Combustion-derived nanoparticles: A review of their toxicology following inhalation exposure

Donaldson, Ken; Tran, Lang; Jiménez, Luis A.; Duffin, Rodger; Newby, David E.; Mills, Nicholas L; MacNee, William; Stone, Vicki

doi:10.1186/1743-8977-2-10

Cited by 742 publications

(285 citation statements)

References 129 publications

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“…UNP workplaces showed the highest concentration for all measured metrics, which differed significantly compared to those at LAB and ENP. Welding is a well-known source of nanoparticles, and welding fumes could lead to adverse health effects (Yoon et al, 2003;Donaldson et al, 2005). Smelting showed the highest nanoparticle concentration (CPC: 50,826 particles cm -3 ) in this study.…”

Section: Discussionsupporting

confidence: 46%

Comparison of Nanoparticle Exposure Levels Based on Facility Type—Small-Scale Laboratories, Large-Scale Manufacturing Workplaces, and Unintended Nanoparticle-Emitting Workplaces

Ham

Kim

Lee

et al. 2015

Aerosol Air Qual. Res.

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The aims of this study were to investigate the concentrations and characteristics of nanoparticle exposure at various workplaces. We compared the concentration and characteristics of nanoparticles at nine workplaces of three types; i.e., small laboratories (LAB), large-scale engineered nanoparticle manufacturing workplaces (ENP), and unintended nanoparticle-emitting workplaces (UNP), using real-time monitoring devices including scanning mobility particle sizers (SMPS), condensation particle counters (CPC), surface area monitors (SAM), and gravimetric sampling. ANOVA and Scheffe's post hoc tests were performed to compare the concentration based on the type of workplace. The concentrations at UNPs were higher than those at other types of workplace for all measured metrics followed by (in order) ENP manufacturing workplaces and LAB (p < 0.01). Geometric means and geometric standard deviations of LAB, ENP, and UNP for total number concentration measured using SMPS were 8,458 (1.41), 19,612 (2.18), and 84,172 (2.80) particles cm , respectively. The characteristics of exposure and size distributions differed among the workplaces. Some tasks or processes at LAB exhibited higher concentrations than those at ENP or UNP workplaces, and LAB showed the lowest concentration. In conclusion, we observed different exposure characteristics at LAB, ENP, and UNP suggesting that different risk management strategies are required.

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Section: Discussionsupporting

confidence: 46%

Comparison of Nanoparticle Exposure Levels Based on Facility Type—Small-Scale Laboratories, Large-Scale Manufacturing Workplaces, and Unintended Nanoparticle-Emitting Workplaces

Ham

Kim

Lee

et al. 2015

Aerosol Air Qual. Res.

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“…Zinc nutrient element is involved as cofactors in the activation of many enzymes on the biosynthetic pathway of secondary metabolites [8]. Nanotechnology is accurate and controlled manipulation of atomic or molecular structure of materials to produce nanoscale tiny particles with new features and special applications [11]. Nanometals features with more contact area and high surface energy may be totally different from characteristics of base metals [12].…”

mentioning

confidence: 99%

Zinc Sulphate and Nano-Zinc Oxide Effects on Some Physiological Parameters of Rosmarinus officinalis

Mohsenzadeh¹,

Moosavian²

2017

AJPS

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In the present study, the effects of foliar application of zinc sulphate and nano-zinc oxide on physiological indices (chlorophyll and carotenoids content, antioxidant activity, total phenolic content, proline, lipid peroxidation and sugar) of rosemary were evaluated. Greenhouse cultivation experiment in a randomized complete block with three levels of foliar zinc and three levels of foliar nano-zinc oxide and control treatment, each with three replications, was carried out. The results showed that low concentrations of zinc and nano-zinc oxide significantly increased chlorophyll and carotenoid compared to the control. Whereas with the high concentration of nano-zinc oxide, chlorophyll and carotenoid decreased compared to the control. Antioxidant enzymes activity increased with zinc and nano-zinc oxide compared to control plants. In addition, proline, membrane lipid peroxidation, soluble sugar and phenolic compounds increased in the treated plants. Proline and plant antioxidant enzymes to scavenge free radicals have increased. Two levels of zinc increased the total phenolic compounds of rosemary leaves significantly but nano-zinc oxide did not show a significant difference compared to the control.

