Risks associated with silver nanoparticles
The risks associated with silver nanoparticles
By the AVICENN team – Last updated August 2022
Hundreds of tons of silver nanoparticles are produced every year in the world for their antibacterial or antifungal properties, despite worrying environmental risks, especially for microorganisms, aquatic flora and fauna1See for example:
– Proteomics reveals multiple effects of titanium dioxide and silver nanoparticles in the metabolism of turbot, Scophthalmus maximus, Araújo MJ et al, Chemosphere, 2022
– The Biological Cost of Antimicrobial Nanosilver Exposure, AzoNano, 30 May 2022 > Whole-lake nanosilver additions reduce northern pike (Esox lucius) growth, Slongo BD et al, Science of The Total Environment, 838(2), 56219, September 2022
– Comparative evaluation on the toxic effect of silver (Ag) and zinc oxide (ZnO) nanoparticles on different trophic levels in aquatic ecosystems: A review, Sibiya A et al, Journal of applied toxicology, 2022
– Nanoparticles disrupt algae, University of Geneva, November 25, 2020(Metabolomics for early detection of stress in freshwater alga Poterioochromonas malhamensis exposed to silver nanoparticles, Liu W et al., Scientific Reports, 10, November 2020)
– How Nanosilver Gets Into Our Freshwater, and What We Need To Do About It, Lauren Hayhusrt, Fisheries Research Biologist, IISD Experimental Lakes Area, April 16, 2020
– Silver Uncontrolled: How nanosilver gets into our fresh water, and what we need to do about it, Lauren Hayhusrt, Fisheries Research Biologist, Experimental Lakes Area, November 29, 2019
– Comparative multi-generation study on long-term effects of pristine and wastewater-borne silver and titanium dioxide nanoparticles on key lifecycle parameters in Daphnia magna, Hartmann S et al, NanoImpact, 14, February 2019
– Phytotoxicity of Silver Nanoparticles to Aquatic Plants, Algae, and Microorganisms, Domingo G et al, Nanomaterials in Plants, Algae and Microorganisms – Concepts and Controversies, volume 2: 143-168, 2019
– France Diplomatie, Silver nanoparticles are toxic to aquatic organisms, October 26, 2018 ; Waterborne exposure of adult zebrafish to silver nanoparticles and to ionic silver results in differential silver accumulation and effects at cellular and molecular levels, Lacave JM et al, Science of The Total Environment, 642: 1209-1220, November 2018
– Accumulation of Silver in Yellow Perch (Perca flavescens) and Northern Pike (Esox lucius) From a Lake Dosed with Nanosilver, Jonathan D. Martin, Paul C. Frost, Holger Hintelmann, Karla Newman, Michael J. Paterson, Lauren Hayhurst, Michael D. Rennie, Margerite A. Xenopoulos, Viviane Yargeau, Chris D. Metcalfe, Environmental Science & Technology, 2018, soil microorganisms2See in particular:
– Destruction of Cell Topography, Morphology, Membrane, Inhibition of Respiration, Biofilm Formation, and Bioactive Molecule Production by Nanoparticles of Ag, ZnO, CuO, TiO2, and Al2O3 toward Beneficial Soil Bacteria, Ahmed B et al, ACS Omega, 5, 14, 7861-7876, 2020
– Effect of silver nanoparticle contaminated biosolids on the soil microbial community, Dias Samarajeewa A et al, NanoImpact, 14, February 2019 Colloidal silver in question, RFJ, November 11, 2021 and health risks (argyrism at high doses3L’argent colloïdal en question, RFJ, 11 novembre 2021 and above all, bacterial resistance).
Risk Assessments
Towards a classification of silver
In 2015, ANSES called for a classification of silver nanoparticles under the European CLP regulation4ANSES recommends limiting the marketing of products containing silver nanoparticles, veillenanos.fr, March 2015 and Assessment of health and environmental risks related to exposure to silver nanoparticles, ANSES, last updated March 2018.
On October 19, 2020, after a long process5 A risk assessment of silver (including its nanoforms) was to be conducted by the Netherlands in 2014 under the ECHA Action Plan (CORAP) due to concerns about the ecotoxicity and environmental fate of silver, particularly in nano form. A 2016 document suggested that the information collected from manufacturers still needed to be completed (see DECISION ON SUBSTANCE EVALUATION PURSUANT TO ARTICLE 46(1) OF REGULATION (EC) NO 1907/2006 For Silver, CAS No 7440-22-4 (EC No 23 1-131-3), ECHA, July 2016).
In 2018, the evaluation of the biocidal use of different forms of silver (including nanocomposite forms) and silver salts was underway, by Sweden, with a view to proposals for harmonized classification and labeling (CLH) of these forms of silver (Cf. SUBSTANCE EVALUATION CONCLUSION and EVALUATION REPORT for Silver EC No. 231-131-3 CAS No. 7440-22-4, November 2018). In 2019, the dedicated page on the ECHA website indicated that a CLH proposal had indeed been formalized in May 2019 by Sweden., the European Chemicals Agency (ECHA) submitted for consultation a proposal for the classification of silver and nano-silver 6Cf. proposal for the classification of silver and nano silver, ECHA, October 2020 with, for the latter, the following values :
- skin sensitization category 1, H317 (may cause skin allergy)
- germ cell mutagenicity category 2, H341 (likely to induce genetic defects)
- reproductive toxicity category 1B, H360FD (may impair fertility, may cause harm to the fetus)
- hazardous to the aquatic environment H400 and H410 (acute and chronic toxicity category 1).
