Dysfunctional copper homeostasis in affects genomic and neuronal stability.

While copper (Cu) is an essential trace element for biological systems due to its redox properties, excess levels may lead to adverse effects partly due to overproduction of reactive species. Thus, a tightly regulated Cu homeostasis is crucial for health. Cu dyshomeostasis and elevated labile Cu levels are associated with oxidative stress and neurodegenerative disorders, but the underlying mechanisms have yet to be fully characterized.

Conceptual basis for the development of guidance for the use of biomarkers of effect in regulatory risk assessment of chemicals.

This Scientific Report was carried out in the context of the self-task mandate (M-2023-00097) of the EFSA's Scientific Committee on 'Guidance on the use of biomarkers of effect in regulatory risk assessment of chemicals'. In the first phase, the project on biomarkers of effect started with a feasibility study (EFSA-Q-2024-00128), with the intention to look closer at definitions and descriptions of biomarkers of effect, as well as to explore several concepts related to the context of application and other scientific principles to be further considered for its development. In addition, relevant activities, initiatives and knowledge in this area were collected and analysed within a complementary mapping study.

Cellular mechanisms of copper neurotoxicity in human, differentiated neurons.

Copper (Cu) is an essential trace element involved in fundamental physiological processes in the human body. Even slight disturbances in the physiological Cu homeostasis are associated with the manifestation of neurodegenerative diseases. While suggesting a crucial role of Cu in the pathogenesis, the exact mechanisms of Cu neurotoxicity involved in the onset and progression of neurological diseases are far from understood.

Risk assessment of complex organoarsenic species in food.

The European Commission asked EFSA for a risk assessment on complex organoarsenic species in food. They are typically found in marine foods and comprise mainly arsenobetaine (AsB), arsenosugars and arsenolipids. For AsB, no reference point (RP) could be derived because of insufficient toxicity data.

The age pigment lipofuscin causes oxidative stress, lysosomal dysfunction, and pyroptotic cell death.

Accumulation of the age pigment lipofuscin represents a ubiquitous hallmark of the aging process. However, our knowledge about cellular effects of lipofuscin accumulation is potentially flawed, because previous research mainly utilized highly artificial methods of lipofuscin generation. In order to address this tremendous problem, we developed a convenient protocol for isolation of authentic lipofuscin from human and equine cardiac tissue in high purity and quantity.