Research and development, where people are exposed to nanomaterials

OBJECTIVES: Many nanomaterials (materials with structures smaller than 100 nm) have chemical, physical and bioactive characteristics of interest for novel applications. Considerable research efforts have been launched in this field. This study aimed to study exposure scenarios commonly encountered in research settings. METHODS: We studied one of the leading Swiss universities and first identified all research units dealing with nanomaterials. After a preliminary evaluation of quantities and process types used, a detailed analysis was conducted in units where more than a few micrograms were used per week. RESULTS: In the investigated laboratories, background levels were usually low and in the range of a few thousand particles per cubic centimeter. Powder applications resulted in concentrations of 10,000 to 100,000 particles/cm(3) when measured inside fume hoods, but there were no or mostly minimal increases in the breathing zone of researchers. Mostly low exposures were observed for activities involving liquid applications. However, centrifugation and lyophilization of nanoparticle-containing solutions resulted in high particle number levels (up to 300,000 particles/cm(3)) in work spaces where researchers did not always wear respiratory protection. No significant increases were found for processes involving nanoparticles bound to surfaces, nor were they found in laboratories that were visualizing properties and structure of small amounts of nanomaterials. CONCLUSIONS: Research activities in modern laboratories equipped with control techniques were associated with minimal releases of nanomaterials into the working space. However, the focus should not only be on processes involving nanopowders but should also be on processes involving nanoparticle-containing liquids, especially if the work involves physical agitation, aerosolization or drying of the liquids.

SiC-Based MIS gas sensor for high water vapor environments

In this work we will prove that SiC-based MIS capacitors can work in environments with extremely high concentrations of water vapor and still be sensitive to hydrogen, CO and hydrocarbons, making these devices suitable for monitoring the exhaust gases of hydrogen or hydrocarbons based fuel cells. Under the harshest conditions (45% of water vapor by volume ratio to nitrogen), Pt/TaOx/SiO2/SiC MIS capacitors are able to detect the presence of 1 ppm of hydrogen, 2 ppm of CO, 100 ppm of ethane or 20 ppm of ethene, concentrations that are far below the legal permissible exposure limits.

Fähigkeit von Kondensationskeimzählern, Nanopartikel mit hydrophober und hydrophiler Oberfläche zu messen

Heute werden Nanopartikel zwar noch in relativ wenigen Produkten eingesetzt und meist kommen die Partikel im Produkt selbst als gebundene Partikel vor. Eine Exposition Endverbrauchers kann nicht ausgeschlossen werden, sie wird aber heute angesichts der geringen Verbreitung als eher unwahrscheinlich betrachtet. Was hingegen heute schon vermehrt vorkommen kann ist eine Exposition eines Arbeiters während des Herstellungs- oder Verarbeitungsprozesses eines Produkts. Auf diesen Bereich muss man daher ein grösseres Augenmerk legen. Um zu bestimmen, ob ein Arbeiter einer Nanopartikel-Exposition ausgesetzt ist, stehen heute verschiedene Messmethoden zur Verfügung. Die meisten Methoden fokussieren sich auf die Messung von Nanopartikel in der Luft, da die Aufnahme von Nanopartikel vor allem über die Atemwege stattfindet. Die heutige Technik erlaubt eine quantitative Ermittlung dieser Konzentration. Da die Technik mit dem Fokus auf Diesel- und Umweltpartikel entwickelt wurde, muss die Vertrauenswürdigkeit dieser Messgeräte für neue Industrie-Partikel mit spezifischen Eigenschaften erneut überprüft werden. Die Effizienz von drei CPC-Messgeräte (Condensation-Particle-Counters) Typen zum Nachweis der Luftkonzentration von Nanopartikel-Pulvern wurde miteinander verglichen. Als Resultat der Studie kann gefolgert werden, dass alle CPCs gleichermassen für die Abschätzung der Nanopartikel-Konzentration an Arbeitsplätzen in der Industrie verwendet werden können. Hierbei spielt es keine wesentliche Rolle, ob das Pulver eine hydrophile oder hydrophobe Oberfläche aufweist. Nur eines der drei hydrophilen Pulvern konnte mit dem Wasser CPC besser nachgewiesen werden als mit den anderen CPC desselben Herstellers.