The classification was announced for March 2022 at the latest but was postponed to July 30, 2022 during the review by the Risk Assessment Committee (RAC) of ECHA in early June 2022. It should result in the implementation of protective measures and probably the withdrawal of certain consumer applications (to be specified according to the chosen classification).
Non-approval as a biocide of silver “as a nanomaterial”
In August 2021, the decision not to approve silver “as a nanomaterial” in biocidal products was published in the Official Journal of the European Union (OJEU) for product types 2, 4 and 9.
This decision was taken because of a legal technicality: an industrialist had not applied for an authorization to use nano-silver for biocidal purposes7Indeed, manufacturers sometimes do not file (or withdraw or do not renew) an application for a biocide that does not meet the stricter requirements of the new Biocidal Regulation (or for which they feel the cost will be too high to meet them). – and not because of the (proven) risks of nano silver for health and/or the environment.
Studies on the toxicity of nanosilver
In 2020, a scientific literature review8Cf. Pulmonary toxicity of silver vapours, nanoparticles and fine dusts: A review, Hadrup N et al, Regulatory Toxicology and Pharmacology, 115, August 2020 conducted by Danish researchers showed that some of the inhaled silver nanoparticles end up in the lungs, lymph nodes, liver, kidneys, spleen, ovaries and testicles and lead to lung function failures and lung inflammation. While ions have a greater effect, the toxicity pattern is similar for nanoparticles. Silver has been evaluated as genotoxic based on in vitro and in vivo studies.
In 2021, the U.S. National Institute of Occupational Health (NIOSH) analyzed more than 100 studies on silver nanomaterials9Cf. Health Effects of Occupational Exposure to Silver Nanomaterials, Current Intelligence Bulletin 70, NIOSH, May 2021:
- In human cell studies, silver nanomaterials were associated with toxicity (cell death and DNA damage) that varied with particle size.
- In animals exposed to silver nanomaterials (by inhalation or other routes of exposure), tissue concentrations of silver were elevated in all organs tested and exposure to silver nanomaterials was associated with a decreased lung function, to an inflammation of the lung tissue and to histopathological (microscopic tissue) changes in the liver and kidneys.
In the (relatively few) studies that have compared the effects of exposure to silver at the nanoscale or microscale, nanoscale silver particles are more absorbed and more toxic than microscale particles.
NIOSH also evaluated data from two subchronic (intermediate duration) inhalation studies in rats that showed adverse effects on the lungs and liver (including early pulmonary inflammation and liver bile duct hyperplasia).
In a paper published in June 2021 by Nature nanotechnology, researchers from the University of Pittsburgh (USA) warned against the widespread use of silver nanoparticles in consumer products (washing machines, textiles, paints, …) and insist that the use of silver nanoparticles should be reserved only for health equipment in order to limit bacterial resistance.
In July 2021, silver nanoparticles were identified as one of the four most risky categories of nanoparticles by a team from University College Dublin10Cf. A semiquantitative risk ranking of potential human exposure to engineered nanoparticles (ENPs) in Europe, Li, Y and Cummins, E, Science of the Total Environment, 778, July 2021.
Risk assessment by application area
In the food sector
In 2011, the Institute for a Culture of Industrial Safety (ICSI) conducted a study that analyzed the cost-benefit ratio of using nanoparticles in refrigerators and its findings suggested that“the net benefit of silver nanoparticles in household refrigerators is negative, i.e. the costs exceed the benefits.”
In April 2015, the presence of silver nanoparticles in the additive E174 (used as a silver and decorative coloring for pastries and chocolates) was confirmed. Nevertheless, in December 2015, EFSA considered that “the available information is insufficient to assess the safety of silver as a food additive”11Cf. Scientific opinion on the re-evaluation of silver (E 174) as food additive, EFSA, December 2015, which was confirmed by the SCCS in 2018 in the cosmetic field (see below).
ANSES also reiterated that silver, whether in nanoparticulate form or not, is not included in the list of minerals that can be used for the manufacture of food supplements. Given the presence of nanosilver in food supplements distributed through online trade, the Agency recommended to strengthen consumer information and control of the distribution of these products that could contain nanosilver particles.
An Italian study published in 2021 showed the accumulation and slow elimination of silver nanoparticles in the brain of mice after a low-dose oral administration, associated with effects on glial cells and ultrastructural alterations of the blood-brain barrier12Repeated oral administration of low doses of silver in mice: tissue distribution and effects on central nervous system, Recordati et al, Particle and Fibre Toxicology, 18:23, 2021.