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“…These hypotheses are based on the scientific literature of particle exposures in animals and humans. This literature has been recently reviewed [Donaldson et al 2005;Maynard and Kuempel 2005;Oberdörster et al 2005a, Donaldson et al 2006Kreyling et al 2006]. In general, the particles used in past studies have not been characterized to the extent recommended for new studies in order to more fully understand the physicochemical properties of the particles that influence toxicity [Oberdörst-er et al 2005b;Thomas et al 2006].…”

Section: Hypotheses From Animal and Epidemiological Studiesmentioning

confidence: 99%

Approaches to safe nanotechnology: managing the health and safety concerns associated with engineered nanomaterials (withdrawn).

2009

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To receive documents or other information about occupational safety and health topics, contact NIOSH at Telephone: 1-800-CDC-INFO (1-800-232-4636) TTY: 1-888-232-6348 E-mail: cdcinfo@cdc.gov or visit the NIOSH Web site at www.cdc.gov/niosh.For a monthly update on news at NIOSH, subscribe to NIOSH eNews by visiting www.cdc.gov/niosh/eNews. No. 2009-125 March 2009 DHHS (NIOSH) Publication Safer • Healthier • People™Approaches to Safe Nanotechnology iii Nanotechnology-the manipulation of matter on a near-atomic scale to produce new structures, materials, and devices-offers the promise of unprecedented scientific advancement for many sectors, such as medicine, consumer products, energy, materials, and manufacturing. Nanotechnology has the power not only to improve existing technologies, but to dramatically enhance the effectiveness of new applications.Research on the potential applications of nanotechnology continues to expand rapidly worldwide. New nanotechnology consumer products emerge at a rate of three to four per week. Over the course of the next decade, nanotechnology could have a $1 trillion impact on the global economy and employ two million workers-half of them residing in the U.S.While nanomaterials present seemingly limitless possibilities, they bring with them new challenges to understanding, predicting, and managing potential safety and health risks to workers. The National Institute for Occupational Safety and Health (NIOSH) remains committed to protecting workers now and in the future, as nanotechnology applications and uses expand.As part of these efforts, in October 2005, NIOSH released for public comment the draft document, Approaches to Safe Nanotechnology: An Information Exchange with NIOSH. Based on feedback received, NIOSH revised and updated the document in July 2006 and sought further public comment. This draft report has been widely cited, and the final version of the report should serve as a vital resource for stakeholders (including occupational safety and health professionals, researchers, policy makers, risk assessors, and workers in the industry) who wish to understand more about the safety and health implications of nanotechnology in the workplace.With the publication of the Approaches to Safe Nanotechnology document, NIOSH hopes to: raise awareness of the occupational safety and health issues involved with nanotechnology; make recommendations on occupational safety and health best practices in the production and use of nanomaterials; facilitate dialogue between NIOSH and its external partners in industry, labor and academia; respond to requests for authoritative safety and health guidelines; and, identify information gaps and areas for future study and research.As our knowledge of nanoscience increases, so too will our efforts to provide valuable guidance on the safe handling of nanoparticles and for protecting the lives and livelihoods of nanotechnology workers.

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Combustion-derived nanoparticles: A review of their toxicology following inhalation exposure

Cited by 742 publications

References 129 publications

Comparison of Nanoparticle Exposure Levels Based on Facility Type—Small-Scale Laboratories, Large-Scale Manufacturing Workplaces, and Unintended Nanoparticle-Emitting Workplaces

Comparison of Nanoparticle Exposure Levels Based on Facility Type—Small-Scale Laboratories, Large-Scale Manufacturing Workplaces, and Unintended Nanoparticle-Emitting Workplaces

Zinc Sulphate and Nano-Zinc Oxide Effects on Some Physiological Parameters of Rosmarinus officinalis

Approaches to safe nanotechnology: managing the health and safety concerns associated with engineered nanomaterials (withdrawn).

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