The multi-facets of sustainable nanotechnology : lessons from a nanosafety symposium

An international symposium for nanosafety was held recently at the Nanyang Technological University in Singapore. Topics relating to understanding nanomaterial properties, tools, and infrastructure required for predicting hazardous outcomes, measuring nanomaterial exposure levels, systems approach for risk assessment and public's perception of nanotechnology were covered. The need for a multidisciplinary approach, across both natural and social sciences, for developing sustainable nanotechnology solutions was heavily emphasized. This commentary highlights the major issues discussed and the commitment of the nanosafety research community in Singapore to contribute collectively to realise the vision of sustainable nanotechnology.

La veille bibliographique. Partie 4, Un élément de surveillance

Voici la quatrième et dernière partie des résultats d'une veille bibliographique sur la surveillance biologique de l'exposition aux produits chimiques en milieu de travail (SBEPCMT) mise en place par un réseau francophone multidisciplinaire.

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Occupational exposures to fungi are very frequent and are known to cause chronic or acute symptoms. To better assess health risks related to fungal exposure, it is crucial to characterize precisely the airborne fungal community in terms of quantity and composition. The objective of this chapter is to synthesize existing knowledge of airborne fungal contamination in various occupational settings. We analyzed 134 papers published between 2000 and 2014 focusing on five different work sectors considered as highly contaminated (i.e., more than 1000 fungal particles/m3): animal confinement buildings, sawmills, waste handling, the food industry, and grain/plant handling. Results show that harvesting grain, washing cheese, and handling salami seem to be the occupational situations with the worst potential for exposure. Moreover, a lack of standardized sampling and analysis methods among countries and even within the same country is highlighted. Occupational exposure limit values do not exist. Recommendations and guidelines based on culture-dependent methods, which are now recognized to underestimate true concentrations, are proposed. Those recommendations are frequently exceeded and protective measures are not always easy to implement.

Respiratory health effects of fifteen years of improved collective protection in a wheat-processing worker population.

INTRODUCTION: Occupational exposure to grain dust causes respiratory symptoms and pathologies. To decrease these effects, major changes have occurred in the grain processing industry in the last twenty years. However, there are no data on the effects of these changes on workers' respiratory health. OBJECTIVES: The aim of this study was to evaluate the respiratory health of grain workers and farmers involved in different steps of the processing industry of wheat, the most frequently used cereal in Europe, fifteen years after major improvements in collective protective equipment due to mechanisation. MATERIALS AND METHOD: Information on estimated personal exposure to wheat dust was collected from 87 workers exposed to wheat dust and from 62 controls. Lung function (FEV1, FVC, and PEF), exhaled nitrogen monoxide (FENO) and respiratory symptoms were assessed after the period of highest exposure to wheat during the year. Linear regression models were used to explore the associations between exposure indices and respiratory effects. RESULTS: Acute symptoms - cough, sneezing, runny nose, scratchy throat - were significantly more frequent in exposed workers than in controls. Increased mean exposure level, increased cumulative exposure and chronic exposure to more than 6 mg.m (-3) of inhaled wheat dust were significantly associated with decreased spirometric parameters, including FEV1 and PEF (40 ml and 123 ml.s (-1) ), FEV1 and FVC (0.4 ml and 0.5 ml per 100 h.mg.m (-3) ), FEV1 and FVC (20 ml and 20 ml per 100 h at >6 mg.m (-3) ). However, no increase in FENO was associated with increased exposure indices. CONCLUSIONS: The lung functions of wheat-related workers are still affected by their cumulative exposure to wheat dust, despite improvements in the use of collective protective equipment.