A review of the scientific literature published in March 2022 alerted on the pro-inflammatory potential, in the intestine, of silver nanoparticles, after human oral exposure (generation of oxidative stress, accompanied by mitochondrial dysfunction, interference with transcription factors and cytokine production)13Pro-inflammatory effects of silver nanoparticles in the intestine, Sousa A et al, Archives of Toxicology, 96: 1551-1571, 2022.
In cosmetics
In the cosmetic field, colloidal silver (nano) has been, since 2015, the subject of an evaluation procedure by the European Scientific Committee European Scientific Committee on Consumer Safety (SCCS) . 63 notifications of products containing colloidal silver were made to the Commission and the SCCS issued an opinion in October 2018 reiterating that the data collected did not provide assurance of the safety of nano-silver in cosmetic applications14See in particular:
– OPINION ON Colloidal Silver (nano) – final version, SCCS, October 2018
– OPINION ON Colloidal Silver (nano) – preliminary version, SCCS, February 2018
– Call for data on ingredients of Colloidial silver nano in the framework of Regulation 1223/2009 on Cosmetic products, SCCS, March 2015
– Request for a scientific opinion: Colloidal Silver (nano) CAS No 7440-22-4, EC No 231-131-3, SCCS, date ?
– Minutes of the 5th Plenary Meeting of the Scientific Committee on Consumer Safety (SCCS), October 24-25, 2017: “A request for information and clarification was sent back to Applicants with a deadline by 30 September 2017. Four replies from 3 Applicants have been received and are under assessment.”.
In textiles
Many articles of sportswear appear to be treated with nano silver.
In December 2018, Svenskt Vattens, the Swedish water and wastewater union alerted on antibacterial and anti-odor silver from sports textiles15Cf. Adidas continues to sell clothing treated with toxic silver despite the risk to aquatic environments, Svenskt Vattens, December 17, 2018. It is the largest known source of silver in water treatment plants, a threat to our lakes and seas, and a risk for the spread of antimicrobial resistance. Brands and retailers are asked to stop selling clothing treated with silver to protect water (Adidas was singled out as the worst performer).
In April 2019, the NGO Women’s Voices for the Earth expressed concern about the use of nanosilver in menstrual pads and underwear16Cf. Concerns About Nanosilver in Period Products, Womens voice, April 24, 2019, due to health and environmental risks.
In March 2020 in the United States, several associations challenged the request for authorization from the U.S. Environmental Protection Agency (EPA) of a nanosilver-based product intended to be applied to textiles, in view of the health and environmental risks that it could entail17See Current EPA Proceeding – Docket ID: EPA-HQ-OPP-2020-0043; see in particular:
– Comments on EPA’s Proposed Registration Decision for a New Active Ingredient, NSPW Nanosilver, the International Center for Technology Assessment, the Center for Biological Diversity, and the Institute for Agriculture and Trade Policy, March 30, 2020;
– EPA Ruling Could Allow Controversial Nanoparticles in Pesticides, Bloomberg Environment, March 23, 2020
– Toxic Textiles Infused with Antimicrobial Nanosilver Poised for EPA Pesticide Registration, Beyond Pesticides, March 23, 2020.
In the medical field
Even in the medical field, the use of nanosilver must be better evaluated, as the association Health Care without Harm (HCWM) underlines18Cf. Dorota Napierska, Health Care Without Harm Europe (HCWH), Nanosilver in healthcare – does the silver bullet exist?.
Protection of workers exposed to nano silver
In the same report as above19Cf. Health Effects of Occupational Exposure to Silver Nanomaterials, Current Intelligence Bulletin 70, NIOSH, May 2021, the U.S. National Institute of Occupational Health (NIOSH) established an occupational exposure limit value (OELV) recommendation for silver nanoparticles of 0.9 μg/m3 as an 8-hour weighted average concentration. In addition, NIOSH continues to recommend an OEL of 10 μg/m3 as an 8-hour weighted average concentration for total silver (metal dust, smoke, and soluble compounds, such as Ag). NIOSH also recommends the use of workplace exposure assessments, engineering controls, safe work procedures, training and education, and established medical surveillance procedures to protect workers.
Towards “safer by design” silver nanoparticles?
In August 2020, French researchers announced that they had developed a “safer by design” biocidal nanomaterial that contained an assembly of silver nanoparticles linked together by a bio-inspired molecule. It releases Ag(I) ions in a slow and controlled manner, unlike the silver nanoparticles currently used which undergo uncontrolled processes of transformation and product release20Cf. New “Safer-by-Design” biocides based on silver nanoparticle assemblies, CEA, August 26, 2020.
