
NanoTrust, a long-term project for the assessment of nanomaterials and advanced materials, has been running since 2007. Now this project is being extended further as ‘NanoTrust-Beyond’ until 2027. NanoTrust-Beyond is intended to continue the tradition of NanoTrust by providing scientific and advisory support for the Austrian model of risk governance in the field of nanotechnologies and advanced materials.
Together with the Federal Ministry of Agriculture and Forestry, Climate and Environmental Protection, Regions and Water Management (BML), the Federal Ministry of Innovation, Mobility and Infrastructure (BMIMI), the Federal Ministry of Labour, Social Affairs, Health, Care and Consumer Protection (BMASGPK) and the Insurance Institution for General Accident (AUVA), a powerful system of various instruments of nano-risk governance has been developed, which is based on the Austrian Nanotechnology Action Plan. In addition to the many aspects of project management, the following two fields of activity can be distinguished:
The main task is to research and process knowledge and the production of orientational and practical knowledge. In particular, NanoTrust provides technically well-founded briefings on the wide range of topics related to nano risk governance, research and development with a focus on both opportunities and risks as well as unintended consequences. The proven policy brief series ‘NanoTrust Dossiers´ will therefore be continued with current topics. In addition, NanoTrust-Beyond will provide an annual status report on ongoing international and national projects in the field of safety research on nanomaterials and advanced materials. The results of the scientific work will also be published in scientific and other specialised media. Finally, the publications database will be continued and made available to the community. A new feature will be the systematic consideration of the save and sustainable by design (SSbD) approach.
The second important task of NanoTrust-Beyond is to contribute to networking within the expert community, both within Austria and internationally. NanoTrust is therefore represented on the Austrian Nano Information Commission of the Ministry of Health and has chaired the Commission since 2013. In addition, the team is hosting an annual conference on a topical issue in the field of nanotechnologies and advanced materials to promote networking among experts. If required, additional smaller workshops on current topics are held. Furthermore, the NanoTrust-Beyond team acts as the Austrian node for various national and international networks and sees it as its task to promote communication in all directions. The project website serves as a hub for information on governance and safety aspects of nanotechnologies 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.
The ‘stealth effect’ refers to a camouflage mechanism that enables bacteria to evade the immune system. In medical research, this phenomenon is utilized to significantly increase both circulation time within the body and precision in targeting disease foci. The primary areas of application lie in targeted tumor therapy, but also include the diagnostics of infectious diseases such as cholera, as well as the treatment of chronic inflammatory bowel diseases. This dossier provides an overview of various natural and synthetic coating methods, many of which are inspired by the model of camouflaged nanoparticles. These include coatings with polymers to increase circulation time in the bloodstream, as well as the use of biomimetic cell membranes that ensure excellent biocompatibility.
Per- and polyfluoroalkyl substances (PFAS) possess remarkable properties that make them attractive for many applications, including non-stick coatings, waterproof clothing, and firefighting foams. However, this is a double-edged sword: their thermal and chemical resistance also means that they do not degrade easily once released into the environment.
Consequently, PFAS are now regularly detected in even the most remote regions of the planet. They are found in blood samples of humans and wildlife, and are associated with a wide range of adverse health outcomes: PFAS have been shown to weaken the immune system, interfere with foetal development,disrupt endocrine function and increase cancer risk.
This NanoTrust Dossier provides an overview of occupational exposure limits for ENMs in Europe. It highlights the challenges in establishing these limits and effectively safeguarding workers in a rapidly evolving field, and presents initiatives to accelerate the toxicity assessment of nanomaterials.
Nano- and microplastics (NMPs) are ubiquitous, persistent, and, as is now widely recognised, a global problem for humans and the environment. Because of the many different types of plastic from which NMPs are derived, conducting a general risk assessment is challenging. In addition, many plastics contain additives such as UV stabilisers or plasticisers that have hormonal effects – so-called endocrine disruptors (EDs) – and can easily be released from the plastics. Furthermore, some endocrine disruptors can strongly adhere to the surface of NMP particles and spread with them throughout the environment.
The effects of endocrine disruptors on humans and the environment remain partially unclear, as they can be very diverse and species-specific, making monitoring difficult. However, a causal link between exposure to endocrine disruptors and various human diseases has now been established. Adverse effects have also been observed in other organisms following exposure to endocrine disruptors, particularly in relation to reproduction.
Even if greener alternatives (e.g. bioplastics) could replace conventional plastics in the future, a significant influx of NMPs into the environment and the use of hormonally active substances can still be expected in the coming decades. Therefore, it is of utmost importance to establish additional test systems to protect human health and the environment, especially at the level of organisms that may facilitate the trophic transfer of EDs into the food chain.
This dossier explores general issues related to NMPs, EDs, and ecotoxicological risk assessment using the aquatic snail Biomphalaria glabrata.
Concluding this three-part series on Engineered Living Materials (ELMs), this dossier builds upon the previously discussed Biogenic Composition Ratio and production methodologies by analysing ELMs through the lens
of material features and hierarchical organisation across length scales. We explore how nano-, micro-, and macrostructural properties emerge from biological components, enabling functionalities such as self-healing and adaptivity. The dossier closes by identifying key challenges – such as vascularisation, scalability, and biosafety – that must be overcome to advance ELMs into practical applications.
This synthesis aims to inspire future research by providing a multidimensional perspective on the design and implementation of ELMs.
