Nanomaterials and other innovative materials (advanced materials) offer interesting functions and application possibilities. They are therefore increasingly used in new products and in many different industries. However, the possible undesirable consequences also need to be carefully researched and assessed. NanoTrust-Advanced, the 6th phase of the long-term NanoTrust project, which has been running since 2007, plays an important role in this endeavor.
In Europe nanomaterials (NM) and advanced materials (AM) are considered to be so-called “key enabling technologies”, which should guarantee the competitiveness of the European economy for the coming decades. NanoTrust-Advanced examines the safety and risk-relevant aspects of Nanomaterials and advanced materials.
Research results are published regularly in the established NanoTrust dossiers as well as in scientific journals. All current information on the project can be found on the newly designed NanoTrust webpage. The annual NanoTrust conference focuses on different topics.
A bridge between science and politics
Science-based policy advice, in which acquired knowledge serves as the primary starting point for qualified decisions, is of great importance. Since 2016, the NanoTrust team has been identifying possible research topics for the Austrian nano environment, health and safety research program (“Nano-EHS”) for which the Federal Ministry for Climate Action, Environment, Energy, Mobility, Innovation and Technology (BMK) is responsible. This research program represents the implementation of one of the main recommendations of the Austrian Nanotechnology Action Plan (ÖNAP) and is continuously adapted to current developments in this research area.
NanoTrust-Advanced also offers an independent discussion platform for ministries, public authorities and other actors active in nanosafety. This enables the exchange of views in an objective context. The NanoTrust-Advanced project leader André Gazsó is chairing the second term of the Nano Information Commission (NIK) for its duration until 2023, enabling the use of governance instruments developed on the basis of the Austrian Nanotechnology Action Plan for the structured exchange of knowledge and opinions. The team members of NanoTrust-Advanced also contribute to the working group for nano worker protection of the Austrian Workers’ Compensation Board (AUVA) and the standardization group "nanotechnology" of the Austrian standardization institute Austrian Standards. This permanent exchange of knowledge and experience, which takes place on many levels and in numerous committees, contributes to the safe and sustainable development of these new materials.
The project page for the previous NanoTrust phases (until 09/2020) can be found here.
Nanocarriers are innovative delivery and encapsulation systems with different chemical compositions and structures and are classified as advanced materials. They are used in a variety of applications, especially in medicine, cosmetics, and agriculture, as well as in food supplements and household products. Nanocarriers can protect sensitive active ingredients, delay their release, and even enable targeted delivery to the site of action, thereby increasing effectiveness and reducing any side effects. In the scientific literature, the term “nanocarrier” covers not only nanomaterials up to a size of 100 nm according to the definition proposed by the European Commission, but also structures up to 1,000 nm. At present, there is no uniform definition or categorisation of nanocarriers. In this dossier, they are classified on the basis of their origin and chemical composition, and categorised as organic, inorganic, and hybrid systems (material combinations of organic and inorganic materials) as well as supraparticles. To date, there has been little research on how nanocarrier systems behave in the various environmental compartments (soil, water, air). Analytical challenges and the lack of standardised test protocols make comprehensive risk assessments difficult.
Quantum dots (QDs) are increasingly widespread in medicine and environmental research. Because of their specific optical characteristics, QDs can be detected by fluorescence analyses, even in complex media, such as environmental or tissue samples. Their unique properties make them useful for a variety of applications, such as for the use as fluorescent markers for cells, as contrast agents in deep tissue and tumour imaging, in biosensing or photodynamic therapy, and for targeted drug delivery. As a result, QDs could potentially be used as detectable and clearly identifiable “nanotracers” to mark or detect specific targets or to be able to draw general conclusions about the fate of engineered nanoparticles (ENPs) in environmentally relevant media, e.g. in wastewater. QDs mainly consist of metallic semiconductor compounds, such as cadmium selenide (CdSe), cadmium telluride (CdTe), lead sulphide (PbS) or indium phosphide (InP), which can have toxic effects on cells and organisms. Research is therefore being conducted on nontoxic carbonbased QDs, amongst others. QDs are already being used in products, such as TV screens and novel solar cell technologies. However, with an increasing number of applications and thusan increase in production volumes, potential exposure is also intensifying. Consequently, risks to humans and the environment are increasing as accidental release and resulting negative effects cannot be ruled out. To date,however, only limited data exist on possible environmental and health risks.
Quantum dots (QDs) are increasingly widespread in medicine and environmental research. Because of their specific optical characteristics, QDs can be detected by fluorescence analyses, even in complex media, such as environmental or tissue samples. Their unique properties make them useful for a variety of applications, such as for the use as fluorescent markers for cells, as contrast agents in deep tissue and tumour imaging, in biosensing or photodynamic therapy, and for targeted drug delivery. As a result, QDs could potentially be used as detectable and clearly identifiable “nanotracers” to mark or detect specific targets or to be able to draw general conclusions about the fate of engineered nanoparticles (ENPs) in environmentally relevant media, e.g. in wastewater. QDs mainly consist of metallic semiconductor compounds, such as cadmium selenide (CdSe), cadmium telluride (CdTe), lead sulphide (PbS) or indium phosphide (InP), which can have toxic effects on cells and organisms. Research is therefore being conducted on nontoxic carbonbased QDs, amongst others. QDs are already being used in products, such as TV screens and novel solar cell technologies. However, with an increasing number of applications and thusan increase in production volumes, potential exposure is also intensifying. Consequently, risks to humans and the environment are increasing as accidental release and resulting negative effects cannot be ruled out. To date,however, only limited data exist on possible environmental and health risks.
06/2021 - 05/2024
Project NanoTrust (until 09/2020)
The following collection contains links to national and international research institutions on nanotechnology, accompanying research and risk management. It focuses von Austrian organizations working on and providing informations on a variety of risk aspects and risk governance.
Austrian Workers' Compensation Board (dt. AUVA)
Bundesinstitut für Risikobewertung (dt. BfR)
Chamber of Labour (dt. BAK)
Federal Ministry of Labour, Social Affairs and Consumer Protection (dt. BMASK)
Federal Ministry of Health (dt. BMG)
Federal Ministry of Agriculture, Forestry, Environment and Water Management (dt. BMLFUW)
Federal Ministry for Transport, Innovation and Technology (dt. BMVIT)
Federal Ministry of Science and Research (dt. BMWF)
Institute for Technology Assessment and Systems Analysis (dt. ITAS)
The Austrian Research Promotion Agency (dt. FFG)
NanoinformationsPortal (german only)
Austrian Society for Toxicology (dt.+en. ASTOX)
Environmental Agency Austria (dt. UBA)
Austrian Economic Chambers (dt. WKO)
Centre for Technology Assessment (dt. TA-SWISS)