– In French :
- SyMMES / CIBEST, Chemical transformation of Ag-NP accumulated in human lung cells: modification of speciation and associated toxicity, CEA, March 2022
- France Diplomatie, Silver nanoparticles are toxic to aquatic organisms, October 26, 2018
- Marianne Marchioni, Ecodesign of new biocidal agents based on bio-inspired silver nanoparticles coating, thesis, Grenoble Alpes, October 2018 (chapters 3 and 4 in particular)
- Maxisciences, Les nanoparticules seraient encore plus harmful que l’on pensait, August 2018 (and in English: Co-exposure to silver nanoparticles and cadmium induces metabolic adaptation in HepG2 cells, Miranda RR et al, Nanotoxicology, July 2018)
- Sputnik news, Russian scientists demonstrate toxicity of silver nanoparticles, June 25, 2018
- Isabelle Passagne, Silver nanoparticles: impacts at the level of glutamatergic transmissions and on hormonal regulation of reproductive function, ANSES Scientific Watch Bulletin, n°33, April 2018
- Benjamin Gibert (LBNL, Berkeley, USA), “Spectromicroscopy of silver nanowires and toxicology of future touchpads”, 1st workshop of the International Medical Geology Association (IMGA), March 2018
- Hygiene in the lab, The dangers of antibacterial silver nanoparticles, October 2017
- Vernis L., Effects of silver nanoparticles on bacterial communities, ANSES Science Watch Bulletin, No. 32, October 2017.
- ForumNanoResp, The Uses of Nano-silver and Proceedings of the May 6 session on nano-silver, May 2015 (paragraph on toxic risks and bacterial resistance)
- European Commission, Call for data on colloidal (nano) silver, 25 March – 30 June 2015
- INERIS, Données technico-économiques sur les substances chimiques en France : Argent et Nano-argent, DRC-14-136881-07002A, 44 p., May 2015
- INRS, Nanoargents: from production to use, what are the risks, Hygiène et sécurité du travail, Note technique 24, March 2015
- ANSES, Opinion and report on “the assessment of health and environmental risks related to exposure to silver nanoparticles,” February 2015
- INRS-IAF (Canada), Silver nanoparticles and inflammation – A breakthrough in nanotoxicology by INRS researchers, February 16, 2015
- SCENIHR, Are silver nanoparticles safe? Implications for health, the environment and microbial resistance June 2014
- Salles D. et al, Silver (Ag, nanoAg) as an emerging contaminant in the Gironde estuary: scientific assessments and risk governance, ERS, July/August 2013
- ASEF, Bacteria resist the antimicrobial power of nanoparticles, June 2013
- Futura Sciences: Silver nanoparticles, a threat to ecosystems, January 2013
- Vivagora, CoExNano, Nanosilver and titanium dioxides in coatings: State of knowledge, uncertainties and controversies, November 2010
- Association Toxicologie-Chimie (ATC), Fiche résumé Toxico Ecotoxico chimique Nanoargent, André Picot, July 2010
- HCSP, Recommendation for vigilance on the safety of silver nanoparticles, March 12, 2010
- AFSSET, Risk assessment of nanomaterials for the general population and the environment, March 2010 (part 6.3, “Textiles and silver”)
- CNAM, What decision-making processes to manage the uncertainty of nanosilver impacts, 2009
- Friends of the Earth, NanoSilver: Health and Environmental Risks, synthesis and partial translation of the report “Nano & biocidal Silver” by Friends of the Earth USA and Australia, 2009
– In English:
Publications of academic works (non-exhaustive list):
- Pro-inflammatory effects of silver nanoparticles in the intestine, Sousa A et al, Archives of Toxicology, 96: 1551-1571, 2022
- Exacerbation of Thrombotic Responses to Silver Nanoparticles in Hypertensive Mouse Model, Ferdous Z et al, Oxidative Medicine and Cellular Longevity, 2022
- Toxicity and chemical transformation of silver nanoparticles in A549 lung cells: dose-rate-dependent genotoxic impact, Bobyk L et al.,
Environ. Sci.: Nano
, 8, 806-821, 2021 - Remote effects and biodistribution of pulmonary instilled silver nanoparticles in mice, Ferdous Z et al, NanoImpact, 22, April 2021
- Toxicity and chemical transformation of silver nanoparticles in A549 lung cells: dose-rate-dependent genotoxic impact, Bobyk L et al, Environmental science. Nano, 8 (3) : 806-821, 2021
- A semiquantitative risk ranking of potential human exposure to engineered nanoparticles (ENPs) in Europe, Li, Y and Cummins, E, Science of the Total Environment, 778, July 2021
- Role of bacterial motility in differential resistance mechanisms of silver nanoparticles and silver ions, Stabryla LM et al, Nature Nanotechnology, June 2021: “our findings caution against the ubiquitous use of AgNPs in consumer products (for example, washing machines, textiles and paints) that result in potentially high human and environmental exposures. To limit and not contribute to the growing global resistance challenge, AgNP use should be reserved for those applications necessitating antimicrobial function, such as in the health care sector and for medical devices where resistant bacteria cause life-threatening situations.”
