The Scientific Committee on Consumer Safety (SCCS) has recently determined that hydroxyapatite (HAP) in nanoform is safe for use in oral care products, with concentrations up to 29.5% in toothpaste and 10% in mouthwash. New safety showed that HAP nano does not cause genetic mutations, cytotoxicity, or inflammation, and is not significantly taken up by cells. The safety assessment applies only to specific types of HAP nano particles that meet certain criteria, such as rod-shaped particles with specific length-to-width ratios and no surface modifications. The case demonstrates that high-quality in vitro safety data can increase the possibilities of safely marketing nanomaterials.

The European Food Safety Authority (EFSA) recently evaluated silver as a food additive (E 174) and concluded that it cannot confirm its safety. This uncertainty arises from significant gaps in scientific data, particularly regarding the physicochemical properties and potential toxicity of silver particles at the nanoscale. The EC will consider EFSA's opinion when shaping its policy on the use of E 174 as a food additive.

Recent advancements in food packaging that use nanotechnology have the potential to improve food quality and safety by extending freshness, repairing damaged packaging, and informing consumers about spoilage. These innovations also offer sustainability benefits by reducing food waste and providing more environmentally friendly packaging options. However, it is crucial to ensure the safety of nanomaterials in food packaging for human health. A “safe-and-sustainable-by-design” approach can help balance innovation, sustainability, recyclability, and safety in packaging development.

Researchers tested the Prevention through Design (PtD) approach by examining the transition from laboratory-scale to pilot-scale production of Few-Layer Graphene (FLG). Based on PtD principles, they recommended reducing worker exposure to FLG during pilot-scale production through measures like using closed systems, local exhaust ventilation, and semi-automatic storage systems. The use of PtD in this study provides valuable insights on safety measures during scale up of nanomaterial production in similar settings.

Researchers have proposed an approach to create metal-organic frameworks (MOFs) that are designed to be safe and sustainable. The approach categorises the transformations that these materials undergo, helping to prevent the formation of harmful transformation products. MOFs are composed of metal clusters linked to organic compounds, resulting in porous structures that are useful in various applications, including catalysis, energy storage, water treatment, and sensors. By adopting a safe and sustainable approach in their design, the full potential of MOFs can be realised.

The U.S. National Nanotechnology Initiative has updated its Environmental Health and Safety strategy to address ongoing challenges and emerging nanotechnology applications. The strategy emphasises responsible innovation and highlights the need for collaborative actions to address concerns related to the impact of engineered nanomaterials on human health and the environment.

Scientists from the public, private and philanthropic sectors involved in the Nano4EARTH initiative have identified key research directions to maximise the impact of nanotechnology in addressing climate change. They focus on enhancing energy storage, reducing industrial carbon emissions and improving efficiency in industrial processes.

Lipid nanoparticles (LNPs) are a groundbreaking delivery system for mRNA vaccines, such as those used for COVID-19. Now, they are pivotal in developing a range of new vaccines and gene therapies. The European Medicines Agency (EMA) and the European Pharmacopoeia are actively updating guidelines and quality requirements to ensure the safe and effective use of LNP-based medicine.

A recent EU ON opinion highlights the potential of advanced materials to support sustainability goals while acknowledging their human health and environmental risks. The European Commission’s 2024 communication emphasises the need for Safe-and-Sustainable-by-Design (SSbD) principles to ensure safety and sustainability.

The degradation of two-dimensional (2D) materials throughout their life cycle can result in the formation of degradation products with different properties and effects on human health and the environment than the original materials.