brain (mesencephalon
cavity)iii) Heartiv) gill archesv) Tail.
(Lee et al., 2007. ACSnano, 1(2):133)
nAg: embryotoxicity in zebrafishnAg: embryotoxicity in zebrafish
(Lee et al., 2007. ACSnano, 1(2):133)
And now, the good news.
Nanotechnologies for soil and Nanotechnologies for soil and groundwater remediationgroundwater remediation
NPsNPs EnvironmentEnvironment Ref.Ref.
amphiphilic amphiphilic polyurethane (APU)polyurethane (APU)
Groundwater and soils Groundwater and soils from polynuclear from polynuclear
aromatic aromatic hydrocarbons.PAHshydrocarbons.PAHs
DOI: 10.1021/es0348997
Nanoscale or emulsified zero-valent
iron (NZVI, EZVI) (NZVI, EZVI)
EPA 542-F-08-009, 2008
http://www.epa.gov/tio/download/remed/542-f-08-009.pdf
bi-metallic nanoscale particles (BNPs)
Au-polymeric nanofoam
Soils from oil, volatile Soils from oil, volatile haromatic haromatic
DOI: 10.1002/cssc.201000410
Nanotechnology for wastewater Nanotechnology for wastewater purificationpurification
NPsNPs PollutantsPollutants
DendrimersDendrimers toxic metal ions, radionuclide and inorganic
anions, delivery vehicles for antimicrobial
Metal nanoparticlesMetal nanoparticles Antimicrobial action, remove As (ZnO NPs)
Zeolite Zeolite nanoparticlesnanoparticles
Remove Cr(III), Ni(II), Zn(II), Cu(II)
and Cd(II). Reverse osmosis for desalination.
Carbon-based nanomaterials
Wide-range applications
Boron nanotubes Desalination
Tiwari et al., 2008 World Applied Sciences Journal 3 (3): 417-433,
Nanotechnology for solar power.Nanotechnology for solar power.Photoactive materials: Semiconductors with appropriate band gap
and high absorption coefficient.1. Inorganic Semiconductors: Si, Ge, CdS, GaAs, CdTe, TiO2,
etc.2. Organic Semiconductors: A. Small molecules: phthalocyanines, porphyrins, etc. B. Conducting polymers: Polythiophenes, polypyrrole,
polyaniline, etc.
Solid-state polymers have lesser problems than liquid ones.Coupling solid-state polymers with C60 improves the performance.
Teketel Y. , Solid-State Photoelectrochemical Solar Energy Conversion Based On Conducting Polymers. ICPC NanoNet 3rd Annual Workshop, May 2011, St.Petersburg, Russia.
Nanotechnology for solar power.Nanotechnology for solar power.
Photoactive materials: Semiconductors with appropriate band gap and high absorption coefficient.
1. Inorganic Semiconductors: Si, Ge, CdS, GaAs, CdTe, TiO2, etc.1. Organic Semiconductors: A. Small molecules: phthalocyanines, porphyrins, etc. B. Conducting polymers: Polythiophenes, polypyrrole, polyaniline, etc.