- On the developmental toxicity of silver nanoparticles
Zhang J et al,
Materials & Design
, 203, May 2021 - The longer the worse: a combined proteomic and targeted study of the long-term versus short-term effects of silver nanoparticles on macrophages, Dalzon B et al., Environ. Sci: Nano, 27 2020: repeated exposure to silver nanoparticles (over twenty days) induces more adverse biological effects on mouse macrophages than a single exposure, although less silver is internalized with repeated exposure
- How Nanosilver Gets Into Our Freshwater, and What We Need To Do About It, Lauren Hayhusrt, Fisheries Research Biologist, IISD Experimental Lakes Area, April 16, 2020: Research in a Canadian lake found that silver nanoparticles are found in the liver and gills of fish – still four years after the fish were exposed to nano silver (in 2014-2015). Nano-silver caused a decrease in the appetite and metabolism of the perch, whose numbers declined; see also, published more recently, this scientific article: Multi-Level Responses of Yellow Perch (Perca flavescens) to a Whole-Lake Nanosilver Addition Study, Hayhurst LD et al, Archives of Environmental Contamination and Toxicology (2020) 79:283-297, 2020
- Silver and titanium nanomaterials present in wastewater have toxic effects on crustaceans and fish cells, Norwegian Institute for Water Research (NIVA), November 2019
- The influence of surface coatings of silver nanoparticles on the bioavailability and toxicity to elliptio complanata mussels Auclair J et al, Journal of Nanomaterials, 2019 : Silver nanoparticles harm mussels: high silver levels in freshwater mussels are linked to reduced survival time in air, weight loss during air exposure, and DNA damage.
- Adverse effects of nanosilver on human health and the environment, Rezvani E et al. Acta Biomaterialia, 94: 145-159, 2019
- How reversible are the effects of silver nanoparticles on macrophages? A proteomic-instructed view, Dalzon B., Environ. Sci.: Nano, 2019
- Comparative multi-generation study on long-term effects of pristine and wastewater-borne silver and titanium dioxide nanoparticles on key lifecycle parameters in Daphnia magna, Hartmann S et al, NanoImpact, 14, February 2019
- Waterborne exposure of adult zebrafish to silver nanoparticles and to ionic silver results in differential silver accumulation and effects at cellular and molecular levels, Lacave JM et al, Science of The Total Environment, 642: 1209-1220, November 2018
- Ecotoxicological Effects of Transformed Silver and Titanium Dioxide Nanoparticles in the Effluent from a Lab-Scale Wastewater Treatment System, Georgantzopoulou A et al., About. Sci. Technol., 52, 16, 9431-9441, 2018
- Co-exposure to silver nanoparticles and cadmium induce metabolic adaptation in HepG2 cells, Miranda RR et al, Nanotoxicology, July 2018
- Ecotoxicity of different-shaped silver nanoparticles: Case of zebrafish embryos, Abramenko NB et al, Journal of Hazardous Materials, 347(5), 89-94, April 2018
- Accumulating over time, even low concentrations of silver can foil wastewater treatment, Oregon State University, May 14, 2018
- Fewtrell, L et al, A re-assessment of the safety of silver in household water treatment: rapid systematic review of mammalian in vivo genotoxicity studies, Environmental Health, 2017; see press release here: https: //www.uea.ac.uk/about/-/common-water-treatments-could-damage-dna
- Gunawan C et al, Widespread and Indiscriminate Nanosilver Use: Genuine Potential for Microbial Resistance, ACS Nano, 2017 and Rampant use of antibacterial nanosilver is a resistance risk, Physorg, (press release) March 2017
- Use of a modified GreenScreen tool to conduct a screening-level comparative hazard assessment of conventional silver and two forms of nanosilver, Sass J et al, Environmental Health, 15:105, 2016
- Wang P et al, Silver Nanoparticles Entering Soils via the Wastewater-Sludge-Soil Pathway Pose Low Risk to Plants but Elevated Cl Concentrations Increase Ag Bioavailability, About. Sci. Technol., 50 (15), pp 8274-8281, 2016
- Shin Patchin E. et al, Size-Dependent Deposition, Translocation, and Microglial Activation of Inhaled Silver Nanoparticles in the Rodent Nose and Brain, Environ Health Perspect, 124: 12, December 2016
- Vanhaecke F, Nanoecotoxicology: nanoparticle behavior dissected, Nature Nanotechnology, 11, 656-657, August 2016
- Andrei J et al, Silver nanoparticles impact the functional role of Gammarus roeseli (Crustacea Amphipoda), Environmental Pollution, 208, 608-618, January 2016
- NIOSH (USA), Health Effects of Occupational Exposure to Silver Nanomaterials (Draft), December 2015
- Degger N et al., Silver nanoparticles disrupt regulation of steroidogenesis in fish ovarian cells, Aquat Toxicol., 4;169:143-151, November 2015: this study shows that silver nanoparticles (nAg) can affect specific genes that regulate steroidogenesis, conferring endocrine disruption potential to nAg (cited by the letter RES-Actus n°15, November 2015).