Building on the foundations, classifications and future potentials established in the NanoTrust-Dossier 64 ”Engineered Living Materials I”, this dossier explores the ELMs landscape in more detail, introducing the Biogenic Composition Ratio (BCR) as a categorisation scheme and providing an in-depth review of ELMs types ranging from fully biogenic to bioinspired materials. Additionally, production methodologies such as lamination, bioprinting, and electrospinning are discussed in ELMs fabrication. This dossier serves as a transition towards examining ELMs properties across length scales. It addresses the complex challenges inherent in designing and scaling ELMs, which are elaborated upon in the concluding part.
Engineered Living Materials (ELMs) incorporate living organisms in the synthesis process or seamlessly integrate them into conventional technological substrates, giving rise to novel functional materials. The transformative impact of ELMs spans various length scales and domains, such as construction, biomedicine and wearable technology. This impact arises from their exceptional attributes, including self-repair mechanisms, environmental responsiveness and inherent biocompatibility. This NanoTrust Dossier thoroughly examines the current state of ELMs production, offering a comprehensive systematic classification based on various parameters and elucidates recent strides in this dynamic field. Exploring ELMs unveils their scientific intricacies and underscores their potential to revolutionize and redefine material technologies in various applications.
Innovative chemicals and materials, such as advanced materials, are increasingly used in various applications. Advanced materials, like nanomaterials or biopolymers pose new challenges for established safety and risk assessments because of their unique properties, such as their size, shape, and surface characteristics, that distinguish them from conventional materials. In recent years, concepts such as “Safe by Design” (SbD) have been developed for nanomaterials to integrate safety aspects into the early stages of design and development. This concept has been further developed, extended to other advanced materials and chemicals in general, and expanded to include the aspect of sustainability in form of “Safe and Sustainable by Design” (SSbD). In 2022, the European Commission’s Joint Research Centre (JRC) presented a framework for safety and sustainability assessment aimed at helping to achieve the ambitious goals of the European Green Deal and the Chemical Strategy for Sustainability (CSS). The SSbD framework is intended to help companies and organisations assess not only safety but also environmental and socioeconomic sustainability, ensuring these factors are considered when (re)designing chemicals and materials. Application of the SSbD concept is currently voluntary. Because of the concept’s complexity and frequent lack of data, practical implementation remains a significant challenge for manufacturers. To effectively promote adoption of the SSbD concept, particularly amongst small and medium-sized enterprises (SMEs), appropriate framework conditions and additional measures to develop competence, cooperation, coordination, and support are needed.
Zunehmend werden innovative Chemikalien und Materialien, wie Advanced Materials, in den verschiedensten Anwendungsbereichen eingesetzt. Advanced Materials, zu denen zum Beispiel Nanomaterialien oder Biopolymere zählen, stellen die etablierte Sicherheitsund Risikobewertung vor neue Herausforderungen, da sie aufgrund ihrer Größe, Form und Oberflächenbeschaffenheit besondere Eigenschaften aufweisen, die sie von konventionellen Materialien unterscheiden. In den letzten Jahren wurden Konzepte wie z. B. „Safe-byDesign“ für Nanomaterialien entwickelt, um den Sicherheitsaspekt bereits in der frühen Design- bzw. Entwicklungsphase zu integrieren. Dieses Konzept wurde weiterentwickelt, auf andere Advanced Materials und generell auf Chemikalien ausgeweitet sowie um den Aspekt der Nachhaltigkeit zu „Safe-and-Sustainable-by-Design“ (SSbD) erweitert. Ein Rahmenwerk für eine Sicherheits- und Nachhaltigkeitsbewertung wurde im Jahr 2022 vom Joint Research Centre (JRC) der Europäischen Kommission vorgelegt und soll dazu beitragen, die ambitionierten Ziele des europäischen „Green Deal“ und die der „Chemical Strategy for Sustainability“ (CSS) zu erreichen. Das SSbD-Rahmenwerk soll Unternehmen und Organisationen Hilfestellung bieten, nicht nur die Sicherheit, sondern auch die ökologische und sozioökonomische Nachhaltigkeit zu bewerten und diese beim (Re-)Design von Chemikalien und Materialien zu berücksichtigen. Eine Anwendung des SSbD-Konzepts beruht derzeit auf Freiwilligkeit. Die praktische Umsetzung stellt für Hersteller aufgrund der Komplexität und oftmals fehlender Daten eine umfangreiche Aufgabe dar. Geeignete Rahmenbedingungen und zusätzliche Maßnahmen zum Kompetenzaufbau, zur Kooperation und Koordination sowie zur Unterstützung sind notwendig, um eine Umsetzung des SSbDKonzeptes in Unternehmen – insbesondere in kleinen und mittleren Unternehmen (KMUs) – weiterhin zu fördern.
Lettner, G. (Speaker)
Schmitt, J. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker), Bettin, S. (Speaker) & Armbruster, O. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Pavlicek, A. (Speaker), Olscher, C. (Contributor), Part, F. (Contributor), Greßler, S. (Contributor), Prenner, S. (Contributor) & Jung-Waclik, S. (Contributor)
Pavlicek, A. (Speaker), Fuchs, D. (Speaker) & Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
Gazsó, A. (Speaker)
07/2024 - 06/2027
Project NanoTrust-Advanced (until 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)