- Yoisungnern T et al, Internalization of silver nanoparticles into mouse spermatozoa results in poor fertilization and compromised embryo development, Scientific Reports, 5, 2015
Silver nanoparticles in the environment
, Jingfu Liu & Guibin Jiang Editors, Springer Berlin Heidelberg, 2015- Hartemann P et al. Nanosilver: Safety, health and environmental effects and role in antimicrobial resistance, Materials Today, 18(3): 122-123, April 2015
- Riebeling C and Kneuer C, Challenges in Human Health Hazard and Risk Assessment of Nanoscale Silver, in
Safety of Nanomaterials along Their Lifecycle: Release, Exposure, and Human Hazards
Wohlleben W et al, CRC Press, 2015 - Silver nanoparticle risks and benefits: Seven things worth knowing, Andrew Maynard, YouTube, 2014
- Pulit-Prociak J et al, Nanosilver products and toxicity, Environmental Chemistry Letters, December 2014
- Huk A et al, Is the toxic potential of nanosilver dependent on its size, Particle and Fibre Toxicology, 11(65 ), December 2014
- Theodorou IG et al, Inhalation of Silver NanomaterialsSeeing the Risks, Int. J. Mol. Sci., 15(12), 23936-23974, December 2014
- Gonzales C., Role of silver nanoparticles (AgNPs) on the cardiovascular system, Archives of Toxicology, December 2014
- Razavian MH and Masaimanesh M, Ingestion of silver nanoparticles leads to changes in blood parameters, Nanomedicine Journal, 1(5): 339-345, Fall 2014
- Ge L et al, Nanosilver particles in medical applications: synthesis, performance, and toxicity, Ge L et al, Int J Nanomedicine, 9: 2399-2407, 2014
- Braakhuis HM et al, Particle size dependent deposition and pulmonary inflammation after short-term inhalation of silver nanoparticles, Particle and Fibre Toxicology, 11:49, 2014
- Carbone S et al, Bioavailability and biological effect of engineered silver nanoparticles in a forest soil, Journal of Hazardous Materials, 280, 89-96, September 2014
- Xu L et al, Toxic responses in rat embryonic cells to silver nanoparticles and released silver ions as analyzed via gene expression profiles and transmission electron microscopy, Nanotoxicology, August 2014
- Dos Santos CA et al, Silver Nanoparticles: Therapeutic Uses, Toxicity, and Safety Issues, Journal of Pharmaceutical Sciences, 2014
- Colman B P et al., Emerging contaminant or an old toxin in disguise? Silver nanoparticle impacts on ecosystems, ES&T, 2014
- Gliga AR et al, Size-dependent cytotoxicity of silver nanoparticles in human lung cells: the role of cellular uptake, agglomeration and Ag release, Particle and Fibre Toxicology, 11:11, 2014
- Tianlu Z. et al, Cytotoxic Potential of Silver Nanoparticles, Yonsei Med J., 55(2):283-291, March 2014
- Chi C. et al, A brief review on toxicity of silver nanoparticles, Chinese Journal of Pharmaceutical Analysis, 33(12): 2025-2033(9), December 2013
- Seltenrich N, Nanosilver: Weighing the Risks and Benefits, Environmental Health Perspectives, 121 (7), July 2013
- Reidy B. et al, Mechanisms of Silver Nanoparticle Release, Transformation and Toxicity: A Critical Review of Current Knowledge and Recommendations for Future Studies and Applications, Materials, 6(6), 2295-2350, June 2013
- Quang Huy Tran et al, Silver nanoparticles: synthesis, properties, toxicology, applications and perspectives, Adv. Nat. Sci: Nanosci. Nanotechnol., 4, May 2013
- Gavanji S., et al, A Review of Destructive Effect of Nano Silver on Human Health, Environment and Animals, IJSRES, 1(9), 2013
- Adverse environmental effects of nanosilver demonstrated under realistic experimental conditions, Duke University, February 2013
- Lowry GV et al, Long term Transformation and Fate of Manufactured Ag Nanoparticles in a Simulated Large Scale Freshwater Emergent Wetland, About. Sci. Technol., 46 (13): 7027-7036, July 2012
- When enough is enough, Foss Hansen S & Baun A, Nature Nanotechnology, 7(7):409-11, July 2012: “The European Commission should be regulating nanosilver, not asking for yet another report on its impact on health and the environment”
- NanoEHS, the database of scientific publications on nanotechnology risks, maintained by the International Council on Nanotechnology (ICON) does not seem to be working anymore
Public or para-public institutions (including health and/or environmental agencies):
- International Institute for Sustainable Development (IISD), Nanosilver: What action needs to be taken to protect Canadians from this emerging contaminant, Policy Brief, October 2020
- NIOSH (USA), Health Effects of Occupational Exposure to Silver Nanomaterials, September 2018.
- European Commission DG Environment News Alert Service, Risk of silver nanoparticles to terrestrial plants is low, but increased by chlorine, 482, 9 February 2017
- European Commission, Call for data on ingredients: Colloidal Silver (nano) – in the framework of Regulation (EC) 1223/2009 on Cosmetic products, 24 March 2015
- European Commission DG Environment News Alert Service, Silver nanoparticles could pose risk to aquatic ecosystems, issue 394, November 2014
- SCENIHR (Europe), Final opinion on the effects of nanosilver on health, the environment and antimicrobial resistance, June 2014
- EPA (USA), EPA Takes Action to Protect Public from an Illegal Nano Silver Pesticide in Food Containers; Cites NJ Company for Selling Food Containers with an Unregistered Pesticide; Warns Large Retailers Not to Sell These Products, press release, March 31, 2014
- SCENIHR (Europe), Preliminary opinion on the health and environmental effects of nanosilver and its role in antimicrobial resistance, December 2013
- ARC (Australia), Resilient Bacteria Adapt to Nanosilver, 29 Oct. 2013
- BfR (Germany), Conference on nanosilver, February 2012
- BfR (Germany), Nanosilver has no place in food, textiles or cosmetics, June 2010
- BfR (Germany), BfR recommends that nano-silver is not used in foods and everyday products, December 2009ONG:
- Coming Clean, Lifting the Nano Veil:A Peek at Nanosilver With GreenScreen®, Fall 2016
- Friends of the Earth (Australia), Nanosilver – Factsheet, September 2014
- NRDC (USA), Court Ruling in NRDC’s Favor Should Limit Pesticide Nanosilver in Textiles, November 2013
- BEUC and ANEC (Europe), Nano – Very small and everywhere, A technological magic silver bullet or a serious safety risk?, June 2012
- Friends of the Earth, Nano-silver policy failure puts public health at risk, September 2011
- Friends of the Earth, Nano & biocidal Silver, 2009
- Luoma S.N, Silver Nanotechnologies and the Environment – Old problems or new challenges?, PEN, 2008
Any questions or comments? This information sheet compiled by AVICENN is intended to be completed and updated. Please feel free to contribute.
Upcoming Nano Agenda
- Advanced Characterization Techniques in Nanomaterials and Nanotechnology
- 10th European Congress on Advanced Nanotechnology and Nanomaterials
- Website: https://nanomaterialsconference.com
- Training intended for occupational physicians, occupational risk prevention specialists (IPRP), company prevention specialists, prevention department staff from Carsat, Cramif and CGSS, institutional prevention specialists (Dreets, Dreal, MSA…).
- Organizer: French National institute of research and security (INRS)
- October 6 to 10, 2025
- Website: www.inrs.fr/…/formation/…JA1030_2025
Sheet originally posted online in May 2018
Notes and references
- 1See for example:
– Proteomics reveals multiple effects of titanium dioxide and silver nanoparticles in the metabolism of turbot, Scophthalmus maximus, Araújo MJ et al, Chemosphere, 2022
– The Biological Cost of Antimicrobial Nanosilver Exposure, AzoNano, 30 May 2022 > Whole-lake nanosilver additions reduce northern pike (Esox lucius) growth, Slongo BD et al, Science of The Total Environment, 838(2), 56219, September 2022
– Comparative evaluation on the toxic effect of silver (Ag) and zinc oxide (ZnO) nanoparticles on different trophic levels in aquatic ecosystems: A review, Sibiya A et al, Journal of applied toxicology, 2022
– Nanoparticles disrupt algae, University of Geneva, November 25, 2020(Metabolomics for early detection of stress in freshwater alga Poterioochromonas malhamensis exposed to silver nanoparticles, Liu W et al., Scientific Reports, 10, November 2020)
– How Nanosilver Gets Into Our Freshwater, and What We Need To Do About It, Lauren Hayhusrt, Fisheries Research Biologist, IISD Experimental Lakes Area, April 16, 2020
– Silver Uncontrolled: How nanosilver gets into our fresh water, and what we need to do about it, Lauren Hayhusrt, Fisheries Research Biologist, Experimental Lakes Area, November 29, 2019
– Comparative multi-generation study on long-term effects of pristine and wastewater-borne silver and titanium dioxide nanoparticles on key lifecycle parameters in Daphnia magna, Hartmann S et al, NanoImpact, 14, February 2019
– Phytotoxicity of Silver Nanoparticles to Aquatic Plants, Algae, and Microorganisms, Domingo G et al, Nanomaterials in Plants, Algae and Microorganisms – Concepts and Controversies, volume 2: 143-168, 2019
– France Diplomatie, Silver nanoparticles are toxic to aquatic organisms, October 26, 2018 ; Waterborne exposure of adult zebrafish to silver nanoparticles and to ionic silver results in differential silver accumulation and effects at cellular and molecular levels, Lacave JM et al, Science of The Total Environment, 642: 1209-1220, November 2018
– Accumulation of Silver in Yellow Perch (Perca flavescens) and Northern Pike (Esox lucius) From a Lake Dosed with Nanosilver, Jonathan D. Martin, Paul C. Frost, Holger Hintelmann, Karla Newman, Michael J. Paterson, Lauren Hayhurst, Michael D. Rennie, Margerite A. Xenopoulos, Viviane Yargeau, Chris D. Metcalfe, Environmental Science & Technology, 2018 - 2See in particular:
– Destruction of Cell Topography, Morphology, Membrane, Inhibition of Respiration, Biofilm Formation, and Bioactive Molecule Production by Nanoparticles of Ag, ZnO, CuO, TiO2, and Al2O3 toward Beneficial Soil Bacteria, Ahmed B et al, ACS Omega, 5, 14, 7861-7876, 2020
– Effect of silver nanoparticle contaminated biosolids on the soil microbial community, Dias Samarajeewa A et al, NanoImpact, 14, February 2019 Colloidal silver in question, RFJ, November 11, 2021 - 3L’argent colloïdal en question, RFJ, 11 novembre 2021
- 4ANSES recommends limiting the marketing of products containing silver nanoparticles, veillenanos.fr, March 2015 and Assessment of health and environmental risks related to exposure to silver nanoparticles, ANSES, last updated March 2018
- 5A risk assessment of silver (including its nanoforms) was to be conducted by the Netherlands in 2014 under the ECHA Action Plan (CORAP) due to concerns about the ecotoxicity and environmental fate of silver, particularly in nano form. A 2016 document suggested that the information collected from manufacturers still needed to be completed (see DECISION ON SUBSTANCE EVALUATION PURSUANT TO ARTICLE 46(1) OF REGULATION (EC) NO 1907/2006 For Silver, CAS No 7440-22-4 (EC No 23 1-131-3), ECHA, July 2016).
In 2018, the evaluation of the biocidal use of different forms of silver (including nanocomposite forms) and silver salts was underway, by Sweden, with a view to proposals for harmonized classification and labeling (CLH) of these forms of silver (Cf. SUBSTANCE EVALUATION CONCLUSION and EVALUATION REPORT for Silver EC No. 231-131-3 CAS No. 7440-22-4, November 2018). In 2019, the dedicated page on the ECHA website indicated that a CLH proposal had indeed been formalized in May 2019 by Sweden. - 6Cf. proposal for the classification of silver and nano silver, ECHA, October 2020
- 7Indeed, manufacturers sometimes do not file (or withdraw or do not renew) an application for a biocide that does not meet the stricter requirements of the new Biocidal Regulation (or for which they feel the cost will be too high to meet them).
- 8Cf. Pulmonary toxicity of silver vapours, nanoparticles and fine dusts: A review, Hadrup N et al, Regulatory Toxicology and Pharmacology, 115, August 2020
- 9Cf. Health Effects of Occupational Exposure to Silver Nanomaterials, Current Intelligence Bulletin 70, NIOSH, May 2021
- 10Cf. A semiquantitative risk ranking of potential human exposure to engineered nanoparticles (ENPs) in Europe, Li, Y and Cummins, E, Science of the Total Environment, 778, July 2021
- 11Cf. Scientific opinion on the re-evaluation of silver (E 174) as food additive, EFSA, December 2015
- 12Repeated oral administration of low doses of silver in mice: tissue distribution and effects on central nervous system, Recordati et al, Particle and Fibre Toxicology, 18:23, 2021
- 13Pro-inflammatory effects of silver nanoparticles in the intestine, Sousa A et al, Archives of Toxicology, 96: 1551-1571, 2022
- 14See in particular:
– OPINION ON Colloidal Silver (nano) – final version, SCCS, October 2018
– OPINION ON Colloidal Silver (nano) – preliminary version, SCCS, February 2018
– Call for data on ingredients of Colloidial silver nano in the framework of Regulation 1223/2009 on Cosmetic products, SCCS, March 2015
– Request for a scientific opinion: Colloidal Silver (nano) CAS No 7440-22-4, EC No 231-131-3, SCCS, date ?
– Minutes of the 5th Plenary Meeting of the Scientific Committee on Consumer Safety (SCCS), October 24-25, 2017: “A request for information and clarification was sent back to Applicants with a deadline by 30 September 2017. Four replies from 3 Applicants have been received and are under assessment.” - 15Cf. Adidas continues to sell clothing treated with toxic silver despite the risk to aquatic environments, Svenskt Vattens, December 17, 2018
- 16Cf. Concerns About Nanosilver in Period Products, Womens voice, April 24, 2019
- 17See Current EPA Proceeding – Docket ID: EPA-HQ-OPP-2020-0043; see in particular:
– Comments on EPA’s Proposed Registration Decision for a New Active Ingredient, NSPW Nanosilver, the International Center for Technology Assessment, the Center for Biological Diversity, and the Institute for Agriculture and Trade Policy, March 30, 2020;
– EPA Ruling Could Allow Controversial Nanoparticles in Pesticides, Bloomberg Environment, March 23, 2020
– Toxic Textiles Infused with Antimicrobial Nanosilver Poised for EPA Pesticide Registration, Beyond Pesticides, March 23, 2020 - 18Cf. Dorota Napierska, Health Care Without Harm Europe (HCWH), Nanosilver in healthcare – does the silver bullet exist?
- 19Cf. Health Effects of Occupational Exposure to Silver Nanomaterials, Current Intelligence Bulletin 70, NIOSH, May 2021
- 20Cf. New “Safer-by-Design” biocides based on silver nanoparticle assemblies, CEA, August 26, 2020